TMS320DM6435 [TI]
Digital Media Processor; 数字媒体处理器型号: | TMS320DM6435 |
厂家: | TEXAS INSTRUMENTS |
描述: | Digital Media Processor |
文件: | 总252页 (文件大小:2029K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
TMS320DM6435
Digital Media Processor
www.ti.com
SPRS344B–NOVEMBER 2006–REVISED NOVEMBER 2007
1 TMS320DM6435 Digital Media Processor
1.1 Features
[Flexible Allocation]
1M-Bit (128K-Byte) L2 Unified Mapped
RAM/Cache [Flexible Allocation]
•
High-Performance Digital Media Processor
(DM6435)
–
–
–
–
–
–
–
2.5-, 2.-, 1.67-ns Instruction Cycle Time
400-, 500-, 600-MHz C64x+™ Clock Rate
Eight 32-Bit C64x+ Instructions/Cycle
3200, 4000, 4800 MIPS
Fully Software-Compatible With C64x
Commercial and Automotive (Q or S suffix)
Grades
•
•
Supports Little Endian Mode Only
Video Processing Subsystem (VPSS), VPFE
Only
– Front End Provides:
•
•
CCD and CMOS Imager Interface
BT.601/BT.656 Digital YCbCr 4:2:2
(8-/16-Bit) Interface
•
VelociTI.2™ Extensions to VelociTI™
Advanced Very-Long-Instruction-Word (VLIW)
TMS320C64x+™ DSP Core
•
•
Preview Engine for Real-Time Image
Processing
Glueless Interface to Common Video
Decoders
–
Eight Highly Independent Functional Units
With VelociTI.2 Extensions:
•
•
Histogram Module
Auto-Exposure, Auto-White Balance and
Auto-Focus Module
•
Six ALUs (32-/40-Bit), Each Supports
Single 32-Bit, Dual 16-Bit, or Quad 8-Bit
Arithmetic per Clock Cycle
•
Two Multipliers Support Four 16 x 16-Bit
Multiplies (32-Bit Results) per Clock
Cycle or Eight 8 x 8-Bit Multiplies (16-Bit
Results) per Clock Cycle
•
Resize Engine
–
–
Resize Images From 1/4x to 4x
Separate Horizontal/Vertical Control
•
External Memory Interfaces (EMIFs)
–
Load-Store Architecture With Non-Aligned
Support
64 32-Bit General-Purpose Registers
Instruction Packing Reduces Code Size
All Instructions Conditional
Additional C64x+™ Enhancements
•
•
–
32-Bit DDR2 SDRAM Memory Controller
With 256M-Byte Address Space (1.8-V I/O)
•
–
–
–
–
Supports up to 333-MHz (data rate) bus
and interfaces to DDR2-400 SDRAM
–
Asynchronous 8-Bit Wide EMIF (EMIFA)
With up to 64M-Byte Address Reach
•
Protected Mode Operation
Exceptions Support for Error Detection
and Program Redirection
Hardware Support for Modulo Loop
Auto-Focus Module Operation
Flash Memory Interfaces
–
–
NOR (8-Bit-Wide Data)
NAND (8-Bit-Wide Data)
•
•
•
Enhanced Direct-Memory-Access (EDMA)
Controller (64 Independent Channels)
•
C64x+ Instruction Set Features
Two 64-Bit General-Purpose Timers (Each
Configurable as Two 32-Bit Timers)
–
–
–
–
–
–
Byte-Addressable (8-/16-/32-/64-Bit Data)
8-Bit Overflow Protection
Bit-Field Extract, Set, Clear
Normalization, Saturation, Bit-Counting
VelociTI.2 Increased Orthogonality
C64x+ Extensions
•
•
•
•
One 64-Bit Watch Dog Timer
Two UARTs (One with RTS and CTS Flow
Control)
•
•
Master/Slave Inter-Integrated Circuit
(I2C Bus™)
Compact 16-bit Instructions
Additional Instructions to Support
Complex Multiplies
Multichannel Buffered Serial Port (McBSP)
–
–
–
–
–
I2S and TDM
AC97 Audio Codec Interface
SPI
Standard Voice Codec Interface (AIC12)
Telecom Interfaces – ST-Bus, H-100
•
C64x+ L1/L2 Memory Architecture
–
256K-Bit (32K-Byte) L1P Program
RAM/Cache [Flexible Allocation]
640K-Bit (80K-Byte) L1D Data RAM/Cache
–
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this document.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2006–2007, Texas Instruments Incorporated
TMS320DM6435
Digital Media Processor
www.ti.com
SPRS344B–NOVEMBER 2006–REVISED NOVEMBER 2007
–
128 Channel Mode
Multichannel Audio Serial Port (McASP0)
Four Serializers and SPDIF (DIT) Mode
•
•
Up to 111 General-Purpose I/O (GPIO) Pins
(Multiplexed With Other Device Functions)
•
–
Packages:
–
361-Pin Pb-Free PBGA Package
(ZWT Suffix), 0.8-mm Ball Pitch
376-Pin Plastic BGA Package
(ZDU Suffix), 1.0-mm Ball Pitch
•
•
•
16-Bit Host-Port Interface (HPI)
High-End CAN Controller (HECC)
10/100 Mb/s Ethernet MAC (EMAC)
–
–
–
–
IEEE 802.3 Compliant
Supports Media Independent Interface (MII)
Management Data I/O (MDIO) Module
•
•
0.09-µm/6-Level Cu Metal Process (CMOS)
3.3-V and 1.8-V I/O, 1.2-V Internal
(-6/-5/-5Q/-5S/-4/-4Q/-4S)
•
•
•
•
•
•
VLYNQ™ Interface (FPGA Interface)
Three Pulse Width Modulator (PWM) Outputs
On-Chip ROM Bootloader
•
•
3.3-V and 1.8-V I/O, 1.05-V Internal
(-6 when SYSCLK1 ≤ 400 MHz only)
Applications:
Individual Power-Savings Modes
Flexible PLL Clock Generators
–
–
–
Digital Media
Networked Media Encode
Video Imaging
IEEE-1149.1 (JTAG™)
Boundary-Scan-Compatible
1.2 Description
The TMS320C64x+™ DSPs (including the TMS320DM6435 device) are the highest-performance
fixed-point DSP generation in the TMS320C6000™ DSP platform. The DM6435 device is based on the
third-generation high-performance, advanced VelociTI™ very-long-instruction-word (VLIW) architecture
developed by Texas Instruments (TI), making these DSPs an excellent choice for digital media
applications. The C64x+™ devices are upward code-compatible from previous devices that are part of the
C6000™ DSP platform. The C64x™ DSPs support added functionality and have an expanded instruction
set from previous devices.
Any reference to the C64x DSP or C64x CPU also applies, unless otherwise noted, to the C64x+ DSP and
C64x+ CPU, respectively.
With performance of up to 4800 million instructions per second (MIPS) at a clock rate of 600 MHz, the
C64x+ core offers solutions to high-performance DSP programming challenges. The DSP core possesses
the operational flexibility of high-speed controllers and the numerical capability of array processors. The
C64x+ DSP core processor has 64 general-purpose registers of 32-bit word length and eight highly
independent functional units—two multipliers for a 32-bit result and six arithmetic logic units (ALUs). The
eight functional units include instructions to accelerate the performance in video and imaging applications.
The DSP core can produce four 16-bit multiply-accumulates (MACs) per cycle for a total of 2400 million
MACs per second (MMACS), or eight 8-bit MACs per cycle for a total of 4800 MMACS. For more details
on the C64x+ DSP, see the TMS320C64x/C64x+ DSP CPU and Instruction Set Reference Guide
(literature number SPRU732).
The DM6435 also has application-specific hardware logic, on-chip memory, and additional on-chip
peripherals similar to the other C6000 DSP platform devices. The DM6435 core uses a two-level
cache-based architecture. The Level 1 program memory/cache (L1P) consists of a 256K-bit memory
space that can be configured as mapped memory or direct mapped cache, and the Level 1 data (L1D)
consists of a 640K-bit memory space —384K-bit of which is mapped memory and 256K-bit of which can
be configured as mapped memory or 2-way set-associative cache. The Level 2 memory/cache (L2)
consists of a 1M-bit memory space that is shared between program and data space. L2 memory can be
configured as mapped memory, cache, or combinations of the two.
2
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Digital Media Processor
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SPRS344B–NOVEMBER 2006–REVISED NOVEMBER 2007
The peripheral set includes: a configurable video port (VPFE); a 10/100 Mb/s Ethernet MAC (EMAC) with
a management data input/output (MDIO) module; a 4-bit transmit, 4-bit receive VLYNQ interface; an
inter-integrated circuit (I2C) Bus interface; a multichannel buffered serial port (McBSP); a multichannel
audio serial port (McASP0) with 4 serializers; 2 64-bit general-purpose timers each configurable as
2 independent 32-bit timers; 1 64-bit watchdog timer; a user-configurable 16-bit host-port interface (HPI);
up to 111-pins of general-purpose input/output (GPIO) with programmable interrupt/event generation
modes, multiplexed with other peripherals; 2 UARTs with hardware handshaking support on 1 UART;
3 pulse width modulator (PWM) peripherals; 1 high-end controller area network (CAN) controller [HECC];
and 2 glueless external memory interfaces: an asynchronous external memory interface (EMIFA) for
slower memories/peripherals, and a higher speed synchronous memory interface for DDR2.
The DM6435 device includes a Video Processing Subsystem (VPSS) with a configurable video/imaging
front-end input peripheral used for video capture.
The Video Processing Front-End (VPFE) is comprised of a CCD Controller (CCDC), a Preview Engine
(Previewer), Histogram Module, Auto-Exposure/White Balance/Focus Module (H3A), and Resizer. The
CCDC is capable of interfacing to common video decoders, CMOS sensors, and Charge Coupled Devices
(CCDs). The Previewer is a real-time image processing engine that takes raw imager data from a CMOS
sensor or CCD and converts from an RGB Bayer Pattern to YUV422. The Histogram and H3A modules
provide statistical information on the raw color data for use by the DM6435. The Resizer accepts image
data for separate horizontal and vertical resizing from 1/4x to 4x in increments of 256/N, where N is
between 64 and 1024.
The Ethernet Media Access Controller (EMAC) provides an efficient interface between the DM6435 and
the network. The DM6435 EMAC support both 10Base-T and 100Base-TX, or 10 Mbits/second (Mbps)
and 100 Mbps in either half- or full-duplex mode, with hardware flow control and quality of service (QOS)
support.
The Management Data Input/Output (MDIO) module continuously polls all 32 MDIO addresses in order to
enumerate all PHY devices in the system.
The I2C and VLYNQ ports allow DM6435 to easily control peripheral devices and/or communicate with
host processors.
The high-end controller area network (CAN) controller [HECC] module provides a network protocol in a
harsh environment to communicate serially with other controllers, typically in automotive applications.
The rich peripheral set provides the ability to control external peripheral devices and communicate with
external processors. For details on each of the peripherals, see the related sections later in this document
and the associated peripheral reference guides.
The DM6435 has a complete set of development tools. These include C compilers, a DSP assembly
optimizer to simplify programming and scheduling, and a Windows™ debugger interface for visibility into
source code execution.
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Digital Media Processor
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SPRS344B–NOVEMBER 2006–REVISED NOVEMBER 2007
1.3 Functional Block Diagram
Figure 1-1 shows the functional block diagram of the DM6435 device.
BT.656,
Y/C,
Raw (Bayer)
JTAG Interface
16b
Video Processing Subsystem (VPSS)
Front End
System Control
DSP Subsystem
C64x+t DSP CPU
128 KB L2 RAM
OSC
Input
Clock(s)
PLLs/Clock Generator
Power/Sleep Controller
Pin Multiplexing
Resizer
CCD
Controller
Video
Histogram/
3A
32 KB
L1 Pgm
80 KB
L1 Data
Interface
Preview
Boot ROM
Switched Central Resource (SCR)
Peripherals
Serial Interfaces
System
General-
Purpose
Timer
Watchdog
Timer
2
GPIO
McASP
EDMA
I C
HECC
UART
McBSP
PWM
Program/Data Storage
Connectivity
EMAC
With
MDIO
DDR2
Mem Ctlr
(32b)
Async EMIF/
NAND/
(8b)
VLYNQ
HPI
Figure 1-1. TMS320DM6435 Functional Block Diagram
4
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Digital Media Processor
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SPRS344B–NOVEMBER 2006–REVISED NOVEMBER 2007
Contents
1
TMS320DM6435 Digital Media Processor........... 1
1.1 Features .............................................. 1
1.2 Description............................................ 2
1.3 Functional Block Diagram ............................ 4
6
Peripheral Information and Electrical
Specifications ......................................... 132
6.1 Parameter Information ............................. 132
6.2
Recommended Clock and Control Signal Transition
Behavior............................................ 133
Revision History............................................... 6
2
6.3 Power Supplies .................................... 133
Device Overview........................................ 11
2.1 Device Characteristics .............................. 11
2.2 CPU (DSP Core) Description ....................... 12
2.3 C64x+ CPU.......................................... 15
2.4 Memory Map Summary ............................. 16
2.5 Pin Assignments .................................... 20
2.6 Terminal Functions.................................. 28
2.7 Device Support ...................................... 62
6.4
Enhanced Direct Memory Access (EDMA3)
Controller........................................... 140
6.5 Reset............................................... 152
6.6
External Clock Input From MXI/CLKIN Pin ........ 161
6.7 Clock PLLs......................................... 163
6.8 Interrupts........................................... 168
6.9 External Memory Interface (EMIF)................. 171
6.10 Video Processing Sub-System (VPSS) Overview . 179
6.11 Universal Asynchronous Receiver/Transmitter
(UART) ............................................. 190
2.8
Device and Development-Support Tool
Nomenclature ....................................... 62
2.9 Documentation Support ............................. 64
Device Configuration .................................. 65
3.1 System Module Registers ........................... 65
3.2 Power Considerations............................... 66
3.3 Clock Considerations................................ 68
3.4 Boot Sequence...................................... 71
3.5 Configurations At Reset ............................. 82
3.6 Configurations After Reset .......................... 84
3.7 Multiplexed Pin Configurations...................... 88
6.12 Inter-Integrated Circuit (I2C) ....................... 193
6.13 Host-Port Interface (HPI) Peripheral............... 197
3
6.14 Multichannel Buffered Serial Port (McBSP)........ 202
6.15 Multichannel Audio Serial Port (McASP0)
Peripheral .......................................... 211
6.16 High-End Controller Area Network Controller
(HECC)............................................. 219
6.17 Ethernet Media Access Controller (EMAC) ........ 225
6.18 Management Data Input/Output (MDIO) .......... 232
6.19 Timers.............................................. 233
6.20 Pulse Width Modulator (PWM)..................... 236
6.21 VLYNQ ............................................. 238
6.22 General-Purpose Input/Output (GPIO)............. 242
6.23 IEEE 1149.1 JTAG................................. 246
Mechanical Data....................................... 248
7.1 Thermal Data for ZWT ............................. 248
7.1.1 Thermal Data for ZDU............................. 249
7.1.2 Packaging Information............................. 249
3.8
Device Initialization Sequence After Reset ........ 123
3.9 Debugging Considerations......................... 125
System Interconnect ................................. 127
4.1 System Interconnect Block Diagram............... 127
Device Operating Conditions....................... 129
4
5
7
5.1
Absolute Maximum Ratings Over Operating
Temperature Range (Unless Otherwise Noted) ... 129
5.2 Recommended Operating Conditions ............. 130
5.3
Electrical Characteristics Over Recommended
Ranges of Supply Voltage and Operating
Temperature (Unless Otherwise Noted) ........... 131
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TMS320DM6435
Digital Media Processor
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SPRS344B–NOVEMBER 2006–REVISED NOVEMBER 2007
Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
This data manual revision history highlights the technical changes made to the SPRS344A device-specific
data manual to make it an SPRS344B revision. Changed DM6435 device information to the
Production Data (PD) stage of development.
Scope: Applicable updates to the DM643x DMP device family, specifically relating to the TMS320DM6435
device, have been incorporated.
•
•
A 1.05 V core supply voltage is only supported on -6 devices operating at SYSCLK1 ≤ 400 MHz.
The DM6435 device now supports 24-bit SPI Boot (McBSP0 + GP[97]) and VLYNQ Boot.
SEE
ADDITIONS/MODIFICATIONS/DELETIONS
Added literature references throughout the document.
Updated/Changed the following DDR2 pin names:
Global
•
•
–
–
–
–
–
DDR_CLK0 to DDR_CLK
DDR_CLK0 to DDR_CLK
DDR_BS[0] to DDR_BA[0]
DDR_BS[1] to DDR_BA[1]
DDR_BS[2] to DDR_BA[2]
•
•
Updated/Changed the -400, -500, -600 frequency designators from -400, -500, and -600 to -4, -4Q, -4S,
-5, -5Q, -5S, and -6, where "Q" represents automotive.
Updated/Changed devices that support a 1.05 V core suppply voltage from 400-MHz (-4) devices to
only 600-MHz (-6) devices when SYSCLK1 ≤ 400 MHz.
•
•
Updated/Changed temperature range designator from "Extended" to "Automotive (Q or S suffix)".
Added memory locations to register tables.
Section 1.1
Section 1.1, Features:
Added "Supports up to 333-MHz (data rate) bus and interfaces with DDR2-400 SDRAM" to "32-Bit DDR2
SDRAM Memory Controller With 256M-Byte Address Space (1.8-V I/O)" bullet
Section 2.1
Section 2.6
Table 2-1, Characteristics of the DM6435 Processor
Updated/Changed Product Status from "PP" to "PD"
Section 2.6, Terminal Functions
Table 2-15, Host-Port Interface Terminal Functions:
Added "For proper HPI operation, if this pin is routed out, it must be pulled up via an external resistor" to
HAS/MDIO/AD3/GP[83] pin description
Table 2-8, RESET and JTAG Terminal Functions:
Added "For proper device operation, do not oppose the IPU on this pin" statement to TMS pin description
Section 3.1
Section 3.1, System Module Registers
Table 3-1, System Module Register Memory Map:
Updated/Changed EDMATCCFG register Description from "EDMA TC Configuration..." to "EDMA Transfer
Controller Default Burst Size Configuration..."
Section 3.4.1
Section 3.4.1, Boot Modes
Table 3-5,Table 3-6, and Table 3-7:
Updated/Changed BOOTMODE[3:0] = 1010 from "Reserved" to "VLYNQ Boot"
Updated/Changed BOOTMODE[3:0] = 1111 from "Reserved" to "24-Bit SPI Boot (McBSP0 + GP[97])"
Section 5.1
Section 5.2
Section 5.1, Absolute Maximum Ratings Over Operating Temperature Range (Unless Otherwise Noted):
Deleted "1.2-V and 1.05-V Operation" from Supply Voltage Range
Section 5.2, Recommended Operating Conditions:
Updated/Changed DVDD Supply voltage, I/O 3.3V (DVDD33) MIN value from "3.14 V" to "2.97 V"
Updated/Changed DVDD Supply voltage, I/O 3.3V (DVDD33) MAX value from "3.46 V" to "3.63 V"
Added "High-level input voltage, MXI/ CLKIN" with a MIN value of 0.65MXVDD to VIH row
Added "Low-level input voltage, MXI/ CLKIN" with a MAX value of 0.35MXVDD to VIL row
Added table note for CVDD Supply voltage, Core (-6 devices)
6
Revision History
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SEE
ADDITIONS/MODIFICATIONS/DELETIONS
Section 5.3
Section 5.3, Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating
Temperature (Unless Otherwise Noted):
Updated/Changed table note from "Measured under the following conditions..." to "Assumes the following
conditions..."
Deleted "VI = VSS to DVDD33 without internal pullup resistor" from Input current [DC] (except I2C) row
Updated/Changed IOZ VO = DVDD33 or VSS; internal pull disabled MAX value from "±20 µA" to "±50 µA"
Updated/Changed IOH CLK_OUT0/PWM2/GPIO[84] MAX value from "8mA" to "-8mA"
Updated/Changed IOH All other peripherals MAX value from "4mA" to "-4mA"
Updated/Changed ICDD CVDD = 1.2V, DSP clock = 600 MHz supply current from "TBD" to "524 mA"
Updated/Changed ICDD CVDD = 1.2V, DSP clock = 500 MHz supply current from "TBD" to "460 mA"
Updated/Changed ICDD CVDD = 1.2V, DSP clock = 400 MHz supply current from "TBD" to "392 mA"
Updated/Changed ICDD CVDD = 1.05V, DSP clock = 400MHz supply current from "TBD" to "341 mA"
Updated/Changed IDDD 3.3 V I/O DSP clock = 600 MHz supply current from "TBD" to "13 mA"
Updated/Changed IDDD 3.3 V I/O DSP clock = 500 MHz supply current from "TBD" to "13 mA"
Updated/Changed IDDD 3.3 V I/O DSP clock = 400 MHz supply current from "TBD" to "13 mA"
Updated/Changed IDDD 1.8V I/O, CVDD = 1.2 V, DSP clock = 600 MHz supply current from "TBD" to "93
mA"
Updated/Changed IDDD 1.8V I/O, CVDD = 1.2 V, DSP clock = 500 MHz supply current from "TBD" to "92
mA"
Updated/Changed IDDD 1.8V I/O, CVDD = 1.2 V, DSP clock = 400 MHz supply current from "TBD" to "91
mA"
Updated/Changed IDDD 1.8V I/O, CVDD = 1.05 V, DSP clock = 400 MHz supply current from "TBD" to "72
mA"
Section 6.5.2
Section 6.5.2, Warm Reset (RESET Pin):
Updated/Changed step 4 from "The POR pin may now be deasserted" to "The RESET pin may now be
deasserted"
Updated/Changed step 4 from "When the POR pin is deasserted" to "When the RESET pin is deasserted"
Section 6.5.6
Section 6.5.7
Section 6.5.6, Reset Priority:
Updated/Changed first paragraph from "The rest request priorities..." to "The reset request priorities..."
Section 6.5.7, Reset Controller Register:
Added TMS320DM643x DMP DSP Subsystem Reference Guide (literature number SPRU978) reference to
paragraph
Section 6.6.1
Section 6.7.1
Section 6.6.1, Clock Input Option 1—Crystal
Table 6-13, Input Requirements for Crystal:
Updated/Changed Frequency stability MAX value from "± 50 or ± 200" to "± 50"
Updated/Changed table note
Section 6.7.1, PLL1 and PLL2:
Table 6-15, PLLC1 Clock Frequency Ranges:
Added "-6 devices at 1.05-V CVDD" and "400 MHz" MAX value to SYSCLK1 (CLKDIV1 Domain) row
Updated/Changed PLLOUT MIN values from "400 MHz" to "300 MHz"
Section 6.7.4
Section 6.7.4, Clock PLL Electrical Data/Timing (Input and Output Clocks)
Table 6-19, Timing Requirements for MXI/CLKIN (-4 -4Q,-4S,-5,-5Q,-5S,-6) Devices:
Added "Frequency Stability"
Added table note
Section 6.4.2
Section 6.8
Table 6-7, DM6435 EDMA Registers:
Updated/Changed the following registers to "Reserved": QRAE2, QRAE3, DRAE2, DRAEH2, DRAE3, and
DRAEH3
Section 6.8, Interrupts:
Deleted "NMI" from "Also, the interrupt controller controls the generation of the CPU exception, NMI, and
emulation interrupts" sentence
Added "The NMI input to the C64x+ DSP interrupt controller is not connected internally; therefore, the NMI
interrupt is not available."
Section 6.9.3
Section 6.9.3, EMIFA Electrical Data/Timing
Table 6-24, Timing Requirements for Asynchronous Memory Cycles for EMIFA Module:
Added "NOM" column to represent nominal values
Updated/Changed tsu(EMDV-EMOEH) MIN value from "TBD" to "5 ns"
Updated/Changed tsu(EMOEH-EMDIV) MIN value from "TBD" to "0 ns"
Updated/Changed tsu(EMWAIT-EMOEH) MIN value from "4E + TBD" to "4E + 5 ns"
Updated/Changed tsu(EMWAIT-EMWEH) MIN value from "4E + TBD" to "4E + 5 ns"
Table 6-25, Switching Characteristics Over Recommended Operating Conditions for Asynchronous Memory
Cycles for EMIFA Module:
Added "NOM" column to represent nominal values
Added "When EW = 1, the EMIF will extend the strobe period up to 4,096 cycles..." table note
Deleted "EW = 1" from tc(EMRCYCLE), tw(EMOEL), tc(EMWCYCLE), and tw(EMWEL)
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Digital Media Processor
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ADDITIONS/MODIFICATIONS/DELETIONS
Updated/Changed the values for the following parameters:
td(TURNAROUND) MIN/ MAX from "(TA + 1) * E - TBD"/ "(TA + 1)*E + TBD" to NOM "(TA + 1)*E"
tc(EMRCYCLE) (EW = 0) MIN/ MAX from "(RS + RST + RH) * E - TBD"/ "(RS + RST + RH) * E + TBD" to NOM
"(RS + RST + RH) * E"
tsu(EMCSL-EMOEL) (SS = 0) MIN/ MAX from "(RS + 1) * E - TBD"/ "(RS + 1) * E + TBD" to "(RS + 1) * E - 4"/
"(RS + 1) * E + 4"
tsu(EMCSL-EMOEL) (SS = 1) MIN/ MAX from "TBD" and "blank" to "-4"/ "4"
th(EMOEH-EMCSH) (SS = 0) MIN/ MAX from "(RH + 1) * E - TBD"/ "(RH + 1) * E + TBD" to "(RH + 1) * E - 4"/
"(RH + 1) * E + 4"
th(EMOEH-EMCSH) (SS = 1) MIN/ MAX from "TBD"/ "blank" to "-4"/ "4"
tsu(EMBAV-EMOEL) MIN/ MAX from "(RS + 1) * E - TBD"/ "(RS + 1) * E + TBD" to "(RS + 1) * E - 4"/ "(RS + 1) *
E + 4"
th(EMOEH-EMBAIV) MIN/ MAX from "(RH + 1) * E - TBD"/ "(RH + 1) * E + TBD" to "(RH + 1) * E - 4"/ "(RH + 1)
* E + 4"
tsu(EMBAV-EMOEL) (SS = 0) MIN/ MAX from "(RS + 1) * E - TBD"/ "(RS + 1) * E + TBD" to "(RS + 1) * E - 4"/
"(RS + 1) * E + 4"
th(EMOEH-EMBAIV) MIN/ MAX from "(RH + 1) * E - TBD"/ "(RH + 1) * E + TBD" to "(RH + 1) * E - 4"/ "(RH + 1)
* E + 4"
tw(EMOEL) (EW = 0) MIN/ MAX from "(RST+ 1) * E - TBD"/ "(RST + 1)*E + TBD" to NOM "(RST + 1)*E"
td(EMWAITH-EMOEH) MAX from "4E + TBD" to "4E + 4"
tc(EMWCYCLE) (EW = 0) MIN/ MAX from "(RS + RST + RH) * E - TBD"/ "(RS + RST + RH) * E + TBD" to
NOM "(WS + WST + WH) * E"
tsu(EMCSL-EMWEL) (SS = 0) MIN/ MAX from "(WS + 1) * E - TBD"/ "(WS + 1) * E + TBD" to "(WS + 1) * E - 4"/
"(WS + 1) * E + 4"
tsu(EMCSL-EMWEL) (SS = 1) MIN/ MAX from "TBD"/ "blank" to "-4"/ "4"
th(EMWEH-EMCSH) (SS = 0) MIN/ MAX from "(WH + 1) * E - TBD"/ "(WH + 1) * E + TBD" to "(WH + 1) * E - 4"/
"(WH + 1) * E + 4"
th(EMWEH-EMCSH) (SS = 1) MIN/ MAX from "TBD"/ "blank" to "-4"/ "4"
tsu(EMRNW-EMWEL) MIN/ MAX from "(WS + 1) * E - TBD"/ "(WS + 1) * E + TBD" to "(WS + 1) * E - 4"/ "(WS +
1) * E + 4"
th(EMWEH-EMRNW) MIN/ MAX from "(WH + 1) * E - TBD"/ "(WH + 1) * E + TBD" to "(WH + 1) * E - 4"/ "(WH +
1) * E + 4"
tsu(EMBAV-EMWEL) MIN/ MAX from "(WS + 1) * E - TBD"/ "(WS + 1) * E + TBD" to "(WS + 1) * E - 4"/ "(WS +
1) * E + 4"
th(EMWEH-EMBAIV) MIN/ MAX from "(WH + 1) * E - TBD"/ "(WH + 1) * E + TBD" to "(WH + 1) * E - 4"/ "(WH +
1) * E + 4"
tsu(EMAV-EMWEL) MIN/ MAX from "(WS + 1) * E - TBD"/ "(WS + 1) * E + TBD" to "(WS + 1) * E - 4"/ "(WS + 1)
* E + 4"
th(EMWEH-EMBAIV) MIN/ MAX from "(WH + 1) * E - TBD"/ "(WH + 1) * E + TBD" to "(WH + 1) * E - 4"/ "(WH +
1) * E + 4"
tw(EMWEL) (EW = 0) MIN/ MAX from "(WST + 1) * E - TBD"/ "(WST + 1) * E + TBD" to NOM "(WST + 1) * E"
td(EMWAITH-EMwEH) MAX from "4E + TBD" to "4E + 4"
tsu(EMDV-EMWEL) MIN/ MAX from "(WS + 1) * E - TBD"/ "(WS + 1) * E + TBD" to "(WS + 1) * E - 4"/ "(WS + 1)
* E + 4"
th(EMWEH-EMDIV) MIN/ MAX from "(WH + 1) * E - TBD"/ "(WH + 1) * E + TBD" to "(WH + 1) * E - 4"/ "(WH +
1) * E + 4"
8
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SEE
ADDITIONS/MODIFICATIONS/DELETIONS
Section 6.10.1.6, VPFE Electrical Data/Timing
Section 6.10.1.6
Table 6-35, Timing Requirements for VPFE PCLK Master/Slave Mode
Updated/Changed tt(PCLK) MAX value from "TBD" to "7 ns"
Table 6-36, Timing Requirements for VPFE (CCD) Slave Mode:
Updated/Changed th(PCLK-CCDV) MIN value from "0.5 ns" to "1 ns"
Updated/Changed th(PCLK-HDV) MIN value from "0.5 ns" to "1 ns"
Updated/Changed th(PCLK-VDV) MIN value from "0.5 ns" to "1 ns"
Updated/Changed th(PCLK-C_WEV) MIN value from "0.5 ns" to "1 ns"
Updated/Changed th(PCLK-C_FIELDV) MIN value from "0.5 ns" to "1 ns"
Table 6-37, Timing Requirements for VPFE (CCD) Master Mode:
Updated/Changed th(PCLK-CCDV) MIN value from "0.5 ns" to "1 ns"
Updated/Changed th(PCLK-CWEV) MIN value from "0.5 ns" to "1 ns"
Table 6-38, Switching Characteristics Over Recommended Operating Conditions for VPFE (CCD) Master
Mode:
Deleted parameters 17, 19, and 21
Figure 6-22, VPFE (CCD) Master Mode Control Output Data Timing:
Updated/Changed C_FIELD diagram name from C_WE/C_FIELD to C_FIELD
Deleted parameters 17, 19, and 21
Section 6.13.3
Section 6.13.3, HPI Electrical Data/Timing:
Deleted HPI Read Timing (HAS Used) figure
Deleted HPI Write Timing (HAS Used) figure
Table 6-47, Timing Requirements for Host-Port Interface Cycles:
Deleted parameters 9,10, 16, 17, and 19
Updated/Changed parameter 13 from "Hold time, HSTROBE low after..." to "Hold time, HSTROBE high
after..."
Table 6-48, Switching Characteristics for Host-Port Interface Cycles:
Deleted TBD from Table Note 1
Section 6.14.2
Section 6.14.2, McBSP Electrical Data/Timing
Table 6-50, Timing Requirements for McBSP
Updated/Changed th(CKRL-FRH) CLKR ext MIN value from "3 ns" to "4 ns"
Updated/Changed th(CKRL-DRV) CLKR ext MIN value from "3 ns" to "3.5 ns"
Table 6-51, Switching Characteristics Over Recommended Operating Conditions for McBSP
Updated/Changed tw(CKRX) CLKR/X int MIN and MAX values from C-1 and C+1 to C-2 and C+2
Updated/Changed td(FXH-DXV) FSX int MIN value from "-3.9 ns" to "-4 ns"
Updated/Changed td(FXH-DXV) FSX ext MIN and MAX values from "-2.1 ns" and "5 ns"to "+1 ns" and "14.5
ns"
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SEE
ADDITIONS/MODIFICATIONS/DELETIONS
Section 6.15.1.2, McASP0 Peripheral Register Description(s)
Table 6-61, McASP0 Control Registers:
Section 6.16.3
Updated/Changed Serializer 0 control register (SRCTL0) HEX ADDRESS RANGE from 01B4 C180 to 01D0
1180.
Section 6.15.1.3, McASP0 Electrical Data/Timing
Table 6-63, Timing Requirements for McASP:
Updated/Changed tsu(FRX-CKRX) ACLKR/X int MIN value from "10 ns" to "11 ns"
Updated/Changed tsu(AXR-CKRX) ACLKR/X int MIN value from "10 ns" to "11 ns"
Added ACLKR/X "ext input" and "ext output" values to th(CKRX-FRX)
Added ACLKR/X "ext input" and "ext output" values to th(CKRX-AXR)
Table 6-64, Switching Characteristics Over Recommended Operating Conditions for McASP
Added ACLKR/X "ext input" and "ext output" values to td(CKRX-FRX)
Added ACLKR/X "ext input" and "ext output" values to td(CKX-AXRV)
Table 6-54, Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master
or Slave: CLKSTP = 10b, CLKXP = 0
Updated/Changed td(FXL-CKXH) MIN value from "L - 2 ns" to "L - 4 ns"
Updated/Changed table note from "...input clock = P if CLKSM = 1..." to "...input clock = 2P if CLKSM = 1..."
Updated/Changed table note from "...input clock = P_clks if CLKSM = 0..." to "...input clock = 2*P_clks if
CLKSM = 0..."
Table 6-54, Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master
or Slave: CLKSTP = 11b, CLKXP = 0
Updated/Changed td(FXL-CKXH) MIN value from "T - 2 ns" to "T - 4 ns"
Updated/Changed td(FXL-DXV) MIN and MAX values from "H - 2 ns" and "H + 4 ns" to "H - 4 ns" and "H + 5.5
ns"
Updated/Changed table note from "...input clock = P if CLKSM = 1..." to "...input clock = 2P if CLKSM = 1..."
Updated/Changed table note from "...input clock = P_clks if CLKSM = 0..." to "...input clock = 2*P_clks if
CLKSM = 0..."
Table 6-54, Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master
or Slave: CLKSTP = 10b, CLKXP = 1
Updated/Changed td(FXL-CKXL) MIN and MAX values from "H - 2 ns" and "H + 3 ns" to "H - 4 ns" and "H + 4
ns"
Updated/Changed table note from "...input clock = P if CLKSM = 1..." to "...input clock = 2P if CLKSM = 1..."
Updated/Changed table note from "...input clock = P_clks if CLKSM = 0..." to "...input clock = 2*P_clks if
CLKSM = 0..."
Table 6-54, Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI Master
or Slave: CLKSTP = 11b, CLKXP = 1
Updated/Changed td(FXL-CKXL) MIN and MAX values from "T - 2 ns" and "T + 1 ns" to "T - 4 ns" and "T + 4
ns"
Updated/Changed table note from "...input clock = P if CLKSM = 1..." to "...input clock = 2P if CLKSM = 1..."
Updated/Changed table note from "...input clock = P_clks if CLKSM = 0..." to "...input clock = 2*P_clks if
CLKSM = 0..."
Table 6-69
Table 6-69, Timing Requirements for HECC Receive:
Deleted "TBD" from Table Note 1
Table 6-70, Switching Characteristics Over Recommended Operating Conditions for HECC Transmit:
Deleted "TBD" from Table Note 1
Section 6.21.2
Table 6-94, Switching Characteristics Over Recommended Operating Conditions for Transmit Data for the
VLYNQ Module:
Updated/Changed td(VCLKH-TXDV) MAX value from "8.5 ns" to "12 ns"
Table 6-95, Timing Requirements for Receive Data for the VLYNQ Module:
Updated/Changed th(VCLKH-RXDV) MIN value from "2 ns" to "3ns"
Table 6-96, RTM RX Data Flop Hold/Setup Timing Constraints:
Added "Typical Values" to title
Updated/Changed HOLD (Y) and SETUP (X) values as follows:
RX Data Flop 0: HOLD (Y) from "0.6" to "1.3"; SETUP (X) from "2.5" to "0.9"
RX Data Flop 1:SETUP (X) from "2.25" to "0.7"
RX Data Flop 2: HOLD (Y) from "1.9" to "1.5"; SETUP (X) from "2" to "-0.4"
RX Data Flop 3: HOLD (Y) from "2" to "1.6"; SETUP (X) from "1.75" to "-0.6"
RX Data Flop 4: HOLD (Y) from "2.5" to "1.8"; SETUP (X) from "1.5" to "-0.8"
RX Data Flop 5: HOLD (Y) from "3" to "2.0"; SETUP (X) from "1.25" to "-1.0"
RX Data Flop 6: HOLD (Y) from "3.5" to "2.2"; SETUP (X) from "1" to "-1.1"
RX Data Flop 7: HOLD (Y) from "4" to "2.4"; SETUP (X) from "0.75" to "-1.2"
Section 6.23.1
Table 6-101, JTAG ID (JTAGID) Register Selection Bit Descriptions:
Updated/Changed VARIANT field DESCRIPTION
10
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2 Device Overview
2.1 Device Characteristics
Table 2-1, provides an overview of the TMS320DM6435 DSP. The tables show significant features of the
DM6435 device, including the capacity of on-chip RAM, the peripherals, the CPU frequency, and the
package type with pin count.
Table 2-1. Characteristics of the DM6435 Processor
HARDWARE FEATURES
DM6435
DDR2 Memory Controller
(16-/32-bit bus width) [1.8 V I/O]
Asynchronous (8-bit bus width),
RAM, Flash, (8-bit NOR or 8-bit NAND)
Asynchronous EMIF [EMIFA]
EDMA3
1 (64 independent channels, 8 QDMA channels)
2 64-bit General Purpose
(configurable as 2 64-bit or 4 32-bit)
1 64-bit Watch Dog
Timers
UARTs
I2C
2 (one with RTS and CTS flow control)
Peripherals
1 (Master/Slave)
1
Not all peripherals pins
are available at the same
time (For more detail, see
the Device Configuration
section).
McBSP
McASP
1 (4 serailizers)
10/100 Ethernet MAC (EMAC) with
Management Data Input/Output (MDIO)
1
VLYNQ
1
General-Purpose Input/Output Port (GPIO)
Up to 111 pins
PWM
3 outputs
HPI (16-bit)
Configurable Video Port
HECC
1
1 Input (VPFE)
1
Size (Bytes)
240KB RAM, 64KB ROM
32K-Byte (32KB) L1 Program (L1P) RAM/Cache
(Cache up to 32KB)
80KB L1 Data (L1D) RAM/Cache (Cache up to 32KB)
128KB Unified Mapped RAM/Cache (L2)
64KB Boot ROM
On-Chip Memory
Organization
Revision ID Register (MM_REVID.[15:0])
(address location: 0x0181 2000)
See the TMS320DM6437/35/33/31 Digital Media
Processor (DMP) [Silicon Revisions 1.1 and 1.0]
Silicon Errata (literature number SPRZ250).
MegaModule Rev ID
CPU ID + CPU Rev ID
JTAG BSDL_ID
Control Status Register (CSR.[31:16])
JTAGID register
(address location: 0x01C4 0028)
See Section 6.23.1, JTAG ID (JTAGID) Register
Description(s)
CPU Frequency
MHz
400, 500, 600
2.5 ns (-4/-4Q/-4S)
2 ns (-5/-5Q/-5S)
1.67 ns (-6)
Cycle Time
ns
1.2 V (-6, -5, -5Q, -5S, -4, -4Q, -4S)
1.05 V (-6 when SYSCLK1 ≤ 400 MHz only)
1.8 V, 3.3 V
Core (V)
I/O (V)
Voltage
MXI/CLKIN frequency multiplier
(27 MHz reference)
PLL Options
x1 (Bypass), x14 to x 30
16 x 16 mm, 0.8 mm pitch
23 x 23 mm, 1.0 mm pitch
µm
361-Pin BGA (ZWT)
376-Pin BGA (ZDU)
0.09 µm
BGA Package(s)
Process Technology
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Table 2-1. Characteristics of the DM6435 Processor (continued)
HARDWARE FEATURES
DM6435
Product Preview (PP), Advance Information (AI),
or Production Data (PD)
Product Status(1)
PD
(1) PRODUCT PREVIEW information concerns experimental products (designated as TMX) that are in the formative or design phase of
development. Characteristic data and other specifications are design goals. Texas Instruments reserves the right to change or
discontinue these products without notice.
2.2 CPU (DSP Core) Description
The C64x+ Central Processing Unit (CPU) consists of eight functional units, two register files, and two
data paths as shown in Figure 2-1. The two general-purpose register files (A and B) each contain
32 32-bit registers for a total of 64 registers. The general-purpose registers can be used for data or can be
data address pointers. The data types supported include packed 8-bit data, packed 16-bit data, 32-bit
data, 40-bit data, and 64-bit data. Values larger than 32 bits, such as 40-bit-long or 64-bit-long values are
stored in register pairs, with the 32 LSBs of data placed in an even register and the remaining 8 or
32 MSBs in the next upper register (which is always an odd-numbered register).
The eight functional units (.M1, .L1, .D1, .S1, .M2, .L2, .D2, and .S2) are each capable of executing one
instruction every clock cycle. The .M functional units perform all multiply operations. The .S and .L units
perform a general set of arithmetic, logical, and branch functions. The .D units primarily load data from
memory to the register file and store results from the register file into memory.
The C64x+ CPU extends the performance of the C64x core through enhancements and new features.
Each C64x+ .M unit can perform one of the following each clock cycle: one 32 x 32 bit multiply, one 16 x
32 bit multiply, two 16 x 16 bit multiplies, two 16 x 32 bit multiplies, two 16 x 16 bit multiplies with
add/subtract capabilities, four 8 x 8 bit multiplies, four 8 x 8 bit multiplies with add operations, and four
16 x 16 multiplies with add/subtract capabilities (including a complex multiply). There is also support for
Galois field multiplication for 8-bit and 32-bit data. Many communications algorithms such as FFTs and
modems require complex multiplication. The complex multiply (CMPY) instruction takes for 16-bit inputs
and produces a 32-bit real and a 32-bit imaginary output. There are also complex multiplies with rounding
capability that produces one 32-bit packed output that contain 16-bit real and 16-bit imaginary values. The
32 x 32 bit multiply instructions provide the extended precision necessary for audio and other
high-precision algorithms on a variety of signed and unsigned 32-bit data types.
The .L or (Arithmetic Logic Unit) now incorporates the ability to do parallel add/subtract operations on a
pair of common inputs. Versions of this instruction exist to work on 32-bit data or on pairs of 16-bit data
performing dual 16-bit add and subtracts in parallel. There are also saturated forms of these instructions.
The C64x+ core enhances the .S unit in several ways. In the C64x core, dual 16-bit MIN2 and MAX2
comparisons were only available on the .L units. On the C64x+ core they are also available on the .S unit
which increases the performance of algorithms that do searching and sorting. Finally, to increase data
packing and unpacking throughput, the .S unit allows sustained high performance for the quad 8-bit/16-bit
and dual 16-bit instructions. Unpack instructions prepare 8-bit data for parallel 16-bit operations. Pack
instructions return parallel results to output precision including saturation support.
Other new features include:
•
SPLOOP - A small instruction buffer in the CPU that aids in creation of software pipelining loops where
multiple iterations of a loop are executed in parallel. The SPLOOP buffer reduces the code size
associated with software pipelining. Furthermore, loops in the SPLOOP buffer are fully interruptible.
•
Compact Instructions - The native instruction size for the C6000 devices is 32 bits. Many common
instructions such as MPY, AND, OR, ADD, and SUB can be expressed as 16 bits if the C64x+
compiler can restrict the code to use certain registers in the register file. This compression is
performed by the code generation tools.
•
Instruction Set Enhancement - As noted above, there are new instructions such as 32-bit
multiplications, complex multiplications, packing, sorting, bit manipulation, and 32-bit Galois field
12
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multiplication.
•
•
•
Exceptions Handling - Intended to aid the programmer in isolating bugs. The C64x+ CPU is able to
detect and respond to exceptions, both from internally detected sources (such as illegal op-codes) and
from system events (such as a watchdog time expiration).
Privilege - Defines user and supervisor modes of operation, allowing the operating system to give a
basic level of protection to sensitive resources. Local memory is divided into multiple pages, each with
read, write, and execute permissions.
Time-Stamp Counter - Primarily targeted for Real-Time Operating System (RTOS) robustness, a
free-running time-stamp counter is implemented in the CPU which is not sensitive to system stalls.
For more details on the C64x+ CPU and its enhancements over the C64x architecture, see the following
documents:
•
•
•
•
TMS320C64x/C64x+ DSP CPU and Instruction Set Reference Guide (literature number SPRU732)
TMS320C64x+ DSP Megamodule Reference Guide (literature number SPRU871)
TMS320C64x to TMS320C64x+ CPU Migration Guide Application Report (literature number SPRAA84)
TMS320C64x+ DSP Cache User's Guide (literature number SPRU862)
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Even
register
file A
(A0, A2,
A4...A30)
src1
src2
Odd
register
file A
(A1, A3,
A5...A31)
.L1
odd dst
even dst
long src
(D)
8
32 MSB
ST1b
ST1a
32 LSB
8
long src
even dst
odd dst
src1
(D)
Data path A
.S1
src2
32
32
(A)
(B)
dst2
dst1
src1
.M1
src2
(C)
32 MSB
32 LSB
LD1b
LD1a
dst
src1
src2
.D1
.D2
DA1
2x
1x
Even
register
file B
(B0, B2,
B4...B30)
Odd
register
file B
(B1, B3,
B5...B31)
src2
DA2
src1
dst
32 LSB
LD2a
LD2b
32 MSB
src2
(C)
.M2
src1
dst2
32
32
(B)
(A)
dst1
src2
src1
.S2
odd dst
even dst
long src
(D)
Data path B
8
8
32 MSB
32 LSB
ST2a
ST2b
long src
even dst
(D)
odd dst
.L2
src2
src1
Control Register
A. On .M unit, dst2 is 32 MSB.
B. On .M unit, dst1 is 32 LSB.
C. On C64x CPU .M unit, src2 is 32 bits; on C64x+ CPU .M unit, src2 is 64 bits.
D. On .L and .S units, odd dst connects to odd register files and even dst connects to even register files.
Figure 2-1. TMS320C64x+™ CPU (DSP Core) Data Paths
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2.3 C64x+ CPU
The C64x+ core uses a two-level cache-based architecture. The Level 1 Program memory/cache (L1P)
consists of 32 KB memory space that can be configured as mapped memory or direct mapped cache. The
Level 1 Data memory/cache (L1D) consists of 80 KB—48 KB of which is mapped memory and 32 KB of
which can be configured as mapped memory or 2-way set associated cache. The Level 2 memory/cache
(L2) consists of a 128 KB memory space that is shared between program and data space. L2 memory can
be configured as mapped memory, cache, or a combination of both.
Table 2-2 shows a memory map of the C64x+ CPU cache registers for the device.
Table 2-2. C64x+ Cache Registers
HEX ADDRESS RANGE
0x0184 0000
REGISTER ACRONYM
L2CFG
DESCRIPTION
L2 Cache configuration register
0x0184 0020
L1PCFG
L1PCC
L1P Size Cache configuration register
L1P Freeze Mode Cache configuration register
L1D Size Cache configuration register
L1D Freeze Mode Cache configuration register
Reserved
0x0184 0024
0x0184 0040
L1DCFG
L1DCC
-
0x0184 0044
0x0184 0048 - 0x0184 0FFC
0x0184 1000
EDMAWEIGHT
-
L2 EDMA access control register
Reserved
0x0184 1004 - 0x0184 1FFC
0x0184 2000
L2ALLOC0
L2ALLOC1
L2ALLOC2
L2ALLOC3
-
L2 allocation register 0
0x0184 2004
L2 allocation register 1
0x0184 2008
L2 allocation register 2
0x0184 200C
L2 allocation register 3
0x0184 2010 - 0x0184 3FFF
0x0184 4000
Reserved
L2WBAR
L2WWC
L2WIBAR
L2WIWC
L2IBAR
L2IWC
L2 writeback base address register
L2 writeback word count register
L2 writeback invalidate base address register
L2 writeback invalidate word count register
L2 invalidate base address register
L2 invalidate word count register
L1P invalidate base address register
L1P invalidate word count register
L1D writeback invalidate base address register
L1D writeback invalidate word count register
Reserved
0x0184 4004
0x0184 4010
0x0184 4014
0x0184 4018
0x0184 401C
0x0184 4020
L1PIBAR
L1PIWC
L1DWIBAR
L1DWIWC
-
0x0184 4024
0x0184 4030
0x0184 4034
0x0184 4038
0x0184 4040
L1DWBAR
L1DWWC
L1DIBAR
L1DIWC
-
L1D Block Writeback
0x0184 4044
L1D Block Writeback
0x0184 4048
L1D invalidate base address register
L1D invalidate word count register
Reserved
0x0184 404C
0x0184 4050 - 0x0184 4FFF
0x0184 5000
L2WB
L2 writeback all register
0x0184 5004
L2WBINV
L2INV
L2 writeback invalidate all register
L2 Global Invalidate without writeback
Reserved
0x0184 5008
0x0184 500C - 0x0184 5027
0x0184 5028
-
L1PINV
-
L1P Global Invalidate
0x0184 502C - 0x0184 5039
0x0184 5040
Reserved
L1DWB
L1DWBINV
L1DINV
L1D Global Writeback
0x0184 5044
L1D Global Writeback with Invalidate
L1D Global Invalidate without writeback
0x0184 5048
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Table 2-2. C64x+ Cache Registers (continued)
HEX ADDRESS RANGE
0x0184 8000 - 0x0184 80BC
0x0184 80C0 - 0x0184 80FC
0x0184 8100 - 0x0184 8104
REGISTER ACRONYM
MAR0 - MAR47
DESCRIPTION
Reserved (corresponds to byte address 0x0000 0000 - 0x2FFF FFFF)
Reserved (corresponds to byte address 0x3000 0000 - 0x3FFF FFFF)
Reserved (corresponds to byte address 0x4000 0000 - 0x41FF FFFF)
MAR48 - MAR63
MAR64 - MAR65
Memory Attribute Registers for EMIFA
(corresponds to byte address 0x4200 0000 - 0x49FF FFFF)
0x0184 8108 - 0x0184 8124
0x0184 8128 - 0x0184 812C
0x0184 8130 - 0x0184 813C
0x0184 8140- 0x0184 81FC
0x0184 8200 - 0x0184 823C
0x0184 8240 - 0x0184 83FC
MAR66 - MAR73
MAR74 - MAR75
MAR76 - MAR79
MAR80 - MAR127
MAR128 - MAR143
MAR144 - MAR255
Reserved (corresponds to byte address 0x4A00 0000 - 0x4BFF FFFF)
Memory Attribute Registers for VLYNQ (corresponds to byte address
0x4C00 0000 - 0x4FFF FFFF)
Reserved (corresponds to byte address 0x5000 0000 - 0x7FFF FFFF)
Memory Attribute Registers for DDR2
(corresponds to byte address 0x8000 0000 - 0x8FFF FFFF)
Reserved (corresponds to byte address 0x9000 0000 - 0xFFFF FFFF)
2.4 Memory Map Summary
Table 2-3 shows the memory map address ranges of the device. Table 2-4 depicts the expanded map of
the Configuration Space (0x0180 0000 through 0x0FFF FFFF). The device has multiple on-chip memories
associated with its two processors and various subsystems. To help simplify software development a
unified memory map is used where possible to maintain a consistent view of device resources across all
bus masters.
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Table 2-3. Memory Map Summary
START
ADDRESS
END
ADDRESS
SIZE
(Bytes)
C64x+
MEMORY MAP
EDMA PERIPHERAL
MEMORY MAP
VPSS
MEMORY MAP
0x0000 0000
0x000F FFFF
1M
Reserved
0x0010 0000
0x0011 0000
0x0080 0000
0x0082 0000
0x00E0 8000
0x00E1 0000
0x00F0 4000
0x00F1 0000
0x00F1 8000
0x0180 0000
0x01C0 0000
0x0200 0000
0x1010 0000
0x1011 0000
0x1080 0000
0x1082 0000
0x10E0 8000
0x10E1 0000
0x10F0 4000
0x10F1 0000
0x10F1 8000
0x1100 0000
0x2000 0000
0x2000 8000
0x3000 0000
0x4000 0000
0x4200 0000
0x4300 0000
0x4400 0000
0x4500 0000
0x4600 0000
0x4700 0000
0x4800 0000
0x4900 0000
0x4A00 0000
0x4C00 0000
0x5000 0000
0x8000 0000
0x9000 0000
0x0010 FFFF
0x007F FFFF
0x0081 FFFF
0x00E0 7FFF
0x00E0 FFFF
0x00F0 3FFF
0x00F0 FFFF
0x00F1 7FFF
0x017F FFFF
0x01BF FFFF
0x01FF FFFF
0x100F FFFF
0x1010 FFFF
0x107F FFFF
0x1081 FFFF
0x10E0 7FFF
0x10E0 FFFF
0x10F0 3FFF
0x10F0 FFFF
0x10F1 7FFF
0x10FF FFFF
0x1FFF FFFF
0x2000 7FFF
0x2FFF FFFF
0x3FFF FFFF
0x41FF FFFF
0x42FF FFFF
0x43FF FFFF
0x44FF FFFF
0x45FF FFFF
0x46FF FFFF
0x47FF FFFF
0x48FF FFFF
0x49FF FFFF
0x4BFF FFFF
0x4FFF FFFF
0x7FFF FFFF
0x8FFF FFFF
0xFFFF FFFF
64K
Boot ROM
7M-64K
128K
6048K
32K
Reserved
L2 RAM/Cache(1)
Reserved
L1P RAM/Cache(1)
Reserved
Reserved
976K
48K
L1D RAM
L1D RAM/Cache(1)
32K
9120K
4M
Reserved
CFG Space
4M
CFG Bus Peripherals
Reserved
CFG Bus Peripherals
Reserved
225M
64K
Boot ROM
7M-48K
128K
6048K
32K
Reserved
L2 RAM/Cache(1)
L2 RAM/Cache(1)
Reserved
L1P RAM/Cache(1)
Reserved
L1P RAM/Cache(1)
Reserved
976K
48K
Reserved
Reserved
L1D RAM
L1D RAM/Cache(1)
L1D RAM
L1D RAM/Cache(1)
32K
1M-96K
240M
32K
Reserved
Reserved
Reserved
Reserved
DDR2 Control Regs
Reserved
DDR2 Control Regs
Reserved
256M-32K
256M
32M
Reserved
Reserved
Reserved
EMIFA Data (CS2)(2)
Reserved
EMIFA Data (CS2)(2)
16M
16M
Reserved
Reserved
16M
EMIFA Data (CS3)(2)
Reserved
EMIFA Data (CS4)(2)
EMIFA Data (CS3)(2)
Reserved
EMIFA Data (CS4)(2)
16M
16M
16M
Reserved
Reserved
16M
EMIFA Data (CS5)(2)
Reserved
EMIFA Data (CS5)(2)
Reserved
16M
32M
Reserved
Reserved
64M
VLYNQ (Remote Data)
Reserved
VLYNQ (Remote Data)
Reserved
768M
256M
1792M
DDR2 Memory Controller
Reserved
DDR2 Memory Controller
Reserved
DDR2 Memory Controller
Reserved
(1) For all bootmodes that default to DSPBOOTADDR = 0x0010 0000 (i.e., all boot modes except the EMIFA ROM Direct Boot,
BOOTMODE[3:0] = 0100, FASTBOOT = 0), the bootloader code disables all C64x+ cache (L2, L1P, and L1D) so that upon exit from the
bootloader code, all C64x+ memories are configured as all RAM (L2CFG.L2MODE = 0h, L1PCFG.L1PMODE = 0h, and
L1DCFG.L1DMODE = 0h). If cache use is required, the application code must explicitly enable the cache. For more information on boot
modes, see Section 3.4.1, Boot Modes. For more information on the bootloader, see the Using the TMS320DM643x Bootloader
Application Report (literature number SPRAAG0). For the EMIFA ROM Direct Boot (BOOTMODE[3:0] = 0100, FASTBOOT = 0), the
bootloader is not executed—that is, L2 RAM/Cache defaults to all RAM (L2CFG.L2MODE = 0h); L1P RAM/Cache defaults to all cache
(L1PCFG.L1PMODE = 7h); and L1D RAM/Cache defaults to all cache (L1DCFG.L1DMODE = 7h).
(2) The EMIFA CS0 and CS1 are not functionally supported on the DM6435 device, and therefore, are not pinned out.
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Table 2-4. Configuration Memory Map Summary
START
END
SIZE
C64x+
ADDRESS
ADDRESS
(Bytes)
0x0180 0000
0x0181 0000
0x0181 1000
0x0181 2000
0x0182 0000
0x0183 0000
0x0184 0000
0x0185 0000
0x0188 0000
0x01BC 0000
0x01BC 0100
0x01BC 0400
0x01C0 0000
0x01C1 0000
0x01C1 0400
0x01C1 0800
0x01C1 0C00
0x01C2 0000
0x01C2 0400
0x01C2 0800
0x01C2 1000
0x01C2 1400
0x01C2 1800
0x01C2 1C00
0x01C2 2000
0x01C2 2400
0x01C2 2800
0x01C2 2C00
0x01C2 3000
0x01C2 4000
0x01C2 5400
0x01C4 0000
0x01C4 0800
0x01C4 0C00
0x01C4 1000
0x01C4 2000
0x01C6 7000
0x01C6 7800
0x01C6 8000
0x01C7 0000
0x01C7 4000
0x01C8 0000
0x01C8 1000
0x01C8 2000
0x01C8 4000
0x0180 FFFF
0x0181 0FFF
0x0181 1FFF
0x0181 2FFF
0x0182 FFFF
0x0183 FFFF
0x0184 FFFF
0x0187 FFFF
0x01BB FFFF
0x01BC 00FF
0x01BC 01FF
0x01BF FFFF
0x01C0 FFFF
0x01C1 03FF
0x01C1 07FF
0x01C1 0BFF
0x01C1 FFFF
0x01C2 03FF
0x01C2 07FF
0x01C2 0FFF
0x01C2 13FF
0x01C2 17FF
0x01C2 1BFF
0x01C2 1FFF
0x01C2 23FF
0x01C2 27FF
0x01C2 2BFF
0x01C2 2FFF
0x01C2 3FFF
0x01C2 53FF
0x01C3 FFFF
0x01C4 07FF
0x01C4 0BFF
0x01C4 0FFF
0x01C4 1FFF
0x01C6 6FFF
0x01C6 77FF
0x01C6 7FFF
0x01C6 FFFF
0x01C7 3FFF
0x01C7 FFFF
0x01C8 0FFF
0x01C8 1FFF
0x01C8 3FFF
0x01C8 47FF
64K
4K
C64x+ Interrupt Controller
C64x+ Powerdown Controller
C64x+ Security ID
C64x+ Revision ID
C64x+ EMC
4K
4K
64K
64K
64K
192K
3328K
256
256
255K
64K
1K
Reserved
C64x+ Memory System
Reserved
Reserved
Reserved
Pin Manager and Trace
Reserved
EDMA CC
EDMA TC0
1K
EDMA TC1
1K
EDMA TC2
29K
1K
Reserved
UART0
1K
UART1
2K
Reserved
1K
I2C
1K
Timer0
1K
Timer1
1K
Timer2 (Watchdog)
PWM0
1K
1K
PWM1
1K
PWM2
1K
Reserved
HECC Control(1)
4K
5K
HECC RAM
107K
2K
Reserved
System Module
PLL Controller 1
PLL Controller 2
Power and Sleep Controller
Reserved
1K
1K
4K
148K
2K
GPIO
2K
HPI
32K
16K
48K
4K
Reserved
VPSS Registers
Reserved
EMAC Control Registers
EMAC Control Module Registers
EMAC Control Module RAM
MDIO Control Registers
4K
8K
2K
(1) Software must not access "Reserved" locations of the HECC. Access to HECC "Reserved" locations may hang the device.
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Table 2-4. Configuration Memory Map Summary (continued)
START
END
SIZE
C64x+
ADDRESS
ADDRESS
(Bytes)
0x01C8 4800
0x01D0 0000
0x01D0 0800
0x01D0 1000
0x01D0 1400
0x01D0 1800
0x01E0 0000
0x01E0 1000
0x01E0 2000
0x01CF FFFF
0x01D0 07FF
0x01D0 0FFF
0x01D0 13FF
0x01D0 17FF
0x01DF FFFF
0x01E0 0FFF
0x01E0 1FFF
0x0FFF FFFF
494K
2K
Reserved
McBSP0
2K
Reserved
1K
McASP0 Control
McASP0 Data
Reserved
1K
1018K
4K
EMIFA Control
4K
VLYNQ Control Registers
Reserved
226M-8K
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2.5 Pin Assignments
Extensive use of pin multiplexing is used to accommodate the largest number of peripheral functions in
the smallest possible package. Pin multiplexing is controlled using a combination of hardware
configuration at device reset and software programmable register settings. For more information on pin
muxing, see Section 3.7, Multiplexed Pin Configurations of this document.
2.5.1 Pin Map (Bottom View)
Figure 2-2 through Figure 2-5 show the bottom view of the ZWT package pin assignments in four
quadrants (A, B, C, and D). Figure 2-6 through Figure 2-9 show the bottom view of the ZDU package pin
assignments in four quadrants (A, B, C, and D).
1
2
3
4
5
6
7
8
9
10
W
V
U
T
V
V
W
V
U
T
DDR_D[7]
DDR_D[9]
DDR_D[12]
DDR_D[14]
DDR_CLK
DDR_CLK
DDR_A[12]
DDR_A[11]
SS
SS
DV
DDR_D[4]
DDR_D[3]
DDR_D[1]
TRST
DDR_D[6]
DDR_D[5]
RSV16
DDR_D[8]
DDR_DQS[0]
DDR_DQM[0]
DDR_D[11]
DDR_D[10]
DDR_D[13]
DDR_DQS[1]
DDR_DQM[1]
DDR_D[15]
DDR_RAS
DDR_CAS
DDR_CKE
DDR_BA[0]
DDR_WE
DDR_BA[1]
DDR_BA[2]
DDR_CS
DDR_A[8]
DDR_A[10]
DDR_ZN
DDR2
DDR_D[2]
DDR_D[0]
DV
DDR2
R
P
N
M
L
R
P
N
M
L
TMS
DV
V
V
DV
V
DV
V
DV
DDR2
SS
SS
DDR2
SS
DDR2
SS
DDR2
EMU0
TDO
TDI
POR
DV
V
DV
V
DV
V
SS
DD33
SS
DDR2
SS
DDR2
DV
DDR2
TCK
EMU1
RESETOUT
V
DV
V
CV
V
CV
DD
SS
DD33
SS
DD
SS
CLKOUT0/
PWM2/
GP[84]
RESET
SCL
SDA
DV
V
CV
V
CV
V
SS
DD33
SS
DD
SS
DD
HECC_RX/
TINP1L/
URXD1/
GP[56]
URTS0/
PWM0/
GP[88]
UCTS0
GP[87]
URXD0/
GP[85]
RSV3
DV
V
CV
V
CV
DD
DD33
SS
DD
SS
HECC_TX/
TOUT1L/
UTXD1/
TINP0L/
GP[98]
UTXD0/
GP[86]
K
K
V
RSV2
5
V
CV
V
CV
V
SS
SS
SS
DD
SS
DD
GP[55]
1
2
3
4
6
7
8
9
10
Figure 2-2. ZWT Pin Map [Quadrant A]
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11
12
13
14
15
16
17
18
19
W
V
U
T
W
V
U
T
DDR_A[6]
DDR_A[5]
DDR_A[0]
DDR_D[16]
DDR_D[18]
DDR_D[21]
DDR_D[27]
DV
DV
DDR2
DDR2
DDR_A[7]
DDR_A[9]
DDR_ZP
DDR_A[4]
DDR_A[3]
DDR_A[2]
DDR_A[1]
DDR_D[17]
DDR_D[19]
DDR_D[20]
DDR_VREF
DDR_D[22]
DDR_DQS[3]
DDR_DQM[3]
DDR_D[24]
DDR_D[25]
DDR_D[23]
DDR_D[29]
V
SS
DDR_DQS[2]
DDR_D[28]
DDR_D[26]
DDR_D[30]
DDR_VDDDLL DDR_VSSDLL DDR_DQM[2]
DDR_D[31]
R
P
N
M
L
R
P
N
M
L
V
DV
RSV5
DV
V
DV
V
V
V
SS
SS
DDR2
DDR2
SS
DDR2
SS
SS
DV
V
DV
V
RSV14
RSV13
RSV11
RSV15
RSV12
RSV10
RSV8
RSV9
RSV7
RSV6
DDR2
SS
DDR2
SS
SS
SS
V
CV
V
SS
V
SS
DD
CV
V
CV
V
DV
V
V
V
V
V
V
DD
SS
DD
DD33
SS
SS
SS
SS
SS
SS
CV
PLL
V
V
DV
RSV4
MXV
MXV
DD
PWR18
SS
SS
DDR2
DD
MXI/
CLKIN
K
K
CV
V
CV
V
DV
V
DV
SS
DD
SS
DD
SS
DD33
SS
DD33
11
12
13
14
15
16
17
18
19
Figure 2-3. ZWT Pin Map [Quadrant B]
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11
12
13
14
15
16
17
18
19
J
H
G
F
J
MXO
V
CV
V
DV
V
DV
V
V
SS
SS
DD
SS
DD33
SS
DD33
SS
H
G
F
CV
V
CV
V
GP[29]
GP[24]/
GP[28]
GP[25]/
GP[27]
GP[26]/
DV
V
SS
DD
SS
DD
SS
DD33
V
DV
V
DV
V
SS
GP[30]
SS
DD33
SS
DD33
(BOOTMODE2) (BOOTMODE3) (FASTBOOT)
GP[23]/
(BOOTMODE1)
EM_D[6]/
GP[20]
EM_D[7]/
GP[21]
GP[22]/
(BOOTMODE0)
EM_CS5/
GP[33]
DV
V
DV
V
SS
DD33
SS
DD33
EM_WAIT/
(RDY/BSY)
EM_D[3]/
GP[17]
EM_D[5]/
GP[19]
EM_D[4]/
GP[18]
EM_CS4/
GP[32]
E
E
D
C
B
A
RSV18
RSV19
V
EM_WE
SS
CI2(CCD10)/
EM_A[18]/
EM_D[5]/
GP[46]
C_FIELD/
EM_A[21]/
GP[34]
C_WE/
EM_R/W/
GP[35]
YI4(CCD4)/
GP[40]
EM_D[0]/
GP[14]
EM_D[2]/
GP[16]
EM_D[1]/
GP[15]
D
EM_OE
GP[31]
CI4(CCD12)/
EM_A[16]/
EM_D[3]/
GP[48]
CI0(CCD8)/
EM_A[20]/
EM_D[7]/
GP[44]
EM_BA[1]/
GP[5]/
(AEM0)
EM_BA[0]/
GP[6]/
(AEM1)
YI5(CCD5)/
GP[41]
YI2(CCD2)/
GP[38]
YI0(CCD0)/
GP[36]
EM_CS3/
GP[13]
EM_CS2/
GP[12]
C
CI5(CCD13)/
EM_A[15]/
EM_D[2]/
GP[49]
EM_A[2]/
(CLE)/GP[8]/
(AEAW0/
CI1(CCD9)/
EM_A[19]/
EM_D[6]/
GP[45]
EM_A[0]/
GP[7]/
(AEM2)
LCD_FIELD/
EM_A[3]/
GP[11]
YI6(CCD6)/
GP[42]
YI3(CCD3)/
GP[39]
YI1(CCD1)/
GP[37]
B
V
V
SS
PLLMS0)
CI3(CCD11)/
EM_A[17]/
EM_D[4]/
GP[47]
EM_A[1]/
(ALE)/GP[9]/
(AEAW1/
EM_A[4]/
GP[10]/
(AEAW2/
PLLMS2)
YI7(CCD7)/
GP[43]
VD/
GP[53]
PCLK/
GP[54]
HD/
GP[52]
A
DV
DD33
SS
PLLMS1)
11
12
13
14
15
16
17
18
19
Figure 2-4. ZWT Pin Map [Quadrant C]
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1
2
3
4
5
6
7
8
9
10
AHCLKR0/
CLKR0/
GP[101]
AXR0[1]/
DX0/
GP[104]
CLKS0/
TOUT0L/
GP[97]
V
SS
J
H
G
F
J
DV
DV
V
CV
V
CV
DD
DD33
DD33
SS
DD
SS
ACLKR0/
CLKX0/
GP[99]
AFSR0/
DR0/
GP[100]
AXR0[0]/
GP[105]
AXR0[2]/
GP[103]
DV
DD33
H
V
CV
V
CV
V
SS
SS
DD
SS
DD
AHCLKX0/
GP[108]
AFSX0/
GP[107]
AMUTE0/
GP[110]
AXR0[3]/
GP[102]
V
SS
G
DV
V
DV
V
DV
DD33
DD33
SS
DD33
SS
ACLKX0/
GP[106]
AMUTEIN0/
GP[109]
GP[4]/
PWM1
V
SS
F
DV
V
DV
V
DV
V
SS
DD33
SS
DD33
SS
DD33
E
D
C
B
A
E
GP[0]
GP[1]
GP[2]
GP[3]
RSV1
DV
V
DV
V
SS
RSV17
DD33
SS
DD33
HAS/
MDIO/
GP[83]
HRDY/
MRXD2/
GP[80]
HCNTL1/
MTXEN/
GP[75]
HD14/
MTXD0/
GP[72]
HD12/
MTXD2/
GP[70]
HD6/
HD1/
EM_A[6]/
GP[95]
EM_A[9]/
GP[92]
EM_A[12]/
GP[89]
D
VLYNQ_TXD1/ VLYNQ_RXD0/
GP[64]
GP[59]
HD0/
HCS/
MDCLK/
GP[81]
HINT/
MRXD3/
GP[82]
HDS2/
MRXD0/
GP[78]
HHWIL/
MRXDV/
GP[74]
HD11/
MTXD3/
GP[69]
HD9/
MCOL/
GP[67]
HD4/
VLYNQ_RXD3/
GP[62]
VLYNQ_
SCRUN/
GP[58]
EM_A[7]/
GP[94]
EM_A[11]/
GP[90]
C
CI7(CCD15)/
EM_A[13]/
EM_D[0]/
GP[51]
HDS1/
MRXD1/
GP[79]
HCNTL0/
MRXER/
GP[76]
HD13/
MTXD1/
GP[71]
HD10/
MCRS/
GP[68]
HD7/
HD3/
EM_A[5]/
GP[96]
EM_A[8]/
GP[93]
B
V
VLYNQ_TXD2/ VLYNQ_RXD2/
SS
GP[65]
GP[61]
CI6(CCD14)/
EM_A[14]/
EM_D[1]/
GP[50]
HR/W/
MRXCLK/
GP[77]
HD15/
MTXCLK/
GP[73]
HD8/
HD5/
VLYNQ_
CLOCK/
GP[57]
HD2/
VLYNQ_RXD1/
GP[60]
EM_A[10]/
GP[91]
A
DV
DV
VLYNQ_TXD3/ VLYNQ_TXD0/
DD33
DD33
GP[66]
GP[63]
1
2
3
4
5
6
7
8
9
10
Figure 2-5. ZWT Pin Map [Quadrant D]
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1
2
3
4
5
6
7
8
9
10
11
V
V
SS
SS
DDR_D[6]
DDR_D[8]
DDR_D[12]
DDR_D[15]
DDR_CLK0
DDR_CLK0
DDR_BS[1]
DDR_BS[2]
DDR_A[10]
AB
AA
AB
AA
DV
DDR_D[3]
DDR_D[4]
DDR_DQS[0] DDR_D[10]
DDR_D[13] DDR_DQS[1]
DDR_A[12]
DDR_WE
DDR_A[11]
DDR_CS
DDR_CKE
DDR_RAS
DDR_BS[0]
DDR_CAS
DDR2
DDR_DQM[0]
DDR_D[7]
DDR_DQM[1]
DDR_D[11]
DDR_D[9]
DDR_D[14]
DDR_D[0]
DDR_D[1]
DDR_D[2]
DDR_D[5]
RSV17
Y
Y
W
V
V
SS
V
DV
V
DV
V
SS
DDR2
SS
DV
DDR2
SS
DDR2
W
DV
TRST
TDO
EMU1
POR
SDA
TMS
TDI
V
V
V
V
DDR2
DV
DV
SS
SS
DV
SS
DV
DDR2
SS
DDR2
DDR2
DDR2
V
U
6
7
9
10
8
11
TCK
V
DV
U
SS
DDR2
EMU0
RESETOUT
RESET
DV
V
SS
DD33
T
T
CLKOUT0/
PWM2/
GP[84]
V
SS
DV
DD33
R
P
R
P
HECC_RX/
TINP1L/
URXD1/
GP[56]
UCTS0/
GP[87]
DV
V
V
CV
CV
DD
DD33
SS
SS
DD
P
N
HECC_TX/
TOUT1L/
UTXD1/
UTXD0/
GP[86]
N
SCL
V
DV
N
CV
V
V
V
SS
DD33
DD
SS
SS
GP[55]
URTS0/
PWM0/
GP[88]
URXD0/
GP[85]
M
V
RSV3
4
V
M
CV
9
CV
10
M
SS
SS
5
DD
DD
SS
1
2
3
11
Figure 2-6. ZDU Pin Map [Quadrant A]
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12
13
14
15
16
17
18
19
20
21
22
DDR_A[7]
DDR_A[9]
DDR_A[4]
DDR_A[1]
DDR_A[0]
DDR_D[18]
DDR_D[21]
DDR_D[22]
DDR_D[25]
DDR_D[28]
DV
DV
DDR2
DDR2
AB
AB
AA
AA
DDR_A[6]
DDR_A[5]
DDR_ZP
DDR_A[3]
DDR_A[2]
DDR_DQS[2] DDR_D[16]
DDR_DQM[2] DDR_D[17]
DDR_D[19] DDR_DQS[3] DDR_D[23]
DDR_D[20] DDR_DQM[3] DDR_D[24]
DDR_D[26]
DDR_D[30]
V
SS
Y
DDR_A[8]
DDR_ZN
DDR_D[27] DDR_D[29]
DDR_D[31]
Y
W
V
DDR_VDDDLL
DDR_VSSDLL
W
V
RSV5
DV
DDR_VREF
DV
V
V
V
SS
DDR2
DDR2
SS
SS
DV
V
DV
V
RSV12
RSV11
RSV13
RSV7
RSV15
RSV9
RSV6
RSV8
DV
V
DV
V
DDR2
SS
DDR2
SS
SS
DDR2
SS
DDR2
16
SS
17
13
14
12
15
U
T
V
V
V
V
U
T
SS
RSV14
RSV10
SS
R
V
V
V
V
R
P
SS
SS
SS
SS
SS
P
N
P
N
M
DV
RSV4
DV
V
DV
DD33
DD33
DD33
SS
CV
V
CV
V
V
SS
DD
DD
MXI/
CLKIN
V
DV
PLL
MXV
MXV
N
M
CV
CV
SS
DD33
PWR18
DD
DD
DD
SS
SS
V
V
DV
V
SS
M
DV
MXO
22
SS
SS
DD33
DD33
SS
18
19
20
21
12
13
14
Figure 2-7. ZDU Pin Map [Quadrant B]
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18
19
20
21
22
12
SS
13
14
GP[24]/
(BOOTMODE2)
L
V
V
CV
CV
L
K
J
V
GP[27]
L
DV
V
DD
DD
DD
SS
DD33
GP[29]
GP[28]
SS
GP[26]/
(FASTBOOT)
GP[23]/
(BOOTMODE1)
V
CV
SS
SS
K
K
DV
GP[30]
DD33
GP[22]/
(BOOTMODE0)
EM_CS5/
GP[33]
CV
CV
V
DD
J
DD
SS
V
DV
DV
DV
J
SS
DD33
GP[25]/
(BOOTMODE3)
EM_D[7]/
GP[21]
EM_CS4/
GP[32]
H
G
F
V
H
DV
SS
DD33
EM_D[1]/
GP[15]
EM_D[4]/
GP[18]
V
G
F
GP[31]
SS
DD33
EM_D[3]/
GP[17]
EM_D[6]/
GP[20]
EM_D[5]/
GP[19]
DV
V
SS
DD33
12
13
14
15
16
17
EM_BA[0]/
GP[6]/
(AEM1)
EM_D[0]/
GP[14]
EM_D[2]/
GP[16]
E
E
V
DV
V
DV
V
DV
V
SS
SS
DD33
SS
DD33
SS
DD33
DD33
LCD_FIELD/
EM_A[3]/
GP[11]
EM_WAIT/
(RDY/BSY)
EM_CS3/
GP[13]
D
D
C
B
A
RSV17
RSV18
RSV19
V
DV
V
DV
EM_OE
EM_WE
SS
DD33
SS
DD33
CI5(CCD13)/
EM_A[15]/
EM_D[2]/
GP[49]
CI1(CCD9)/
EM_A[19]/
EM_D[6]/
GP[45]
CI0(CCD8)/
EM_A[20]/
EM_D[7]/
GP[44]
EM_A[0]/
GP[7]/
(AEM2)
C_FIELD/
EM_A[21]/
GP[34]
C_WE/
EM_R/W/
GP[35]
EM_BA[1]/
GP[5[/
(AEM0)
EM_A[11]/
GP[90]
YI4(CCD4)/
GP[40]
EM_CS2/
GP[12]
C
B
A
EM_A[1]/
(ALE)/GP[9]/
(AEAW1/
EM_A[4]/
GP[10]/
(AEAW2/
PLLMS2)
CI4(CCD12)/ CI3(CCD11)/
EM_A[12]/
GP[89]
EM_A[16]/
EM_D[3]/
GP[48]
EM_A[17]/
EM_D[4]/
GP[47]
YI6(CCD6)/
GP[42]
YI5(CCD5)/
GP[41]
YI2(CCD2)
GP[38]
YI1(CCD1)/
GP[37]
YI0(CCD0)/
GP[36]
V
V
SS
PLLMS1)
EM_A[2]/
(CLE)/GP[8]/
(AEAW0/
CI7(CCD15)/ CI6(CCD14)/ CI2(CCD10)/
EM_A[13]/
EM_D[0]/
GP[51]
EM_A[14]/
EM_D[1]/
GP[50]
EM_A[18]/
EM_D[5]/
GP[46]
YI7(CCD7)/
GP[43]
YI3(CCD3)/
GP[39]
VD/
GP[53]
PCLK/
GP[54]
HD/
GP[52]
DV
DD33
SS
PLLMS0)
12
13
14
15
16
17
18
19
20
21
22
Figure 2-8. ZDU Pin Map [Quadrant C]
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1
2
3
4
5
9
10
V
11
V
CLKS0/
TOUT0L/
GP[97]
TINP0L/
GP[98]
L
K
J
L
K
J
CV
L
K
J
DV
RSV2
DV
DD33
DD
DD
SS
SS
DD33
AHCLKR0/
CLKR0/
GP[101]
AXR0[1]/
DX0/
GP[104]
AFSR0/
DR0/
GP[100]
V
CV
V
V
SS
SS
SS
DV
DD33
ACLKR0/
CLKX0/
GP[99]
AXR0[2]/
FSX0/
GP[103]
AXR0[3]/
FSR0/
GP[102]
DV
V
V
CV
CV
DD
DD33
SS
SS
DD
AHCLKX0/
GP[108]
AXR0[0]/
GP[105]
AMUTE0/
GP[110]
H
G
F
V
H
G
F
DV
SS
DD33
ACLKX0/
GP[106]
AFSX0/
GP[107]
AMUTEIN0/
GP[109]
DV
V
DD33
SS
GP[4]/
PWM1
V
SS
GP[2]
GP[0]
GP[3]
GP[1]
DV
DD33
6
7
8
9
10
11
E
D
C
B
A
V
V
V
E
DV
DV
DV
DV
V
DV
DD33
SS
SS
SS
DD33
DD33
DD33
DD33
SS
HCS/
MDCLK/
GP[81]
HINT/
MRXD3/
GP[82]
HHWIL/
MRXDV/
GP[74]
V
V
SS
D
C
B
A
SS
RSV1
V
DV
DV
DV
V
SS
SS
DD33
DD33
DD33
HAS/
MDIO/
GP[83]
HDS2/
MRXD0/
GP[78]
HRDY/
MRXD2/
GP[80]
HCNTL1/
MTXEN/
GP[75]
HD12/
MTXD2/
GP[70]
HD9/
MCOL/
GP[67]
HD6/
HD4/
HD1/
EM_A[7]/
GP[94]
EM_A[9]/
GP[92]
VLYNQ_TXD1/ VLYNQ_RXD3/ VLYNQ_RXD0/
GP[64]
HD7/
GP[62]
GP[59]
HD0/
HCNTL0/
MRXER/
GP[76]
HDS1/
MRXD1/
GP[79]
HD13/
MTXD1/
GP[71]
HD14/
MTXD0/
GP[72]
HD10/
MCRS/
GP[68]
HD3/
EM_A[6]/
AD20/
GP[95]
VLYNQ_
SCRUN/
GP[58]
EM_A[10]/
GP[91]
VLYNQ_TXD2/ VLYNQ_RXD2/
DV
DD33
GP[65]
GP[61]
HR/W/
MRXCLK/
GP[77]
HD15/
MTXCLK/
GP[73]
HD11/
MTXD3/
GP[69]
HD8/
VLYNQ_TXD3/
GP[66]
HD5/
VLYNQ_TXD0
GP[63]
VLYNQ_
CLOCK/
GP[57]
HD2/
VLYNQ_RXD1/
GP[60]
EM_A[5]/
GP[96]
EM_A[8]/
GP[93]
V
DV
SS
DD33
2
6
1
3
4
5
7
8
9
10
11
Figure 2-9. ZDU Pin Map [Quadrant D]
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2.6 Terminal Functions
The terminal functions tables (Table 2-5 through Table 2-28) identify the external signal names, the
associated pin (ball) numbers along with the mechanical package designator, the pin type, whether the pin
has any internal pullup or pulldown resistors, and a functional pin description. For more detailed
information on device configuration, peripheral selection, multiplexed/shared pin, and debugging
considerations, see the Device Configurations section of this data manual.
All device boot and configuration pins are multiplexed configuration pins— meaning they are multiplexed
with functional pins. These pins function as device boot and configuration pins only during device reset.
The input states of these pins are sampled and latched into the BOOTCFG register when device reset is
deasserted (see Note below). After device reset is deasserted, the values on these multiplexed pins no
longer have to hold the configuration.
For proper device operation, external pullup/pulldown resistors may be required on these device boot and
configuration pins. Section 3.9.1, Pullup/Pulldown Resistors discusses situations where external
pullup/pulldown resistors are required.
Note: Internal to the chip, the two device reset pins RESET and POR are logically AND’d together for the
purpose of latching device boot and configuration pins. The values on all device boot and configuration
pins are latched into the BOOTCFG register when the logical AND of RESET and POR transitions from
low-to-high.
Table 2-5. BOOT Terminal Functions
SIGNAL
TYPE(1) OTHER(2)(3)
BOOT
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
GP[25]/
(BOOTMODE3)
G16
G15
F15
F18
H21
L20
K20
J20
Bootmode configuration bits. These bootmode functions along
with the FASTBOOT function determine what device bootmode
configuration is selected.
The DM6435 device supports several types of bootmodes along
with a FASTBOOT option; for more details on the types/options,
see Section 3.4.1, Boot Modes.
GP[24]/
(BOOTMODE2)
IPD
I/O/Z
DVDD33
GP[23]/
(BOOTMODE1)
GP[22]/
(BOOTMODE0)
Fast Boot
0 = Not Fast Boot
1 = Fast Boot
GP[26]/
(FASTBOOT)
IPD
I/O/Z
G17
K19
DVDD33
EM_A[4]/GP[10]/
(AEAW2/PLLMS2)
IPD
I/O/Z
EMIFA Address Bus Width (AEAW) and Fast Boot PLL Multiplier
Select (PLLMS).
These configuration pins serve two purposes which are based
on AEM[2:0] settings.
For AEM[2:0] = 001 [8-bit EMIFA (Async) Pinout Mode 1], the
AEAW/PLLMS pins serve as the AEAW function to select
EMIFA Address Bus Width.
A17
A16
B21
B20
DVDD33
EM_A[1]/(ALE)/
GP[9]/(AEAW1/PLLMS1)
IPD
I/O/Z
DVDD33
EM_A[2]/(CLE)/
GP[8]/(AEAW0/PLLMS0)
IPD
I/O/Z
For all other AEM modes, the AEAW/PLLMS pins select the PLL
multiplier for fast boot.
B16
A20
DVDD33
For more details, see Section 3.5.1.2, EMIFA Address Width
Select (AEAW) and Fast Boot PLL Multipler Select (PLLMS).
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-5. BOOT Terminal Functions (continued)
SIGNAL
TYPE(1) OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
EM_A[0]/GP[7]/
(AEM2)
IPD
I/O/Z
Selects EMIFA Pinout Mode
B17
C17
C21
E20
DVDD33
The DM6435 supports the following EMIFA Pinout Modes:
EM_BA[0]/GP[6]/
(AEM1)
IPD
I/O/Z
AEM[2:0] = 000, No EMIFA
AEM[2:0] = 001, 8-bit EMIFA (Async) Pinout Mode 1
AEM[2:0] = 101, 8-bit EMIFA (NAND) Pinout Mode 5
DVDD33
EM_BA[1]/GP[5]/
(AEM0)
IPD
I/O/Z
C16
H16
C20
J21
DVDD33
This signal doesn't actually affect the EMIFA module. It only
affects how the EMIFA is pinned out.
For proper DM6435 device operation, if this pin is both routed
and 3-stated (not driven) during device reset, it must be pulled
down via an external resistor. For more detailed information on
pullup/pulldown resistors, see Section 3.9.1, Pullup/Pulldown
Resistors.
IPD
I/O/Z
GP[28]
GP[27]
DVDD33
For proper DM6435 device operation, if this pin is both routed
and 3-stated (not driven) during device reset, it must be pulled
up via an external resistor. For more detailed information on
pullup/pulldown resistors, see Section 3.9.1, Pullup/Pulldown
Resistors.
IPU
I/O/Z
H17
L19
DVDD33
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Table 2-6. Oscillator/PLL Terminal Functions
SIGNAL
ZWT
TYPE(1)
OTHER(2)
DESCRIPTION
ZDU
NO.
NAME
NO.
OSCILLATOR, PLL
Crystal input MXI for MX oscillator (system oscillator, typically 27 MHz).
If the internal oscillator is bypassed, this is the external oscillator clock
input.(3)
MXI/
CLKIN
K19
N22
I
MXVDD
MXO
J19
L18
M22
N21
O
S
MXVDD
Crystal output for MX oscillator
1.8 V power supply for MX oscillator. On the board, this pin can be
connected to the same 1.8 V power supply as DVDDR2
(4)
MXVDD
.
(4)
(4)
MXVSS
K18
L16
M21
N20
GND
S
Ground for MX oscillator
PLLPWR18
1.8 V power supply for PLLs
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) Specifies the operating I/O supply voltage for each signal
(3) For more information on external board connections, see Section 6.6, External Clock Input From MXI/CLKIN Pin.
(4) For more information, see the Recommended Operating Conditions table
Table 2-7. Clock Generator Terminal Functions
SIGNAL
TYPE(1) OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
CLOCK GENERATOR
This pin is multiplexed between the System Clock generator (PLL1), PWM2,
and GPIO.
CLKOUT0/
PWM2/GP[84]
IPD
I/O/Z
M1
R1
For the System Clock generator (PLL1), it is clock output CLKOUT0. This is
configurable for 27 MHz or other 27 MHz-divided-down (/1 to /32) clock
outputs.
DVDD33
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-8. RESET and JTAG Terminal Functions
SIGNAL
ZWT
TYPE(1) OTHER(2)(3)
RESET
DESCRIPTION
ZDU
NO.
NAME
NO.
IPU
DVDD33
RESET
RESETOUT
POR
M4
N3
N4
R3
T3
R2
I
Device reset
–
O/Z
Reset output status pin. The RESETOUT pin indicates when the
device is in reset.
DVDD33
IPU
DVDD33
I
Power-on reset.
JTAG
IPU
DVDD33
JTAG test-port mode select input.
For proper device operation, do not oppose the IPU on this pin.
TMS
TDO
TDI
R3
P3
P4
N1
V3
U2
U3
U1
I
–
O/Z
JTAG test-port data output
JTAG test-port data input
JTAG test-port clock input
DVDD33
IPU
DVDD33
I
IPU
DVDD33
TCK
I
JTAG test-port reset. For IEEE 1149.1 JTAG compatibility, see
the IEEE 1149.1 JTAG compatibility statement portion of this data
sheet
IPD
DVDD33
TRST
R2
V2
I
IPU
I/O/Z
EMU1
EMU0
N2
P2
T2
T1
Emulation pin 1
Emulation pin 0
DVDD33
IPU
I/O/Z
DVDD33
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-9. EMIFA Terminal Functions (Boot Configuration)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
EMIFA: BOOT CONFIGURATION
EM_A[4]/GP[10]/
(AEAW2/PLLMS2)
IPD
DVDD33
These pins are multiplexed between the EMIFA and GPIO. When
RESET or POR is asserted, these pins function as EMIFA
configuration pins. At reset if AEM[2:0] = 001 (EMIFA in 8-bit Async
mode), then the input states of AEAW[2:0] are sampled to set the
EMIFA Address Bus Width. After reset, these pins function as EMIFA
or GPIO pin functions based on pin mux selection.
A17
A16
B21
B20
I/O/Z
I/O/Z
EM_A[1]/(ALE)/GP[9]/
(AEAW1/PLLMS1)
IPD
DVDD33
EM_A[2]/(CLE)/GP[8]/
(AEAW0/PLLMS0)
IPD
DVDD33
For more details on the AEAW/PLLMS functions, see Section 3.5.1.2,
EMIFA Address Width Select (AEAW) and Fast Boot PLL Multipler
Select (PLLMS).
B16
A20
I/O/Z
EM_BA[1]/GP[5]/
(AEM0)
IPD
DVDD33
These pins are multiplexed between the EMIFA and GPIO. When
RESET or POR is asserted, these pins function as EMIFA
configuration pins. At reset, the input states of AEM[2:0] are sampled
to set the EMIFA Pinout Mode.
For more details, see Section 3.5.1, Configurations at Reset. After
reset, these pins function as EMIFA or GPIO pin functions based on
pin mux selection.
C16
C17
C20
E20
I/O/Z
I/O/Z
EM_BA[0]/GP[6]/
(AEM1)
IPD
DVDD33
EM_A[0]/GP[7]/
(AEM2)
IPD
DVDD33
B17
C21
I/O/Z
For more details on the AEM functions, see Section 3.5.1.1, EMIFA
Pinout Mode (AEM[2:0]).
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-10. EMIFA Terminal Functions (EMIFA Pinout Mode 1, AEM[2:0] = 001)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
EMIFA FUNCTIONAL PINS: 8-Bit ASYNC/NOR (EMIFA Pinout Mode 1, AEM[2:0] = 001)
Actual pin functions are determined by the PINMUX0 and PINMUX1 register bit settings (e.g., AEAW[2:0], AEM[2:0], etc.). For more details,
see Section 3.7, Multiplexed Pin Configurations.
This pin is multiplexed between EMIFA and GPIO.
For EMIFA, this pin is Chip Select 2 output EM_CS2 for use with
asynchronous memories (i.e., NOR flash).
EM_CS2/
GP[12]
IPD
DVDD33
This is the chip select for the default boot and ROM boot modes.
C19
C22
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA and GPIO.
For EMIFA, this pin is Chip Select 3 output EM_CS3 for use with
asynchronous memories (i.e., NOR flash).
EM_CS3/
GP[13]
IPD
DVDD33
C18
D22
H22
I/O/Z
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA and GPIO.
For EMIFA, it is Chip Select 4 output EM_CS4 for use with
asynchronous memories (i.e., NOR flash).
EM_CS4/
GP[32]
IPD
DVDD33
E19
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA and GPIO.
For EMIFA, it is Chip Select 5 output EM_CS5 for use with
asynchronous memories (i.e., NOR flash).
EM_CS5/
GP[33]
IPD
DVDD33
F19
D13
J22
I/O/Z
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
For EMIFA, it is read/write output EM_R/W.
C_WE/EM_R/W/
GP[35]
IPD
DVDD33
C17
EM_WAIT/
(RDY/BSY)
IPU
DVDD33
For EMIFA (ASYNC/NOR), this pin is wait state extension input
EM_WAIT.
E15
D15
E14
D20
D19
C19
I/O/Z
I/O/Z
I/O/Z
IPU
DVDD33
EM_OE
EM_WE
For EMIFA, it is output enable output EM_OE.
IPU
DVDD33
For EMIFA, it is write enable output EM_WE.
This pin is multiplexed between EMIFA and GPIO.
EM_BA[0]/GP[6]/
(AEM1)
IPD
DVDD33
For EMIFA, this is the Bank Address 0 output (EM_BA[0]). When
connected to an 8-bit asynchronous memory, this pin is the lowest
order bit of the byte address.
C17
C16
E20
C20
I/O/Z
I/O/Z
This pin is multiplexed between EMIFA and GPIO.
EM_BA[1]/GP[5]/
(AEM0)
IPD
DVDD33
For EMIFA, this is the Bank Address 1 output EM_BA[1]. When
connected to an 8-bit asynchronous memory, this pin is the 2nd bit of
the address.
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-10. EMIFA Terminal Functions (EMIFA Pinout Mode 1, AEM[2:0] = 001) (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
C_FIELD/
EM_A[21]/GP[34]
IPD
DVDD33
D12
C16
I/O/Z
For EMIFA, it is address bit 21 output EM_A[21].
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI0(CCD8)/
EM_A[20]/GP[44]
IPD
DVDD33
C12
C15
I/O/Z
For EMIFA (AEM[2:0] = 001), this pin is address bit 20 output
EM_A[20] if AEAW[2:0] = 100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI1(CCD9)/
EM_A[19]/GP[45]
IPD
DVDD33
B12
D11
A11
C11
B11
A10
B10
C14
A14
B14
B13
C13
A13
A12
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
For EMIFA (AEM[2:0] = 001), this pin is address bit 19 output
EM_A[19] if AEAW[2:0] = 100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI2(CCD10)/
EM_A[18]/GP[46]
IPD
DVDD33
For EMIFA (AEM[2:0] = 001), this pin is address bit 18 output
EM_A[18] if AEAW[2:0] = 011/100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI3(CCD11)/
EM_A[17]/GP[47]
IPD
DVDD33
For EMIFA (AEM[2:0] = 001), this pin is address bit 17 output
EM_A[17] if AEAW[2:0] = 011/100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI4(CCD12)/
EM_A[16]/GP[48]
IPD
DVDD33
For EMIFA (AEM[2:0] = 001), this pin is address bit 16 output
EM_A[16] if AEAW[2:0] = 010/011/100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI5(CCD13)/
EM_A[15]/GP[49]
IPD
DVDD33
For EMIFA (AEM[2:0] = 001), this pin is address bit 15 output
EM_A[15] if AEAW[2:0] = 010/011/100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI6(CCD14)/
EM_A[14]/GP[50]
IPD
DVDD33
For EMIFA (AEM[2:0] = 001), this pin is address bit 14 output
EM_A[14] if AEAW[2:0] = 001/010/011/100b.
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
CI7(CCD15)/
EM_A[13]/GP[51]
IPD
DVDD33
For EMIFA (AEM[2:0] = 001), this pin is address bit 13 output
EM_A[13] if AEAW[2:0] = 001/010/011/100b.
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
EM_A[12]/GP[89]
EM_A[11]/GP[90]
EM_A[10]/GP[91]
EM_A[9]/GP[92]
EM_A[8]/GP[93]
EM_A[7]/GP[94]
EM_A[6]/GP[95]
EM_A[5]/GP[96]
D10
C10
A9
B12
C12
B11
C11
A11
C10
B10
A10
B21
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
For EMIFA, this pin is address bit 12 output EM_A[12].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
For EMIFA, this pin is address bit 11 output EM_A[11].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
For EMIFA, this pin is address bit 10 output EM_A[10].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
D9
For EMIFA, this pin is address bit 9 output EM_A[9].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
B9
For EMIFA, this pin is address bit 8 output EM_A[8].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
C9
For EMIFA, this pin is address bit 7 output EM_A[7].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
D8
For EMIFA, this pin is address bit 6 output EM_A[6].
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
B8
For EMIFA, this pin is address bit 5 output EM_A[5].
This pin is multiplexed between EMIFA and GPIO.
EM_A[4]/GP[10]/
(AEAW2/PLLMS2)
IPD
DVDD33
A17
For EMIFA, this pin is address bit 4 output EM_A[4].
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Table 2-10. EMIFA Terminal Functions (EMIFA Pinout Mode 1, AEM[2:0] = 001) (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
This pin is multiplexed between EMIFA and GPIO.
IPD
DVDD33
EM_A[3]/GP[11]
B18
B16
A16
D21
A20
B20
I/O/Z
I/O/Z
I/O/Z
For EMIFA, this pin is address bit 3 output EM_A[3].
This pin is multiplexed between EMIFA and GPIO.
EM_A[2]/(CLE)/GP[8]/
(AEAW0/PLLMS0)
IPD
DVDD33
For EMIFA, this pin is address bit 2 output EM_A[2].
This pin is multiplexed between EMIFA and GPIO.
EM_A[1]/(ALE)/GP[9]/
(AEAW1/PLLMS1)
IPD
DVDD33
For EMIFA, this pin is address output EM_A[1].
This pin is multiplexed between EMIFA and GPIO.
For EMIFA, this pin is Address output EM_A[0], which is the least
significant bit on a 32-bit word address.
For an 8-bit asynchronous memory, this pin is the 3rd bit of the
address.
EM_A[0]/GP[7]/
(AEM2)
IPD
DVDD33
B17
C21
I/O/Z
IPD
DVDD33
EM_D0/GP[14]
EM_D1/GP[15]
EM_D2/GP[16]
EM_D3/GP[17]
EM_D4/GP[18]
EM_D5/GP[19]
EM_D6/GP[20]
EM_D7/GP[21]
D16
D18
D17
E16
E18
E17
F16
F17
E21
G20
E22
F20
G21
F22
F21
H20
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
These pins are multiplexed between EMIFA and GPIO.
For EMIFA (AEM[2:0] = 001), these pins are the 8-bit bi-directional
data bus (EM_D[7:0]).
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
EMIFA FUNCTIONAL PINS: 8-Bit NAND (EMIFA Pinout Mode 1, AEM[2:0] = 001)
This pin is multiplexed between EMIFA (NAND) and GPIO.
EM_A[1]/(ALE)/GP[9]/
(AEAW1/PLLMS1)
IPD
DVDD33
A16
B16
B20
A20
I/O/Z
I/O/Z
When used for EMIFA (NAND) , this pin is the Address Latch Enable
output (ALE).
This pin is multiplexed between EMIFA (NAND) and GPIO.
EM_A[2]/(CLE)/GP[8]/
(AEAW0/PLLMS0)
IPD
DVDD33
When used for EMIFA (NAND), this pin is the Command Latch
Enable output (CLE).
EM_WAIT/
(RDY/BSY)
IPU
DVDD33
E15
D15
E14
D20
D19
C19
I/O/Z
I/O/Z
I/O/Z
When used for EMIFA (NAND), it is ready/busy input (RDY/BSY).
When used for EMIFA (NAND), this pin is read enable output (RE).
IPU
DVDD33
EM_OE
EM_WE
IPU
DVDD33
When used for EMIFA (NAND), this pin is write enable output (WE).
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA (NAND), this pin is Chip Select 2 output EM_CS2 for use
with NAND flash.
EM_CS2/
GP[12]
IPD
DVDD33
This is the chip select for the default boot and ROM boot modes.
C19
C22
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
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Table 2-10. EMIFA Terminal Functions (EMIFA Pinout Mode 1, AEM[2:0] = 001) (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA (NAND), this pin is Chip Select 3 output EM_CS3 for use
with NAND flash.
EM_CS3/
GP[13]
IPD
DVDD33
C18
E19
F19
D22
H22
J22
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA (NAND), it is Chip Select 4 output EM_CS4 for use with
NAND flash.
EM_CS4/
GP[32]
IPD
DVDD33
I/O/Z
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA (NAND), it is Chip Select 5 output EM_CS5 for use with
NAND flash.
EM_CS5/
GP[33]
IPD
DVDD33
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
IPD
DVDD33
EM_D0/GP[14]
EM_D1/GP[15]
EM_D2/GP[16]
EM_D3/GP[17]
EM_D4/GP[18]
EM_D5/GP[19]
EM_D6/GP[20]
EM_D7/GP[21]
D16
D18
D17
E16
E18
E17
F16
F17
E21
G20
E22
F20
G21
F22
F21
H20
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
These pins are multiplexed between EMIFA (NAND) and GPIO.
For EMIFA (NAND) AEM[2:0] = 001, these are the 8-bit bi-directional
data bus (EM_D[7:0]).
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
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Table 2-11. EMIFA Terminal Functions (EMIFA Pinout Mode 5, AEM[2:0] = 101)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
EMIFA FUNCTIONAL PINS: 8-Bit NAND (EMIFA Pinout Mode 5, AEM[2:0] = 101)
Actual pin functions are determined by the PINMUX0 and PINMUX1 register bit settings (e.g., AEAW[2:0], AEM[2:0], etc.). For more details,
see Section 3.7, Multiplexed Pin Configurations.
This pin is multiplexed between EMIFA (NAND) and GPIO.
EM_A[1]/(ALE)/GP[9]/
(AEAW1/PLLMS1)
IPD
DVDD33
A16
B16
B20
A20
I/O/Z
I/O/Z
When used for EMIFA (NAND) , this pin is the Address Latch Enable
output (ALE).
This pin is multiplexed between EMIFA (NAND) and GPIO.
EM_A[2]/(CLE)/GP[8]/
(AEAW0/PLLMS0)
IPD
DVDD33
When used for EMIFA (NAND) , this pin is the Command Latch
Enable output (CLE).
EM_WAIT/
(RDY/BSY)
IPU
DVDD33
E15
D15
E14
D20
D19
C19
I/O/Z
I/O/Z
I/O/Z
When used for EMIFA (NAND), it is ready/busy input (RDY/BSY).
When used for EMIFA (NAND), this pin is read enable output (RE).
IPU
DVDD33
EM_OE
EM_WE
IPU
DVDD33
When used for EMIFA (NAND), this pin is write enable output (WE).
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA, this pin is Chip Select 2 output EM_CS2 for use with
NAND flash.
IPD
DVDD33
This is the chip select for the default boot and ROM boot modes.
EM_CS2/GP[12]
C19
C22
I/O/Z
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA, this pin is Chip Select 3 output EM_CS3 for use with
NAND flash.
IPD
EM_CS3/GP[13]
EM_CS4/GP[32]
EM_CS5/GP[33]
C18
E19
F19
D22
H22
J22
I/O/Z
I/O/Z
I/O/Z
DVDD33
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA, it is Chip Select 4 output EM_CS4 for use with NAND
flash.
IPD
DVDD33
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
This pin is multiplexed between EMIFA (NAND) and GPIO.
For EMIFA, it is Chip Select 5 output EM_CS5 for use with NAND
flash.
IPD
DVDD33
Note: This pin features an internal pulldown (IPD). If this pin is
connected and used as an EMIFA chip select signal, for proper
device operation, an external pullup resistor must be used to ensure
the EM_CSx function defaults to an inactive (high) state.
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-11. EMIFA Terminal Functions (EMIFA Pinout Mode 5, AEM[2:0] = 101) (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
IPD
DVDD33
EM_D0/GP[14]
EM_D1/GP[15]
EM_D2/GP[16]
EM_D3/GP[17]
EM_D4/GP[18]
EM_D5/GP[19]
EM_D6/GP[20]
EM_D7/GP[21]
D16
D18
D17
E16
E18
E17
F16
F17
E21
G20
E22
F20
G21
F22
F21
H20
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
These pins are multiplexed between EMIFA (NAND) and GPIO.
For EMIFA AEM[2:0] = 101 (NAND), these are the 8-bit bi-directional
data bus (EM_D[7:0]).
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
IPD
DVDD33
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Table 2-12. DDR2 Memory Controller Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
DDR2 Memory Controller
DDR2 Clock Output
DDR_CLK
DDR_CLK
W7
W8
V8
AB7
AB8
AA8
Y11
Y10
Y18
Y15
Y7
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DVDDR2
DDR2 Differential Clock Output
DDR2 Clock Enable Output
DDR_CKE
DDR_CS
T9
DDR2 Active Low Chip Select Output
DDR2 Active Low Write Enable Output
DDR_WE
T8
DDR_DQM[3]
DDR_DQM[2]
DDR_DQM[1]
DDR_DQM[0]
DDR_RAS
T16
T14
T6
DDR2 Data Mask Outputs
DQM3: For upper byte data bus DDR_D[31:24]
DQM2: For DDR_D[23:16]
DQM1: For DDR_D[15:8]
DQM0: For lower byte DDR_D[7:0]
T4
Y4
U7
T7
Y8
DDR2 Row Access Signal Output
DDR2 Column Access Signal Output
DDR_CAS
Y9
DDR_DQS[0]
DDR_DQS[1]
DDR_DQS[2]
U4
U6
U14
AA4
AA7
AA15
Data Strobe Input/Outputs for each byte of the 32-bit data bus. They
are outputs to the DDR2 memory when writing and inputs when
reading. They are used to synchronize the data transfers.
DQS3 : For upper byte DDR_D[31:24]
DQS2: For DDR_D[23:16]
DQS1: For DDR_D[15:8]
DQS0: For bottom byte DDR_D[7:0]
DDR_DQS[3]
U16
AA18
I/O/Z
DVDDR2
DDR_BA[0]
DDR_BA[1]
DDR_BA[2]
DDR_A[12]
DDR_A[11]
DDR_A[10]
DDR_A[9]
DDR_A[8]
DDR_A[7]
DDR_A[6]
DDR_A[5]
DDR_A[4]
DDR_A[3]
DDR_A[2]
DDR_A[1]
DDR_A[0]
U8
V9
AA9
AB9
Bank Select Outputs (BA[2:0]). Two are required to support 1Gb DDR2
memories.
I/O/Z
DVDDR2
U9
AB10
AA10
AA11
AB11
AA12
Y12
W9
W10
U10
U11
V10
V11
W11
W12
V12
U12
V13
U13
W13
AB12
AA13
Y13
I/O/Z
DVDDR2
DDR2 Address Bus Output
AB13
AA14
Y14
AB14
AB15
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Fore more information, see the Recommended Operating Conditions table
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Table 2-12. DDR2 Memory Controller Terminal Functions (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
ZDU
NO.
NAME
NO.
T19
U19
V18
U18
W17
T18
U17
V17
T17
V16
W16
U15
V15
W15
V14
W14
V7
DDR_D[31]
DDR_D[30]
DDR_D[29]
DDR_D[28]
DDR_D[27]
DDR_D[26]
DDR_D[25]
DDR_D[24]
DDR_D[23]
DDR_D[22]
DDR_D[21]
DDR_D[20]
DDR_D[19]
DDR_D[18]
DDR_D[17]
DDR_D[16]
DDR_D[15]
DDR_D[14]
DDR_D[13]
DDR_D[12]
DDR_D[11]
DDR_D[10]
DDR_D[9]
Y22
AA21
Y21
AB20
Y20
AA20
AB19
Y19
AA19
AB18
AB17
Y17
AA17
AB16
Y16
AA16
AB6
Y6
DDR2 bi-directional data bus can be configured as 32-bits wide or
16-bits wide.
I/O/Z
DVDDR2
W6
V6
AA6
AB5
Y5
W5
V5
U5
AA5
W5
W4
V4
DDR_D[8]
AB4
W4
DDR_D[7]
W3
V3
DDR_D[6]
AB3
Y3
DDR_D[5]
U3
DDR_D[4]
V2
AA3
AA2
W2
DDR_D[3]
U2
DDR_D[2]
U1
DDR_D[1]
T2
Y2
DDR_D[0]
T1
Y1
(3)
(3)
(3)
DDR_VREF
DDR_VSSDLL
DDR_VDDDLL
T15
T13
T12
W18
W15
W14
I
Reference voltage input for the SSTL_18 I/O buffers
Ground for the DDR2 DLL
GND
S
Power (1.8 Volts) for the DDR2 Digital Locked Loop
Impedance control for DDR2 outputs. This must be connected via a
(3)
(3)
DDR_ZN
DDR_ZP
T10
T11
W12
W13
200-Ω resistor to DVDDR2
Impedance control for DDR2 outputs. This must be connected via a
200-Ω resistor to VSS
.
.
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Table 2-13. EMAC and MDIO Terminal Functions
SIGNAL
ZWT
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZDU
NO.
NAME
NO.
EMAC
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Transmit Enable output MTXEN.
HCNTL1/MTXEN/
GP[75]
IPD
DVDD33
D3
A4
C6
C5
D5
B4
D4
A3
C4
B3
B5
C2
D2
B2
C3
C4
A4
C6
A5
C5
B4
B5
A3
D3
B2
B6
D2
C3
B3
C2
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Transmit Clock input MTXCLK.
HD15/MTXCLK/
GP[73]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Collision Detect input MCOL.
HD9/MCOL/
GP[67]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Transmit Data 3 output MTXD3.
HD11/MTXD3/
GP[69]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Transmit Data 2 output MTXD2.
HD12/MTXD2/
GP[70]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Transmit Data 1 output MTXD1.
HD13/MTXD1/
GP[71]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Transmit Data 0 output MTXD0.
HD14/MTXD0/
GP[72]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive Clock input MRXCLK.
HR/W/MRXCLK/
GP[77]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive Data Valid input MRXDV.
HHWIL/MRXDV/
GP[74]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive Error input MRXER.
HCNTL0/MRXER/
GP[76]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Carrier Sense input MCRS.
HD10/MCRS/
GP[68]
IPD
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive Data 3 input MRXD3.
HINT/MRXD3/
GP[82]
IPU
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive Data 2 input MRXD2.
HRDY/MRXD2/
GP[80]
IPU
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive data 1 input MRXD1.
HDS1/MRXD1/
GP[79]
IPU
DVDD33
This pin is multiplexed between HPI, Ethernet MAC (EMAC), and
GPIO.
In Ethernet MAC mode, it is Receive Data 0 input MRXD0.
HDS2/MRXD0/
GP[78]
IPU
DVDD33
MDIO
This pin is multiplexed between HPI, MDIO, and GPIO.
In Ethernet MAC mode, it is Management Data Clock output
MDCLK.
HCS/MDCLK/
GP[81]
IPU
DVDD33
C1
D1
D1
C1
I/O/Z
I/O/Z
HAS/MDIO/
GP[83]
IPU
DVDD33
This pin is multiplexed between HPI, MDIO, and GPIO.
In Ethernet MAC mode, it is Management Data IO MDIO (I/O/Z).
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-14. VLYNQ Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
VLYNQ
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
VLYNQ_CLOCK/
GP[57]
IPU
DVDD33
This pin is multiplexed between VLYNQ, and GPIO.
For VLYNQ, it is the clock VLYNQ_CLOCK (I/O/Z).
A7
C8
A8
B9
I/O/Z
I/O/Z
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is the Serial Clock run request VLYNQ_SCRUN
(I/O/Z).
HD0/VLYNQ_SCRUN/
GP[58]
IPU
DVDD33
HD8/VLYNQ_TXD3/
GP[66]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is transmit bus bit 3 output VLYNQ_TXD3.
A5
B6
D6
A6
C7
B7
A8
D7
A6
B7
C7
A7
C8
B8
A9
C9
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
HD7/VLYNQ_TXD2/
GP[65]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is transmit bus bit 2 output VLYNQ_TXD2.
HD6/VLYNQ_TXD1/
GP[64]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is transmit bus bit 1 output VLYNQ_TXD1.
HD5/VLYNQ_TXD0/
GP[63]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is transmit bus bit 0 output (VLYNQ_TXD0).
HD4/VLYNQ_RXD3/
GP[62]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is receive bus bit 3 input VLYNQ_RXD3.
HD3/VLYNQ_RXD2/
GP[61]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is receive bus bit 2 input VLYNQ_RXD2.
HD2/VLYNQ_RXD1/
GP[60]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is receive bus bit 1 input VLYNQ_RXD1.
HD1/VLYNQ_RXD0/
GP[59]
IPD
DVDD33
This pin is multiplexed between HPI, VLYNQ, and GPIO.
For VLYNQ, it is receive bus bit 0 input VLYNQ_RXD0.
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-15. Host-Port Interface Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
Host-Port Interface (HPI)
HD0/VLYNQ_SCRUN/
GP[58]
IPU
DVDD33
C8
D7
A8
B7
C7
A6
D6
B6
A5
C6
B5
C5
D5
B4
D4
A4
B9
C9
A9
B8
C8
A7
C7
B7
A6
C6
B6
A5
C5
B4
B5
A4
HD1/VLYNQ_RXD0/
GP[59]
HD2/VLYNQ_RXD1/
GP[60]
HD3/VLYNQ_RXD2/
GP[61]
HD4/VLYNQ_RXD3/
GP[62]
HD5/VLYNQ_TXD0/
GP[63]
HD6/VLYNQ_TXD1/
GP[64]
This pin is multiplexed between HPI, VLYNQ or EMAC, and
GPIO.
In HPI mode, these pins are host-port data pins HD[15:0]
(I/O/Z) and are multiplexed internally with the HPI address
lines.
HD7/VLYNQ_TXD2/
GP[65]
I/O/Z
HD8/VLYNQ_TXD3/
GP[66]
IPD
DVDD33
HD9/MCOL/
GP[67]
HD10/MCRS/
GP[68]
HD11/MTXD3/
GP[69]
HD12/MTXD2/
GP[70]
HD13/MTXD1/
GP[71]
HD14/MTXD0/
GP[72]
HD15/MTXCLK/
GP[73]
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is half-word identification input HHWIL
(I).
HHWIL/MRXDV/
GP[74]
IPD
DVDD33
C4
D3
D3
C4
I/O/Z
I/O/Z
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is control input 1 HCNTL1 (I). The state
of HCNTL1 and HCNTL0 determines if address, data, or
control information is being transmitted between an external
host and the DM6435.
HCNTL1/MTXEN/
GP[75]
IPD
DVDD33
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is control input 0 HCNTL0 (I). The state
of HCNTL1 and HCNTL0 determines if address, data, or
control information is being transmitted between an external
host and the DM6435.
HCNTL0/MRXER/
GP[76]
IPD
DVDD33
B3
B2
I/O/Z
HR/W/MRXCLK/
GP[77]
IPD
DVDD33
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is host read or write select HR/W(I).
A3
C3
B2
A3
C2
B3
I/O/Z
I/O/Z
I/O/Z
HDS2/MRXD0/
GP[78]
IPU
DVDD33
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is host data strobe input 2 HDS2 (I).
HDS1/MRXD1/
GP[79]
IPU
DVDD33
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is host data strobe input 1 HDS1 (I).
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-15. Host-Port Interface Terminal Functions (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is host ready output from DSP to host
(O/Z).
HRDY/MRXD2/
GP[80]
IPU
DVDD33
D2
C3
I/O/Z
This pin is multiplexed between HPI, MDIO, and GPIO.
In HPI mode, this pin is HPI active low chip select input HCS
(I).
HCS/MDCLK/
GP[81]
IPU
DVDD33
C1
C2
D1
D2
I/O/Z
I/O/Z
HINT/RXD3/
GP[82]
IPU
DVDD33
This pin is multiplexed between HPI, EMAC, and GPIO.
In HPI mode, this pin is host interrupt output HINT (O/Z).
This pin is multiplexed between HPI, MDIO, and GPIO.
In HPI mode, this pin is host address strobe HAS (I).
For proper HPI operation, if this pin is routed out, it must be
pulled up via an external resistor.
HAS/MDIO/
GP[83]
IPU
DVDD33
D1
C1
I/O/Z
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Table 2-16. VPFE Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
VIDEO/IMAGE IN (VPFE)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
In VPFE mode, this pin is the pixel clock input (PCLK) used to load
image data into the CCD Controller (CCDC) on pins CI[7:0] and
YI[7:0].
IPD
DVDD33
PCLK/GP[54]
VD/GP[53]
HD/GP[52]
A14
A13
A15
A18
A17
A19
I/O/Z
I/O/Z
I/O/Z
This pin is multiplexed between the VPFE (CCDC) and GPIO.
In VPFE mode, this pin is the vertical synchronization signal (VD) that
can be either an input (slave mode) or an output (master mode),
which signals the start of a new frame to the CCDC.
IPD
DVDD33
This pin is multiplexed between the VPFE (CCDC) and GPIO.
In VPFE mode, this pin is the horizontal synchronization signal (HD)
that can be either an input (slave mode) or an output (master mode),
which signals the start of a new line to the CCDC.
IPD
DVDD33
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
When used by the CCDC as input CI7, it supports several modes:
In 16-bit CCD Raw mode, it is input CCD15.
In 16-bit YCbCr mode, it is time multiplexed between CB7, and CR7
inputs.(4)
CI7(CCD15)/
EM_A[13]/GP[51]
IPD
DVDD33
B10
A10
B11
A12
A13
C13
I/O/Z
I/O/Z
I/O/Z
In 8-bit YCbCr mode, it is time multiplexed between Y7, CB7, and
CR7 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
When used by the CCDC as input CI6, it supports several modes:
In 16-bit CCD Raw mode, it is input CCD14.
In 16-bit YCbCr mode, it is time multiplexed between CB6, and CR6
inputs.(4)
CI6(CCD14)/
EM_A[14]/GP[50]
IPD
DVDD33
In 8-bit YCbCr mode, it is time multiplexed between Y6, CB6, and
CR6 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
When used by the CCDC as input CI5, it supports several modes:
In 16-bit CCD Raw mode, it is input CCD13.
In 16-bit YCbCr mode, it is time multiplexed between CB5 and CR5
inputs.(4)
CI5(CCD13)/
EM_A[15]/GP[49]
IPD
DVDD33
In 8-bit YCbCr mode, it is time multiplexed between Y5, CB5, and
CR5 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
When used by the CCDC as input CI4, it supports several modes:
CI4(CCD12)/
EM_A[16]/GP[48]
IPD
DVDD33
C11
B13
I/O/Z
In 16-bit CCD Raw mode, it is input CCD12.
In 16-bit YCbCr mode, it is time multiplexed between CB4 and CR4
inputs.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y4, CB4, and
CR4 of the upper 8-bit channel.(4)
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
(4) In addition to these default functions, in YCbCr mode, the VPFE CCD Configuration register CCDCFG.YCINSWP bit field allows the
user to swap the function of the YI[7:0] and CI[7:0] pins.
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Table 2-16. VPFE Terminal Functions (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
When used by the CCDC as input CI3, it supports several modes:
CI3(CCD11)/
EM_A[17]/GP[47]
IPD
DVDD33
A11
D11
B12
C12
B14
A14
C14
C15
I/O/Z
In 16-bit CCD Raw mode, it is input CCD11.
In 16-bit YCbCr mode, it is time multiplexed between CB3 and CR3
inputs.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y3, CB3, and
CR3 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
This pin is CCDC input CI2 and it supports several modes:
CI2(CCD10)/
EM_A[18]/GP[46]
IPD
DVDD33
I/O/Z
I/O/Z
I/O/Z
In 16-bit CCD Raw mode, it is input CCD10.
In 16-bit YCbCr mode, it is time multiplexed between CB2 and CR2
inputs.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y2, CB2, and
CR2 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
This pin is CCDC input CI1 and it supports several modes:
CI1(CCD9)/
EM_A[19]/GP[45]
IPD
DVDD33
In 16-bit CCD Raw mode, it is input CCD9.
In 16-bit YCbCr mode, it is time multiplexed between CB1 and CR1
inputs.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y1, CB1, and
CR1 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC), EMIFA, and
GPIO.
This pin is CCDC input CI0 and it supports several modes:
CI0(CCD8)/
EM_A[20]/GP[44]
IPD
DVDD33
In 16-bit CCD Raw mode, it is input CCD8.
In 16-bit YCbCr mode, it is time multiplexed between CB0 and CR0
inputs.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y0, CB0, and
CR0 of the upper 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
his pin is CCDC input YI7 and it supports several modes:
YI7(CCD7)/
GP[43]
IPD
DVDD33
A12
B13
C13
A15
B15
B16
I/O/Z
I/O/Z
I/O/Z
In 16-bit CCD Raw mode, it is input CCD7.
In 16-bit YCbCr mode, it is input Y7.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y7, CB7, and
CR7 of the lower 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
This pin is CCDC input YI6 and it supports several modes:
YI6(CCD6)/
GP[42]
IPD
DVDD33
In 16-bit CCD Raw mode, it is input CCD6.
In 16-bit YCbCr mode, it is input Y6.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y6, CB6, and
CR6 of the lower 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
This pin is CCDC input YI5 and it supports several modes:
YI5(CCD5)/
GP[41]
IPD
DVDD33
In 16-bit CCD Raw mode, it is input CCD5.
In 16-bit YCbCr mode, it is input Y5.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y5, CB5, and
CR5 of the lower 8-bit channel.(4)
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Table 2-16. VPFE Terminal Functions (continued)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
This pin is multiplexed between the VPFE(CCDC) and GPIO.
This pin is CCDC input YI4 and it supports several modes:
In 16-bit CCD Raw mode, it is input CCD4.
YI4(CCD4)/
GP[40]
IPD
DVDD33
D14
B14
C14
B15
C15
C18
A16
B17
B18
B19
I/O/Z
In 16-bit YCbCr mode, it is input Y4.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y4, CB4, and
CR4 of the lower 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
This pin is CCDC input YI3 and it supports several modes:
In 16-bit CCD Raw mode, it is input CCD3.
YI3(CCD3)/
GP[39]
IPD
DVDD33
I/O/Z
I/O/Z
I/O/Z
I/O/Z
In 16-bit YCbCr mode, it is input Y3.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y3, CB3, and
CR3 of the lower 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
This pin is CCDC input YI2 and it supports several modes:
In 16-bit CCD Raw mode, it is input CCD2.
YI2(CCD2)/
GP[38]
IPD
DVDD33
In 16-bit YCbCr mode, it is input Y2.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y2, CB2, and
CR2 of the lower 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
This pin is CCDC input YI1 and it supports several modes:
In 16-bit CCD Raw mode, it is input CCD1.
YI1(CCD1)/
GP[37]
IPD
DVDD33
In 16-bit YCbCr mode, it is input Y1.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y1, CB1, and
CR1 of the lower 8-bit channel.(4)
This pin is multiplexed between the VPFE (CCDC) and GPIO.
This pin is CCDC input YI0 and it supports several modes:
In 16-bit CCD Raw mode, it is input CCD0.
YI0(CCD0)/
GP[36]
IPD
DVDD3
In 16-bit YCbCr mode, it is input Y0.(4)
In 8-bit YCbCr mode, it is time multiplexed between Y0, CB0, and
CR0 of the lower 8-bit channel.(4)
C_WE/EM_R/W/
GP[35]
IPD
DVDD33
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
In VPFE mode, it is the CCD Controller write enable input C_WE.
D13
D12
C17
C16
I/O/Z
I/O/Z
This pin is multiplexed between VPFE (CCDC), EMIFA, and GPIO.
In VPFE mode, it is CCDC field identification bidirectional signal
C_FIELD.
C_FIELD/EM_A[21]/
GP[34]
IPD
DVDD33
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Table 2-17. I2C Terminal Functions
SIGNAL
ZWT
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZDU
NO.
NAME
NO.
I2C
For I2C, this pin is I2C clock. In I2C master mode, this pin is an
output. In I2C slave mode, this pin is an input.
When the I2C module is used, for proper device operation, this pin
must be pulled up via an external resistor.
SCL
SDA
M2
M3
N2
P2
I/O/Z
I/O/Z
DVDD33
For I2C, this pin is the I2C bi-directional data signal.
When the I2C module is used, for proper device operation, this pin
must be pulled up via an external resistor.
DVDD33
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-18. Multichannel Buffered Serial Port 0 (McBSP0) Terminal Functions
SIGNAL
ZWT
NO.
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZDU
NO.
NAME
Multichannel Buffered Serial Port 0 (McBSP0)
For more details on pin multiplexing, see Section 3.7, Multiplexed Pin Configurations.
CLKS0/TOUT0L/
GP[97]
IPD
DVDD33
This pin is multiplexed between McBSP0, Timer0, and GPIO.
For McBSP0, it is McBSP0 external clock source (I).
J4
H1
J2
L3
J1
K1
I/O/Z
I/O/Z
I/O/Z
ACLKR0/CLKX0/
GP[99]
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McBSP0, it is McBSP0 transmit clock CLKX0 (I/O/Z).
AHCLKR0/CLKR0/
GP[101]
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McBSP0, it is McBSP0 receive clock CLKR0 (I/O/Z).
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McBSP0, it is McBSP0 transmit frame synchronization FSX0
(I/O/Z).
AXR0[2]/FSX0/
GP[103]
IPD
DVDD33
H3
G4
J2
J3
I/O/Z
I/O/Z
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McBSP0, it is McBSP0 receive frame synchronization FSR0
(I/O/Z).
AXR0[3]/FSR0/
GP[102]
IPD
DVDD33
AXR0[1]/DX0/
GP[104]
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McBSP0, it is McBSP0 data transmit output DX0 (O/Z).
J3
K2
K3
I/O/Z
I/O/Z
AFSR0/DR0/
GP[100]
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McBSP0, it is McBSP0 data receive input DR0 (I).
H4
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-19. Multichannel Audio Serial Port (McASP0) Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
McASP0
AMUTEIN0/
GP[109]
IPD
DVDD33
This pin is multiplexed between McASP0 and GPIO.
For McASP0, it is McASP0 mute input AMUTEIN0 (I).
F2
G3
H1
G3
H3
J1
I/O/Z
I/O/Z
I/O/Z
IPD
DVDD33
This pin is multiplexed between McASP0 and GPIO.
For McASP0, it is McASP0 mute output AMUTE0 (O/Z).
AMUTE0/GP[110]
ACLKR0/CLKX0/
GP[99]
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McASP0, it is McASP0 receive bit clock ACLKR0 (I/O/Z).
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McASP0, it is McASP0 receive high-frequency master clock
AHCLKR0 (I/O/Z).
AHCLKR0/CLKR0/
GP[101]
IPD
DVDD33
J2
F1
G1
K1
G1
H1
I/O/Z
I/O/Z
I/O/Z
IPD
DVDD33
This pin is multiplexed between McASP0 and GPIO.
For McASP0, it is McASP0 transmit bit clock ACLKX0 (I/O/Z).
ACLKX0/GP[106]
AHCLKX0/GP[108]
This pin is multiplexed between McASP0 and GPIO.
For McASP0, it is McASP0 transmit high-frequency master clock
AHCLKX0 (I/O/Z).
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McASP0, it is McASP0 receive frame synchronization AFSX0
(I/O/Z).
AFSR0/DR0/
GP[100]
IPD
DVDD33
H4
G2
G4
H3
J3
K3
G2
J3
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
This pin is multiplexed between McASP0 and GPIO.
For McASP0, it is McASP0 transmit frame synchronization AFSR0
(I/O/Z).
IPD
DVDD33
AFSX0/GP[107]
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McASP0, it is McASP0 transmit/receive (TX/RX) data pin 3
AXR0[3] (I/O/Z).
AXR0[3]/FSR0/
GP[102]
IPD
DVDD33
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McASP0, it is McASP0 transmit/receive (TX/RX) data pin 2
AXR0[2] (I/O/Z).
AXR0[2]/FSX0/
GP[103]
IPD
DVDD33
J2
This pin is multiplexed between McASP0, McBSP0, and GPIO.
For McASP0, it is McASP0 transmit/receive (TX/RX) data pin 1
AXR0[1] (I/O/Z).
AXR0[1]/DX0/
GP[104]
IPD
DVDD33
K2
H2
This pin is multiplexed between McASP0 and GPIO.
For McASP0, it is McASP0 transmit/receive (TX/RX) data pin 0
AXR0[0] (I/O/Z).
IPD
DVDD33
AXR0[0]/GP[105]
H2
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-20. High-End Controller Area Network (HECC)
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
HECC
HECC_RX/
TINP1L/
URXD1/
GP[56]
IPU
DVDD33
This pin is multiplexed between HECC, Timer 1, UART1, and GPIO.
For HECC, this pin is HECC receive serial data HECC_RX (I).
L4
K4
P3
N3
I/O/Z
I/O/Z
HECC_TX/
TOUT1L/
UTXD1/
IPU
DVDD33
This pin is multiplexed between HECC, Timer 1, UART1, and GPIO.
For HECC, this pin is HECC transmit serial data HECC_TX (O/Z).
GP[55]
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-21. UART0 and UART1 Terminal Functions
SIGNAL
ZWT
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZDU
NO.
NAME
NO.
UART1
HECC_RX/
TINP1L/
URXD1/
GP[56]
This pin is multiplexed between the HECC, Timer 1, UART1 (Data),
and GPIO.
Fo UART1 this pin is the receive data input URXD1.
IPU
DVDD33
L4
P3
N3
I/O/Z
I/O/Z
HECC_TX/
TOUT1L/
UTXD1/
This pin is multiplexed between the HECC, Timer 1, UART1 (Data),
and GPIO.
Fo UART1 this pin is the transmit data output UTXD1.
IPU
DVDD33
K4
GP[55]
UART0
URXD0/
GP[85]
IPU
DVDD33
This pin is multiplexed between UART0 (Data) and GPIO.
When used by UART0 this pin is the receive data input URXD0.
L2
K3
L1
M2
N1
P1
I/O/Z
I/O/Z
I/O/Z
UTXD0/
GP[86]
IPU
DVDD33
This pin is multiplexed between UART0 (Data) and GPIO.
In UART0 mode, this pin is the transmit data output UTXD0.
UCTS0
GP[87]
IPU
DVDD33
This pin is multiplexed between the UART0 (Flow Control) and GPIO.
In UART0 mode, this pin is the clear to send input UCTS0.
URTS0
PWM0
GP[88]
This pin is multiplexed between the UART0 (Flow Control), PWM0,
and GPIO.
In UART0 mode, this pin is the ready to send output URTS0.
IPU
DVDD33
L3
M3
I/O/Z
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-22. PWM0, PWM1, and PWM2 Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
PWM2
This pin is multiplexed between the System Clock generator (PLL1),
PWM2, and GPIO.
For PWM2, this pin is output PWM2.
CLKOUT0/PWM2/
GP[84]
IPD
DVDD33
M1
F3
L3
R1
F3
I/O/Z
I/O/Z
I/O/Z
PWM1
IPD
DVDD33
This pin is multiplexed between GPIO and PWM1.
For PWM1, this pin is output PWM1.
GP[4]/PWM1
PWM0
This pin is multiplexed between the UART0 (Flow Control), PWM0,
and GPIO.
For PWM0, this pin is output PWM0.
URTS0/PWM0/
GP[88]
IPU
DVDD33
M3
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-23. Timer 0, Timer 1, and Timer 2 Terminal Functions
SIGNAL
ZWT
NO.
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZDU
NO.
NAME
Timer 2
No external pins. The Timer 2 (watchdog) peripheral pins are not pinned out as external pins.
Timer 1
HECC_RX/
TINP1L/
URXD1/
GP[56]
This pin is multiplexed between the HECC, Timer 1, UART1 (Data),
and GPIO.
For Timer 1, this pin is the timer 1 input pin for the lower 32-bit
counter
IPU
DVDD33
L4
K4
P3
N3
I/O/Z
I/O/Z
HECC_TX/
TOUT1L/
UTXD1/
This pin is multiplexed between the HECC, Timer 1, UART1, and
GPIO.
For Timer 1, this pin is the timer 1 output pin for the lower 32-bit
counter
IPU
DVDD33
GP[55]
Timer 0
This pin is multiplexed between the Timer 0 and GPIO.
For Timer 0, this pin is the timer 0 input pin for the lower 32-bit
counter
TINP0L/
GP[98]
IPD
DVDD33
K2
J4
L2
L3
I/O/Z
I/O/Z
CLKS0/
TOUT0L/
GP[97]
This pin is multiplexed between the McBSP0, Timer 0, and GPIO.
For Timer 0, this pin is the timer 0 output pin for the lower 32-bit
counter
IPD
DVDD33
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-24. GPIO Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
GPIO
97 out of 111 GPIO pins on the DM6435 device are multiplexed with other peripherals pin functions (e.g., VPFE, HPI, VLYNQ,
EMAC/MDIO, McASP0, McBSP0, Timer 0, Timer 1, UART0, UART1, PWM0, PWM1, PWM2, EMIFA, and the CLKOUT0 pin), see the
peripheral-specific Terminal Functions tables for the GPIO multiplexing.
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-25. Standalone GPIO 3.3 V Terminal Functions
SIGNAL
ZWT
TYPE(1)
OTHER(2)(3)
Standalone GPIO 3.3 V
DESCRIPTION
ZDU
NO.
NAME
NO.
IPD
DVDD33
GP[0]
GP[1]
GP[2]
GP[3]
E1
E2
E1
E2
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
I/O/Z
This pin functions as standalone GPIO pin 0.
This pin functions as standalone GPIO pin 1.
This pin functions as standalone GPIO pin 2.
This pin functions as standalone GPIO pin 3.
IPD
DVDD33
IPD
DVDD33
E3
F1
IPD
DVDD33
E4
F2
GP[22]/
(BOOTMODE0)
IPD
DVDD33
F18
F15
G15
G16
G17
J20
K20
L20
H21
K19
GP[23]/
(BOOTMODE1)
IPD
DVDD33
GP[24]/
(BOOTMODE2)
IPD
DVDD33
These pins function as boot configuration pins during device reset.
After device reset, these pins function as standalone GPIO.
GP[25]/
(BOOTMODE3)
IPD
DVDD33
GP[26]/
(FASTBOOT)
IPD
DVDD33
For proper DM6435 device operation, this pin must be pulled up via
an external resistor.
After device reset, this pin functions as standalone GPIO pin 27.
IPU
DVDD33
GP[27]
GP[28]
H17
H16
L19
J21
I/O/Z
I/O/Z
For proper DM6435 device operation, this pin must be pulled down
via an external resistor.
After device reset, this pin functions as standalone GPIO pin 28.
IPD
DVDD33
IPD
DVDD33
GP[29]
GP[30]
GP[31]
H15
G19
D19
K21
K22
G22
I/O/Z
I/O/Z
I/O/Z
This pin functions as standalone GPIO pin 29.
This pin functions as standalone GPIO pin 30.
This pin functions as standalone GPIO pin 31.
IPD
DVDD33
IPD
DVDD33
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-26. Reserved Terminal Functions
SIGNAL
TYPE(1)
OTHER(2)(3)
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
RESERVED
RSV1
RSV2
RSV3
RSV4
RSV5
E5
K5
D4
L4
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
L5
M4
L15
R13
P19
W16
Reserved. This pin must be tied directly to VSS for normal device
operation.
RSV6
N19
V22
RSV7
RSV8
RSV9
RSV10
P19
P18
N18
N17
V21
U22
T21
T22
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. This pin must be tied directly to VSS for normal device
operation.
RSV11
RSV12
RSV13
RSV14
RSV15
RSV16
RSV17
RSV18
RSV19
P16
P17
N15
P15
N16
T3
U20
V20
T20
T19
U21
W3
Reserved. This pin must be tied directly to VSS for normal device
operation.
Reserved. This pin must be tied directly to VSS for normal device
operation.
Reserved. This pin must be tied directly to VSS for normal device
operation.
Reserved. This pin must be tied directly to VSS for normal device
operation.
IPD
DVDD33
Reserved. For proper DM6435 device operation, this pin must be
pulled down via an external resistor and tied to VSS.
I
IPD
DVDD33
E10
E11
E12
D12
D13
D14
I/O/Z
I/O/Z
I/O/Z
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
Reserved. (Leave unconnected, do not connect to power or ground)
IPD
DVDD33
IPD
DVDD33
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
(2) IPD = Internal pulldown, IPU = Internal pullup. For more detailed information on pullup/pulldown resistors and situations where external
pullup/pulldown resistors are required, see Section 3.9.1, Pullup/Pulldown Resistors.
(3) Specifies the operating I/O supply voltage for each signal
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Table 2-27. Supply Terminal Functions
SIGNAL
ZWT
TYPE(1) OTHER
SUPPLY VOLTAGE PINS
DESCRIPTION
ZDU
NO.
NAME
NO.
A1
A2
A2
A21
B1
A18
E6
D6
E8
D8
F5
D10
D16
D18
E3
F7
F9
F11
F13
G6
E5
E7
G8
E9
G10
G12
G14
H5
E11
E13
E15
E17
E19
F4
H18
J1
J6
F18
G5
J14
J16
K15
K17
L6
3.3 V I/O supply voltage
(see the Power-Supply Decoupling section of this data manual)
DVDD33
S
G19
H4
H18
J5
M5
M15
N6
J19
K4
K18
L1
P1
L5
L21
M18
M20
N5
N19
P4
P18
P20
P22
R5
T4
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
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Table 2-27. Supply Terminal Functions (continued)
SIGNAL
TYPE(1) OTHER
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
L14
P5
U5
V1
P7
V4
P9
V6
P11
P13
R4
V8
V10
V12
V14
V16
V18
W7
R6
R8
1.8 V DDR2 I/O supply voltage
(see the Power-Supply Decoupling section of this data manual)
DVDDR2
S
R10
R12
R14
R16
T5
W9
W11
W17
W19
AA1
AB21
AB22
J10
J11
J12
J13
K9
V1
W18
W19
H7
H9
H11
H13
J8
J10
J12
K7
K14
L9
L13
L14
M9
K9
K11
K13
L8
1.20 V supply voltage (-6, -5, -5Q, -5S, -4, -4Q, -4S devices)
1.05 V core supply voltage (-6 when SYSCLK1 ≤ 400 MHz)
(see the Power-Supply Decoupling section of this data manual)
CVDD
M10
M14
N9
S
L10
L12
M7
N14
P10
P11
P12
P13
M9
M11
M13
N8
N10
N12
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Table 2-28. Ground Terminal Functions
SIGNAL
ZWT
TYPE(1) OTHER
DESCRIPTION
ZDU
NO.
NAME
NO.
GROUND PINS
A19
B1
A1
A22
B22
D5
B19
E7
E9
D7
E13
F4
D9
D11
D15
D17
E4
F6
F8
F10
F12
F14
G5
E6
E8
E10
E12
E14
E16
E18
F5
G7
G9
G11
G13
G18
H6
F19
G4
VSS
H8
GND
Ground pins
H10
H12
H14
H19
J5
G18
H5
H19
J4
J9
J7
J14
J18
K5
J9
J11
J13
J15
J17
J18
K1
K10
K11
K12
K13
L10
L11
L12
L18
L22
M1
K6
K8
K10
K12
K14
K16
M5
(1) I = Input, O = Output, Z = High impedance, S = Supply voltage, GND = Ground, A = Analog signal
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Table 2-28. Ground Terminal Functions (continued)
SIGNAL
TYPE(1) OTHER
DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
L7
L9
M11
M12
M13
M19
N4
L11
L13
L17
L19
M6
N10
N11
N12
N13
N18
P5
M8
M10
M12
M14
M16
M17
M18
M19
N5
P9
P14
P21
R4
R18
R19
R20
R21
R22
T5
N7
N9
N11
N13
N14
P6
VSS
T18
U4
GND
Ground pins
P8
P10
P12
P14
R1
U18
U19
V5
V7
R5
V9
R7
V11
V13
V15
V17
V19
W1
R9
R11
R15
R17
R18
R19
V19
W1
W2
W6
W8
W10
W20
W21
W22
AA22
AB1
AB2
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2.7 Device Support
2.7.1 Development Support
TI offers an extensive line of development tools for the TMS320DM643x DMP platform, including tools to
evaluate the performance of the processors, generate code, develop algorithm implementations, and fully
integrate and debug software and hardware modules. The tool's support documentation is electronically
available within the Code Composer Studio™ Integrated Development Environment (IDE).
The following products support development of TMS320DM643x DMP-based applications:
Software Development Tools:
Code Composer Studio™ Integrated Development Environment (IDE): including Editor
C/C++/Assembly Code Generation, and Debug plus additional development tools
Scalable, Real-Time Foundation Software (DSP/BIOS™), which provides the basic run-time target
software needed to support any SoC application.
Hardware Development Tools:
Extended Development System (XDS™) Emulator (supports TMS320DM643x DMP multiprocessor
system debug) EVM (Evaluation Module)
For a complete listing of development-support tools for the TMS320DM643x DMP platform, visit the
Texas Instruments web site on the Worldwide Web at http://www.ti.com uniform resource locator
(URL). For information on pricing and availability, contact the nearest TI field sales office or authorized
distributor.
2.8 Device and Development-Support Tool Nomenclature
To designate the stages in the product development cycle, TI assigns prefixes to the part numbers of all
DSP devices and support tools. Each DSP commercial family member has one of three prefixes: TMX,
TMP, or TMS (e.g., TMX320DM6435ZWT400). Texas Instruments recommends two of three possible
prefix designators for its support tools: TMDX and TMDS. These prefixes represent evolutionary stages of
product development from engineering prototypes (TMX/TMDX) through fully qualified production
devices/tools (TMS/TMDS).
Device development evolutionary flow:
TMX
TMP
TMS
Experimental device that is not necessarily representative of the final device's electrical
specifications.
Final silicon die that conforms to the device's electrical specifications but has not completed
quality and reliability verification.
Fully-qualified production device.
Support tool development evolutionary flow:
TMDX
Development-support product that has not yet completed Texas Instruments internal
qualification testing.
TMDS
Fully qualified development-support product.
TMX and TMP devices and TMDX development-support tools are shipped against the following
disclaimer:
"Developmental product is intended for internal evaluation purposes."
TMS devices and TMDS development-support tools have been characterized fully, and the quality and
reliability of the device have been demonstrated fully. TI's standard warranty applies.
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Predictions show that prototype devices (TMX or TMP) have a greater failure rate than the standard
production devices. Texas Instruments recommends that these devices not be used in any production
system because their expected end-use failure rate still is undefined. Only qualified production devices are
to be used.
TI device nomenclature also includes a suffix with the device family name. This suffix indicates the
package type (for example, ZWT), the temperature range (for example, "Blank" is the commercial
temperature range), and the device speed range in megahertz (for example, "6" indicates [600-MHz]).
Figure 2-10 provides a legend for reading the complete device name for any TMS320DM643x DMP
platform member.
TMX 320
DM6435
(
)
ZWT
(
)
( )
DEVICE SPEED RANGE
4 = 400 MHz
5 = 500 MHz
6 = 600 MHz
PREFIX
TMX = Experimental device
TMS = Qualified device
TEMPERATURE RANGE (JUNCTION)
Blank
= 0° C to 90° C, Commercial Grade
= -40°C to 125°C, Automotive Grade
DEVICE FAMILY
320 = TMS320™ DSP Family
Q
R
S
= 0° C to 90° C, Commercial Grade (Tape and Reel)
= -40°C to 125°C, Automotive Grade (Tape and Reel)
DEVICE
PACKAGE TYPE(A)
ZWT 361-pin plastic BGA, with Pb-Free soldered balls
ZDU 376-pin plastic BGA, with Pb-Free soldered balls [Green]
C64x+™ DSP:
DM6437
DM6435
=
=
DM6433
DM6431
SILICON REVISION:
Blank Revision 1.3
=
A. BGA = Ball Grid Array
B. For “TMX” initial devices, the device number is DM6437.
Figure 2-10. Device Nomenclature(B)
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2.9 Documentation Support
2.9.1 Related Documentation From Texas Instruments
The following documents describe the TMS320DM643x Digital Media Processor (DMP). Copies of these
documents are available on the Internet at www.ti.com. Tip: Enter the literature number in the search box
provided at www.ti.com.
The current documentation that describes the DM643x DMP, related peripherals, and other technical
collateral, is available in the C6000 DSP product folder at: www.ti.com/c6000.
SPRU978
TMS320DM643x DMP DSP Subsystem Reference Guide. Describes the digital signal
processor (DSP) subsystem in the TMS320DM643x Digital Media Processor (DMP).
SPRU983
TMS320DM643x DMP Peripherals Overview Reference Guide. Provides an overview and
briefly describes the peripherals available on the TMS320DM643x Digital Media Processor
(DMP).
SPRAA84 TMS320C64x to TMS320C64x+ CPU Migration Guide. Describes migrating from the Texas
Instruments TMS320C64x digital signal processor (DSP) to the TMS320C64x+ DSP. The
objective of this document is to indicate differences between the two cores. Functionality in
the devices that is identical is not included.
SPRU732
TMS320C64x/C64x+ DSP CPU and Instruction Set Reference Guide. Describes the CPU
architecture, pipeline, instruction set, and interrupts for the TMS320C64x and TMS320C64x+
digital signal processors (DSPs) of the TMS320C6000 DSP family. The C64x/C64x+ DSP
generation comprises fixed-point devices in the C6000 DSP platform. The C64x+ DSP is an
enhancement of the C64x DSP with added functionality and an expanded instruction set.
SPRU871
TMS320C64x+ DSP Megamodule Reference Guide. Describes the TMS320C64x+ digital
signal processor (DSP) megamodule. Included is a discussion on the internal direct memory
access (IDMA) controller, the interrupt controller, the power-down controller, memory
protection, bandwidth management, and the memory and cache.
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3 Device Configuration
3.1 System Module Registers
The system module includes status and control registers required for configuration of the device. Brief
descriptions of the various registers are shown in Table 3-1. System Module registers required for device
configurations are discussed in the following sections.
Table 3-1. System Module Register Memory Map
HEX ADDRESS RANGE
0x01C4 0000
REGISTER ACRONYM
PINMUX0
DESCRIPTION
Pin Multiplexing Control 0 (see Section 3.7.2.1, PINMUX0 Register
Description).
0x01C4 0004
PINMUX1
Pin Multiplexing Control 1 (see Section 3.7.2.2, PINMUX1 Register
Description).
0x01C4 0008
DSPBOOTADDR
DSP Boot Address (see Section 3.4.2.3, DSPBOOTADDR Register).
Boot Complete (see Section 3.4.2.2, BOOTCMPLT Register).
Reserved
0x01C4 000C
BOOTCOMPLT
0x01C4 0010
–
0x01C4 0014
BOOTCFG
–
Device Boot Configuration (see Section 3.4.2.1, BOOTCFG Register).
Reserved
0x01C4 0018 - 0x01C4 0027
0x01C4 0028
JTAGID
JTAG ID (see Section 6.23.1, JTAG ID (JTAGID) Register
Description(s)).
0x01C4 002C
0x01C4 0030
0x01C4 0034
0x01C4 0038
0x01C4 003C
–
Reserved
HPICTL
HPI Control (see Section 3.6.2.1, HPI Control Register).
–
Reserved
Reserved
–
MSTPRI0
Bus Master Priority Control 0 (see Section 3.6.1, Switch Central
Resource (SCR) Bus Priorities).
0x01C4 0040
MSTPRI1
Bus Master Priority Control 1 (see Section 3.6.1, Switch Central
Resource (SCR) Bus Priorities).
0x01C4 0044
0x01C4 0048
VPSS_CLKCTL
VPSS Clock Control (see Section 3.3.2, VPSS Clocks).
VDD3P3V_PWDN
VDD 3.3-V I/O Powerdown Control (see Section 3.2, Power
Considerations).
0x01C4 004C
DDRVTPER
DDR2 VTP Enable Register (see Section 6.9.4, DDR2 Memory
Controller).
0x01C4 0050 - 0x01C4 0080
0x01C4 0084
–
Reserved
TIMERCTL
EDMATCCFG
Timer Control (see Section 3.6.2.2, Timer Control Register).
0x01C4 0088
EDMA Transfer Controller Default Burst Size Configuration (see
Section 3.6.2.3, EDMA TC Configuration Register).
0x01C4 008C
–
Reserved
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3.2 Power Considerations
The DM6435 provides several means of managing power consumption.
As described in the Section 6.3.4, DM6435 Power and Clock Domains, the DM6435 has one single power
domain—the “Always On” power domain. Within this power domain, the DM6435 utilizes local clock gating
via the Power and Sleep Controller (PSC) to achieve power savings. For more details on the PSC, see
Section 6.3.5, Power and Sleep Controller (PSC) and the TMS320DM643x DMP DSP Subsystem
Reference Guide (literature number SPRU978).
Some of the DM6435 peripherals support additional power saving features. For more details on power
saving features supported, see the TMS320DM643x DMP Peripherals Overview Reference Guide
(literature number SPRU983).
Most DM6435 3.3-V I/Os can be powered-down to reduce power consumption. The VDD3P3V_PWDN
register in the System Module (see Figure 3-1) is used to selectively power down unused 3.3-V I/O pins.
For independent control, the 3.3-V I/Os are separated into functional groups—most of which are named
according to the pin multiplexing groups (see Table 3-2). For these I/O groups, only the I/O buffers needed
for Host/EMIFA Boot or Power-Up Operations are powered up by default (CLKOUT Block, EMIFA/VPSS
Block, Host Block, and GPIO Block).
Note: To save power, all other I/O buffers are powered down by default. Before using these pins, the user
must program the VDD3P3V_PWDN register to power up the corresponding I/O buffers.
For a list of multiplexed pins on the device and the pin mux group each pin belongs to, see
Section 3.7.3.1, Multiplexed Pins on DM6435.
31
15
16
RESERVED
R-0000 0000 0000 0000
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
RESERVED
RSV
EMBK3
UR0FC
UR0DAT TIMER1
TIMER0
SP
PWM1
GPIO
HOST
EMBK2
EMBK1
EMBK0
CLKOUT
R-00
R/W-0
R/W-0
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-1
R/W-0
R/W-0
R/W-0
R/W-0
R/W-0
R/W-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Figure 3-1. VDD3P3V_PWDN Register
Table 3-2. VDD3P3V_PWDN Register Bit Descriptions(1)
BIT
NAME
DESCRIPTION
Reserved. Read-only, writes have no effect.
31:14
RESERVED
Reserved. This bit should be programmed to 1 during device initialization (see Section 3.8,
Device Initialization Sequence After Reset).
13
12
RSV
EMIFA/VPSS Sub-Block 3 I/O Power Down Control.
Controls the power of the 8 I/O pins in the EMIFA/VPSS Sub-Block 3.
EMBK3
UR0FC
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
UART0 Flow Control Block I/O Power Down Control.
Controls the power of the 2 I/O pins in the UART0 Flow Control Block.
11
0 = I/O pins powered up.
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z) [default].
(1) For more details on I/O pins belonging to each pin mux block, see Section 3.7, Multiplexed Pin Configurations.
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Table 3-2. VDD3P3V_PWDN Register Bit Descriptions (continued)
BIT
NAME
DESCRIPTION
UART0 Data Block I/O Power Down Control.
Controls the power of the 2 I/O pins in the UART0 Data Block.
0 = I/O pins powered up.
10
UR0DAT
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z) [default].
Timer1 Block I/O Power Down Control.
Controls the power of the 2 I/O pins in the Timer1 Block.
9
8
TIMER1
TIMER0
0 = I/O pins powered up.
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z) [default].
Timer0 Block I/O Power Down Control.
Controls the power of the 2 I/O pins in the Timer0 Block.
0 = I/O pins powered up.
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z) [default].
Serial Port Block I/O Power Down Control.
Controls the power of the 12 I/O pins in the Serial Port Block (Serial Port Sub-Block 0 and
Serial Port Sub-Block 1).
7
6
5
SP
0 = I/O pins powered up.
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z) [default].
PWM1 Block I/O Power Down Control.
Contros thel power of the 1 I/O pin in the PWM1 Block.
PWM1
GPIO
0 = I/O pins powered up.
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z) [default].
GPIO Block I/O Power Down Control.
Controls the power of the 4 I/O pins in the GPIO Block (GP[3:0]).
Note: The GPIO Block contains standalone GPIO pins and is not a pin mux group.
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
Host Block I/O Power Down Control.
Controls the power of the 27 I/O pins in the Host Block.
4
3
2
1
0
HOST
EMBK2
EMBK1
EMBK0
CLKOUT
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
EMIFA/VPSS Sub-Block 2 I/O Power Down Control.
Controls the power of the 3 I/O pins in the EMIFA/VPSS Sub-Block 2.
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
EMIFA/VPSS Sub-Block 1 I/O Power Down Control.
Controls the power of the 29 I/O pins in the EMIFA/VPSS Sub-Block 1.
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
EMIFA/VPSS Sub-Block 0 I/O Power Down Control.
Controls the power of the 21 I/O pins in the EMIFA/VPSS Sub-Block 0.
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
CLKOUT Block I/O Power Down Control.
Controls the power of the 1 I/O pin in the CLKOUT Block.
0 = I/O pins powered up [default].
1 = I/O pins powered down and not operational. Outputs are 3-stated (Hi-Z).
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3.3 Clock Considerations
Global device and local peripheral clocks are controlled by the PLL Controllers (PLLC1 and PLLC2) and
the Power and Sleep Controller (PSC). In addition, the System Module VPSS_CLKCTL register configures
the clock source to the Video Processing Subsystem (VPSS).
3.3.1 Clock Configurations after Device Reset
After device reset, the user is responsible for programming the PLL Controllers (PLLC1 and PLLC2) and
the Power and Sleep Controller (PSC) to bring the device up to the desired clock frequency and the
desired peripheral clock state (clock gating or not).
For additional power savings, some of the DM6435 peripherals support clock gating within the peripheral
boundary. For more details on clock gating and power saving features supported by a specific peripheral,
see the peripheral-specific reference guides [listed/linked in the TMS320DM643x DMP Peripherals
Overview Reference Guide (literature number SPRU983)].
3.3.1.1 Device Clock Frequency
The DM6435 defaults to PLL bypass mode. To bring the device up to the desired clock frequency, the
user should program PLLC1 and PLLC2 after device reset.
DM6435 supports a FASTBOOT option, where upon exit from device reset the internal bootloader code
automatically programs the PLLC1 into PLL mode with a specific PLL multiplier and divider to speed up
device boot. While the FASTBOOT option is beneficial for faster boot, the PLL multiplier and divider
selected for boot may not be the exact frequency desired for the run-time application. It is the user's
responsibility to reconfigure PLLC1 after fastboot to bring the device into the desired clock frequency.
Section 3.4.1, Boot Modes discusses the different fast boot modes in more detail.
The user must adhere to the various clock requirements when programming the PLLC1 and PLLC2:
•
Fixed frequency ratio requirements between CLKDIV1, CLKDIV3, and CLKDIV6 clock domains. For
more details on the frequency ratio requirements, see Section 6.3.4, DM6435 Power and Clock
Domains.
•
PLL multiplier and frequency ranges. For more details on PLL multiplier and frequency ranges, see
Section 6.7.1, PLL1 and PLL2.
3.3.1.2 Module Clock State
The clock and reset state for each of the modules is controlled by the Power and Sleep Controller (PSC).
Table 3-3 shows the default state of each module after a device-level global reset. The DM6435 device
has four different module states—Enable, Disable, SyncReset, or SwRstDisable. For more information on
the definitions of the module states, the PSC, and PSC programming, see Section 6.3.5, Power and Sleep
Controller (PSC) and the TMS320DM643x DMP DSP Subsystem Reference Guide (literature number
SPRU978).
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Table 3-3. DM6435 Default Module States
DEFAULT MODULE STATE
[PSC Register MDSTATn.STATE]
LPSC #
MODULE NAME
0
1
VPSS (Master)
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
VPSS (Slave)
EDMACC
2
3
EDMATC0
EDMATC1
EDMATC2
EMAC Memory Controller
MDIO
4
5
6
7
8
EMAC
9
McASP0
11
12
13
VLYNQ
HPI
DDR2 Memory Contoller
SwRstDisable, if configuration pins AEM[2:0] = 000b
14
EMIFA
Enable, if configuration pins AEM[2:0] = Others [001b and 101b]
16
18
19
20
22
23
24
25
26
27
28
39
McBSP0
I2C
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
SwRstDisable
Enable
UART0
UART1
HECC
PWM0
PWM1
PWM2
GPIO
TIMER0
TIMER1
C64x+ CPU
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3.3.2 VPSS Clocks
The Video Processing SubSystem (VPSS) clocks are controlled via the VPSS_CLKCTL register. The
VPSS_CLKCTL register format is shown in Figure 3-2 and the bit field descriptions are given in Table 3-4.
31
15
16
RESERVED
R-0000 0000 0000 0000
5
4
3
2
1
0
PCLK
INV
RESERVED
RESERVED
R/W-00
RESERVED
R/W-00
R-0000 0000 000
R/W-0
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-2. VPSS_CLKCTL Register
Table 3-4. VPSS_CLKCTL Register Bit Description
BIT
NAME
DESCRIPTION
31:5
RESERVED
Reserved. Read-only, writes have no effect.
Reserved. For proper device operation, the user must only write "0" to these
bits.
4:3
RESERVED
PCLK polarity
2
PCLKINV
0 = VPSS receives normal PCLK [default].
1 = VPSS receives inverted PCLK.
Reserved. For proper device operation, the user must only write "0" to these
bits.
1:0
RESERVED
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3.4 Boot Sequence
The boot sequence is a process by which the device's memory is loaded with program and data sections,
and by which some of the device's internal registers are programmed with predetermined values. The boot
sequence is started automatically after each device-level global reset. For more details on device-level
global resets, see Section 6.5, Reset.
There are several methods by which the memory and register initialization can take place. Each of these
methods is referred to as a boot mode. The boot mode to be used is selected at reset. For more
information on the bootmode selections, see Section 3.4.1, Boot Modes.
The device is booted through multiple means—primary bootloaders within internal ROM or EMIFA, and
secondary user bootloaders from peripherals or external memories. Boot modes, pin configurations, and
register configurations required for booting the device, are described in the following subsections.
3.4.1 Boot Modes
The DM6435 boot modes are determined by these device boot and configuration pins. For information on
how these pins are sampled at device reset, see Section 6.5.1.2, Latching Boot and Configuration Pins.
•
•
•
•
BOOTMODE[3:0]
FASTBOOT
AEM[2:0]
PLLMS[2:0]
Note: the PLLMS[2:0] configuration pins are actually multiplexed with the AEAW[2:0] configuration pins.
For more details on the multiplexed AEAW[2:0]/PLLMS[2:0] configuration pins and control, see
Section 3.5.1.2, EMIFA Address Width Selects (AEAW[2:0]) and FASTBOOT PLL Multiplier Selects
(PLLMS[2:0]).
BOOTMODE[3:0] determines the type of boot (e.g., I2C Boot, EMIFA Boot, or HPI Boot, etc.). FASTBOOT
determines if the PLL is enabled during boot to speed up the boot process.
The combination of AEM[2:0] and PLLMS[2:0] is used by bootloader code to determine the PLL multiplier
used during fastboot modes (FASTBOOT = 1).
The DM6435 boot modes are grouped into three categories—Non-Fastboot Modes, Fixed-Multiplier
Fastboot Modes, and User-Select Multiplier Fastboot Modes.
•
Non-Fastboot Modes (FASTBOOT = 0): The device operates in default PLL bypass mode during
boot. The Non-Fastboot bootmodes available on the DM6435 are shown in Table 3-5.
•
Fixed-Multiplier Fastboot Modes (FASTBOOT = 1, AEM[2:0] = 001b): The bootloader code speeds
up the device during boot according to the fixed PLL multipliers. The Fixed-Multiplier Fastboot
bootmodes available on the DM6435 are shown in Table 3-6.
Note: The PLLMS[2:0] configurations have no effect on the Fixed-Multiplier Fastboot Modes, as these
pins function as AEAW[2:0] to select the EMIFA address width when AEM[2:0] = 001b.
•
User-Select Multiplier Fastboot Modes (FASTBOOT = 1, AEM[2:0] = 000b and 101b): The
bootloader code speeds up the device during boot. The PLL multiplier is selected by the user via the
PLLMS[2:0] pins. The User-Select Multiplier Fastboot bootmodes available on the DM6435 are shown
in Table 3-7.
All other modes not shown in these tables are reserved and invalid settings.
For more information on how these pins are sampled at device reset, see Section 6.5.1.2, Latching Boot
and Configuration Pins.
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Table 3-5. Non-Fastboot Modes (FASTBOOT = 0)
DEVICE BOOT AND
CONFIGURATION
PINS
PLLC1 CLOCK SETTING AT BOOT
DM6435 DMP
(Master/Slave)
DSPBOOTADDR
(DEFAULT)(1)
BOOT DESCRIPTION(1)
DEVICE
FREQUENCY
(SYSCLK1)
PLL
CLKDIV1 DOMAIN
BOOTMODE[3:0]
MODE(2)
(SYSCLK1 DIVIDER)
0000
0001
0010
0011
No Boot (Emulation Boot)
Reserved
Master
Bypass
/1
–
CLKIN
0x0010 0000
–
Slave
–
–
Bypass
–
–
CLKIN
–
–
HPI Boot
/1
–
0x0010 0000
–
Reserved
EMIFA ROM Direct Boot
[PLL Bypass Mode]
0100
0101
Master
Master
Bypass
Bypass
/1
/1
CLKIN
CLKIN
0x4200 000
I2C Boot
0x0010 0000
[STANDARD MODE](3)
0110
0111
16-bit SPI Boot [McBSP0]
NAND Flash Boot
Master
Master
Bypass
Bypass
/1
/1
CLKIN
CLKIN
0x0010 0000
0x0010 0000
UART Boot without
Hardware Flow Control
[UART0]
1000
Master
Bypass
/1
CLKIN
0x0010 0000
1001
1010
1011
1100
1101
Reserved
VLYNQ Boot
Reserved
Reserved
Reserved
–
–
–
/1
–
–
–
Slave
Bypass
CLKIN
0x0010 0000
–
–
–
–
–
–
–
–
–
–
–
–
–
–
UART Boot with Hardware
Flow Control [UART0]
1110
1111
Master
Master
Bypass
Bypass
/1
/1
CLKIN
CLKIN
0x0010 0000
0x0010 0000
24-bit SPI Boot (McBSP0 +
GP[97])
(1) For all boot modes that default to DSPBOOTADDR = 0x0010 0000 (i.e., all boot modes except the EMIFA ROM Direct Boot,
BOOTMODE[3:0] = 0100, FASTBOOT = 0), the bootloader code disables all C64x+ cache (L2, L1P, and L1D) so that upon exit from the
bootloader code, all C64x+ memories are configured as all RAM. If cache use is required, the application code must explicitly enable the
cache. For more information on the bootloader, see the Using the TMS320DM643x Bootloader Application Report (literature number
SPRAAG0).
(2) The PLL MODE for Non-Fastboot Modes is fixed as shown in this table; therefore, the PLLMS[2:0] configuration pins have no effect on
the PLL MODE.
(3) I2C Boot (BOOTMODE[3:0] = 0101b) is only available if the MXI/CLKIN frequency is between 21 MHz to 30 MHz. I2C Boot is not
available for MXI/CLKIN frequencies less than 21 MHz.
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Table 3-6. Fixed-Multiplier Fastboot Modes (FASTBOOT = 1, AEM[2:0] = 001b)
DEVICE BOOT AND
CONFIGURATION
PINS
PLLC1 CLOCK SETTING AT BOOT
DM6435 DMP
(Master/Slave)
DSPBOOTADDR
(DEFAULT)(1)
BOOT DESCRIPTION(1)
DEVICE
FREQUENCY
(SYSCLK1)
PLL
CLKDIV1 DOMAIN
BOOTMODE[3:0]
MODE(2)
(SYSCLK1 DIVIDER)
0000
0001
No Boot (Emulation Boot)
Master
Slave
Bypass
x27
/1
/2
CLKIN
0x0010 0000
0x0010 0000
HPI Boot with PLL
Multiplier x27 at boot
CLKIN x27 / 2
HPI Boot with PLL
Multiplier x20 at boot
0010
0011
Slave
Slave
x20
x15
/2
/2
CLKIN x20 / 2
CLKIN x15 / 2
0x0010 0000
0x0010 0000
HPI Boot with PLL
Multiplier x15 at boot
EMIFA ROM FASTBOOT
with Application Image
Script (AIS)
0100
0101
Master
Master
x20
x20
/2
/2
CLKIN x20 / 2
CLKIN x20 / 2
0x0010 000
I2C Boot
0x0010 0000
[FAST MODE](3)
0110
0111
16-bit SPI Boot [McBSP0]
NAND Flash Boot
Master
Master
x20
x20
/2
/2
CLKIN x20 / 2
CLKIN x20 / 2
0x0010 0000
0x0010 0000
UART Boot without
Hardware Flow Control
[UART0]
1000
1001
Master
Master
x20
x20
/2
/2
CLKIN x20 / 2
CLKIN x20 / 2
0x0010 0000
0x0010 0000
EMIFA ROM FASTBOOT
without AIS
1010
1011
1100
1101
VLYNQ Boot
Reserved
Reserved
Reserved
Slave
x20
–
/2
–
CLKIN x20 / 2
0x0010 0000
–
–
–
–
–
–
–
–
–
–
–
–
–
UART Boot with Hardware
Flow Control [UART0]
1110
1111
Master
Master
x20
x20
/2
/2
CLKIN x20 / 2
CLKIN x20 / 2
0x0010 0000
0x0010 0000
24-bit SPI Boot (McBSP0 +
GP[97])
(1) For all boot modes that default to DSPBOOTADDR = 0x0010 0000, the bootloader code disables all C64x+ cache (L2, L1P, and L1D)
so that upon exit from the bootloader code, all C64x+ memories are configured as all RAM. If cache use is required, the application
code must explicitly enable the cache. For more information on the bootloader, see the Using the TMS320DM643x Bootloader
Application Report (literature number SPRAAG0).
(2) The PLL MODE for Fixed-Multiplier Fastboot Modes is fixed as shown in this table; therefore, the PLLMS[2:0] configuration pins have no
effect on the PLL MODE.
(3) I2C Boot (BOOTMODE[3:0] = 0101b) is only available if the MXI/CLKIN frequency is between 21 MHz to 30 MHz. I2C Boot is not
available for MXI/CLKIN frequencies less than 21 MHz.
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Table 3-7. User-Select Multiplier Fastboot Modes (FASTBOOT = 1, AEM[2:0] = 000b or 101b)
DEVICE BOOT AND
CONFIGURATION
PINS
PLLC1 CLOCK SETTING AT BOOT
DM6435 DMP
(Master/Slave)
DSPBOOTADDR
(DEFAULT)(1)
BOOT DESCRIPTION(1)
DEVICE
FREQUENCY
(SYSCLK1)
PLL
CLKDIV1 DOMAIN
BOOTMODE[3:0]
MODE(2)
(SYSCLK1 DIVIDER)
0000
0001
0010
0011
No Boot (Emulation Boot)
Reserved
Master
Bypass
/1
–
CLKIN
0x0010 0000
–
Slave
–
–
Table 3-8
–
–
Table 3-8
–
–
HPI Boot
/2
–
0x0010 0000
–
Reserved
EMIFA ROM FASTBOOT
with AIS
0100
0101
Master
Master
Table 3-8
Table 3-8
/2
/2
Table 3-8
Table 3-8
0x0010 0000
0x0010 0000
I2C Boot
[FAST MODE](3)
0110
0111
16-bit SPI Boot [McBSP0]
NAND Flash Boot
Master
Master
Table 3-8
Table 3-8
/2
/2
Table 3-8
Table 3-8
0x0010 0000
0x0010 0000
UART Boot without
Hardware Flow Control
[UART0]
1000
1001
Master
Master
Table 3-8
Table 3-8
/2
/2
Table 3-8
Table 3-8
0x0010 0000
–
EMIFA ROM FASTBOOT
without AIS
1010
1011
1100
1101
Reserved
Reserved
Reserved
Reserved
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
UART Boot with Hardware
Flow Control [UART0]
1110
1111
Master
–
Table 3-8
–
/2
–
Table 3-8
–
0x0010 0000
–
Reserved
(1) For all boot modes that default to DSPBOOTADDR = 0x0010 0000, the bootloader code disables all C64x+ cache (L2, L1P, and L1D)
so that upon exit from the bootloader code, all C64x+ memories are configured as all RAM. If cache use is required, the application
code must explicitly enable the cache. For more information on the bootloader, see the Using the TMS320DM643x Bootloader
Application Report (literature number SPRAAG0).
(2) Any supported PLL MODE is available. [See Table 3-8 for supported DM6435 PLL MODE options].
(3) I2C Boot (BOOTMODE[3:0] = 0101b) is only available if the MXI/CLKIN frequency is between 21 MHz to 30 MHz. I2C Boot is not
available for MXI/CLKIN frequencies less than 21 MHz.
Table 3-8. PLL Multiplier Selection (PLLMS[2:0]) in User-Select Multiplier Fastboot Modes
(FASTBOOT = 1; AEM[2:0] = 000b or 101b)
DEVICE BOOT AND
PLLC1 CLOCK SETTING AT BOOT
CONFIGURATION PINS
CLKDIV1 DOMAIN
(SYSCLK1 DIVIDER)
PLLMS[2:0]
PLL MODE
DEVICE FREQUENCY (SYSCLK1)
000
001
010
011
100
101
110
111
x20
x15
x16
x18
x22
x25
x27
x30
/2
/2
/2
/2
/2
/2
/2
/2
CLKIN x20 / 2
CLKIN x15 / 2
CLKIN x16 / 2
CLKIN x18 / 2
CLKIN x22 / 2
CLKIN x25 / 2
CLKIN x27 / 2
CLKIN x30 / 2
As shown in Table 3-5, Table 3-6, and Table 3-7, at device reset the Boot Controller defaults the
DSPBOOTADDR to one of two values based on the boot mode selected. In all boot modes, the C64x+ is
immediately released from reset and begins executing from address location indicated in
DSPBOOTADDR.
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•
Internal Bootloader ROM (0x0010 0000): For most boot modes, the DSPBOOTADDR defaults to the
internal Bootloader ROM so that the DSP can immediately execute the bootloader code in the internal
ROM. The bootloader code decodes the captured BOOTMODE, FASTBOOT, default AEM (DAEM),
and PLLMS information (in the BOOTCFG register) to determine the proper boot operation.
Note: For all boot modes that default to DSPBOOTADDR = 0x0010 0000, the bootloader code
disables all C64x+ cache (L2, L1P, and L1D) so that upon exit from the bootloader code, all C64x+
memories are configured as all RAM. If cache use is required, the application code must explicitly
enable the cache. For more information on boot modes, see Section 3.4.1, Boot Modes. For more
information on the bootloader, see the Using the TMS320DM643x Bootloader Application Report
(literature number SPRAAG0).
•
EMIFA Chip Select Space 2 (0x4200 0000): The EMIFA ROM Direct Boot in PLL Bypass Mode
(BOOTCFG settings BOOTMODE[3:0] = 0100b, FASTBOOT = 0) is the only exception where the
DSPBOOTADDR defaults to the EMIFA Chip Select Space 2. The DSP begins execution directly from
the external ROM at this EMIFA space.
For more information how the bootloader code handles each boot mode, see Using the TMS320DM643x
Bootloader Application Report (literature number SPRAAG0).
3.4.1.1 FASTBOOT
When DM6435 exits pin reset (RESET or POR released), the PLL Controllers (PLLC1 and PLLC2) default
to PLL Bypass Mode. This means the PLLs are disabled, and the MXI/CLKIN clock input is driving the
chip. All the clock domain divider ratios discussed in Section 6.3.4, DM6435 Power and Clock Domains,
still apply. For example, assume an MXI/CLKIN frequency of 27 MHz—meaning the internal clock source
for EMIFA is at CLKDIV3 domain = 27 MHz/3 = 9 MHz, a very slow clock. In addition, the EMIFA registers
are reset to the slowest configuration which translates to very slow peripheral operation/boot.
To optimize boot time, the user should reprogram clock settings via the PLLC as early as possible during
the boot process. The FASTBOOT pin facilitates this operation by allowing the device to boot at a faster
clock rate.
Except for the EMIFA ROM Direct Boot in PLL Bypass Mode (BOOTCFG settings BOOTMODE[3:0] =
0100b, FASTBOOT = 0), all other boot modes default to executing from the Internal Bootloader ROM. The
first action that the bootloader code takes is to decode the boot mode. If the FASTBOOT option is
selected (BOOTCFG.FASTBOOT = 1), the bootloader software begins by programming the PLLC1
(System PLLC) to PLL Mode to give the device a slightly faster operation before fetching code from
external devices. The exact PLL multiplier that the bootloader uses is determined by the AEM[2:0] and
PLLMS[2:0] settings, as shown in Table 3-6 and Table 3-7.
Some boot modes must be accompanied with FASTBOOT = 1 so that the corresponding peripheral can
run at a reasonable rate to communicate to the external device(s).
Note: PLLC2 still stays in PLL Bypass Mode, the bootloader does not reconfigure it.
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3.4.1.2 Selecting FASTBOOT PLL Multiplier
Table 3-6, Table 3-7, and Table 3-8 show the PLL multipliers used by the bootloader code during fastboot
(FASTBOOT = 1) and the resulting device frequency. The user is responsible for selecting the bootmode
with the appropriate PLL multiplier for their MXI/CLKIN clock source so that the device speed and PLL
frequency range requirements are met. For the PLLC1 Clock Frequency Ranges, see Table 6-15, PLLC1
Clock Frequency Ranges in Section 6.7.1, PLL1 and PLL2.
The following are guidelines for PLL output frequency and device speed (frequency):
•
PLL Output Frequency: (PLLOUT = CLKIN frequency * boot PLL Multiplier) must stay within the
PLLOUT frequency range in Table 6-15, PLLC1 Clock Frequency Ranges.
•
Device Frequency: (SYSCLK1) calculated from Table 3-6 and Table 3-7 must not exceed the
SYSCLK1 maximum frequency in Table 6-15, PLLC1 Clock Frequency Ranges.
For example, for a 600-MHz device with a CLKIN = 27 MHz, in order to stay within the PLLOUT
frequency range and SYSCLK1 maximum frequency from Table 6-15, PLLC1 Clock Frequency
Ranges, the user must select a boot mode with a PLL1 multiplier between x15 and x22.
3.4.1.3 EMIFA Boot Modes
As shown in Table 3-5, Table 3-6, and Table 3-7, there are different types of EMIFA Boot Modes. This
subsection summarizes these types of EMIFA boot modes. For further detailed information, see the Using
the TMS320DM643x Bootloader Application Report (literature number SPRAAG0).
•
EMIFA ROM Direct Boot in PLL Bypass Mode (FASTBOOT = 0, BOOTMODE[3:0] = 0100b)
–
The C64x+ fetches the code directly from EMIFA Chip Select 2 Space [EM_CS2] (address
0x42000000)
–
–
The PLL is in Bypass Mode
EMIFA is configured as Asynchronous EMIF. The user is responsible for ensuring the desirable
Asynchronous EMIF pins are available through configuration pins AEM[2:0] and AEAW[2:0].
AEM[2:0] must be configured to 001b [8-bit EMIFA (Async) Pinout Mode 1].
•
EMIFA ROM Fastboot with AIS (FASTBOOT = 1, BOOTMODE[3:0] = 0100b)
–
–
The C64x+ begins execution from the internal bootloader ROM at address 0x00100000.
The bootloader code programs PLLC1 to PLL Mode to speed up the boot process. The PLL
multiplier value is determined by the AEM[2:0] and PLLMS[2:0] configurations as shown in
Table 3-6 and Table 3-7.
–
–
The bootloader code reads code from the EMIFA EM_CS2 space using the application image script
(AIS) format.
EMIFA is configured as Asynchronous EMIF. The user is responsible for ensuring the desirable
Asynchronous EMIF pins are available through configuration pins AEM[2:0] and AEAW[2:0].
AEM[2:0] must be configured to 001b [8-bit EMIFA (Async) Pinout Mode 1].
•
EMIFA ROM Fastboot without AIS: (FASTBOOT = 1, BOOTMODE[3:0] = 1001b)
–
–
The C64x+ begins execution from the internal bootloader ROM at address 0x00100000.
The bootloader code programs PLLC1 to PLL Mode to speed up the boot process. The PLL
multiplier value is determined by the AEM[2:0] and PLLMS[2:0] configurations as shown in
Table 3-6 and Table 3-7.
–
–
The bootloader code then jumps to the EMIFA EM_CS2 space, at which point the C64x+ fetches
the code directly from address 0x42000000.
EMIFA is configured as Asynchronous EMIF. The user is responsible for ensuring the desirable
Asynchronous EMIF pins are available through configuration pins AEM[2:0] and AEAW[2:0].
AEM[2:0] must be configured to 001b [8-bit EMIFA (Async) Pinout Mode 1].
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•
NAND Flash Boot: (FASTBOOT = 0 or 1, BOOTMODE[3:0] = 0111b)
–
–
The C64x+ begins execution from the internal bootloader ROM at address 0x00100000.
Depending on the FASTBOOT, AEM[2:0], and PLLMS[2:0] settings, the bootloader code may
program the PLLC1 to PLL Mode to speed up the boot process. See Table 3-5, Table 3-6, and
Table 3-7.
–
–
The bootloader code reads the code from EMIFA (NAND) EM_CS2 (address 0x42000000) using
AIS format.
EMIFA is configured in NAND mode. The user is responsible for ensuring the desirable
Asynchronous EMIF pins are available through configuration pins AEM[2:0] and AEAW[2:0].
AEM[2:0] can be configured to 001b [8-bit EMIFA (Async) Pinout Mode 1] or 101b [8-bit EMIFA
(NAND) Pinout Mode 5].
3.4.1.4 Serial Boot Modes (I2C, UART[UART0], SPI[McBSP0])
This subsection discusses how the bootloader configures the clock dividers for the serial boot modes—I2C
boot, UART boot, and SPI boot.
3.4.1.4.1 I2C Boot
If FASTBOOT = 0, then I2C Boot (BOOTMODE = 0101) is performed in Standard-Mode (up-to 100 kbps).
If FASTBOOT = 1, then I2C Boot is performed in Fast-Mode (up-to 400 kbps). The actual I2C data
transfer rate is dependent on the MXI/CLKIN frequency.
This is how the bootloader programs the I2C:
•
I2C Boot in Fast-Mode (BOOTMODE[3:0] = 0101b, FASTBOOT = 1)
–
–
I2C register settings: ICPSC.IPSC = 210, ICCLKL.ICCL = 810, ICCKH.ICCH = 810
Resulting in the following I2C prescaled module clock frequency (internal I2C clock):
•
(CLKIN frequency in MHz) / 3
–
Resulting in the following I2C serial clock (SCL):
•
•
•
SCL frequency (in kHz) = (CLKIN frequency in MHz) / 78 * 1000
SCL low pulse duration (in µs) = 39 / (CLKIN frequency in MHz)
SCL high pulse duration (in µs) = 39 / (CLKIN frequency in MHz)
•
I2C Boot in Standard-Mode (BOOTMODE[3:0] = 0101b, FASTBOOT = 0)
–
–
I2C register settings: ICPSC.IPSC = 210, ICCLKL.ICCL = 4510, ICCKH.ICCH = 4510
Resulting in the following I2C prescaled module clock frequency (internal I2C clock):
•
(CLKIN frequency in MHz) / 3
–
Resulting in the following I2C serial clock (SCL):
•
•
•
SCL frequency (in kHz) = (CLKIN frequency in MHz) / 300 * 1000
SCL low pulse duration (in µs) = 150 / (CLKIN frequency in MHz)
SCL high pulse duration (in µs) = 150 / (CLKIN frequency in MHz)
Note: The I2C peripheral requires that the prescaled module clock frequency must be between 7 MHz
and 12 MHz. Therefore, the I2C boot is only available for MXI/CLKIN frequency between 21 MHz and
30 MHz.
For more details on the I2C periperhal configurations and clock requirements, see the TMS320DM643x
DMP Inter-Integrated Circuit (I2C) Peripheral User’s Guide (literature number SPRU991).
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3.4.1.4.2 UART Boot
For UART Boot (BOOTMODE[3:0] = 1000b or 1110b), the bootloader programs the UART0 peripheral as
follows:
•
•
UART0 divisor is set to 1510
Resulting in this UART0 baud rate in kilobit per second (kbps):
–
(CLKIN frequency in MHz) * 1000 / (15 * 16)
The user is responsible for ensuring the resulting baud rate is appropriate for the system. The UART0
divisor (/15) is optimized for CLKIN frequency between 27 to 29 MHz to stay within 5% of the 115200-bps
baud rate.
For more details on the UART peripheral configurations and clock generation, see the TMS320DM643x
DMP Universal Asynchronous Receiver/Transmitter (UART) User's Guide (literature number SPRU997).
3.4.1.4.3 SPI Boot
Both 16-bit address SPI Boot (BOOTMODE = 0110) and 24-bit address SPI boot are performed through
the McBSP0 peripheral. The bootloader programs the McBSP0 peripheral as follows:
•
•
McBSP0 register settings: SRGR.CLKGDV = 210
Resulting in this SPI serial clock frequency:
–
(SYSCLK3 frequency in MHz) / 3
SYSCLK3 frequency = SYSCLK1 frequency / 6. SYSCLK1 frequency during boot can be found in
Table 3-5, Table 3-6, Table 3-7, and/or Table 3-8 based on the boot mode selection.
For example, if BOOTMODE[3:0] = 0110b, FASTBOOT = 1, the MXI/CLKIN frequency = 27 MHz,
AEM[2:0] = 000b, PLLMS[2:0] = 100b, the combination of Table 3-7 and Table 3-8 indicates that the
device frequency (SYSCLK1) is CLKIN x 22 / 2 = 297 MHz. This means SYSCLK3 frequency is
297 / 6 = 49.5 MHz, resulting in SPI serial clock frequency of 49.5 / 3 = 16.5 MHz.
3.4.1.5 Host Boot Modes
The DM6435 supports HPI Boot.
The HPI Boot is available in fastboot and non-fastboot, as shown in Table 3-5, Table 3-6, and Table 3-7.
Note: the HPI HSTROBE inactive pulse duration timing requirement [tw(HSTBH)] is dependent on the HPI
internal clock source (SYSCLK3) frequency (see Section 6.13.3, HPI Electrical Data/Timing). The external
host must be aware of the SYSCLK3 frequency during boot to ensure the HSTROBE pulse duration
timing requirement is met.
3.4.2 Bootmode Registers
3.4.2.1 BOOTCFG Register
The Device Bootmode (see Section 3.4.1, Boot Modes) and Configuration pins (see Section 3.5.1, Device
and Peripheral Configurations at Device Reset) latched at reset are captured in the Device Boot
Configuration (BOOTCFG) register which is accessible through the System Module. This is a read-only
register. The bits show the values latched from the corresponding configuration pins sampled at device
reset. For more information on how these pins are sampled at device reset, see Section 6.5.1.2, Latching
Boot and Configuration Pins. For the corresponding device boot and configuration pins, see Table 2-5,
BOOT Terminal Functions.
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31
15
20
19
18
17
16
RESERVED
FASTBOOT
RESERVED
R-0000 0000 0001
R-L
3
R-000
14
13
12
11
10
9
8
7
6
5
4
2
1
0
RSV
R-0
PLLMS
RSV
DAEM
RESERVED
R-0000
BOOTMODE
R-LLL
R-0
R-LLL
R-LLLL
LEGEND: R = Read only; L = pin state latched at reset rising edge; -n = value after reset
Figure 3-3. BOOTCFG Register—0x01C4 0014
Table 3-9. BOOTCFG Register Description
Bit
Field Name
Description
31:20
RESERVED
Reserved. Writes have no effect.
Fastboot (see Section 3.4.1.1, FASTBOOT)
This field is used by the device bootloader code to determine if it needs to speed up the device to PLL mode
before booting.
19
FASTBOOT
RSV
0 = No Fastboot
1 = Fastboot
The default value is latched from FASTBOOT configuration pin.
18:15
Reserved. Writes have no effect.
PINMUX0.AEAW default [AEAW] and Fastboot PLL Multiplier Select [PLLMS] (see Section 3.5.1.2, EMIFA
Address Width Select [AEAW] and Fast Boot PLL Multiplier Select [PLLMS])
The AEAW[2:0]/PLLMS configuration pins serve two purposes:
AEAW[2:0]: 8-bit EMIFA (Async) Pinout Mode 1 Address Width
If AEM = 001, this field serves as AEAW and it indicates the 8-bit EMIFA (Async) Pinout Mode 1 Address
Width. In this case, this field affects pin mux control only by setting the default of Pin Mux Control Register
PINMUX0.AEAW[2:0]. This field does not affect EMIFA register settings.
14:12
PLLMS
For more details on the AEAW settings, see Section 3.7.2.1, PINMUX0 Register Description.
PLLMS: Fastboot PLL Multiplier Select
If FASTBOOT = 1 and AEM[2:0] = 000b or 101b, this field selects the FASTBOOT PLL Multiplier. In this case,
this field does not affect the pin mux control or the EMIFA register settings. The bootloader code uses this field
to determine the PLL multiplier used for Fastboot.
11
RSV
Reserved. Writes have no effect.
PINMUX0.AEM default [DAEM] (see Section 3.5.1.1, EMIFA Pinout Mode (AEM[2:0]))
For more details on the AEM settings, see Section 3.7.2.1, PINMUX0 Register Description.
10:8
DAEM
This field affects pin mux control by setting the default of PINMUX0.AEM. This field does not affect EMIFA
Register settings.
The default value is latched from the AEM[2:0] configuration pins.
Reserved. Writes have no effect.
7:4
3:0
RESERVED
BOOTMODE
Boot Mode (see Section 3.4.1, Boot Modes)
This field is used in conjunction with FASTBOOT, AEM, and PLLMS to determine the device boot mode.
The default value is latched from the BOOTMODE[3:0] configuration pins.
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3.4.2.2 BOOTCMPLT Register
If the bootloader code detects an error during boot, it records the error status in the Boot Complete
(BOOTCMPLT) register.
In addition, the BOOTCMPLT register is used for communication between the external host and the
bootloader code during a Host Boot (HPI Boot). Once the external host has completed boot, it must
perform the following communication with the bootloader code:
•
Write the desired 32-bit CPU starting address in the DSPBOOTADDR register (see Section 3.4.2.3,
DSPBOOTADDR Register).
•
Write a ‘1’ to the Boot Complete (BC) bit field in the BOOTCMPLT register to indicate that the host has
completed booting this device.
Once the bootloader code detects BC = 1, it directs the CPU to begin executing from the
DSPBOOTADDR register.
The BOOTCMPLT register is reset by any device-level global reset. For the list of device-level global
resets, see Section 6.5, Reset.
31
15
20
19
16
RESERVED
ERR
R/W-0000
1
R/W-0000 0000 0000
0
RESERVED
R/W- 0000 0000 0000 000
LEGEND: R = Read; W = Write; -n = value after reset
BC
R/W-0
Figure 3-4. BOOTCMPLT Register— 0x01C4 000C
Table 3-10. BOOTCMPLT Register Description
Bit
Field Name Description
31:20
RESERVED Reserved. For proper device operation, the user should only write "0" to these bits.
Boot Error
0000 = No Error (default).
19:16
15:1
ERR
0001 - 1111 = bootloader software detected a boot error and aborted the boot. For the error codes, see the
Using the TMS320DM643x DMP Bootloader Application Report (literature number SPRAAG0).
RESERVED Reserved. For proper device operation, the user should only write "0" to these bits.
Boot Complete Flag from Host
This field is only applicable to Host Boots.
0
BC
0 = Host has not completed booting this device (default).
1 = Host has completed booting this device. DSP can begin executing from the DSPBOOTADDR register
value.
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3.4.2.3 DSPBOOTADDR Register
The DSP Boot Address (DSPBOOTADDR) register contains the starting address for the C64x+ CPU.
Whenever the C64x+ is released from reset, it begins executing from the location pointed to by
DSPBOOTADDR register. For Host boots (HPI Boot), the DSPBOOTADDR register is also used for
communication between the Host and the bootloader code during boot.
The DSPBOOTADDR register is reset by any device-level global reset. For the list of device-level global
resets, see Section 6.5, Reset.
31
0
DSPBOOTADDR
R/W-0x0010 0000 or 0x4200 00000
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-5. DSPBOOTADDR Register— 0x01C4 0008
Table 3-11. DSPBOOTADDR Register Description
Bit
Field Name
Description
DSP Boot Address
After boot, the C64x+ CPU begins execution from this 32-bit address location. The lower 10 bits
(bits 9:0) should always be programmed to "0" as they are ignored by the C64x+. The default
value of the DSPBOOTADDR depends on the boot mode selected.
31:0
DSPBOOTADDR
The DSPBOOTADDR defaults to 0x00100000 when the Internal Bootloader ROM is used.
or
The DSPBOOTADDR defaults to 0x42000000 when EMIFA CS2 Space is used.
For the boot mode selections, see Table 3-5, Non-Fastboot Modes; Table 3-6, Fixed-Multiplier
Fastboot Modes; and Table 3-7, User-Select Multiplier Fastboot Modes.
For Non-Host Boot Modes, software can leave the DSPBOOTADDR register at default.
For Host Boots (HPI Boot), the DSPBOOTADDR register is also used for communication between the
Host and the bootloader code during boot. For Host Boots, the DSPBOOTADDR register defaults to
Internal Bootloader ROM, and the C64x+ CPU is immediately released from reset so that it can begin
executing the bootloader code in this internal ROM. The bootloader code waits for the Host to boot the
device. Once the Host is done booting the device, it must write a new starting address into the
DSPBOOTADDR register, and follow with writing BOOTCMPLT.BC = 1 to indicate the boot is complete.
As soon as the bootloader code detects BOOTCMPLT.BC = 1, it instructs the CPU to jump to this new
DSPBOOTADDR address. At this point, the CPU continues the rest of the code execution starting from
the new DSPBOOTADDR location and the boot is completed.
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3.5 Configurations At Reset
Some device configurations are determined at reset. The following subsections give more details.
3.5.1 Device and Peripheral Configurations at Device Reset
Table 2-5, BOOT Terminal Functions lists the device boot and configuration pins that are latched at device
reset for configuring basic device settings for proper device operation. Table 3-12, summarizes the device
boot and configuration pins, and the device functions that they affect.
Table 3-12. Default Functions Affected by Device Boot and Configuration Pins
DEVICE BOOT AND
CONFIGURATION
BOOT SELECTED
Boot Mode
PIN MUX CONTROL
GLOBAL SETTING
PERIPHERAL SETTING
PINS(1)
BOOTMODE[3:0]
PINMUX0/PINMUX1
Registers:
I/O Pin Power:
Based on
PSC/Peripherals:
Based on
Based on
BOOTMODE[3:0], the
BOOTMODE[3:0], the
BOOTMODE[3:0], the
bootloader code programs bootloader code programs
bootloader code programs VDD3P3V_PWDN register the PSC to put
PINMUX0 and PINMUX1 to power up the I/O pins boot-related peripheral(s)
registers to select the
appropriate pin functions
required for boot.
required for boot.
in the Enable State, and
programs the peripheral(s)
for boot operation.
FASTBOOT
Fastboot
–
Sets Device Frequency:
Based on BOOTMODE,
FASTBOOT, PLLMS, and
AEM the bootloader code
programs PLLC1.
–
AEAW[2:0]/PLLMS[2:0]
If FASTBOOT = 1 and
AEM = 000b or 101b the
PLLMS[2:0] selects the
FASTBOOT PLL
PINMUX0.AEAW:
AEAW[2:0] sets the
default of this field to
control the EMIFA
address bus width (only
applicable if
Sets Device Frequency:
Based on BOOTMODE,
FASTBOOT, PLLMS, and
AEM the bootloader code
programs PLLC1.
–
Multiplier.
PINMUX0.AEM = 001b).
Affects the pin muxing in
EMIFA/VPSS Sub-Block
0.
AEM[2:0]
Together with FASTBOOT PINMUX0.AEM:
Sets Device Frequency: PSC/EMIFA:
and PLLMS[2:0] ,
determines the
FASTBOOT PLL
Multiplier.
Sets the default of this
field to control the EMIFA FASTBOOT, PLLMS, and defaults to SwRstDisable
Pinout Mode.
Based on BOOTMODE,
The EMIFA module state
AEM the bootloader code if AEM = 0; otherwise, the
programs PLLC1.
EMIFA module state
defaults to Enable.
Affects the pin muxing in
EMIFA/VPSS Sub-Block
0, 1, and 3.
(1) Software can modify all PINMUX0 and PINMUX1 bit fields from their defaults.
For proper device operation, external pullup/pulldown resistors may be required on these device boot and
configuration pins. For discussion situations where external pullup/pulldown resistors are required, see
Section 3.9.1, Pullup/Pulldown Resistors.
Note: All DM6435 configuration inputs (BOOTMODE[3:0], FASTBOOT, AEAW[2:0]/PLLMS[2:0] and
AEM[2:0]) are multiplexed with other functional pins. These pins function as device boot and configuration
pins only during device reset. The user must take care of any potential data contention in the system. To
help avoid system data contention, the DM6435 puts these configuration pins into a high-impedance state
(Hi-Z) when device reset (RESET or POR) is asserted, and continues to hold them in a high-impedance
state until the internal global reset is removed; at which point, the default peripheral (either GPIO or
EMIFA based on default of AEM[2:0]) will now control these pins.
All of the device boot and configuration pin settings are captured in the corresponding bit fields in the
BOOTCFG register (see Section 3.4.2.1).
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The following subsections provide more details on the device configurations determined at device reset:
AEM and AEAW/PLLMS.
3.5.1.1 EMIFA Pinout Mode (AEM[2:0])
To support different usage scenarios, the DM6435 provides intricate pin multiplexing between the EMIFA
and other peripherals. The PINMUX0.AEM register bit field in the System Module determines the EMIFA
Pinout Mode. The AEM[2:0] pins only select the default EMIFA Pinout Mode. It is latched at device reset
de-assertion (high) into the BOOTCFG.DAEM bit field. The AEM[2:0] value also sets the default of the
PINMUX0.AEM bit field. While the BOOTCFG.DAEM bit field shows the actual latched value and cannot
be modified, the PINMUX0.AEM value can be changed by software to modify the EMIFA Pinout Mode.
Note: The AEM[2:0] value does not affect the operation of the EMIFA module itself. It only affects which
EMIFA pins are brought out to the device pins. For more details on the AEM settings, see Section 3.7,
Multiplexed Pin Configurations.
In addition, for Fastboot modes (FASTBOOT = 1), the bootloader code determines the PLL1 multiplier
based on the default settings of AEM[2:0] and PLLMS[2:0]. For more details, see Section 3.4.1.1,
Fastboot, and Section 3.5.1.2, EMIFA Address Width Select (AEAW) and FASTBOOT PLL Multiplier
Select (PLLMS).
3.5.1.2 EMIFA Address Width Select (AEAW) and FASTBOOT PLL Multiplier Select (PLLMS)
The AEAW[2:0]/PLLMS[2:0] pins serve two functional purposes (AEAW or PLLMS), depending on the
FASTBOOT and AEM settings. The AEAW[2:0]/PLLMS[2:0] pins are latched at device reset de-assertion
(high) and captured in the BOOTCFG.PLLMS bit field. This value also sets the default of the
PINMUX0.AEAW field.
While the BOOTCFG.PLLMS field shows the actual latched value and cannot be modified, the
PINMUX0.AEAW value can be changed by software to modify the EMIFA pinout.
AEAW as EMIFA Address Width Select (AEAW)
If AEM[2:0] = 001b [8-bit EMIFA (Async) Pinout Mode 1], the AEAW[2:0]/PLLMS[2:0] pins serve as AEAW
to set the default of the EMIFA Address Width Selection.
When EMIFA is used in the 8-bit EMIFA (Async) Pinout Mode 1 (PINMUX0.AEM = 001b), the user has the
option to determine how many address pins are needed. The unused address pins can be used as
general-purpose input/output (GPIO) pins or extra data pins for VPFE. For more details on how the AEAW
settings control the exact pin out when AEM = 001b, see Section 3.7.3.11, EMIFA/VPSS Block Muxing.
For other EMIFA Pinout Modes (AEM not 001b), AEAW is not applicable in determining the EMIFA
address width.
Note: AEAW[2:0] value does not affect the operation of the EMIFA module itself. It only affects which of
the EMIFA address bits are brought out to the device pins.
AEAW as Fast Boot PLL Multiplier Select (PLLMS)
If FASTBOOT = 1, and AEM[2:0] = 000b [No EMIFA] or 101b [8-bit EMIFA (NAND) Pinout Mode 5], the
AEAW[2:0]/PLLMS[2:0] pins serve as PLLMS to select PLL multiplier for Fastboot modes.
For more information on boot modes and the FASTBOOT PLL multiplier selection, see Section 3.4.1, Boot
Modes.
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3.6 Configurations After Reset
The following sections provide details on configuring the device after reset.
Multiplexed pins are configured both at and after reset. Section 3.5.1, Device and Peripheral
Configurations at Device Reset, discusses multiplexed pin control at reset. For more details on multiplexed
pins control after reset, see Section 3.7 , Multiplexed Pin Configurations.
3.6.1 Switch Central Resource (SCR) Bus Priorities
Prioritization within the Switched Central Resource (SCR) is programmable for each master. The register
bit fields and default priority levels for DM6435 bus masters are shown in Table 3-13, DM6435 Default Bus
Master Priorities. The priority levels should be tuned to obtain the best system performance for a particular
application. Lower values indicate higher priority. For most masters, their priority values are programmed
at the system level by configuring the MSTPRI0 and MSTPRI1 registers. Details on the MSTPRI0/1
registers are shown in Figure 3-6 and Figure 3-7. The C64x+, VPSS, and EDMA masters contain registers
that control their own priority values.
Table 3-13. DM6435 Default Bus Master Priorities
Priority Bit Field
VPSSP
Bus Master
VPSS
Default Priority Level
0 (VPSS PCR Register)
EDMATC0P
EDMATC1P
EDMATC2P
C64X+_DMAP
C64X+_CFGP
EMACP
EDMATC0
EDMATC1
EDMATC2
C64X+ (DMA)
C64X+ (CFG)
EMAC
0 (EDMACC QUEPRI Register)
0 (EDMACC QUEPRI Register)
0 (EDMACC QUEPRI Register)
7 (C64x + MDMAARBE.PRI field)
1 (MSTPRI0 Register)
4 (MSTPRI1 Register)
VLYNQP
VLYNQ
4 (MSTPRI1 Register)
HPIP
HPI
4 (MSTPRI1 Register)
31
15
16
0
RESERVED
R-0000 0000 0000 0000
11
10
9
8
7
RESERVED
R-0000 0
C64X+_CFGP
R/W-001
RESERVED
R-0000 0000
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-6. MSTPRI0 Register— 0x01C4 003C
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Table 3-14. MSTPRI0 Register Description
Bit
Field Name
Description
31:11
RESERVED
Reserved. Read-only, writes have no effect.
C64X+_CFG master port priority in System Infrastructure.
000 = Priority 0 (Highest)
001 = Priority 1
100 = Priority 4
10:8
7:0
C64X+_CFGP
RESERVED
101 = Priority 5
010 = Priority 2
110 = Priority 6
011 = Priority 3
111 = Priority 7 (Lowest)
Reserved. Read-only, writes have no effect.
31
15
27
26
25
24
23
22
21
20
19
RSV
R-0
3
18
2
17
16
0
RESERVED
R-0000 0
RSV
RSV
R-0
HPIP
VLYNQP
R/W-100
1
R/W-100
R/W-100
RESERVED
EMACP
R/W-100
R- 0000 0000 0000 0
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-7. MSTPRI1 Register— 0x01C4 0040
Table 3-15. MSTPRI1 Register Description
Bit
Field Name
Description
31:27
RESERVED
Reserved. Read-only, writes have no effect.
Reserved. For proper device operation, the user must only write "100" to
these bits.
26:24
23
RSV
RSV
Reserved. Read-only, writes have no effect.
HPI master port priority in System Infrastructure.
000 = Priority 0 (Highest)
001 = Priority 1
100 = Priority 4
22:20
19
HPIP
101 = Priority 5
010 = Priority 2
110 = Priority 6
011 = Priority 3
111 = Priority 7 (Lowest)
RSV
Reserved. Read-only, writes have no effect.
VLYNQ master port priority in System Infrastructure.
000 = Priority 0 (Highest)
001 = Priority 1
100 = Priority 4
18:16
15:3
2:0
VLYNQP
RESERVED
EMACP
101 = Priority 5
010 = Priority 2
110 = Priority 6
011 = Priority 3
111 = Priority 7 (Lowest)
Reserved. Read-only, writes have no effect.
EMAC master port priority in System Infrastructure.
000 = Priority 0 (Highest)
001 = Priority 1
100 = Priority 4
101 = Priority 5
010 = Priority 2
110 = Priority 6
011 = Priority 3
111 = Priority 7 (Lowest)
3.6.2 Peripheral Selection After Device Reset
After device reset, most peripheral configurations are done within the peripheral’s registers. This section
discusses some additional peripheral controls in the System Module. For information on multiplexed pin
controls that determine what peripheral pins are brought out to the pins, see Section 3.7, Multiplexed Pin
Configurations.
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3.6.2.1 HPI Control Register (HPICTL)
The HPI Control (HPICTL) register determines the Host Burst Write Time-Out value. The user should
only modify this register once during device initialization. When modifying this register, the user
must ensure the HPI FIFOs are empty and there are no on-going HPI transactions.
31
15
16
RESERVED
R-0000 0000 0000 0000
10
9
8
7
0
RESERVED
R- 0000 00
RESERVED
R/W-00
TIMOUT
R/W-1000 0000
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-8. HPICTL Register— 0x01C4 0030
Table 3-16. HPICTL Register Description
Bit
Field Name Description
31:10
9:8
RESERVED Reserved. Read-only, writes have no effect.
RESERVED Reserved. For proper device operation, the user should only write "0" to these bits (default).
Host Burst Write Timeout Value
When the HPI time-out counter reaches the value programmed here, the HPI write FIFO content is flushed. For
more details on the time-out counter and its use in write bursting, see the TMS320DM643x DMP Host Port
Interface (HPI) User's Guide (literature number SPRU998).
7:0
TIMOUT
3.6.2.2 Timer Control Register (TIMERCTL)
The Timer Control Register (TIMERCTL) provides additional control for Timer0 and Timer2. The user
should only modify this register once during device initialization, when the corresponding Timer is
not in use.
•
Timer 2 Control: The TIMERCTL.WDRST bit determines if the WatchDog timer event (Timer 2) can
cause a device max reset. For more details on the description of a maximum reset, see Section 6.5.3,
Maximum Reset.
•
Timer 0 Control: The TINP0SEL bit selects the clock source connected to Timer0's TIN0 input.
31
15
16
RESERVED
R-0000 0000 0000 0000
2
1
0
TINP0
SEL
WD
RST
RESERVED
R- 0000 0000 0000 00
R/W-0
R/W-1
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-9. TIMERCTL Register— 0x01C4 0084
Table 3-17. TIMERCTL Register Description
Bit
Field Name Description
31:2
RESERVED Reserved. Read-Only, writes have no effect.
Timer0 External Input (TIN0) Select
0 = Timer0 external input comes directly from the TINP0L pin (default).
1 = Timer0 external input is TINP0L pin divided by 6. For example, if TINP0L = 27MHz, Timer0 input TIN0 is
27MHz / 6 = 4.5 MHz.
1
TINP0SEL
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Table 3-17. TIMERCTL Register Description (continued)
Bit
Field Name Description
WatchDog Reset Enable
0
WDRST
0 = WatchDog Timer Event (WDINT from Timer2) does not cause device reset.
1 = WatchDog Timer Event (WDINT from Timer2) causes a device max reset (default).
3.6.2.3 EDMA TC Configuration Register (EDMATCCFG)
The EDMA Transfer Controller Configuration (EDMATCCFG) register configures the default burst size
(DBS) for EDMA TC0, EDMA TC1, and EDMA TC2. For more information on the correct usage of DBS,
see the TMS320DM643x DMP Enhanced Direct Memory Access (EDMA) Controller User's Guide
(literature number SPRU987). The user should only modify this register once during device
initialization and when the corresponding EDMA TC is not in use.
31
15
16
RESERVED
R-0000 0000 0000 0000
6
5
4
3
2
1
0
RESERVED
TC2DBS
R/W-10
TC1DBS
R/W-01
TC0DBS
R/W-00
R-0000 0000 00
LEGEND: R = Read; W = Write; -n = value after reset
Figure 3-10. EDMATCCFG Register— 0x01C4 0088
Table 3-18. EDMATCCFG Register Description
Bit
Field
Description
31:6
RESERVED Reserved. Read-Only, writes have no effect.
EDMA TC2 Default Burst Size
00 = 16 byte
01 = 32 byte
10 = 64 byte (default)
11= reserved
5:4
3:2
1:0
TC2DBS
EDMA TC2 is intended for miscellaneous transfers.
TC2 FIFO size is 128 bytes, regardless of Default Burst Size setting.
EDMA TC1 Default Burst Size
00 = 16 byte
01 = 32 byte (default)
10 = 64 byte
11 = reserved
TC1DBS
EDMA TC1 is intended for high throughput bulk transfers.
TC1 FIFO size is 256 bytes, regardless of Default Burst Size setting.
EDMA TC0 Default Burst Size
00 = 16 byte (default)
01 = 32 byte
10 = 64 byte
11 = reserved
TC0DBS
EDMA TC0 is intended for short burst transfers with stringent deadlines (e.g., McBSP, McASP).
TC0 FIFO size is 128 bytes, regardless of Default Burst Size setting.
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3.7 Multiplexed Pin Configurations
DM6435 makes extensive use of pin multiplexing to accommodate a large number of peripheral functions
in the smallest possible package, providing ultimate flexibility for end applications.
The Pin Multiplex Registers PINMUX0 and PINMUX1 in the System Module are responsible for controlling
all pin multiplexing functions on the DM6435. The default setting of some of the PINMUX0 and PINMUX1
bit fields are configured by configuration pins latched at reset (see Section 3.5.1, Device and Peripheral
Configurations at Device Reset). After reset, software may program the PINMUX0 and PINMUX1 registers
to switch pin functionalities.
The following peripherals have multiplexed pins: VPSS (VPFE), EMIFA, HPI, VLYNQ, EMAC, McASP0,
McBSP0, PWM0, PWM1, PWM2, Timer0, Timer1, UART0, UART1, HECC, and GPIO.
The device is divided into the following Pin Multiplexed Blocks (Pin Mux Blocks):
•
EMIFA/VPSS Block: VPSS (VPFE), EMIFA, and GPIO. This block is further subdivided into these
sub-blocks:
–
–
–
–
Sub-Block 0: VPFE (CCDC), part of EMIFA (address and control), and GPIO
Sub-Block 1: part of EMIFA (data, address, control), and GPIO
Sub-Block 2: part of EMIFA (control signals EM_WAIT/(RDY/BSY), EM_OE, and EM_WE)
Sub-Block 3: part of EMIFA (address EM_A[12:5]), and GPIO
•
•
Host Block: HPI, VLYNQ, EMAC, and GPIO
Serial Port Block: McBSP0, McASP0, and GPIO. This block is further sub-divided into sub-blocks.
–
–
Serial Port Sub-Block 0: McBSP0, part of McASP0, and GPIO
Serial Port Sub-Block 1: part of McASP0 and GPIO
•
•
•
•
•
•
UART0 Flow Control Block: UART0 flow control, PWM0, and GPIO
UART0 Data Block: UART0 data and GPIO
Timer0 Block: Timer0 and McBSP0 CLKS pins
Timer1 Block: Timer1 and HECC, UART1 data
PWM1 Block: PWM1 and GPIO
CLKOUT Block: CLKOUT0, PWM2, and GPIO
As shown in the list above, the McBSP0 and UART0 peripherals span multiple Pin Mux Blocks. To use
these peripherals, they must be selected in all relevant Pin Mux Blocks. For more details, see
Section 3.7.3, Pin Multiplexing Details, and Section 3.7.3.2, Peripherals Spanning Multiple Pin Mux
Blocks.
Note: there is no actual pin multiplexing in EMIFA/VPSS Sub-Block 2. However this is still considered a
"pin mux block" because it contains part of the pins necessary for EMIFA.
A high level view of the Pin Mux Blocks is shown in Figure 3-11. In each Pin Mux Block, the
PINMUX0/PINMUX1 default settings are underlined.
Note: some default pin functions are determined by configuration pins (AEAW[2:0] and AEM[2:0]);
therefore, more than one configuration setting can serve as default based on the configuration pin settings
latched at device reset.
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(A)
Host Block (27 pins)
VLYNQ
(10)
VLYNQ
(10)
GPIO (27)
HPI (26)
GPIO (1)
EMAC (15)
MDIO
(2)
GPIO (17)
EMAC (15)
MDIO
(2)
GPIO (10)
HOSTBK=000
HOSTBK=001
HOSTBK=010
HOSTBK=011
HOSTBK=100
PWM 1 Block (1 pin)
CLKOUT Block (1 pin)
GPIO
(1)
PWM1
(1)
GPIO
(1)
CLKOUT
(1)
PWM2
(1)
PWM1BK=0
PWM1BK=1
CKOBK=00 CKOBK=01
CKOBK=10
UART0 Data Block (2 pins)
UART0 Flow Control Block (2 pins)
PWM0 (1)
GPIO (1)
UART
GPIO (2)
UART0
GPIO (2)
Data (2)
FlowCtrl (2)
UR0DBK=0
UR0DBK=1
UR0FCBK=00
UR0FCBK=01
UR0FCBK=10
(C)
Timer1 Block (2 pins)
Timer0 Block (2 pins)
Timer1
(2)
UART1
Data (2)
HECC
(2)
McBSP0
CLKS0 (1)
Timer0
(2)
GPIO (2)
GPIO (2)
Timer0
TINPOL (1)
TIM1BK=00
TIM1BK=01
TIM1BK=10
(C)
TIM1BK=11
TIM0BK=00
TIM0BK=01
TIM0BK=11
Serial Port Sub-Block 0 (6 pins)
Serial Port Sub-Block 1 (6 pins)
McBSP0
GPIO (6)
(6)
GPIO (6)
McASP0
McASP0 Receive
and 3 Serializers (6)
Transmit and
1 Serializer (6)
SPBK0=00
SPBK0=01
SPBK0=10
(A)(B)
SPBK1=00
SPBK1=10
EMIFA/VPSS Block (61 pins)
8b EMIFA
(Async)
Pinout
Mode 1
32KB-16MB
per CE
8b EMIFA
(NAND)
Pinout
Mode 5
8-16b
VPFE
8-16b
VPFE
8-16b
VPFE
GPIO
GPIO
GPIO
Major Config
Option A
Major Config
Option B
Major Config
Option E
AEM=000
AEM=001
AEM=101
A. Default settings for PINMUX0 and PINMUX1 registers are underlined.
B. EMIFA/VPSS Block: shows the Major Config Options based on the AEM settings. Actual pin functions in the
EMIFA/VPSS Block are further determined by other PINMUX fields.
C. McBSP0 pins span multiple blocks (Serial Port Sub-Block0 and Timer0 Block). Serial Port Sub-Block0 contains most
of the pins needed for McBSP0 operation. Timer0 Block contains the optional external clock source input CLKS0.
Figure 3-11. Pin Mux Block Selection
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3.7.1 Pin Muxing Selection At Reset
This section summarizes pin mux selection at reset.
The configuration pins AEM[2:0] and AEAW[2:0] latched at device reset determine default pin muxing for
the following Pin Mux Blocks:
•
EMIFA/VPSS Block: default pin mux determined by AEM[2:0] and AEAW[2:0]. After reset, software
may modify settings in the PINMUX0 register to add VPFE functionalities into this block.
–
–
–
AEM[2:0] = 000b, AEAW[2:0] = don't care: Major Config Option A is selected. This block defaults to
61 GPIO pins.
AEM[2:0] = 001b, AEAW[2:0] = 000b to 100b: Major Config Option B is selected. This block
defaults to 8-bit EMIFA (Async) Pinout Mode 1, plus 24-to-32 GPIO pins.
AEM[2:0] = 101b, AEAW[2:0] = don't care: Major Config Option E is selected. This block defaults to
8-bit EMIFA (NAND) Pinout mode 5, plus 47 GPIO pins.
For a description of the PINMUX0 and PINMUX1 registers and more details on pin muxing, see
Section 3.7.2, Pin Muxing Selection After Reset.
3.7.2 Pin Muxing Selection After Reset
The PINMUX0 and PINMUX1 registers in the System Module allow software to select the pin functions in
the Pin Mux Blocks. The pin control of some of the Pin Mux Blocks requires a combination of
PINMUX0/PINMUX1 bit fields. For more details on the combination of the PINMUX bit fields that control
each muxed pin, see Section 3.7.3.1, Multiplexed Pins on DM6435.
This section only provides an overview of the PINMUX0 and PINMUX1 registers. For more detailed
discussion on how to program each Pin Mux Block, see Section 3.7.3, Pin Multiplexing Details.
3.7.2.1 PINMUX0 Register Description
The Pin Multiplexing 0 Register (PINMUX0) controls the pin function in the EMIFA/VPSS Block. The
PINMUX0 register format is shown in Figure 3-12 and the bit field descriptions are given in Table 3-19.
Some muxed pins are controlled by more than one PINMUX bit field. For the combination of the PINMUX
bit fields that control each muxed pin, see Section 3.7.3.1, Multiplexed Pins on DM6435. For more
information on EMIFA/VPSS Block pin muxing, see Section 3.7.3.11, EMIFA/VPSS Block Muxing. For the
pin-by-pin muxing control of the EMIFA/VPSS Block, see Section 3.7.3.11.7, EMIFA/VPSS Block
Pin-By-Pin Multiplexing Summary.
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
16
CWEN
SEL
RSV
CI10SEL
R/W-0
RSV
CI32SEL
R/W-0
RSV
CI54SEL CI76SEL CFLDSEL
HVDSEL
R/W-0
RSV
CCDCSEL
R/W-0
RSV
AEAW
R/W-LLL
R/W-0
R/W-0
R/W-0
R/W-0
10
R/W-0
9
R/W-0
8
R/W-0
7
R/W-0
R/W-0
15
14
13
12
11
6
5
4
3
2
1
0
RESERVED
R/W-0000
CS3SEL
R/W-00
CS4SEL
R/W-00
CS5SEL
R/W-00
RESERVED
R/W-000
AEM
R/W-LLL
LEGEND: R/W = Read/Write; R = Read only; L = pin state latched at reset rising edge; -n = value after reset
(1) For proper DM6435 device operation, always write a value of "0" to all RESERVED/RSV bits.
Figure 3-12. PINMUX0 Register— 0x01C4 0000 (1)
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Table 3-19. PINMUX0 Register Description
Bit
Field Name
Description
Pins Controlled
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
31
30
29
28
27
26
RSV
Sub-Block 0
CI[1:0] Function Select.
CI1(CCD9)/EM_A[19]/GP[45]
CI0(CCD8)/EM_A[20]/GP[44]
0 = No CCDC CI[1:0].
Pins function as GPIO or EMIFA based on AEM and AEAW settings (default).
CI10SEL
RSV
1 = Selects CCDC [1:0] (as CCD8 and CCD9, respectively) to get at least a 10-bit
CCDC.
To use the 10-bit CCDC, the user must also configure PINMUX0.CCDCSEL = 1.
The combination of PINMUX0 fields AEM,
AEAW, and CI10SEL bits control the pin
(1)
muxing of these 2 pins.
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
CI[3:2] Function Select.
Sub-Block 0
0 = No CCDC CI[3:2].
Pins function as GPIO or EMIFA based on AEM and AEAW settings (default).
CI3(CCD11)/EM_A[17]/GP[47]
CI2(CCD10)/EM_A[18]/GP[46]
CI32SEL
RSV
1 = Selects CCDC [3:2] (as CCD10 and CCD11, respectively) to get at least a
12-bit CCDC.
To use the 12-bit CCDC, the user must also configure PINMUX0.CCDCSEL = 1
and PINMUX0.CI10SEL = 1.
The combination of PINMUX0 fields AEM,
AEAW, and CI32SEL bits control the pin
(1)
muxing of these 2 pins.
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
CI[5:4] Function Select.
Sub-Block 0
0 = No CCDC CI[5:4].
Pins function as GPIO or EMIFA based on AEM and AEAW settings (default).
CI5(CCD13)/EM_A[15]/GP[49]
CI4(CCD12)/EM_A[16]/GP[48]
CI54SEL
1 = Selects CCDC [5:4] (as CCD12 and CCD13, respectively) to get at least a
14-bit CCDC.
The combination of PINMUX0 fields AEM,
AEAW, and CI54SEL bits control the pin
muxing of these 2 pins.(1)
To use the 14-bit CCDC, the user must also configure PINMUX0.CCDCSEL = 1,
PINMUX0.CI10SEL = 1, and PINMUX0.CI32SEL = 1.
CI[7:6] Function Select.
Sub-Block 0
0 = No CCDC CI[7:6].
Pins function as GPIO or EMIFA based on AEM and AEAW settings (default).
CI7(CCD15)/EM_A[13]/GP[51]
CI6(CCD14)/EM_A[14]/GP[50]
25
CI76SEL
1 = Selects CCDC [7:6] (as CCD14 and CCD15, respectively) to get at least a
16-bit CCDC.
To use the 16-bit CCDC, the user must also configure PINMUX0.CCDCSEL = 1,
PINMUX0.CI10SEL = 1, PINMUX0.CI32SEL = 1, and PINMUX0.CI54SEL = 1.
The combination of PINMUX0 fields AEM,
AEAW, and CI76SEL bits control the pin
muxing of these 2 pins.(1)
Sub-Block 0
CCDC Field Select.
C_FIELD/EM_A[21]/GP[34]
0 = No CCDC Field (C_FIELD).
24
23
CFLDSEL
CWENSEL
Pin functions as EMIFA EM_A[21] or GPIO based on AEM setting (default).
The combination of PINMUX0/1 fields
CFLDSEL and AEM control the muxing of this
1 = CCDC Field (C_FIELD).
CCDC Write Enable Select.
(1)
pin.
Sub-Block 0
0 = No CCDC Write Enable.
Pin functions as EMIFA EM_R/W or GPIO based on AEM setting (default).
C_WE/EM_R/W/GP[35]
1 = CCDC Write Enable (C_WE).
Pin functions as CCDC Write Enable C_WE.
Applicable only for AEM = 0 (000b) or 5 (101b).
The combination of PINMUX0 fields CWENSEL
and AEM control the muxing of this pin.
(1)
Sub-Block 0
CCDC HD and VD Select.
VD/GP[53]
HD/GP[52]
0 = No CCDC HD and VD.
Pins function as GPIO (GP[53] and GP[52]) (default).
22
21
HVDSEL
RSV
The PINMUX0 field HVDSEL alone controls the
muxing of these 2 pins.
1 = CCDC HD and VD.
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
(1) For the full set of valid configurations of these pins, see Section 3.7.3.11.7, EMIFA/VPSS Block Pin-By-Pin Multiplexing Summary.
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Table 3-19. PINMUX0 Register Description (continued)
Bit
Field Name
Description
Pins Controlled
Sub-Block 0
PCLK/GP[54]
YI7(CCD7)/GP[43]
YI6(CCD6)/GP[42]
YI5(CCD5)/GP[41]
YI4(CCD4)/GP[40]
YI3(CCD3)/GP[39]
YI2(CCD2)/GP[38]
YI1(CCD1)/GP[37]
YI0(CCD0)/GP[36]
CCDC Select.
This bit field determines if CCDC is supported or not.
0 = CCDC not supported.
Pins function as GPIO (GP[54] and GP[43:36]) (default).
20
CCDCSEL
1 = CCDC supported.
Pins function as CCDC PCLK, YI[7:0].
The PINMUX0 field CCDCSEL alone controls
the muxing of these 9 pins.
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
19
RSV
8-bit EMIFA (Async) Pinout Mode 1 Address Width Select or Fast Boot PLL
Multiplier Select
This field serves two purposes:
1. If AEM = 001b, this field serves as the 8-bit EMIFA (Async) Pinout Mode 1
Address Width Select.
2. If FASTBOOT = 1 and AEM = 0 (000b) or 5 (101b), this field serves as the
Fastboot PLL Multiplier Select.
Fastboot PLL Multiplier Select: For more details on the AEAW pin functions as
Fastboot PLL Multiplier Select, see Section 3.4.1, Bootmodes.
EMIFA Address Width Select:
000b = EMIFA (Async) pinout supports only EM_A[12:0] address pins.
EMIFA (Async) signals EM_A[20:13] are not pinned out. PINMUX bit fields
CI76SEL, CI54SEL, CI32SEL, and CI10SEL determine the function of these 8
pins.
Sub-Block 0
CI7(CCD15)/EM_A[13]/GP[51]
CI6(CCD14)/EM_A[14]/GP[50]
CI5(CCD13)/EM_A[15]/GP[49]
CI4(CCD12)/EM_A[16]/GP[48]
CI3(CCD11)/EM_A[17]/GP[47]
CI2(CCD10)/EM_A[18]/GP[46]
CI1(CCD9)/EM_A[19]/GP[45]
CI0(CCD8)/EM_A[20]/GP[44]
001b = EMIFA (Async) pinout supports only EM_A[14:0] address pins.
EMIFA (Async) signals EM_A[14:13] are pinned out. PINMUX0 bit field CI76SEL
must be programmed to 0.
EMIFA (Async) signals EM_A[20:15] are not pinned out. PINMUX0 bit fields
CI54SEL, CI32SEL, and CI10SEL determine the function of these 6 pins.
18:16
AEAW(1)
010b = EMIFA (Async) pinout supports only address pins EM_A[16:0].
EMIFA (Async) signals EM_A[16:13] are pinned out. PINMUX0 bit fields CI76SEL
and CI54SEL must be programmed to 0.
EMIFA (Async) signals EM_A[20:17] are not pinned out. PINMUX0 bit fields
CI32SEL and CI10SEL determine the function of these 4 pins.
The combination of PINMUX0 fields AEM,
AEAW, CI10SEL, CI32SEL, CI54SEL, and
CI76SEL control the muxing of these 8 pins.
(2)
011b = EMIFA (Async) pinout supports only address pins EM_A[18:0].
EMIFA (Async) signals EM_A[18:13] are pinned out. PINMUX0 bit fields
CI76SEL, CI54SEL, and CI32SEL must be programmed to 0.
EMIFA (Async) signals EM_A[20:19] are not pinned out. PINMUX0 bit field
CI10SEL determines the function of these 2 pins.
100b = EMIFA (Async) pinout supports address pins EM_A[20:0].
EMIFA (Async) signals EM_A[20:13] are pinned out. PINMUX0 bit fields
CI76SEL, CI54SEL, CI32SEL, and CI10SEL must be programmed to 0.
101b through 111b = Reserved.
Reserved. For proper device operation, the user should only write "0" to these bits
(default).
15:12
11:10
RESERVED
CS3SEL
Chip Select 3 Select.
Sub-Block 1
00 = GPIO pin (GP13) (default)
01 = EMIFA Chip Select 3 (EM_CS3)
10 = Reserved
EM_CS3/GP[13]
The PINMUX0 field CS3SEL alone controls the
muxing of this pin.
11 = Reserved
(1) The AEAW default value is latched at reset from AEAW[2:0] configuration inputs. The latched values are also shown at
BOOTCFG.PLLMS (read-only).
(2) For the full set of valid configurations of these pins, see Section 3.7.3.11.7, EMIFA/VPSS Block Pin-By-Pin Multiplexing Summary.
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Table 3-19. PINMUX0 Register Description (continued)
Bit
Field Name
Description
Pins Controlled
Chip Select 4 Select.
Sub-Block 1
00 = GPIO pin (GP32) (default)
EM_CS4/GP[32]
9:8
CS4SEL
01 = EMIFA Chip Select 4 (EM_CS4)
10 = Reserved
The PINMUX0 field CS4SEL alone controls the
muxing of this pin.
11 = Reserved
Chip Select 5 Select.
Sub-Block 1
00 = GPIO pin (GP33) (default)
01 = EMIFA Chip Select 5 (EM_CS5)
10 = Reserved
EM_CS5/GP[33]
7:6
5:3
CS5SEL
The PINMUX0 field CS5SEL alone controls the
muxing of this pin.
11 = Reserved
Reserved. For proper device operation, the user should only write "0" to these bits
(default).
RESERVED
Sub-Block 0
C_WE/EM_R/W/GP[35]
C_FIELD/EM_A[21]/GP[34]
CI7(CCD15)/EM_A[13]/GP[51]
CI6(CCD14)/EM_A[14]/GP[50]
CI5(CCD13)/EM_A[15]/GP[49]
CI4(CCD12)/EM_A[16]/GP[48]
CI3(CCD11)/EM_A[17]/GP[47]
CI2(CCD10)/EM_A[18]/GP[46]
CI1(CCD9)/EM_A[19]/GP[45]
CI0(CCD8)/EM_A[20]/GP[44]
EMIFA Pinout Modes
This field does not affect the actual EMIFA operation. It only determines what
multiplexed pins in the EMIFA/VPSS Block serves as EMIFA pins.
Sub-Block 1
EM_D[7]/GP[21]
EM_D[6]/GP[20]
EM_D[5]/GP[19]
EM_D[4]/GP[18]
000b = No EMIFA Mode.
None of the multiplexed pins in the EMIFA/VPSS Block serves as EMIFA pins.
EM_D[3]/GP[17]
EM_D[2]/GP[16]
EM_D[1]/GP[15]
EM_D[0]/GP[14]
001b = 8-bit EMIFA (Async) Pinout Mode 1.
(Up to 16M-Byte address reach per Chip Select Space).
Pinout allows up to a maximum of these functions from EMIFA/VPSS Block: 8-bit
EMIFA (Async or NAND) + 16-bit CCDC (VPFE)
2:0
AEM(1)
EM_CS2/GP[12]
EM_A[3]/GP[11]
010b = Reserved.
011b = Reserved.
100b = Reserved.
EM_A[4]/GP[10]/(AEAW2/PLLMS2)
EM_A[1]/(ALE)/GP[9]/(AEAW1/PLLMS1)
EM_A[2]/(CLE)/GP[8]/(AEAW0/PLLMS0)
EM_A[0]/GP[7]/(AEM2)
EM_BA[0]/GP[6]/(AEM1)
EM_BA[1]/GP[5]/(AEM0)
101b = 8-bit EMIFA (NAND) Pinout Mode 5.
Pinout allows up to a maximum of these functions from EMIFA/VPSS Block: 8-bit
EMIFA (NAND) + 16-bit CCDC (VPFE)
Sub-Block3
110b through 111b = Reserved.
EM_A[12]/GP[89]
EM_A[11]/GP[90]
EM_A[10]/GP[91]
EM_A[9]/GP[92]
EM_A[8]/GP[93]
EM_A[7]/GP[94]
EM_A[6]/GP[95]
EM_A[5]/GP[96]
The pin mux for these pins are controlled by a
combination of AEM and other PINMUX0 fields,
including CWENSEL, CFLDSEL, AEAW,
(2)
CI76SEL, CI54SEL, CI32SEL, and CI10SEL.
(1) The AEM default value is latched at reset from AEM[2:0] configuration inputs. The latched values are also shown at BOOTCFG.DAEM
(read-only).
(2) For the full set of valid configurations of these pins, see Section 3.7.3.11.7, EMIFA/VPSS Block Pin-By-Pin Multiplexing Summary.
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3.7.2.2 PINMUX1 Register Description
The Pin Multiplexing 1 Register (PINMUX1) controls the pin multiplexing of all Pin Mux Blocks. The
PINMUX1 register format is shown in Figure 3-13 and the bit field descriptions are given in Table 3-20.
Some muxed pins are controlled by more than one PINMUX bit field. For the combination of PINMUX bit
fields that control each muxed pin, see Section 3.7.3.1, Multiplexed Pins on DM6435.
31
15
26
25
24
23
22
21
20
19
18
17
16
RESERVED
SPBK1
SPBK0
TIM1BK
R/W-00
RSV
TIM0BK
R/W-00
R/W-0000 00
R/W-00
R/W-00
R/W-00
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
CKOBK
RSV
PWM1BK
UR0FCBK
RSV
UR0DBK
RSV
HOSTBK
RESERVED
R/W-000
RSV
R-0
R/W-01
R/W-0
R/W-0
R/W-00
R/W-0
R/W-0
R/W-0
R/W-000
LEGEND: R/W = Read/Write; R = Read only; P = specified pin state; -n = value after reset
(1) For proper DM6435 device operation, always write a value of "0" to all RESERVED/RSV bits.
Figure 3-13. PINMUX1 Register— 0x01C4 0004 (1)
Table 3-20. PINMUX1 Register Description
Bit
Field Name
Description
Pins Controlled
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
31:26
RESERVED
–
Serial Port Sub-Block 1 Pin Select.
Selects the function of the multiplexed pins in the Serial Port Sub-Block 1.
Serial Port Sub-Block 1:
AXR0[0]/GP[105]
ACLKX0/GP[106]
AFSX0/GP[107]
00 = GPIO Mode (default).
Pins function as GPIO (GP[110:105]).
25:24
SPBK1
01 = Reserved.
AHCLKX0/GP[108]
AMUTEIN0/GP[109]
AMUTE0/GP[110]
10 = McASP0 Transmit and 1 serializer.
Pins function as McASP0: AXR0[0], ACLKX0, AFSX0, AHCLKX0, AMUTEIN0,
and AMUTE0.
11 = Reserved.
Serial Port Sub-Block 0 Pin Select.
Selects the function of the multiplexed pins in the Serial Port Sub-Block 0.
00 = GPIO Mode (default).
Pins function as GPIO (GP[104:99]).
Serial Port Sub-Block 0:
ACLKR0/CLKX0/GP[99]
AFSR0/DR0/GP[100]
AHCLKR0/CLKR0/GP[101]
AXR0[3]/FSR0/GP[102]
AXR0[2]/FSX0/GP[103]
AXR0[1]/DX0/GP[104]
01 = McBSP0 Mode.
Pins function as McBSP0 CLKX0, FSX0, DX0, CLKR0, FSR0, and DR0.
23:22
SPBK0
10 = McASP0 Receive and 3 serializers.
Pins function as McASP0 ACLKR0, AFSR0, AHCLKR0, AXR0_3, AXR0_2, and
AXR0_1.
11 = Reserved
Timer1 Block Pin Select.
Selects the function of the multiplexed pins in theTimer1 Block.
00 = GPIO Mode (default).
Pins function as GPIO (GP[56:55]).
Timer1 Block:
HECC_RX/TINP1L/URXD1/GP[56]
HECC_TX/TOUT1L/UTXD1/GP[55]
01 = Timer1 Mode.
Pins function as Timer1 TINP1L and TOUT1L.
21:20
19:18
TIM1BK
10 = UART1 Data Mode.
Pins function as UART1 data pins URXD1 and UTXD1.
11 = HECC Mode.
Pins function as HECC HECC_RX and HECC_TX.
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
RSV
–
94
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Table 3-20. PINMUX1 Register Description (continued)
Bit
Field Name
Description
Pins Controlled
Timer0 Block Pin Select.
Selects the function of the multiplexed pins in the Timer0 Block.
00 = GPIO Mode (default).
Pins function as GPIO (GP[98:97]).
Timer0 Block:
TINP0L/GP[98]
CLKS0/TOUT0L/GP[97]
01 = Timer0 Mode.
Pins function as Timer0 TINP0L and TOUT0L.
17:16
TIM0BK
10 =Reserved.
11 = McBSP0 External Clock Source + Timer0 Input Mode.
Pins function as McBSP0 external clock source CLKS0, and Timer0 input
TINP0L.
CLKOUT Block Pin Select.
Selects the function of the multiplexed pins in the CLKOUT Block.
00 = GPIO Mode.
Pin functions as GPIO (GP[84]).
CLKOUT Block:
CLKOUT0/PWM2/GP[84]
15:14
CKOBK
01 = CLKOUT Mode (default).
Pin functions as device clock output CLKOUT0, sourced from PLLC1 OBSCLK.
10 = PWM2 Mode.
Pin functions as PWM2.
11 = Reserved
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
13
12
RSV
–
PWM1 Block Pin Select.
Selects the function of the multiplexed pins in the PWM1 Block.
0 = GPIO Mode (default).
Pin functions as GPIO (GP[4]).
PWM1 Block:
GP[4]/PWM1
PWM1BK
1 = PWM1 Mode.
Pin functions as PWM1.
UART0 Flow Control Block Pin Select.
Selects the function of the multiplexed pins in the UART0 Flow Control Block.
00 = GPIO Mode (default).
Pins function as GPIO (GP[88:87]).
UART0 Flow Control Block:
UCTS0/GP[87]
11:10
UR0FCBK
01 = UART0 Flow Control Mode.
Pins function as UART0 Flow Control UCTS0 and URTS0.
URTS0/PWM0/GP[88]
10 = PWM0 + GPIO Mode.
Pins function as PWM0 and GPIO (GP[87]).
11 = Reserved
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
9
8
RSV
–
UART0 Data Block Pin Select.
Selects the function of the multiplexed pins in the UART0 Data Block.
UART0 Data Block:
URXD0/GP[85]
UTXD0/GP[86]
0 = GPIO Mode (default).
Pins function as GPIO (GP[86:85]).
UR0DBK
1 = UART0 Data Mode.
Pins function as UART0 data URXD0 and UTXD0.
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Table 3-20. PINMUX1 Register Description (continued)
Bit
Field Name
Description
Pins Controlled
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
7
RSV
–
Host Block:
VLYNQ_CLOCK/GP[57]
HD0/VLYNQ_SCRUN/GP[58]
HD1/VLYNQ_RXD0/GP[59]
HD2/VLYNQ_RXD1/GP[60]
HD3/VLYNQ_RXD2/GP[61]
HD4/VLYNQ_RXD3/GP[62]
HD5/VLYNQ_TXD0/GP[63]
HD6/VLYNQ_TXD1/GP[64]
HD7/VLYNQ_TXD2/GP[65]
HD8/VLYNQ_TXD3/GP[66]
HD9/MCOL/GP[67]
Host Block Pin Select.
If EMAC opertaion is desired, EMAC must be placed in reset before
programminng PINMUX1 HOSTBK to select EMAC pins.
HOSTBK = 000: GPIO Mode (default).
Pins function as GPIO (GP[83:57]).
HOSTBK = 001: HPI + 1 GPIO Mode.
Pins function as HPI and GPIO (GP[57]).
HOSTBK = 010: VLYNQ + 17 GPIO Mode.
HD10/MCRS/GP[68]
Pins function as VLYNQ (VLYNQ_CLOCK, VLYNQ_SCRUN, VLYNQ_RXD[3:0], HD11/MTXD3/GP[69]
6:4
HOSTBK
VLYNQ_TXD[3:0]), and GP[83:67].
HD12/MTXD2/GP[70]
HD13/MTXD1/GP[71]
HD14/MTXD0/GP[72]
HD15/MTXCLK/GP[73]
HHWIL/MRXDV/GP[74]
HCNTL1/MTXEN/GP[75]
HCNTL0/MRXER/GP[76]
HR/W/MRXCLK/GP[77]
HDS2/MRXD0/GP[78]
HDS1/MRXD1/GP[79]
HRDY/MRXD2/GP[80]
HCS/MDCLK/GP[81]
HINT/MRXD3/GP[82]
HAS/MDIO/GP[83]
HOSTBK = 011: VLYNQ + MII + MDIO Mode.
Pins function as VLYNQ (VLYNQ_CLOCK, VLYNQ_SCRUN, VLYNQ_RXD[3:0],
VLYNQ_TXD[3:0]), MII (TXCLK, CRS, COL, TXD[3:0], RXVD, TXEN, RXER,
RXCLK, RXD[3:0]), and MDIO (MDIO, MDC).
HOSTBK = 100: MII + MDIO +10 GPIO Mode.
Pins function as MII (TXCLK, CRS, COL, TXD[3:0], RXVD, TXEN, RXER,
RXCLK, RXD[3:0]), MDIO (MDIO, MDC), and GP[66:57].
All other HOSTBK combinations reserved.
Reserved. For proper device operation, the user should only write "0" to this bit
(default).
3:1
0
RESERVED
RSV
–
–
Reserved. Writes have no effect.
96
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3.7.3 Pin Multiplexing Details
This section discusses how to program each Pin Mux Block to select the desired peripheral functions.
The following steps can be used to determine pin muxing suitable for the application:
1. Understand the major configuration choices available for the specific application.
a. Device Major Configuration Choices: Figure 3-11 shown in Section 3.7, Multiplexed Pin
Configurations, provides a high-level view of the device pin muxing and can be used to determine
the possible mix of peripheral options for a specific application.
b. EMIFA/VPSS Block Major Configuration Choices: The EMIFA/VPSS block features extensive pin
multiplexing to accommodate a variety of applications. In addition to Figure 3-11, Section 3.7.3.11,
EMIFA/VPSS Block Muxing, provides more details on the Major Configuration choices for this
block.
2. See Section 3.7.3.1, Multiplexed Pins on DM6435, for a summary of all the multiplexed pins on this
device and the pin mux group they belong to.
3. Refer to the individual pin mux sections (Section 3.7.3.3, Host Block Muxing to Section 3.7.3.11,
EMIFA/VPSS Block Muxing) for pin muxing details for a specific pin mux block.
a. For peripherals that span multiple pin mux blocks, the user must select the appropriate pins for that
peripheral in all relevant pin mux blocks. For more details, see Section 3.7.3.2, Peripherals
Spanning Multiple Pin Mux Blocks .
For details on PINMUX0 and PINMUX1 registers, see Section 3.7.2.
3.7.3.1 Multiplexed Pins on DM6435
Table 3-21 summarizes all of the multiplexed pins on DM6435, the pin mux group for each pin, and the
PINMUX register fields that control the pin. For pin mux details, see the specific pin mux group section
(Section 3.7.3.3, Host Block Muxing to Section 3.7.3.11, EMIFA/VPSS Block Muxing). For a description of
the PINMUX register fields, see Section 3.7.2.
Table 3-21. Multiplexed Pins on DM6435
SIGNAL
PINMUX DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
PINMUX GROUP
CONTROLLED BY PINMUX BIT FIELDS
PCLK/GP[54]
VD/GP[53]
HD/GP[52]
A14
A13
A15
B10
A10
B11
C11
A11
D11
B12
C12
A12
B13
C13
D14
B14
C14
B15
C15
A18
A17
A19
A12
A13
C13
B13
B14
A14
C14
C15
A15
B15
B16
C18
A16
B17
B18
B19
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
CCDCSEL
HVDSEL
HVDSEL
CI7(CCD15)/EM_A[13]/GP[51]
CI6(CCD14)/EM_A[14]/GP[50]
CI5(CCD13)/EM_A[15]/GP[49]
CI4(CCD12)/EM_A[16]/GP[48]
CI3(CCD11)/EM_A[17]/GP[47]
CI2(CCD10)/EM_A[18]/GP[46]
CI1(CCD9)/EM_A[19]/GP[45]
CI0(CCD8)/EM_A[20]/GP[44]
YI7(CCD7)/GP[43]
AEM, AEAW, CI76SEL
AEM, AEAW, CI76SEL
AEM, AEAW, CI54SEL
AEM, AEAW, CI54SEL
AEM, AEAW, CI32SEL
AEM, AEAW, CI32SEL
AEM, AEAW, CI10SEL
AEM, AEAW, CI10SEL
CCDCSEL
YI6(CCD6)/GP[42]
CCDCSEL
YI5(CCD5)/GP[41]
CCDCSEL
YI4(CCD4)/GP[40]
CCDCSEL
YI3(CCD3)/GP[39]
CCDCSEL
YI2(CCD2)/GP[38]
CCDCSEL
YI1(CCD1)/GP[37]
CCDCSEL
YI0(CCD0)/GP[36]
CCDCSEL
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Table 3-21. Multiplexed Pins on DM6435 (continued)
SIGNAL
PINMUX DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
PINMUX GROUP
CONTROLLED BY PINMUX BIT FIELDS
C_WE/EM_R/W/GP[35]
D13
D12
F19
E19
D19
G19
H15
H16
H17
G17
G16
G15
F15
F18
F17
F16
E17
E18
E16
D17
D18
D16
C18
C19
B18
A17
C17
C16
J22
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 0
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
AEM, CWENSEL
AEM, CFLDSEL
CS5SEL
C_FIELD/EM_A[21]/GP[34]
EM_CS5/GP[33]
EM_CS4/GP[32]
GP[31]
H22
G22
K22
K21
J21
CS4SEL
(1)
–
(1)
GP[30]
–
(1)
GP[29]
–
(1)
GP[28]
–
(1)
GP[27]
L19
K19
H21
L20
K20
J20
–
(1)
GP[26]/(FASTBOOT)
GP[25]/(BOOTMODE3)
GP[24]/(BOOTMODE2)
GP[23]/(BOOTMODE1)
GP[22]/(BOOTMODE0)
EM_D[7]/GP[21]
EM_D[6]/GP[20]
EM_D[5]/GP[19]
EM_D[4]/GP[18]
EM_D[3]/GP[17]
EM_D[2]/GP[16]
EM_D[1]/GP[15]
EM_D[0]/GP[14]
EM_CS3/GP[13]
EM_CS2/GP[12]
EM_A[3]/GP[11]
EM_A[4]/GP[10]/(AEAW2/PLLMS2)
–
(1)
–
(1)
–
(1)
–
(1)
–
H20
F21
F22
G21
F20
E22
G20
E21
D22
C22
D21
B21
AEM
AEM
AEM
AEM
AEM
AEM
AEM
AEM
CS3SEL
AEM
AEM
AEM
EM_A[1]/(ALE)/GP[9]/
(AEAW1/PLLMS1)
A16
B16
B20
A20
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
AEM
AEM
EM_A[2]/(CLE)/GP[8]/
(AEAW0/PLLMS0)
EM_A[0]/GP[7]/(AEM2)
EM_BA[0]/GP[6]/(AEM1)
EM_BA[1]/GP[5]/(AEM0)
EM_A[12]/GP[89]
B17
C17
C16
D10
C10
A9
C21
E20
C20
B12
C12
B11
C11
A11
C10
B10
A10
A8
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 1
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
EMIFA/VPSS Sub-Block 3
Host Block
AEM
AEM
AEM
AEM
EM_A[11]/GP[90]
AEM
EM_A[10]/GP[91]
AEM
EM_A[9]/GP[92]
D9
AEM
EM_A[8]/GP[93]
B9
AEM
EM_A[7]/GP[94]
C9
AEM
EM_A[6]/GP[95]
D8
AEM
EM_A[5]/GP[96]
B8
AEM
VLYNQ_CLOCK/GP[57]
HD0/VLYNQ_SCRUN/GP[58]
HD1/VLYNQ_RXD0/GP[59]
A7
HOSTBK
HOSTBK
HOSTBK
C8
B9
Host Block
D7
C9
Host Block
(1) GP[31:22] are standalone pins. They are not muxed with any other functions, but they are included in this table because they are
grouped in the EMIFA/VPSS Sub-Block 1.
98
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Table 3-21. Multiplexed Pins on DM6435 (continued)
SIGNAL
PINMUX DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
PINMUX GROUP
CONTROLLED BY PINMUX BIT FIELDS
HD2/VLYNQ_RXD1/GP[60]
HD3/VLYNQ_RXD2/GP[61]
HD4/VLYNQ_RXD3/GP[62]
HD5/VLYNQ_TXD0/GP[63]
HD6/VLYNQ_TXD1/GP[64]
HD7/VLYNQ_TXD2/GP[65]
HD8/VLYNQ_TXD3/GP[66]
HD9/MCOL/GP[67]
A8
B7
C7
A6
D6
B6
A5
C6
B5
C5
D5
B4
D4
A4
C4
D3
B3
A3
C3
B2
D2
C1
C2
D1
F3
H1
H4
J2
A9
B8
C8
A7
C7
B7
A6
C6
B6
A5
C5
B4
B5
A4
D3
C4
B2
A3
C2
B3
C3
D1
D2
C1
F3
J1
Host Block
Host Block
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
HOSTBK
PWM1BK
SPBK0
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
HD10/MCRS/GP[68]
HD11/MTXD3/GP[69]
HD12/MTXD2/GP[70]
HD13/MTXD1/GP[71]
HD14/MTXD0/GP[72]
HD15/MTXCLK/GP[73]
HHWIL/MRXDV/GP[74]
HCNTL1/MTXEN/GP[75]
HCNTL0/MRXER/GP[76]
HR/W/MRXCLK/GP[77]
HDS2/MRXD0/GP[78]
HDS1/MRXD1/GP[79]
HRDY/MRXD2/GP[80]
HCS/MDCLK/GP[81]
HINT/MRXD3/GP[82]
HAS/MDIO/GP[83]
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
Host Block
GP[4]/PWM1
PWM1Block
ACLKR0/CLKX0/GP[99]
AFSR0/DR0/GP[100]
AHCLKR0/CLKR0/GP[101]
AXR0[3]/FSR0/GP[102]
AXR0[2]/FSX0/GP[103]
AXR0[1]/DX0/GP[104]
AXR0[0]/GP[105]
Serial Port Sub-Block 0
Serial Port Sub-Block 0
Serial Port Sub-Block 0
Serial Port Sub-Block 0
Serial Port Sub-Block 0
Serial Port Sub-Block 0
Serial Port Sub-Block 1
Serial Port Sub-Block 1
Serial Port Sub-Block 1
Serial Port Sub-Block 1
Serial Port Sub-Block 1
Serial Port Sub-Block 1
Timer 1 Block
K3
K1
J3
SPBK0
SPBK0
G4
H3
J3
SPBK0
J2
SPBK0
K2
H2
G1
G2
H1
G3
H3
P3
N3
L2
SPBK0
H2
F1
G2
G1
F2
G3
L4
SPBK1
ACLKX0/GP[106]
SPBK1
AFSX0/GP[107]
SPBK1
AHCLKX0/GP[108]
SPBK1
AMUTEIN0/GP[109]
SPBK1
AMUTE0/GP[110]
SPBK1
HECC_RX/TINP1L/URXD1/GP[56]
HECC_TX/TOUT1L/UTXD1/GP[55]
TINP0L/GP[98]
TIM1BK
TIM1BK
TIM0BK
TIM0BK
UR0DBK
UR0DBK
UR0FCBK
UR0FCBK
K4
K2
J4
Timer 1 Block
Timer 0 Block
CLKS0/TOUT0L/GP[97]
URXD0/GP[85]
L3
Timer 0 Block
L2
M2
N1
P1
M3
UART0 Data Block
UART0 Data Block
UART0 Flow Control Block
UART0 Flow Control Block
UTXD0/GP[86]
K3
L1
UCTS0/GP[87]
URTS0/PWM0/GP[88]
L3
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Table 3-21. Multiplexed Pins on DM6435 (continued)
SIGNAL
PINMUX DESCRIPTION
ZWT
NO.
ZDU
NO.
NAME
PINMUX GROUP
CONTROLLED BY PINMUX BIT FIELDS
CLKOUT0/PWM2/GP[84]
M1
R1
CLKOUT Block
CKOBK
Note: PINMUX group EMIFA/VPSS Sub-Block 2 is not shown in the above table because there is no
actual pin multiplexing in that block. But this block is still considered a "pin mux block" because it contains
some of the pins necessary for EMIFA. The pins in this block are as follows:
•
EMIFA/VPSS Sub-Block 2
–
–
–
EM_WAIT/(RDY/BSY)
EM_OE
EM_WE
3.7.3.2 Peripherals Spanning Multiple Pin Mux Blocks
Some peripherals span multiple Pin Mux Blocks. To use these peripherals, they must be selected in all of
the relevant Pin Mux Blocks. The following is the list of peripherals that span multiple Pin Mux Blocks:
•
McBSP0: Six McBSP0 pins are located in the Serial Port Sub-Block 0, but the CLKS0 pin is muxed in
the Timer0 Block. To select McBSP0 pins, program PINMUX registers as follows:
–
–
Serial Port Sub-Block 0: SPBK0 = 01
Timer0 Block: If CLKS0 pin is desired, program TIM0BK = 10 or 11.
•
UART0: The two UART0 data pins are located in the UART0 Data Block, but the two UART0 flow
control pins are located in the UART0 Flow Control Block. To select UART0, program PINMUX
registers as follows:
–
–
UART0 Data Block: UR0BK = 1
UART0 Flow Control Block: If flow control pins are desired, program UR0FCBK = 01.
100
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3.7.3.3 Host Block Muxing
This block of 27 pins consists of HPI, VLYNQ, EMAC, MDIO, and GPIO muxed pins. The following
register field selects the pin functions in the Host Block:
•
PINMUX1.HOSTBK
Table 3-22 summarizes the 27 pins in the Host Block, the multiplexed function on each pin, and the
PINMUX configurations to select the corresponding function.
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Table 3-22. Host Block Muxed Pins Selection
MULTIPLEXED FUNCTIONS
SIGNAL NAME
HPI
EMAC/MDIO
VLYNQ
GPIO
FUNCTION
SELECT
FUNCTION
SELECT
FUNCTION
SELECT
FUNCTION
SELECT
HOSTBK = 000
or
VLYNQ_CLOCK/GP[57]
–
–
–
–
VLYNQ_CLOCK
GP[57]
HOSTBK = 001
or
HOSTBK = 100
HD0/VLYNQ_SCRUN/GP[58]
HD1/VLYNQ_RXD0/GP[59]
HD2/VLYNQ_RXD1/GP[60]
HD3/VLYNQ_RXD2/GP[61]
HD4/VLYNQ_RXD3/GP[62]
HD5/VLYNQ_TXD0/GP[63]
HD6/VLYNQ_TXD1/GP[64]
HD7/VLYNQ_TXD2/GP[65]
HD8/VLYNQ_TXD3/GP[66]
HD9/MCOL/GP[67]
HD0
HD1
–
–
–
–
–
–
–
–
–
–
–
VLYNQ_SCRUN
GP[58]
GP[59]
GP[60]
GP[61]
GP[62]
GP[63]
GP[64]
GP[65]
GP[66]
GP[67]
GP[68]
GP[69]
GP[70]
GP[71]
GP[72]
GP[73]
GP[74]
GP[75]
GP[76]
GP[77]
GP[78]
GP[79]
GP[80]
GP[81]
GP[82]
GP[83]
VLYNQ_RXD0
HOSTBK = 010
or
HOSTBK = 011
HD2
–
VLYNQ_RXD1
HD3
–
VLYNQ_RXD2
HOSTBK = 000
or
HOSTBK = 100
HD4
–
VLYNQ_RXD3
HD5
–
VLYNQ_TXD0
HD6
–
VLYNQ_TXD1
HD7
–
VLYNQ_TXD2
HD8
–
VLYNQ_TXD3
HD9
MCOL
MCRS
MTXD3
MTXD2
MTXD1
MTXD0
MTXCLK
MRXDV
MTXEN
MRXER
MRXCLK
MRXD0
MRXD1
MRXD2
MDCLK
MRXD3
MDIO
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
–
HD10/MCRS/GP[68]
HD10
HD11
HD12
HD13
HD14
HD15
HHWIL
HCNTL1
HCNTL0
HR/W
HDS2
HDS1
HRDY
HCS
HD11/MTXD3/GP[69]
HD12/MTXD2/GP[70]
HOSTBK = 001
HD13/MTXD1/GP[71]
HD14/MTXD0/GP[72]
HD15/MTXCLK/GP[73]
HHWIL/MRXDV/GP[74]
HCNTL1/MTXEN/GP[75]
HCNTL0/MRXER/GP[76]
HR/W/MRXCLK/GP[77]
HDS2/MRXD0/GP[78]
HDS1/MRXD1/GP[79]
HRDY/MRXD2/GP[80]
HCS/MDCLK/GP[81]
HOSTBK = 011
or
HOSTBK = 100
HOSTBK = 000
or
HOSTBK = 010
HINT/MRXD3/GP[82]
HINT
HAS
HAS/MDIO/GP[83]
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Table 3-23 provides a different view of the Host Block pin muxing, showing the Host Block function based
on PINMUX1 settings. The selection options are also shown pictorially in Figure 3-11.
If EMAC operation is desired, EMAC must be placed in reset before programming PINMUX1.HOSTBK to
select EMAC pins.
Table 3-23. Host Block Function Selection
PINMUX1
SETTING
BLOCK FUNCTION
RESULTING PIN FUNCTIONS
HOSTBK
GPIO (27)
(default)
000
001
GPIO: GP[83:57]
HPI: HHWIL, HCNTL[1:0], HR/W, HDS2, HDS1, HRDY, HCS, HINT, HAS, HD[15:0]
HPI + GPIO (1)
GPIO: GP[57]
VLYNQ: VLYNQ_CLOCK, VLYNQ_SCRUN, VLYNQ_RXD[3:0], VLYNQ_TXD[3:0]
010
VLYNQ + GPIO (17)
GPIO: GP[83:67]
VLYNQ: VLYNQ_CLOCK, VLYNQ_SCRUN, VLYNQ_RXD[3:0], VLYNQ_TXD[3:0]
EMAC (MII): TXCLK, CRS, COL, TXD[3:0], RXDV, TXEN, RXER, RXCLK,
RXD[3:0]
011
VLYNQ + EMAC (MII) + MDIO
MDIO: MDC, MDIO
If EMAC operation is desired, EMAC must be placed in reset before
programming PINMUX1.HOSTBK to select EMAC pins.
EMAC (MII): TXCLK, CRS, COL, TXD[3:0], RXDV, TXEN, RXER, RXCLK,
RXD[3:0]
MDIO: MDC, MDIO
GPIO: GP[66:57]
100
EMAC (MII) + MDIO + GPIO (10)
If EMAC operation is desired, EMAC must be placed in reset before
programming PINMUX1.HOSTBK to select EMAC pins.
101 to 111
Reserved
Reserved
The VDD3P3V_PWDN.HOST field determines the power state of the Host Block pins. The Host Block
pins default to powered up. For more details on the VDD3P3V_PWDN.HOST field, see Section 3.2, Power
Considerations.
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3.7.3.4 UART0 Data Block Muxing
This block of 2 pins consists of UART0 Data and GPIO muxed pins. The PINMUX1.UR0DBK register field
select the pin functions in the UART0 Data Block.
Table 3-24 summarizes the 2 pins in the UART0 Data Block, the multiplexed function on each pin, and the
PINMUX configurations to select the corresponding function.
Table 3-24. UART0 Data Block Muxed Pins Selection
MULTIPLEXED FUNCTIONS
SIGNAL
UART0
GPIO
NAME
FUNCTION
URXD0
SELECT
FUNCTION
GP[85]
SELECT
URXD0/GP[85]
UTXD0/GP[86]
UR0DBK = 1
UR0DBK = 0
UTXD0
GP[86]
As discussed in Section 3.7.3.2, Peripherals Spanning Multiple Pin Mux Blocks, the UART0 pins span
across two Pin Mux Blocks: UART0 Data Block, and UART0 Flow Control Block. For proper UART0
operation, the two pins in the UART0 Data Block must be configured for UART0 data functions. The two
pins in the UART0 Flow Control Block are optional.
Table 3-25 provides a different view of the UART0 Data Block pin muxing, showing the UART0 Data Block
function based on PINMUX1.UR0DBK setting. The selection options are also shown pictorially in
Figure 3-11.
Table 3-25. UART0 Data Block Function Selection
PINMUX1.UR0DBK
BLOCK FUNCTION
GPIO (2) (default)
UART0 Data
RESULTING PIN FUNCTIONS
GPIO: GP[86:85]
0
1
UART0: URXD0, UTXD0
In addition, the VDD3P3V_PWDN.UR0DAT field determines the power state of the UART0 Data Block
pins. The UART0 Data Block pins default to powered down and not operational. To use these pins, user
must first program VDD3P3V_PWDN.UR0DAT = 0 to power up the pins. For more details on the
VDD3P3V_PWDN.UR0DAT field, see Section 3.2, Power Considerations.
The UART0 Data Block features internal pullup resistors, which matches the UART inactive polarity.
3.7.3.5 UART0 Flow Control Block
This block of 2 pins consists of UART0 Flow Control, PWM0, and GPIO muxed pins. The
PINMUX1.UR0FCBK register field selects the pin functions in the UART0 Flow Control Block.
Table 3-26 summarizes the 2 pins in the UART0 Flow Control Block, the multiplexed function on each pin,
and the PINMUX configurations to select the corresponding function.
Table 3-26. UART0 Flow Control Block Muxed Pins Selection
MULTIPLEXED FUNCTIONS
SIGNAL
UART0
PWM0
GPIO
NAME
FUNCTION
SELECT
FUNCTION
SELECT
FUNCTION
SELECT
UCTS0/
GP[87]
UCTS0
–
–
GP[87]
UR0FCBK = 00/10
UR0FCBK = 01
URTS0/
PWM0/
GP[88]
URTS0
PWM0
UR0FCBK = 10
GP[88]
UR0FCBK = 00
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As discussed in Section 3.7.3.2, Peripherals Spanning Multiple Pin Mux Blocks, the UART0 pins span
across two Pin Mux Blocks: UART0 Data Block, and UART0 Flow Control Block. For proper UART0
operation, the two pins in the UART0 Data Block must be configured for UART0 data functions. The two
pins in the UART0 Flow Control Block are optional.
Table 3-27 provides a different view of the UART0 Flow Control Block pin muxing, showing the UART0
Flow Control Block function based on PINMUX1.UR0FCBK setting. The selection options are also shown
pictorially in Figure 3-11.
Table 3-27. UART0 Flow Control Block Function Selection
PINMUX1.UR0FCBK
BLOCK FUNCTION
GPIO (2) (default)
UART0 Flow Control
RESULTING PIN FUNCTIONS
GPIO: GP[88:87]
00
01
UART0: UCTS0, URTS0
PWM0: PWM0
GPIO: GP[87]
10
11
PWM0 + GPIO (1)
Reserved
Reserved
In addition, the VDD3P3V_PWDN.UR0FC field determines the power state of the UART0 Flow Control
Block pins. The UART0 Flow Control Block pins default to powered down and not operational. To use
these pins, user must first program VDD3P3V_PWDN.UR0FC = 0 to power up the pins. For more details
on the VDD3P3V_PWDN.UR0FC field, see Section 3.2, Power Considerations.
The UART0 Flow Control Block features internal pullup resistors, which matches the UART inactive
polarity.
3.7.3.6 Timer0 Block
This block of 2 pins consists of Timer0, McBSP0, and GPIO muxed pins. The PINMUX1.TIM0BK register
field selects the pin functions in the Timer0 Block.
Table 3-28 summarizes the 2 pins in the Timer0 Block, the multiplexed function on each pin, and the
PINMUX configurations to select the corresponding function.
Table 3-28. Timer0 Block Muxed Pins Selection
MULTIPLEXED FUNCTIONS
SIGNAL
NAME
McBSP
Timer0
GPIO
FUNCTION
SELECT
FUNCTION
SELECT
FUNCTION
SELECT
TINP0L/
GP[98]
–
–
TINP0L
TIM0BK = 01/11
GP[98]
TIM0BK = 00
CLKS0/
TOUT0L/
GP[97]
CLKS0
TIM0BK = 11
TOUT0L
TIM0BK = 01
GP[97]
As discussed in Section 3.7.3.2, Peripherals Spanning Multiple Pin Mux Blocks, the McBSP0 pins span
across two Pin Mux Blocks: Serial Port Sub-Block0, and Timer0 Block. For proper McBSP0 operation, the
Serial Port Sub-Block0 must be programmed to select McBSP0 function. The McBSP0 CLKS0 pin in the
Timer0 Block is optional for McBSP0 operation. CLKS0 is only needed if you desire using CLKS0 as an
external clock source to the McBSP0 internal sample rate generator.
Table 3-29 provides a different view of the Timer0 Block pin muxing, showing the Timer0 Block function
based on PINMUX1.TIM0BK setting. The selection options are also shown pictorially in Figure 3-11.
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Table 3-29. Timer0 Block Function Selection
PINMUX1.TIM0BK
BLOCK FUNCTION
GPIO (2) (default)
Timer0
RESULTING PIN FUNCTIONS
00
01
10
GPIO: GP[98:97]
Timer0: TINP0L, TOUT0L
Reserved
–
McBSP0 External Clock Source,
Timer0 Input
McBSP0: CLKS0
Timer0: TINP0L
11
In addition, the VDD3P3V_PWDN.TIMER0 field determines the power state of the Timer0 Block pins. The
Timer0 Block pins default to powered down and not operational. To use these pins, user must first
program VDD3P3V_PWDN.TIMER0
VDD3P3V_PWDN.TIMER0 field, see Section 3.2, Power Considerations.
3.7.3.7 Timer1 Block
=
0 to power up the pins. For more details on the
This block of 2 pins consists of Timer1, HECC, UART1 Data, and GPIO muxed pins. The
PINMUX1.TIM1BK register field selects the pin functions in the Timer1 Block.
Table 3-30 summarizes the 2 pins in the Timer1 Block, the multiplexed function on each pin, and the
PINMUX configurations to select the corresponding function.
Table 3-30. Timer1 Block Muxed Pins Selection
MULTIPLEXED FUNCTIONS
SIGNAL
NAME
HECC
TIMER1
FUNCTION
UART1
FUNCTION
GPIO
FUNCTION
SELECT
SELECT
SELECT
FUNCTION
SELECT
HECC_RX/
TINP1L/
URXD1/
GP[56]
HECC_RX
TINP1L
URXD1
UTXD1
GP[56]
TIM1BK = 11
TIM1BK = 01
TIM1BK = 10
TIM1BK = 00
HECC_TX/
TOUT1L/
UTXD1/
HECC_TX
TOUT1L
GP[55]
GP[55]
Unlike UART0, UART1 only supports data pins but not flow control pins.
Table 3-31 provides a different view of the Timer1 Block pin muxing, showing the Timer1 Block function
based on PINMUX1.TIM1BK setting. The selection options are also shown pictorially in Figure 3-11.
Table 3-31. Timer1 Block Function Selection
PINMUX1.TIM1BK
BLOCK FUNCTION
GPIO (2) (default)
Timer1
RESULTING PIN FUNCTIONS
GPIO: GP[56:55]
00
01
10
11
Timer1: TINP1L, TOUT1L
UART1: URXD1, UTXD1
HECC: HECC_RX, HECC_TX
UART1 Data
HECC
In addition, the VDD3P3V_PWDN.TIMER1 field determines the power state of the Timer1 Block pins. The
Timer1 Block pins default to powered down and not operational. To use these pins, user must first
program VDD3P3V_PWDN.TIMER1
=
0 to power up the pins. For more details on the
VDD3P3V_PWDN.TIMER1 field, see Section 3.2, Power Considerations.
The Timer1 Block features internal pull up resistors, which matches the UART and HECC inactive polarity.
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3.7.3.8 Serial Port Block
This block of 12 pins consists of McASP0, McBSP0, and GPIO muxed pins. The following register fields
select the pin functions in the Serial Port Block:
•
•
PINMUX1.SPBK0
PINMUX1.SPBK1
The Serial Port Block is further subdivided into these sub-blocks:
•
•
Serial Port Sub-Block 0: McBSP0, part of McASP0, and GPIO.
Serial Port Sub-Block 1: part of McASP0 and GPIO.
Table 3-32 summarizes the 12 pins in the Serial Port Block, the multiplexed function on each pin, and the
PINMUX configurations to select the corresponding function.
Table 3-32. Serial Port Block Muxed Pins Selection
MULTIPLEXED FUNCTIONS
SIGNAL NAME
McASP0
FUNCTION
McBSP0
FUNCTION
GPIO
SELECT
SELECT
FUNCTION
SELECT
Serial Port Sub-block 0
ACLKR0/CLKX0/GP[99]
AFSR0/DR0/GP[100]
ACLKR0
AFSR0
CLKX0
DR0
GP[99]
GP[100]
GP[101]
GP[102]
GP[103]
GP[104]
AHCLKR0/CLKR0/GP[101]
AXR0[3]/FSR0/GP[102]
AXR0[2]/FSX0/GP[103]
AXR0[1]/DX0/GP[104]
AHCLKR0
AXR0[3]
AXR0[2]
AXR0[1]
CLKR0
SPBK0 = 10
SPBK0 = 01
SPBK0 = 00
FSR0
FSX0
DX0
Serial Port Sub-block 1
AXR0[0]/GP[105]
ACLKX0/GP[106]
AFSX0/GP[107]
AXR0[0]
ACLKX0
AFSX0
–
–
–
–
–
–
–
–
–
GP[105]
GP[106]
GP[107]
GP[108]
GP[109]
GP[110]
SPBK1 = 10
SPBK1 = 00
AHCLKX0/GP[108]
AMUTEIN0/GP[109]
AMUTE0/GP[110]
AHCLKX0
AMUTEIN0
AMUTE0
–
–
–
As discussed in Section 3.7.3.2, Peripherals Spanning Multiple Pin Mux Blocks, the McBSP0 pins span
across two Pin Mux Blocks: Serial Port Sub-Block0, and Timer0 Block. For proper McBSP0 operation, the
Serial Port Sub-Block0 must be programmed to select McBSP0 function. The McBSP0 CLKS0 pin in the
Timer0 Block is optional for McBSP0 operation. CLKS0 is only needed if you desire using CLKS0 as an
external clock source to the McBSP0 internal sample rate generator.
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Table 3-33 and Table 3-34 provide a different view of the Serial Port Block. Table 3-33 shows the Serial
Port Sub-Block 0 function based on PINMUX1.SPBK0 setting. Table 3-34 shows the Serial Port Sub-Block
1 function based on PINMUX1.SPBK1 setting. These selection options are also shown pictorially in
Figure 3-11.
Table 3-33. Serial Port Sub-Block 0 Function Selection
PINMUX1.SPBK0
BLOCK FUNCTION
GPIO (6) (default)
McBSP0
RESULTING PIN FUNCTIONS
GPIO: GP[104:99]
00
01
McBSP0: CLKX0, FSX0, DX0, CLKR0, FSR0, DR0
McASP0: ACLKR0, AFSR0, AHCLKR0, AXR0[3],
10
11
McASP0 Receive, 3 Serializers
Reserved
AXR0[2], AXR0[1]
Reserved
Table 3-34. Serial Port Sub-Block 1 Function Selection
PINMUX1.SPBK1
BLOCK FUNCTION
GPIO (6) (default)
Reserved
RESULTING PIN FUNCTIONS
00
01
GPIO: GP[110:105]
–
McASP0 Transmit with 1 Serializer and
Mute Control
McASP0: AXR0[0], ACLKX0, AFSX0, AHCLKX0,
10
11
AMUTEIN0(1), AMUTE0
Reserved
–
(1) The input from the AMUTEIN0/GP[109] pin is connected to both the McASP0 and GPIO.
In addition, the VDD3P3V_PWDN.SP field determines the power state of the Serial Port Block pins. The
Serial Port Block pins default to powered down and not operational. To use these pins, user must first
program VDD3P3V_PWDN.SP = 0 to power up the pins. For more details on the VDD3P3V_PWDN.SP
field, see Section 3.2, Power Considerations.
To facilitate McASP0 operation, the input from the AMUTEIN0/GP[109] pin is connected to both the
McASP0 and the GPIO module. Therefore when an external mute event occurs, in addition to notifying the
McASP0, it can also cause an interrupt through the GPIO module.
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3.7.3.9 PWM1 Block
This block of 1 pin consists of PWM1 and GPIO muxed pins (GP[4]/PWM1). The PINMUX1.PWM1BK
register field selects the pin function in the PWM1 Block.
Table 3-35 summarizes the 1 pin in the PWM1 Block, its multiplexed function, and the PINMUX
configurations to select the corresponding function.
Table 3-35. PWM1 Block Muxed Pin Selection
MULTIPLEXED FUNCTIONS
SIGNAL
PWM1
GPIO
NAME
FUNCTION
SELECT
FUNCTION
SELECT
GP[4]/PWM1
PWM1
PWM1BK = 1
GP[4]
PWM1BK = 0
Table 3-36 provides a different view of the PWM1 Block pin muxing, showing the PWM1 Block function
based on PINMUX1.PWM1BK setting. The selection options are also shown pictorially in Figure 3-11.
Table 3-36. PWM1 Block Function Selection
PINMUX1.PWM1BK
BLOCK FUNCTION
GPIO (1) (default)
PWM1
RESULTING PIN FUNCTIONS
GPIO: GP[4]
PWM1: PWM1
0
1
In addition, the VDD3P3V_PWDN.PWM1 field determines the power state of the PWM1 Block pin. The
PWM1 Block pin defaults to powered down and not operational. To use this pin, user must first program
VDD3P3V_PWDN.PWM1 = 0 to power up the pin. For more details on the VDD3P3V_PWDN.PWM1 field,
see Section 3.2, Power Considerations.
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3.7.3.10 CLKOUT Block
This block of 1 pin consists of CLKOUT, PWM2, and GPIO muxed pin (CLKOUT0/PWM2/GP[84]). The
PINMUX1.CKOBK register field selects the pin function in the CLKOUT Block.
Table 3-37 summarizes the 1 pin in the CLKOUT Block, its multiplexed function, and the PINMUX
configurations to select the corresponding function.
Table 3-37. CLKOUT Block Multiplexed Pin Selection
MULTIPLEXED FUNCTIONS
SIGNAL
CLKOUT0
SELECT
PWM2
GPIO
NAME
FUNCTION
FUNCTION
SELECT
CKOBK = 10
FUNCTION
SELECT
CLKOUT0/
PWM2/
CLKOUT0
CKOBK = 01
PWM2
GP[84]
CKOBK = 00
GP[84]
Table 3-38 provides a different view of the CLKOUT Block pin muxing, showing the CLKOUT Block
function based on PINMUX1.CKOBK setting. The selection options are also shown pictorially in
Figure 3-11.
Table 3-38. CLKOUT Block Function Selection
PINMUX1.CKOBK
BLOCK FUNCTION
GPIO (1)
RESULTING PIN FUNCTIONS
GPIO: GP[84]
00
01
10
11
CLKOUT (default)
PWM2
Device Clock-Out: CLKOUT0
PWM2: PWM2
Reserved
Reserved
This block defaults to CLKOUT0 pin function.
In addition, the VDD3P3V_PWDN.CLKOUT field determines the power state of the CLKOUT Block pin.
The CLKOUT Block pin defaults to powered up. For more details on the VDD3P3V_PWDN.CLKOUT field,
see Section 3.2, Power Considerations.
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3.7.3.11 EMIFA/VPSS Block Muxing
This block of 61 pins consists of VPSS, EMIFA, and GPIO muxed pins. The following register fields affect
the pin functions in the EMIFA/VPSS Block:
•
All PINMUX0 register fields: AEM, CS5SEL, CS4SEL, CS3SEL, AEAW, CCDCSEL, HVDSEL,
CWENSEL, CFLDSEL, CI76SEL, CI54SEL, CI32SEL, and CI10SEL
The EMIFA/VPSS Block is divided into multiple sub-blocks for ultimate flexibility in pin multiplexing to
accommodate a wide variety of applications:
•
•
•
•
Sub-Block 0: multiplexed between VPFE, EMIFA address/control pins, and GPIO.
Sub-Block 1: multiplexed between EMIFA data/address/control pins, and GPIO.
Sub-Block 2: no multiplexing. EMIFA control pins EM_WAIT/(RDY/BSY), EM_OE, EM_WE.
Sub-Block 3: multiplexed between EMIFA address pins EM_A[12:6] and GPIO.
The EMBK0, EMBK1, EMBK2, EMBK3 fields in the VDD3P3V_PWDN register determine the power state
of the EMIFA/VPSS Block pins. The EMIFA/VPSS Block pins default to powered up. For more details on
the EMBK0, EMBK1, EMBK2, EMBK3 fields in the VDD3P3V_PWDN register, see Section 3.2, Power
Considerations.
To understand pin multiplexing in the EMIFA/VPSS Block, the user should start with Section 3.7.3.11.1,
EMIFA/VPSS Block Pin Selection Procedure, which outlines the procedures to select pin functions of this
block. Section 3.7.3.11.7, EMIFA/VPSS Block Pin-By-Pin Multiplexing Summary, provides a pin-by-pin
multiplexing summary for the EMIFA/VPSS Block. For more information on the PINMUX0 and PINMUX1
registers, see Section 3.7.2, Pin Muxing Selection After Device Reset.
3.7.3.11.1 EMIFA/VPSS Block Pin Selection Procedure
Follow the steps below to perform pin selection for the EMIFA/VPSS Block and its sub-blocks.
1. Major Configuration Options: start with Table 3-39, EMIFA/VPSS Block Major Configuration Choices.
Based on the peripheral needs, the user should select from the major configuration options in this
block: Major Config Options A, B, and E.
2. Sub-Block 2 and Sub-Block 3 Selection: After selecting the major configuration option from
Table 3-39, EMIFA/VPSS Block Major Configuration Choices, the pin selection for Sub-Block 2 and
Sub-Block 3 is complete.
3. Sub-Block 0 Selection: Use Table 3-40 through Table 3-42, EMIFA/VPSS Sub-Block 0 Configuration
Choices, to refine Sub-Block 0 pin selections.
a. Go to the table with the Major Configuration Option chosen in Step 1.
b. Each Major Configuration Option is further divided down into multiple Minor Configuration Options.
Select a Minor Configuration Option that best suits the application need.
c. Within the chosen Minor Configuration Option, further refine the detailed pin configurations by
selecting the settings of PINMUX0 fields CCDCSEL, HVDSEL, CWENSEL, CFLDSEL, CI10SEL,
CI32SEL, CI54SEL, and CI76SEL.
d. The Selection Fields columns show the settings needed to program the PINMUX0 register.
4. Sub-Block 1 Selection: Use Table 3-43 through Table 3-45, EMIFA/VPSS Sub-Block 1 Configuration
Choices, to refine Sub-Block 1 pin selection.
a. Go to the table with the Major Configuration Option chosen in Step 1.
b. Each Major Configuration Option is further divided down into multiple Minor Configuration Options.
Select a Minor Configuration Option that best suits the application need.
c. Within the chosen Minor Configuration Option, further refine the detailed pin configurations by
selecting the settings of PINMUX0 fields CS3SEL, CS4SEL, and CS5SEL.
d. The Selection Fields columns show the settings needed to program the PINMUX0 register.
After following the procedure in this section to determine pin functions for the EMIFA/VPSS Block, the
user should refer to Section 3.7.3.11.7, EMIFA/VPSS Block Pin-By-Pin Multiplexing Summary, for
pin-multiplexing information on a pin-by-pin basis.
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3.7.3.11.2 EMIFA/VPSS Block Major Configuration Choices
Table 3-39 shows the major configuration choices in the EMIFA/VPSS Block. For instructions on how to
use the EMIFA/VPSS Block Major Configuration Choices table for the EMIFA/VPSS Block and
Sub-Blocks, see Section 3.7.3.11.1.
Table 3-39. EMIFA/VPSS Block Major Configuration Choices
PINMUX SELECTION
RESULTING PERIPHERALS/PINS
FIELDS(1)
MAJOR
CONFIG.
OPTION
# GP PINS
VPFE AND # GP PINS
(FROM GP[54:34])
AEM
CCDCSEL
EMIFA
(FROM GP[33:5])
# GP Pins
CCDCSEL
VPFE & # GP Pins
No CCDC
21 GP pins
0
A
B
E
000
001(2)
101
0, 1
0, 1
0, 1
-
29 GP pins
8-to-16-bit CCDC
0-to-12 GP pins
1
0
No CCDC
11-to-19 GP pins
8-bit EMIFA (ASYNC)
Pinout Mode 1 with address pins
to support 32KB to 16MB per
CS.
9-to-13 GP pins
14-to-18 GP pins
8-to-16-bit CCDC(2)
0-to-10 GP pins
1(2)
0
No CCDC
21 GP pins
8-bit EMIFA (NAND)
Pinout Mode 5
8-to-16-bit CCDC
0-to-12 GP pins
1
(1) For additional pin mux details for each Sub-Block, see Table 3-40 through Table 3-42, EMIFA/VPSS Sub-Block 0 Configuration Choices,
and Table 3-43 through Table 3-45, EMIFA/VPSS Sub-Block 1 Configuration Choices.
(2) If PINMUX0.AEM = 001, it is not possible to get the C_WE pin for VPFE.
As shown in Table 3-39, the major configuration choices of the EMIFA/VPSS Block are determined by the
following PINMUX register fields:
•
PINMUX0 register fields AEM and CCDCSEL
Based on the peripheral needs, select from the major configuration options in this block: Major
Configuration Options A, B, and E.
The following is an example on how to read Table 3-39. For example, the "PINMUX Selection Fields"
columns indicate that Major Configuration Choice B is selected through setting PINMUX0.AEM = 1 and
CCDCSEL = 0 or 1 (based on the system's VPFE requirement). The "Resulting Peripherals/Pins" columns
indicate that Major Configuration Option B can support the following combination of pin functions:
•
Pins for 8-bit EMIFA (Async or NAND) function. The number of address pins supported provide
32KByte to 16MByte address reach per EMIFA Chip Select (CS) space.
•
Pins for up to 16-bit VPFE. If 8-to-16-bit VPFE (CCDCSEL = 1) is selected, the user may have 0 to 10
GPIO pins. Exact detail on number of GPIO pins and VPFE control pins is furthered determined by
other PINMUX0 settings discussed in the EMIFA/VPSS Sub-Block 0 Configuration Choices.
•
9-to-13 GPIO pins from GP[33:5]. For details on the number of GPIO pins, see
Section 3.7.3.11.4,EMIFA/VPSS Sub-Block 1 Configuration Choices.
After using Table 3-39 to select the Major Configuration Option for the EMIFA/VPSS Block, proceed to
select the detailed pin choices in the EMIFA/VPSS Sub-Blocks.
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3.7.3.11.3 EMIFA/VPSS Sub-Block 0 Configuration Choices
Table 3-40 through Table 3-42 show the configuration choices in the EMIFA/VPSS Sub-Block 0. For
instructions on how to use the different configuration choices tables for the EMIFA/VPSS Block and
Sub-Blocks, see Section 3.7.3.11.1. Note: italics in these tables indicate mandatory settings for a given
Minor Configuration option.
Before using Table 3-40 through Table 3-42 to configure the details of the EMIFA/VPSS Sub-Block 0, the
user should first select a Major Configuration Option for the EMIFA/VPSS Block (see Section 3.7.3.11.2).
After determining the Major Configuration Option (A, B, or E), the user can now use Table 3-40 through
Table 3-42 to refine Sub-Block 0 pin selections:
1. Go to the table with the Major Configuration Option chosen from Table 3-39.
2. Each Major Configuration Option is further divided down into multiple Minor Configuration Options.
Select a Minor Configuration Option that best suits the application need.
3. Within the chosen Minor Configuration Option, further refine the detailed pin configurations by selecting
the settings of PINMUX0 fields CCDCSEL, HVDSEL, CWENSEL, CFLDSEL, CI10SEL, CI32SEL,
CI54SEL, and CI76SEL.
4. The PINMUX Selection Fields columns show the settings needed to program the PINMUX0 register.
Table 3-40. EMIFA/VPSS Sub-Block 0 Configuration Choice A(1)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
AEAW
OTHERS
EMIFA
VPFE
# GPIO PINS
Cfg Summary
No EMIFA
No CCDC
21 GP pins
0 = GP[54, 43:36]
0 = GP[53:52]
0 = GP[35]
CCDCSEL = 0
HVDSEL = 0
CWENSEL = 0
CFLDSEL = 0
CI10SEL = 0
CI32SEL = 0
CI54SEL = 0
CI76SEL = 0
A1
000
000
0 = GP[34]
-
-
0 = GP[45:44]
0 = GP[47:46]
0 = GP[49:48]
0 = GP[51:50]
0-to-12 GP pins
-
A
Cfg Summary
No EMIFA
8-to-16-bit CCDC
1 = PCLK, YI[7:0]
1 = VD, HD
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0,1
CFLDSEL = 0,1
CI10SEL = 0,1
CI31SEL = 0,1
CI54SEL = 0,1
CI76SEL = 0,1
0 = GP[53:52]
0 = GP[35]
1 = C_WEN
1 = C_FIELD
1 = CI[1:0]
A2
000
000
0 = GP[34]
-
0 = GP[45:44]
0 = GP[47:46]
0 = GP[49:48]
0 = GP[51:50]
1 = CI[3:2]
1 = CI[5:4]
1 = CI[7:6]
(1) Italics indicate mandatory settings for a given Minor Configuration option.
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Table 3-41. EMIFA/VPSS Sub-Block 0 Configuration Choice B(1)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
AEAW
OTHERS
EMIFA
VPFE
# GPIO PINS
8-bit EMIFA
(Async) Pinout
mode 1 w/
Config Summary
No CCDC
11 GP pins
EM_A[21:0]
CCDCSEL = 0
HVDSEL = 0
CWENSEL = 0
CFLDSEL = 0
CI10SEL = 0
CI32SEL = 0
CI54SEL = 0
CI76SEL = 0
-
-
0 = GP[54, 43:36]
0 = GP[53:52]
B
B1
001
100
0 = EM_R/W
-
-
-
-
-
-
0 = EM_A21
-
0 = EM_A[19:20]
0 = EM_A[17:18]
0 = EM_A[15:16]
0 = EM_A[13:14]
8-bit EMIFA
(Async) Pinout
mode 1 w/
Config Summary
8-to-16-bit CCDC
0-to-10 GP pins
EM_A[12:0] only
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0
-
1 = PCLK, YI[7:0]
-
-
1 = VD, HD
-
0 = GP[53:52]
-
0 = EM_R/W
B
B2
001
000
0 = EM_A21
(not used)
CFLDSEL = 0,1
1 = C_FIELD
-
CI10SEL = 0,1
CI32SEL = 0,1
CI54SEL = 0,1
CI76SEL = 0,1
-
-
-
-
1 = CI[1:0]
1 = CI[3:2]
1 = CI[5:4]
1 = CI[7:6]
0 = GP[45:44]
0 = GP[47:46]
0 = GP[49:48]
0 = GP[51:50]
8-bit EMIFA
(Async) Pinout
mode 1 w/
Config Summary
8-to-14-bit CCDC
0-to-8 GP pins
EM_A[14:0] only
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0
-
1 = PCLK, YI[7:0]
-
-
1 = VD, HD
-
0 = GP[53:52]
-
0 = EM_R/W
B
B3
001
001
0 = EM_A21
(not used)
CFLDSEL = 0,1
1 = C_FIELD
-
CI10SEL = 0,1
CI32SEL = 0,1
CI54SEL = 0,1
CI76SEL = 0
-
1 = CI[1:0]
1 = CI[3:2]
1 = CI[5:4]
-
0 = GP[45:44]
0 = GP[47:46]
0 = GP[49:48]
-
-
-
0 = EM_A[13:14]
(1) Italics indicate mandatory settings for a given Minor Configuration option.
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Table 3-41. EMIFA/VPSS Sub-Block 0 Configuration Choice B (continued)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
AEAW
OTHERS
EMIFA
VPFE
# GPIO PINS
8-bit EMIFA
(Async) Pinout
mode 1 w/
Config Summary
8-to-12-bit CCDC
0-to-6 GP pins
EM_A[16:0] only
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0
-
-
1 = PCLK, YI[7:0]
-
1 = VD, HD
-
0 = GP[53:52]
-
0 = EM_R/W
B
B4
001
010
0 = EM_A21
(not used)
CFLDSEL = 0,1
1 = C_FIELD
-
CI10SEL = 0,1
CI32SEL = 0,1
CI54SEL = 0
CI76SEL = 0
-
1 = CI[1:0]
0 = GP[45:44]
-
1 = CI[3:2]
0 = GP[47:46]
0 = EM_A[15:16]
0 = EM_A[13:14]
-
-
-
-
8-bit EMIFA
(Async) Pinout
mode 1 w/
Config Summary
8-to-10-bit CCDC
0-to-4 GP pins
EM_A[18:0] only
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0
-
1 = PCLK, YI[7:0]
-
-
1 = VD, HD
-
0 = GP[53:52]
-
0 = EM_R/W
B
B5
001
011
0 = EM_A21
(not used)
CFLDSEL = 0,1
1 = C_FIELD
-
CI10SEL = 0,1
CI32SEL = 0
CI54SEL = 0
CI76SEL = 0
-
1 = CI[1:0]
0 = GP[45:44]
0 = EM_A[17:18]
0 = EM_A[15:16]
0 = EM_A[13:14]
-
-
-
-
-
-
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Table 3-41. EMIFA/VPSS Sub-Block 0 Configuration Choice B (continued)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
AEAW
OTHERS
EMIFA
VPFE
# GPIO PINS
8-bit EMIFA
(Async) Pinout
mode 1 w/
Config Summary
8-bit CCDC
0-to-2 GP pins
EM_A[21:0]
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0
CFLDSEL = 0,1
CI10SEL = 0
CI32SEL = 0
CI54SEL = 0
CI76SEL = 0
-
-
1 = PCLK, YI[7:0]
-
1 = VD, HD
0 = GP[53:52]
B
B6
001
100
0 = EM_R/W
-
-
-
-
-
-
-
0 = EM_A21
1 = C_FIELD
0 = EM_A[19:20]
0 = EM_A[17:18]
0 = EM_A[15:16]
0 = EM_A[13:14]
-
-
-
-
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Table 3-42. EMIFA/VPSS Sub-Block 0 Configuration Choice E(1)
RESULTING
PERIPHERALS/PI
NS
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
AEM
AEAW
OTHERS
EMIFA
VPFE
# GPIO PINS
21 GP pins
8-bit EMIFA
(NAND) Pinout
mode 5
Cfg Summary
No CCDC
CCDCSEL = 0
0 = GP[54, 43:36]
0 = GP[53:52]
0 = GP[35]
HVDSEL = 0
CWENSEL = 0
CFLDSEL = 0
CI10SEL = 0
CI32SEL= 0
CI54SEL = 0
CI76SEL = 0
E1
101
000
0 = GP[34]
-
-
0 = GP[45:44]
0 = GP[47:46]
0 = GP[49:48]
0 = GP[51:50]
E
8-bit EMIFA
(NAND) Pinout
mode 5
Cfg Summary
8-to-16-bit CCDC
0-to-12 GP pins
CCDCSEL = 1
HVDSEL = 0,1
CWENSEL = 0,1
CFLDSEL = 0,1
CI10SEL = 0,1
CI31SEL = 0,1
CI54SEL = 0,1
CI76SEL = 0,1
1 = PCLK, YI[7:0]
1= VD, HD
1 = C_WEN
1 = C_FIELD
1 = CI[1:0]
-
0 = GP[53:52]
0 = GP[35]
0 = GP[34]
0 = GP[45:44]
0 = GP[47:46]
0 = GP[49:48]
0 = GP[51:50]
E2
101
000
-
1 = CI[3:2]
1 = CI[5:4]
1 = CI[7:6]
(1) Italics indicate mandatory settings for a given Minor Configuration option.
As shown in Table 3-40 through Table 3-42, the configuration choices of the EMIFA/VPSS Sub-Block 0
are determined by the following PINMUX register fields:
•
PINMUX0 register fields AEM, AEAW, CCDCSEL, HVDSEL, CWENSEL, CFLDSEL, CI10SEL,
CI32SEL, CI54SEL, and CI76SEL.
The following is an example of how to read Table 3-40 through Table 3-42 using Sub-Block 0 Minor
Configuration B6 as an example:
•
The PINMUX Selection Fields columns indicate that Sub-Block 0 Minor Configuration Option B6 is
selected through setting, PINMUX0.AEM = 1, PINMUX0.AEAW = 4, CCDCSEL = 1, HVDSEL = 0 or 1
(based on the system’s need for VPFE control signals VD and HD), CWENSEL = 0 (mandatory
setting), CFLDSEL = 0 or 1 (based on the system’s need for VPFE control signal C_FIELD), CI10SEL
= 0 (mandatory), CI32SEL = 0 (mandatory), CI54SEL = 0 (mandatory), and CI76SEL = 0 (mandatory).
•
The Resulting Peripherals/Pins columns show the functional pins resulting from the PINMUX setting.
For example, PINMUX0.CCDCSEL = 1 gives the user the PCLK and YI[7:0] pins for the VPFE.
PINMUX0.HVDSEL = 1 gives the user VD and HD pins for VPFE, while HVDSEL = 0 gives the user 2
GP pins.
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3.7.3.11.4 EMIFA/VPSS Sub-Block 1 Configuration Choices
Table 3-43 through Table 3-45 show the configuration choices in the EMIFA/VPSS Sub-Block 1. For
instructions on how to use the different configuration choices tables for the EMIFA/VPSS Block and
Sub-Blocks, see Section 3.7.3.11.1, EMIFA/VPSS Block Pin Selection Procedure.
Before using Table 3-43 through Table 3-45 to configure the details of the EMIFA/VPSS Sub-Block 1, the
user should first select the Major Configuration Option for the EMIFA/VPSS Block (see Section 3.7.3.11.2,
EMIFA/VPSS Block Major Configuration Choices). After determining the Major Configuration Option (A, B,
or E), the user can now use Table 3-43 through Table 3-45 to refine the Sub-Block 1 pin selections.
1. Go to the table with the Major Configuration Option chosen from Table 3-39.
2. Each Major Configuration Option is further divided down into multiple Minor Configuration Options.
Select a Minor Configuration Option that best suits the application need.
3. Within the chosen Minor Configuration Option, further refine the detailed pin configurations by selecting
the settings of PINMUX0 fields CS3SEL, CS4SEL, and CS5SEL.
4. The PINMUX Selection Fields columns give the user the settings needed to program the PINMUX0
register.
Table 3-43. EMIFA/VPSS Sub-Block 1 Configuration Choice A(1)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
OTHERS
EMIFA
GPIO
Cfg Summary
No EMIFA
29 GP pins
CS3SEL = 0
A
A1
000
CS4SEL = 0
CS5SEL = 0
–
0 = GP[33:5]
(1) Italics indicate mandatory settings for a given Minor Configuration option.
Table 3-44. EMIFA/VPSS Sub-Block 1 Configuration Choice B(1)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
OTHERS
EMIFA
GPIO
8-bit EMIFA (Async)
Pinout Mode 1
Cfg Summary
10-to-13 GP pins
EM_D[7:0], EM_CS2,
EM_A[4:0], EM_BA[1:0]
Basic Pins You Get
0 = GP[31:22]
B
B1
001
CS3SEL = 0,1
CS4SEL = 0,1
CS5SEL = 0,1
1 = EM_CS3
1 = EM_CS4
1 = EM_CS5
0 = GP[13]
0 = GP[32]
0 = GP[33]
(1) Italics indicate mandatory setting for a given Minor Configuration option.
Table 3-45. EMIFA/VPSS Sub-Block 1 Configuration Choice E(1)
MAJOR
CONFIG
OPTION
MINOR
CONFIG
OPTION
PINMUX SELECTION FIELDS
RESULTING PERIPHERALS/PINS
AEM
OTHERS
EMIFA
GPIO
8-bit EMIFA (NAND)
Pinout Mode 5
Cfg Summary
15-to-18 GP pins
EM_D[7:0], EM_A[2:1],
EM_CS2
0 = GP[31:22, 11:10,
7:5]
Basic Pins You Get
E
E1
101
CS3SEL = 0,1
CS4SEL = 0,1
CS5SEL = 0,1
1 = EM_CS3
1 = EM_CS4
1 = EM_CS5
0 = GP[13]
0 = GP[32]
0 = GP[33]
(1) Italics indicate mandatory setting for a given Minor Configuration option.
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The Sub-Block 1 Minor Configuration Options are independent from the Sub-Block 0 Minor Configuration
Options. The user can independently select the appropriate Minor Configuration Option for each
Sub-Block.
As shown in Table 3-43 through Table 3-45, the configuration choices of the EMIFA/VPSS Sub-Block 1
are determined by the following PINMUX register fields:
•
PINMUX0 register fields AEM, CS3SEL, CS4SEL, and CS5SEL.
The following is an example on how to read Table 3-43 through Table 3-45 using Sub-Block 1 Minor
Configuration E1 as an example:
•
The PINMUX Selection Fields columns indicate that Sub-Block 1 Minor Configuration Option E1 is
selected through setting PINMUX0 fields to AEM = 5, CS3SEL = 0/1 (based on the desired pin choice),
CS4SEL = 0/1 (based on the desired pin choice), and CS5SEL = 0/1 (based on the desired pin
choice).
•
The Resulting Peripherals/Pins columns show the functional pins resulting from the PINMUX setting.
For example, you automatically get EMIFA pins EM_D[7:0], EM_A[2:1], and EM_CS2 in addition to at
least 15 GPIO pins in Minor Config Option E1 (GP[31:22], GP[11:10], and GP[7:5]). If you program
CS3SEL = 1, CS4SEL = 0, and CS5SEL = 0, you also get EM_CS3, GP[32], and GP[33].
3.7.3.11.5 EMIFA/VPSS Sub-Block 2 Configuration Choices
The 3 pins in the EMIFA/VPSS Sub-Block 2 are standalone (non-multiplexed) pins. They always function
as EMIFA control pins EM_WAIT/(RDY/BSY), EM_OE, and EM_WE. No pin mux selection is necessary
for this Sub-Block.
3.7.3.11.6 EMIFA/VPSS Sub-Block 3 Configuration Choices
The 8 pins in the EMIFA/VPSS Sub-Block 3 are multiplexed between:
•
•
EMIFA Address Pins EM_A[12:5]
GPIO pins GP[96:89]
The pin functions in the EMIFA/VPSS Sub-Block 3 are determined by the following PINMUX register
fields:
•
PINMUX0.AEM
Once the Major Configuration Option for the EMIFA/VPSS Block (see Section 3.7.3.11.2, EMIFA/VPSS
Block Major Configuration Choices) is chosen, no further actions are necessary to refine the EMIFA/VPSS
Sub-Block 3 pin selection. For instructions on configuring the EMIFA/VPSS Block, see Section 3.7.3.11.1,
EMIFA/VPSS Block Pin Selection Procedure.
Table 3-46 summarizes the pin selections in the EMIFA/VPSS Sub-Block 3 based on the PINMUX
selections.
Table 3-46. EMIFA/VPSS Sub-Block 3 Configuration Choices
MAJOR
CONFIG
OPTION
PINMUX SELECTION FIELD
AEM
RESULTING PERIPHERALS/PINS
GPIO
EMIFA
A
B
E
000
001
101
-
GP[96:89]
-
EM_A[12:5]
-
GP[96:89]
The following is an example on how to read Table 3-46 using Sub-Block 3 Major Configuration B as an
example:
•
The PINMUX Selection Fields columns indicate that Sub-Block 3 Major Configuration Option B is
selected through setting PINMUX0.AEM = 001b.
•
The Resulting Peripherals/Pins columns show the functional pins resulting from the PINMUX setting. In
Major Configuration B, the user gets EMIFA address pins EM_A[12:5] from Sub-Block 3.
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3.7.3.11.7 EMIFA/VPSS Block Pin-By-Pin Multiplexing Summary
This section summarizes the EMIFA/VPSS Block muxing on a pin-by-pin basis. It provides an alternative
view to pin muxing in the EMIFA/VPSS Block. This section should only be used after following the
procedures listed in Section 3.7.3.11.1 to determine the actual EMIFA/VPSS Configuration Option for the
application need.
Table 3-47 shows the pin multiplexing control for each pin in the EMIFA/VPSS Sub-Block 0. These are the
fields in the PINMUX0 and PINMUX1 registers that control the multiplexing in this sub-block:
•
PINMUX0: AEM, AEAW, CWENSEL, CFLDSEL, CI10SEL, CI32SEL, CI54SEL, CI76SEL, CCDCSEL,
and HVDSEL
Table 3-48 shows the pin multiplexing control for each pin in the EMIFA/VPSS Sub-Block 1. These are the
fields in the PINMUX0 register that control the multiplexing in this sub-block:
•
PINMUX0: AEM, CS5SEL, CS4SEL, and CS3SEL
EMIFA/VPSS Sub-Block 2 is dedicated to EMIFA pins EM_WAIT/(RDY/BSY), EM_OE, and EM_WE.
There is no pin multiplexing in this block. These pins always function as EMIFA control pins.
Table 3-49 shows the pin multiplexing control for each pin in the EMIFA/VPSS Sub-Block 3. These are the
fields in the PINMUX0 register that control the multiplexing in this sub-block:
•
PINMUX0: AEM
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Table 3-47. EMIFA/VPSS Sub-Block 0 Pin-By-Pin Mux Control
MULTIPLEXED FUNCTIONS
SIGNAL NAME
VPFE
EMIFA ADDR/CTRL
GPIO
FUNCTION
PCLK
SELECT
FUNCTION
SELECT
FUNCTION
GP[54]
GP[43]
GP[42]
GP[41]
GP[40]
GP[39]
GP[38]
GP[37]
GP[36]
GP[53]
GP[52]
GP[51]
SELECT
PCLK/GP[54]
CCDCSEL = 1
–
–
–
–
–
–
–
–
–
–
–
–
CCDCSEL = 0
YI7(CCD7)/GP[43]
YI6(CCD6)/GP[42]
YI5(CCD5)/GP[41]
YI4(CCD4)/GP[40]
YI3(CCD3)/GP[39]
YI2(CCD2)/GP[38]
YI1(CCD1)/GP[37]
YI0(CCD0)/GP[36]
VD/GP[53]
YI7(CCD7)
YI6(CCD6)
YI5(CCD5)
YI4(CCD4)
YI3(CCD3)
YI2(CCD2)
YI1(CCD1)
YI0(CCD0)
VD
–
–
–
–
–
–
–
–
HVDSEL = 1
–
–
HVDSEL = 0
HD/GP[52]
HD
CI7(CCD15)/EM_A[13]/GP[51]
CI6(CCD14)/EM_A[14]/GP[50]
CI7(CCD15)
AEM = 0/1/5,
AEAW = 0,
CI76SEL = 1
EM_A[13]
AEM = 1,
AEAW = 1/2/3/4,
CI76SEL = 0
AEM = 0/1/5,
AEAW = 0,
CI76SEL = 0
CI6(CCD14)
CI5(CCD13)
CI4(CCD12)
CI3(CCD11)
CI2(CCD10)
CI1(CCD9)
CI0(CCD8)
EM_A[14]
EM_A[15]
EM_A[16]
EM_A[17]
EM_A[18]
EM_A[19]
EM_A[20]
GP[50]
GP[49]
GP[48]
GP[47]
GP[46]
GP[45]
GP[44]
CI5(CCD13)/EM_A[15]/GP[49]
CI4(CCD12)/EM_A[16]/GP[48]
AEM = 0/1/5,
AEM = 1,
AEAW = 2/3/4,
CI54SEL = 0
AEM = 0/1/5,
AEAW = 0/1(1)
CI54SEL = 1
,
AEAW = 0/1(1)
CI54SEL = 0
,
CI3(CCD11)/EM_A[17]/GP[47]
CI2(CCD10)/EM_A[18]/GP[46]
AEM = 0/1/5,
AEAW = 0/1/2(1)
CI32SEL = 1
AEM = 1,
AEAW = 3/4,
CI32SEL = 0
AEM = 0/1/5,
AEAW = 0/1/2(1)
CI32SEL = 0
,
,
CI1(CCD9)/EM_A[19]/GP[45]
CI0(CCD8)/EM_A[20]/GP[44]
AEM = 0/1/5,
AEM = 1,
AEAW = 4,
CI10SEL = 0
AEM = 0/1/5,
AEAW = 0/1/2/3(1)
CI10SEL = 1
,
AEAW = 0/1/2/3(1)
CI10SEL = 0
,
C_WE/EM_R/W/GP[35]
CWENSEL = 1,
AEM = 0/5
CWENSEL = 0,
AEM = 1
CWENSEL = 0,
AEM = 0/5
C_WE
EM_R/W
EM_A[21]
GP[35]
GP[34]
C_FIELD/EM_A[21]/GP[34]
CFLDSEL = 1,
AEM = 0/1/5
CFLDSEL = 0,
AEM = 1
CFLDSEL = 0,
AEM = 0/5
C_FIELD
(1) AEAW = 1/2/3/4 is only valid if AEM[2:0] = 1.
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Table 3-48. EMIFA/VPSS Sub-Block 1 Pin-By-Pin Mux Control
MULTIPLEXED FUNCTIONS
SIGNAL
NAME
EMIFA
GPIO(1)
FUNCTION
EM_CS5
EM_CS4
SELECT
FUNCTION
GP[33]
GP[32]
GP[31]
GP[30]
GP[29]
GP[28]
GP[27]
GP[26]
GP[25]
GP[24]
GP[23]
GP[22]
GP[21]
GP[20]
GP[19]
GP[18]
GP[17]
GP[16]
GP[15]
GP[14]
GP[13]
GP[12]
SELECT
EM_CS5/GP[33]
EM_CS4/GP[32]
GP[31]
CS5SEL = 1
CS4SEL = 1
CS5SEL = 0
CS4SEL = 0
GP[30]
GP[29]
GP[28]
GP[27]
–
–
–
GP[26]/(FASTBOOT)
GP[25]/(BOOTMODE3)
GP[24]/(BOOTMODE2)
GP[23]/(BOOTMODE1)
GP[22]/(BOOTMODE0)
EM_D[7]/GP[21]
EM_D[7]
EM_D[6]
EM_D[5]
EM_D[4]
EM_D[3]
EM_D[2]
EM_D[1]
EM_D[0]
EM_CS3
EM_CS2
EM_D[6]/GP[20]
EM_D[5]/GP[19]
EM_D[4]/GP[18]
AEM = 1/5
AEM = 0
EM_D[3]/GP[17]
EM_D[2]/GP[16]
EM_D[1]/GP[15]
EM_D[0]/GP[14]
EM_CS3/GP[13]
CS3SEL = 1
AEM = 1/5
CS3SEL = 0
AEM = 0
EM_CS2/GP[12]
EM_A[1]/(ALE)/
GP[9]/(AEAW1/PLLMS1)
EM_A[1]/(ALE)
GP[9]
EM_A[2]/(CLE)/GP[8]/
(AEAW0/PLLMS0)
EM_A[2]/(CLE)
EM_A[3]
GP[8]
GP[11]
GP[10]
EM_A[3]/GP[11]
EM_A[4]/GP[10]/
(AEAW2/PLLMS2)
EM_A[4]
AEM = 1
AEM = 0/5
EM_A[0]/GP[7]/(AEM2)
EM_BA[0]/GP[6]/(AEM1)
EM_BA[1]/GP[5]/(AEM0)
EM_A[0]
EM_BA[0]
EM_BA[1]
GP[7]
GP[6]
GP[5]
(1) GP[31:22] are standalone pins. They are not muxed with any other functions. They are included in this table because they are grouped
in the EMIFA/VPSS Sub-Block 1.
Table 3-49. EMIFA/VPSS Sub-Block 3 Pin-By-Pin Mux Control
MULTIPLEXED FUNCTIONS
SIGNAL
NAME
EMIFA
GPIO
FUNCTION
EM_A[12]
EM_A[11]
EM_A[10]
EM_A[9]
EM_A[8]
EM_A[7]
EM_A[6]
EM_A[5]
SELECT
FUNCTION
GP[89]
GP[90]
GP[91]
GP[92]
GP[93]
GP[94]
GP[95]
GP[96]
SELECT
EM_A[12]/GP[89]
EM_A[11]/GP[90]
EM_A[10]/GP[91]
EM_A[9]/GP[92]
EM_A[8]/GP[93]
EM_A[7]/GP[94]
EM_A[6]/GP[95]
EM_A[5]/GP[96]
AEM = 1
AEM = 0/5
122
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3.8 Device Initialization Sequence After Reset
Software should follow this initialization sequence after coming out of device reset.
1. Complete the boot sequence as needed. For more details on the boot sequence, see the Using the
TMS320DM643x Bootloader Application Report (literature number SPRAAG0).
2. If the device is not already at the desired operating frequency, program the PLL Controllers (PLLC1
and PLLC2) to configure the device frequency. For details on how to program the PLLC, see the
TMS320DM643x DMP DSP Subsystem Reference Guide (literature number SPRU978).
3. Program PINMUX0 and PINMUX1 registers to select device pin functions. For more details on
programming the PINMUX0 and PINMUX1 registers to select device pin functions, see Section 3.7,
Multiplexed Pin Configurations.
Note: if EMAC operation is desired, the EMAC must be placed in reset before programming
PINMUX1.HOSTBK to select EMAC pins.
4. Program the VDD3P3V_PWDN register to power up the necessary I/O pins. For more details on
programming the VDD3P3V_PWDN register, see Section 3.2, Power Considerations. On DM6435, the
user should program VDD3P3V_PWDN bit 13 to 1 to power down the reserved pins RSV17, RSV18,
and RSV19.
5. As needed by the application, program the following System Module registers when there are no active
transactions on the respective peripherals:
a. HPICTL (Section 3.6.2.1, HPI Control Register): applicable for HPI only if a different host burst
write timeout value from default is desired.
b. TIMERCTL (Section 3.6.2.2, Timer Control Register): applicable for Timer0 and Watchdog Timer2
only.
c. EDMATCCFG (Section 3.6.2.3, EDMA TC Configuration Register): applicable for EDMA only. The
recommendation is to leave the EDMATCCFG register at its default.
d. VPSS_CLKCTL (Section 3.3.2, VPSS Clocks): applicable for VPSS only.
6. Program the Power and Sleep Controller (PSC) to enable the desired peripherals. For details on how
to program the PSC, see the TMS320DM643x DMP DSP Subsystem Reference Guide (literature
number SPRU978).
7. Program the Switched Central Resource (SCR) bus priorities for the master peripherals
(Section 3.6.1). This must be configured when there are no active transactions on the respective
peripherals:
a. Program the MSTPRI0 and MSTPRI1 registers in the System Module. These registers can be
programmed before or after the respective peripheral is enabled by the PSC in step 6.
b. Program the EDMACC QUEPRI register, the C64x+ MDMAARBE.PRI field, and the VPSS PCR
register. These registers can only be programmed after the respective peripheral is enabled by the
PSC in step 6.
8. Configure the C64x+ Megamodule and the peripherals.
a. For details on C64x+ Megamodule configuration, see the TMS320C64x+ DSP Megamodule
Reference Guide (literature number SPRU871).
Special considerations: Bootloader disables C64x+ cache—For all boot modes that default to
DSPBOOTADDR = 0x0010 0000 (i.e., all boot modes except the EMIFA ROM Direct Boot,
BOOTMODE[3:0] = 0100, FASTBOOT = 0), the bootloader code disables all C64x+ cache (L2,
L1P, and L1D) so that upon exit from the bootloader code, all C64x+ memories are configured as
all RAM (L2CFG.L2MODE = 0h, L1PCFG.L1PMODE = 0h, and L1DCFG.L1DMODE = 0h). If cache
use is required, the application code must explicitly enable the cache. For more information on boot
modes, see Section 3.4.1, Boot Modes. For more information on the bootloader, see the Using the
TMS320DM643x Bootloader Application Report (literature number SPRAAG0).
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b. Peripherals configuration: see the respective peripheral user’s guide.
Special considerations: DDR2 memory controller—the Peripheral Bus Burst Priority Register
(PBBPR) should be programmed to ensure good DDR2 throughput and to prevent command
starvation (prevention of certain commands from being processed by the DDR2 memory controller).
For more details, see the TMS320DM643x DMP DDR2 Memory Controller User’s Guide (literature
number SPRU986). A hex value of 0x20 is recommended for the PBBPR PR_OLD_COUNT field to
provide a good DSP performance and still allow good utilization by other modules.
124
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3.9 Debugging Considerations
3.9.1 Pullup/Pulldown Resistors
Proper board design should ensure that input pins to the DM643x DMP device always be at a valid logic
level and not floating. This may be achieved via pullup/pulldown resistors. The DM643x DMP features
internal pullup (IPU) and internal pulldown (IPD) resistors on most pins to eliminate the need, unless
otherwise noted, for external pullup/pulldown resistors.
An external pullup/pulldown resistor needs to be used in the following situations:
•
Boot and Configuration Pins: If the pin is both routed out and 3-stated (not driven), an external
pullup/pulldown resistor is strongly recommended, even if the IPU/IPD matches the desired
value/state.
•
•
Other Input Pins: If the IPU/IPD does not match the desired value/state, use an external
pullup/pulldown resistor to pull the signal to the opposite rail.
EMIFA Chip Select Outputs: On DM6435, the EMIFA chip select pins (EM_CS2, EM_CS3, EM_CS4,
and EM_CS5) feature an internal pulldown (IPD) resistor. If these pins are connected and used as an
EMIFA chip select signal, for proper device operation, an external pullup resistor must be used to
ensure the EM_CSx function defaults to an inactive (high) state.
For the boot and configuration pins (listed in Table 2-5, Boot Terminal Functions), if they are both routed
out and 3-stated (not driven), it is strongly recommended that an external pullup/pulldown resistor be
implemented. Although, internal pullup/pulldown resistors exist on these pins and they may match the
desired configuration value, providing external connectivity can help ensure that valid logic levels are
latched on these device boot and configuration pins. In addition, applying external pullup/pulldown
resistors on the boot and configuration pins adds convenience to the user in debugging and flexibility in
switching operating modes.
Tips for choosing an external pullup/pulldown resistor:
•
Consider the total amount of current that may pass through the pullup or pulldown resistor. Make sure
to include the leakage currents of all the devices connected to the net, as well as any internal pullup or
pulldown resistors.
•
Decide a target value for the net. For a pulldown resistor, this should be below the lowest VIL level of
all inputs connected to the net. For a pullup resistor, this should be above the highest VIH level of all
inputs on the net. A reasonable choice would be to target the VOL or VOH levels for the logic family of
the limiting device; which, by definition, have margin to the VIL and VIH levels.
•
•
Select a pullup/pulldown resistor with the largest possible value; but, which can still ensure that the net
will reach the target pulled value when maximum current from all devices on the net is flowing through
the resistor. The current to be considered includes leakage current plus, any other internal and
external pullup/pulldown resistors on the net.
For bidirectional nets, there is an additional consideration which sets a lower limit on the resistance
value of the external resistor. Verify that the resistance is small enough that the weakest output buffer
can drive the net to the opposite logic level (including margin).
•
•
Remember to include tolerances when selecting the resistor value.
For pullup resistors, also remember to include tolerances on the DVDD rail.
For most systems, a 1-kΩ resistor can be used to oppose the IPU/IPD while meeting the above criteria.
Users should confirm this resistor value is correct for their specific application.
For most systems, a 20-kΩ resistor can be used to compliment the IPU/IPD on the boot and configuration
pins while meeting the above criteria. Users should confirm this resistor value is correct for their specific
application.
For more detailed information on input current (II), and the low-/high-level input voltages (VIL and VIH) for
the DM643x DMP, see Section 5.3, Electrical Characteristics Over Recommended Ranges of Supply
Voltage and Operating Temperature.
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For the internal pullup/pulldown resistors for all device pins, see the peripheral/system-specific terminal
functions table.
126
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4 System Interconnect
On the DM6435 device, the C64x+ Megamodule, the EDMA3 transfer controllers, and the system
peripherals are interconnected through a switch fabric architecture (see Figure 4-1). The switch fabric is
composed of multiple switched central resources (SCRs) and multiple bridges. The SCRs establish
low-latency connectivity between master peripherals and slave peripherals. Additionally, the SCRs provide
priority-based arbitration and facilitate concurrent data movement between master and slave peripherals.
Through an SCR, the DSP subsystem can send data to the DDR2 Memory Controller without affecting a
data transfer between the EMAC and L2 memory. Bridges are mainly used to perform bus-width
conversion as well as bus operating frequency conversion. For example, in Figure 4-1, Bridge 6 performs
a frequency conversion between a bus operating at DSP/3 clock rate and a bus operating at DSP/6 clock
rate. Furthermore, Bridge 5 performs a bus-width conversion between a 64-bit bus and a 32-bit bus.
The C64x+ Megamodule, the EDMA3 transfer controllers (EDMA3TC[2:0]), and the various system
peripherals can be classified into two categories: master peripherals and slave peripherals. Master
peripherals are typically capable of initiating read and write transfers in the system and do not rely on the
EDMA3 or on the CPU to perform transfers to and from them. The system master peripherals include the
C64x+ Megamodule, the EDMA3 transfer controllers, VLYNQ, EMAC, HPI, and VPSS. Not all master
peripherals may connect to all slave peripherals. The supported connections are designated by ' Y' in
Table 4-1.
Table 4-1. System Connection Matrix
SLAVE PERIPHERALS/MODULES
MASTER
PERIPHERALS/MODULES
DDR2
MEMORY
CONTROLLER
SCR2, SCR6,
C64x+ SDMA
SCR4(1)
SCR7, SCR8(1)
C64x+ MDMA
–
–
Y
Y
Y
Y
Y
Y
–
–
–
Y
–
VPSS
VLYNQ
Y
Y
Y
Y
–
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
EMAC
HPI
EDMA3TC's (EDMA3TC2/TC1/TC0)
C64x+ CFG
(1) All the peripherals/modules that support a connection to SCR2, SCR4, SCR6, SCR7, and SCR8 have access to all peripherals/modules
connected to those respective SCRs.
4.1 System Interconnect Block Diagram
Figure 4-1 displays the DM6435 system interconnect block diagram. The following is a list that helps in
the interpretation of this diagram:
•
•
•
The direction of the arrows indicates either a bus master or bus slave.
The arrow originates at a bus master and terminates at a bus slave.
The direction of the arrows does not indicate the direction of data flow. Data flow is typically
bi-directional for each of the documented bus paths.
•
•
The pattern of each arrow's line indicates the clock rate at which it is operating— i.e., either DSP/3,
DSP/6, or MXI/CLKIN clock rate.
A peripheral may have multiple instances shown in Figure 4-1 for the following reason:
–
The peripheral/module has master port(s) for data transfers, as well as slave port(s) for register
access, data access, and/or memory access. Examples of these peripherals are C64x+
Megamodule, EDMA3, VPSS, VLYNQ, HPI, and EMAC.
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MXI/CLKIN Clock Rate
DSP/6 Clock Rate
DSP/6 Clock Rate
32
32
32
UART0
UART1
HECC
I2C
Bridge 8
DDR2 Memory
Controller
(Memory/Register)
32
64
64
VLYNQ
EMAC
HPI
32
32
32
32
32
64
Bridge 2
32
32
32
32
32
32
SCR 5
HPI
32
64x+
L2/L1
VPSS Reg
EMAC Reg
32
32
32
32
32
32
32
32
32
PWM0
PWM1
PWM2
Timer0
Timer1
Timer2
SCR 2
EMAC Control
Module Reg
64
VPSS
EMAC Control
Module RAM
SCR 6
64
64
32
32
Read
64
64
Bridge 5
Bridge 4
MDIO
EDMA3TC0
EDMA3TC1
EDMA3TC2
SCR 1
Write
Read
Write
Read
Write
32
64
32
32
GPIO
64
64
64
System Reg
PSC
32
32
Bridge 6
PLLC1
PLLC2
64
32
Bridge 3
SCR 3
L2 Cache
32
32
EMIFA
VLYNQ
SCR 4
32
32
SCR 7
SCR 8
64
32
EDMA3CC
64x+
32
32
EDMA3TC0
EDMA3TC1
EDMA3TC2
32
McBSP0
McASP0
DSP/3 Clock Rate
DSP/3 Clock Rate
DSP/6 Clock Rate
MXI/CLKIN Clock Rate
Figure 4-1. System Interconnect Block Diagram
128
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5 Device Operating Conditions
5.1 Absolute Maximum Ratings Over Operating Temperature Range (Unless Otherwise
Noted)(1)
(2)
Supply voltage ranges:
Core (CVDD
)
–0.5 V to 1.5 V
–0.5 V to 4.2 V
–0.5 to 2.5 V
–0.5 V to 4.2 V
–0.5 V to 2.5 V
–0.5 V to 4.2 V
–0.5 V to 2.5 V
0C to 90C
(2)
I/O, 3.3V (DVDD33
)
(2)
I/O, 1.8V (DVDDR2, DDR_VDDDLL, PLLPWR18, MXVDD
)
Input voltage ranges:
Output voltage ranges:
VI I/O, 3.3-V pins
VI I/O, 1.8 V
VO I/O, 3.3-V pins
VO I/O, 1.8 V
Operating Junction temperature
ranges, TJ:
Commercial
Automotive
–40C to 125C
(Q or S suffix)
Storage temperature range, Tstg
(default)
–65C to 150C
(1) Stresses beyond those listed under "absolute maximum ratings" may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under "recommended operating
conditions" is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
(2) All voltage values are with respect to VSS.
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5.2 Recommended Operating Conditions(1)
MIN
1.14
NOM
1.2
MAX
1.26
UNIT
(-6, -5, -5Q, -5S, -4, -4Q,
-4S devices)
V
(2)(3)
CVDD
Supply voltage, Core (CVDD)
(-6 devices)
1.0
1.05
3.3
1.1
V
V
Supply voltage, I/O, 3.3V (DVDD33
)
2.97
3.63
DVDD
Supply voltage, I/O, 1.8V (DVDDR2, DDR_VDDDLL, PLLPWR18
,
1.71
1.8
1.89
V
(4)
MXVDD
)
(5)
VSS
Supply ground (VSS, DDR_VSSDLL, MXVSS
DDR2 reference voltage(6)
)
0
0
0.5DVDDR2
VSS
0
V
V
V
V
V
V
DDR_VREF
DDR_ZP
DDR_ZN
0.49DVDDR2
0.51DVDDR2
DDR2 impedance control, connected via 200 Ω resistor to VSS
DDR2 impedance control, connected via 200 Ω resistor to DVDDR2
High-level input voltage, 3.3V (except I2C pins)
High-level input voltage, MXI/ CLKIN
DVDDR2
2
0.65MXV
0.7DVDD33
VIH
High-level input voltage, I2C
Low-level input voltage, 3.3V (except I2C pins)
Low-level input voltage, MXI/ CLKIN
0.8
0.35MXV
0.3DVDD33
90
V
V
VIL
Low-level input voltage, I2C
0
0
V
Commercial
C
Operating Junction
TJ
temperature(7)(8)
Automotive (Q or S suffix)
–40
0
125
C
Commercial
Operating Ambient Temperature(8)
Automotive (Q or S suffix)
70
C
TA
-40
85
C
(-6 devices, 1.2 V)
600
MHz
MHz
MHz
MHz
(-6 devices, 1.05 V)(3)
400
DSP Operating Frequency
(SYSCLK1)
FSYSCLK1
(-5, -5Q, -5S devices)
500
(-4, -4Q, -4S devices)
400
(1) The actual voltage must be determined at device power-up, and not be changed dynamically during run-time.
(2) Future variants of TI SOC devices may operate at voltages ranging from 0.9 V to 1.4 V to provide a range of system power/performance
options. TI highly recommends that users design-in a supply that can handle multiple voltages within this range (i.e., 1.0 V, 1.05 V,
1.1 V, 1.14 V, 1.2, 1.26 V with 3% tolerances) by implementing simple board changes such as reference resistor values or input pin
configuration modifications. Not incorporating a flexible supply may limit the system's ability to easily adapt to future versions of TI SOC
devices.
(3) 1.05 V CVDD is only supported on -6 devices running at SYSCLK1 ≤ 400 MHz.
(4) Oscillator 1.8 V power supply (MXVDD) can be connected to the same 1.8 V power supply as DVDDR2
(5) Oscillator ground (MXVSS) must be kept separate from other grounds and connected directly to the crystal load capacitor ground.
(6) DDR_VREF is expected to equal 0.5DVDDR2 of the transmitting device and to track variations in the DVDDR2
.
.
(7) In the absence of a heat sink or direct thermal attachment on the top of the device, use the following formula to determine the device
junction temperature: TJ = TC + (Power x PsiJT). Power and TC can be measured by the user. Section 7.1, Thermal Data for ZWT and
Section 7.1.1, Thermal Data for ZDU provide the junction-to-package top (PSIJT) value based on airflow in the system. In the presence
of a heat sink or direct thermal attachment on the top of the device, additional calculations and considerations must be taken into
account. For more detailed information on thermal considerations, measurements, and calculations, see the Thermal Considerations for
TMS320DM64xx, TMS320DM64x, and TMS320C6000 Devices Application Report (literature number SPRAAL9).
(8) Applications must meet both the Operating Junction Temperature and Operating Ambient Temperature requirements. For more detailed
information on thermal considerations, measurements, and calculations, see the Thermal Considerations for TMS320DM64xx,
TMS320DM64x, and TMS320C6000 Devices Application Report (literature number SPRAAL9).
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5.3 Electrical Characteristics Over Recommended Ranges of Supply Voltage and Operating
Temperature (Unless Otherwise Noted)
(1)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX UNIT
High-level output voltage (3.3V I/O except
I2C pins)
VOH
DVDD33 = MIN, IOH = MAX
2.4
V
Low-level output voltage (3.3V I/O except
I2C pins)
DVDD33 = MIN, IOL = MAX
0.4
0.4
V
V
VOL
Low-level output voltage (3.3V I/O I2C pins) IO = 3 mA
0
VI = VSS to DVDD33 with internal pullup
resistor
50
100
250
µA
(3)
Input current [DC] (except I2C capable
pins)
II(2)
VI = VSS to DVDD33 with internal
pulldown resistor
–250
–100
–50
µA
µA
(3)
Input current [DC] (I2C)
VI = VSS to DVDD33
±10
CLK_OUT0/PWM2/GPIO[84] and
VLYNQ_CLOCK/GP[57]
-8 mA
IOH
High-level output current [DC]
DDR2
–13.4 mA
-4 mA
All other peripherals
CLK_OUT0/PWM2/GPIO[84] and
VLYNQ_CLOCK/GP[57]
8
mA
IOL
Low-level output current [DC]
I/O Off-state output current
DDR2
13.4 mA
All other peripherals
4
mA
µA
VO = DVDD33 or VSS; internal pull
disabled
50
(4)
IOZ
VO = DVDD33 or VSS; internal pull
enabled
±100
A
CVDD = 1.2 V, DSP clock = 600 MHz
CVDD = 1.2 V, DSP clock = 500 MHz
CVDD = 1.2 V, DSP clock = 400 MHz
CVDD = 1.05 V, DSP clock = 400 MHz
DVDD = 3.3 V, DSP clock = 600 MHz
DVDD = 3.3 V, DSP clock = 500 MHz
DVDD = 3.3 V, DSP clock = 400 MHz
524
460
392
341
13
mA
mA
mA
mA
mA
mA
mA
ICDD
Core (CVDD, VDDA_1P1V) supply current(5)
IDDD
3.3V I/O (DVDD33) supply current(5)
13
13
DVDD = 1.8 V, CVDD = 1.2 V, DSP clock
= 600 MHz
93
92
91
72
mA
mA
mA
mA
DVDD = 1.8 V, CVDD = 1.2 V, DSP clock
= 500 MHz
1.8V I/O (DVDDR2, DDR_VDDDLL,
PLLVPRW18, VDDA_1P8V, MXVDD) supply
current(5)
IDDD
DVDD = 1.8 V, CVDD = 1.2 V, DSP clock
= 400 MHz
DVDD = 1.8 V, CVDD = 1.05 V, DSP
clock = 400 MHz
CI
Input capacitance
Output capacitance
5
5
pF
pF
Co
(1) For test conditions shown as MIN, MAX, or NOM, use the appropriate value specified in the recommended operating conditions table.
(2) II applies to input-only pins and bi-directional pins. For input-only pins, II indicates the input leakage current. For bi-directional pins, II
indicates the input leakage current and off-state (Hi-Z) output leakage current.
(3) Applies only to pins with an internal pullup (IPU) or pulldown (IPD) resistor.
(4) IOZ applies to output-only pins, indicating off-state (Hi-Z) output leakage current.
(5) Measured under the following conditions: 60% DSP CPU utilization doing typical activity (peripheral configurations, other housekeeping
activities); DDR2 Memory Controller at 50% utilization (135 MHz), 50% writes, 32 bits, 50% bit switching; 2 MHz McBSP0 at 100%
utilization and 50% switching; Timer0 at 100% utilization. At room temperature (25 C) for typical process ZWT devices. The actual
current draw varies across manufacturing processes and is highly application-dependent. For more details on core and I/O activity, as
well as information relevant to board power supply design, see the TMS320DM643x Power Consumption Summary Application Report
(literature number SPRAAO6).
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6 Peripheral Information and Electrical Specifications
6.1 Parameter Information
Tester Pin Electronics
Data Sheet Timing Reference Point
42 Ω
3.5 nH
Output
Under
Test
Transmission Line
Z0 = 50 Ω
(see Note)
Device Pin
(see Note)
4.0 pF
1.85 pF
NOTE: The data sheet provides timing at the device pin. For output timing analysis, the tester pin electronics and its transmission line effects must
be taken into account. A transmission line with a delay of 2 ns can be used to produce the desired transmission line effect. The transmission
line is intended as a load only. It is not necessary to add or subtract the transmission line delay (2 ns) from the data sheet timings.
Input requirements in this data sheet are tested with an input slew rate of < 4 Volts per nanosecond (4 V/ns) at the device pin.
Figure 6-1. Test Load Circuit for AC Timing Measurements
The load capacitance value stated is only for characterization and measurement of AC timing signals. This
load capacitance value does not indicate the maximum load the device is capable of driving.
6.1.1 3.3-V Signal Transition Levels
All input and output timing parameters are referenced to Vref for both "0" and "1" logic levels. For 3.3 V I/O,
Vref = 1.5 V. For 1.8 V I/O, Vref = 0.9 V.
V
ref
Figure 6-2. Input and Output Voltage Reference Levels for AC Timing Measurements
All rise and fall transition timing parameters are referenced to VIL MAX and VIH MIN for input clocks,
VOLMAX and VOH MIN for output clocks.
V
ref
= V MIN (or V MIN)
IH OH
V
ref
= V MAX (or V MAX)
IL OL
Figure 6-3. Rise and Fall Transition Time Voltage Reference Levels
6.1.2 3.3-V Signal Transition Rates
All timings are tested with an input edge rate of 4 volts per nanosecond (4 V/ns).
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6.1.3 Timing Parameters and Board Routing Analysis
The timing parameter values specified in this data sheet do not include delays by board routings. As a
good board design practice, such delays must always be taken into account. Timing values may be
adjusted by increasing/decreasing such delays. TI recommends utilizing the available I/O buffer
information specification (IBIS) models to analyze the timing characteristics correctly. To properly use IBIS
models to attain accurate timing analysis for a given system, see the Using IBIS Models for Timing
Analysis application report (literature number SPRA839). If needed, external logic hardware such as
buffers may be used to compensate any timing differences.
For the DDR2 memory controller interface, it is not necessary to use the IBIS models to analyze timing
characteristics. TI provides a PCB routing rules solution that describes the routing rules to ensure the
DDR2 memory controller interface timings are met. See the Implementing DDR2 PCB Layout on the
TMS320DM643x DMP DMSoC Application Report (literature number SPRAAL6).
6.2 Recommended Clock and Control Signal Transition Behavior
All clocks and control signals must transition between VIH and VIL (or between VIL and VIH) in a monotonic
manner.
6.3 Power Supplies
For more information regarding TI's power management products and suggested devices to power TI
DSPs, visit www.ti.com/dsppower.
6.3.1 Power-Supply Sequencing
The DM6435 includes one core supply (CVDD), and two I/O supplies—DVDD33 and DVDDR2. To ensure
proper device operation, a specific power-up sequence must be followed. Some TI power-supply devices
include features that facilitate power sequencing—for example, Auto-Track and Slow-Start/Enable
features. For more information on TI power supplies and their features, visit www.ti.com/dsppower.
Here is a summary of the power sequencing requirements:
•
The power ramp order must be DVDD33 before DVDDR2, and DVDDR2 before CVDD—meaning during
power up, the voltage at the DVDDR2 rail should never exceed the voltage at the DVDD33 rail. Similarly,
the voltage at the CVDD rail should never exceed the voltage at the DVDDR2 rail.
•
From the time that power ramp begins, all power supplies (DVDD33, DVDDR2, CVDD) must be stable
within 200 ms. The term "stable" means reaching the recommended operating condition (see
Section 5.2, Recommended Operating Conditions table).
6.3.2 Power-Supply Design Considerations
Core and I/O supply voltage regulators should be located close to the DSP to minimize inductance and
resistance in the power delivery path. Additionally, when designing for high-performance applications
utilizing the DM6435 device, the PC board should include separate power planes for core, I/O, and
ground; all bypassed with high-quality low-ESL/ESR capacitors.
6.3.3 Power-Supply Decoupling
In order to properly decouple the supply planes from system noise, place as many capacitors (caps) as
possible close to the DSP. These caps need to be close to the DSP, no more than 1.25 cm maximum
distance to be effective. Physically smaller caps are better, such as 0402, but need to be evaluated from a
yield/manufacturing point-of-view. Parasitic inductance limits the effectiveness of the decoupling
capacitors, therefore physically smaller capacitors should be used while maintaining the largest available
capacitance value.
Larger caps for each supply can be placed further away for bulk decoupling. Large bulk caps (on the order
of 100 µF) should be furthest away, but still as close as possible. Large caps for each supply should be
placed outside of the BGA footprint.
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As with the selection of any component, verification of capacitor availability over the product's production
lifetime should be considered.
For more details on capacitor usage and placement, see the Implementing DDR2 PCB Layout on the
TMS320DM643x DMP DMSoC Application Report (literature number SPRAAL6).
6.3.4 DM6435 Power and Clock Domains
The DM6435 includes one single power domain — the "Always On" power domain. The "Always On"
power domain is always on when the chip is on. The "Always On" domain is powered by the CVDD pins of
the DM6435. All DM6435 modules lie within the "Always On" power domain. Table 6-1 provides a listing of
the DM6435 clock domains.
One primary reference clock is required for the DM6435 device. The can be either a crystal input or driven
by external oscillators. A 27-MHz crystal is recommended for the system PLLs, which generate the
internal clocks for the digital media processor, coprocessors, peripherals (including imaging peripherals),
and the EDMA3. For further description of the DM6435 clock domains, see Table 6-3 and Figure 6-4.
Table 6-1. DM6435 Power and Clock Domains
Power Domain
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Always On
Clock Domain
CLKIN
Peripheral/Module
UART0
UART1
HECC
CLKIN
CLKIN
CLKIN
I2C
CLKIN
Timer0
Timer1
Timer2
PWM0
PWM1
PWM2
DDR2
CLKIN
CLKIN
CLKIN
CLKIN
CLKIN
CLKDIV3
CLKDIV3
CLKDIV3
CLKDIV3
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV6
CLKDIV1
VPSS
EDMA
SCR
GPSC
LPSCs
PLLC1
PLLC2
Ice Pick
EMIFA
HPI
VLYNQ
EMAC
McASP0
McBSP0
GPIO
C64x+ CPU
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Table 6-2. DM6435 Clock Domains
DOMAIN CLOCK
SOURCE
FIXED RATIO vs.
SYSCLK1 FREQUENCY
EXAMPLE
FREQUENCY (MHz)
SUBSYSTEM
CLOCK DOMAIN
Peripherals (CLKIN Domain)
DSP Subsystem
CLKIN
PLLC1 AUXCLK(1)
PLLC1 SYSCLK1
PLLC1 SYSCLK2
PLLC1 SYSCLK2
PLLC1 SYSCLK2
PLLC1 SYSCLK3
–
27 MHz
594 MHz
198 MHz
198 MHz
198 MHz
99 MHz
CLKDIV1
CLKDIV3
CLKDIV3
CLKDIV3
CLKDIV6
1:1
1:3
1:3
1:3
1:6
EDMA3
VPSS
Peripherals (CLKDIV3 Domain)
Peripherals (CLKDIV6 Domain)
(1) PLLC1 AUXCLK runs at exactly the same frequency as the device clock source from the MXI/CLKIN pin.
The CLKDIV1:CLKDIV3:CLKDIV6 ratio must be strictly followed by programming the PLL Controller 1
(PLLC1) PLLDIV1, PLLDIV2, and PLLDIV3 registers appropriately (see Table 6-3).
Table 6-3. PLLC1 Programming for CLKDIV1, CLKDIV3, CLKDIV6 Domains
CLKDIV1 DOMAIN
(SYSCLK1)
CLKDIV3 DOMAIN
(SYSCLK2)
CLKDIV6 DOMAIN
(SYSCLK3)
PLL1
Divide-Down
PLL1
Divide-Down
PLL1
Divide-Down
PLLDIV1.RATIO
PLLDIV2.RATIO
PLLDIV3.RATIO
DIV1
DIV2
DIV3
/1
/2
/3
0
1
2
/3
/6
/9
2
5
8
/6
5
/12
/18
11
17
HECC
UARTs (x2)
I2C
MXI/CLKIN
(27 MHz)
AUXCLK
PWMs (x3)
Timers (x3)
OBSCLK
(CLKOUT0 Pin)
OSCDIV1 (/1)
PLLDIV1 (/1)
PLLDIV3 (/6)
PLLDIV2 (/3)
PLL Controller 1
SYSCLK1
DSP Subsystem
SYSCLK3
SYSCLK2
HPI
SCR
VLYNQ
EMAC
EDMA
EMIFA
McASP0
McBSP0
GPIO
VPFE
PCLK
PLLDIV1 (/2)
DDR2 PHY
DDR2 VTP
BPDIV
DDR2 Mem Ctlr
PLL Controller 2
Figure 6-4. PLL1 and PLL2 Clock Domain Block Diagram
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For further detail on PLL1 and PLL2, see the structure block diagrams Figure 6-5 and Figure 6-6,
respectively.
CLKMODE
PLLEN
PLLOUT
CLKIN
1
0
SYSCLK1
(CLKDIV1 Domain)
PLLDIV1 (/1)
PLLDIV2 (/3)
PLLDIV3 (/6)
PLL
1
0
OSCIN
SYSCLK2
(CLKDIV3 Domain)
PLLM
SYSCLK3
(CLKDIV6 Domain)
AUXCLK
(CLKIN Domain)
OBSCLK
(CLKOUT0 Pin)
OSCDIV1
Figure 6-5. PLL1 Structure Block Diagram
CLKMODE
PLLEN
PLLOUT
CLKIN
OSCIN
1
0
PLL
1
0
PLL2_SYSCLK1
(DDR2 PHY)
PLLDIV1 (/2)
PLLM
PLL2_SYSCLKBP
(DDR2 VTP)
BPDIV
Figure 6-6. PLL2 Structure Block Diagram
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6.3.5 Power and Sleep Controller (PSC)
The Power and Sleep Controller (PSC) controls power by turning off unused power domains or by gating
off clocks to individual peripherals/modules. The DM6435 device only utilizes the clock gating feature of
the PSC for power savings. The PSC consists of a Global PSC (GPSC) and a set of Local PSCs (LPSCs).
The GPSC contains memory mapped registers, PSC interrupt control, and a state machine for each
peripheral/module. An LPSC is associated with each peripheral/module and provides clock and reset
control. The LPSCs for DM6435 are shown in Table 6-4. The PSC Register memory map is given in
Table 6-5. For more details on the PSC, see the TMS320DM643x DMP DSP Subsystem Reference Guide
(literature number SPRU978).
Table 6-4. DM6435 LPSC Assignments
LPSC
Peripheral/Module
LPSC
Peripheral/Module
LPSC
Peripheral/Module
Number
Number
Number
0
VPSS DMA
VPSS MMR
EDMACC
14
15
16
17
18
19
EMIFA
Reserved
McBSP0
Reserved
I2C
28
29
30
31
32
33
34
35
36
37
38
39
40
TIMER1
1
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
C64x+ CPU
Reserved
2
3
EDMATC0
EDMATC1
EDMATC2
4
5
UART0
UART1
Reserved
HECC
6
EMAC Memory Controller 20
7
MDIO
21
22
23
24
25
26
27
8
EMAC
9
McASP0
PWM0
PWM1
PWM2
GPIO
10
11
12
13
Reserved
VLYNQ
HPI
DDR2 Memory Controller
TIMER0
Table 6-5. PSC Register Memory Map
REGISTER
ACRONYM
HEX ADDRESS RANGE
0x01C4 1000
DESCRIPTION
PID
Peripheral Revision and Class Information Register
Reserved
0x01C4 1004 - 0x01C4 100F
0x01C4 1010
-
GBLCTL
Global Control Register
Reserved
0x01C4 1014
-
0x01C4 1018
INTEVAL
Interrupt Evaluation Register
Reserved
0x01C4 101C - 0x01C4 103F
0x01C4 1040
-
MERRPR0
Module Error Pending 0 (mod 0 - 31) Register
Module Error Pending 1 (mod 32- 63) Register
Reserved
0x01C4 1044
MERRPR1
0x01C4 1048 - 0x01C4 104F
0x01C4 1050
-
MERRCR0
Module Error Clear 0 (mod 0 - 31) Register
Module Error Clear 1 (mod 32 - 63) Register
Reserved
0x01C4 1054
MERRCR1
0x01C4 1058 - 0x01C4 105F
0x01C4 1060
-
PERRPR
Power Error Pending Register
Reserved
0x01C4 1064 - 0x01C4 1067
0x01C4 1068
-
PERRCR
Power Error Clear Register
Reserved
0x01C4 106C - 0x01C4 111F
0x01C4 1120
-
PTCMD
-
Power Domain Transition Command Register
Reserved
0x01C4 1124 - 0x01C4 1127
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Table 6-5. PSC Register Memory Map (continued)
REGISTER
ACRONYM
HEX ADDRESS RANGE
0x01C4 1128
DESCRIPTION
PTSTAT
-
Power Domain Transition Status Register
0x01C4 112C - 0x01C4 11FF
0x01C4 1200
Reserved
PDSTAT0
-
Power Domain Status 0 Register (Always On)
Reserved
0x01C4 1204 - 0x01C4 12FF
0x01C4 1300
PDCTL0
-
Power Domain Control 0 Register (Always On)
Reserved
0x01C4 1304 - 0x1C4 150F
0x01C4 1510
MCKOUT0
MCKOUT1
-
Module Clock Output Status (mod 0-31) Register
Module Clock Output Status (mod 32-63) Register
Reserved
0x01C4 1514
0x01C4 1518 - 0x01C4 15FF
0x01C4 1600 - 0x01C4 17FF
0x01C4 1800
-
Reserved
MDSTAT0
MDSTAT1
MDSTAT2
MDSTAT3
MDSTAT4
MDSTAT5
MDSTAT6
MDSTAT7
MDSTAT8
MDSTAT9
-
Module Status 0 Register (VPSS DMA)
Module Status 1 Register (VPSS MMR)
Module Status 2 Register (EDMACC)
Module Status 3 Register (EDMATC0)
Module Status 4 Register (EDMATC1)
Module Status 5 Register (EMACTC2)
Module Status 6 Register (EMAC Memory Controller)
Module Status 7 Register (MDIO)
Module Status 8 Register (EMAC)
Module Status 9 Register (McASP0)
Reserved
0x01C4 1804
0x01C4 1808
0x01C4 180C
0x01C4 1810
0x01C4 1814
0x01C4 1818
0x01C4 181C
0x01C4 1820
0x01C4 1824
0x01C4 1828
0x01C4 182C
MDSTAT11
MDSTAT12
MDSTAT13
MDSTAT14
-
Module Status 11 Register (VLYNQ)
Module Status 12 Register (HPI)
Module Status 13 Register (DDR2)
Module Status 14 Register (EMIFA)
Reserved
0x01C4 1830
0x01C4 1834
0x01C4 1838
0x01C4 183C
0x01C4 1840
MDSTAT16
-
Module Status 16 Register (McBSP0)
Reserved
0x01C4 1844
0x01C4 1848
MDSTAT18
MDSTAT19
MDSTAT20
-
Module Status 18 Register (I2C)
Module Status 19 Register (UART0)
Module Status 20 Register (UART1)
Reserved
0x01C4 184C
0x01C4 1850
0x01C4 1854
0x01C4 1858
MDSTAT22
MDSTAT23
MDSTAT24
MDSTAT25
MDSTAT26
MDSTAT27
MDSTAT28
-
Module Status 22 Register (HECC)
Module Status 23 Register (PWM0)
Module Status 24 Register (PWM1)
Module Status 25 Register (PWM2)
Module Status 26 Register (GPIO)
Module Status 27 Register (TIMER0)
Module Status 28 Register (TIMER1)
Reserved
0x01C4 185C
0x01C4 1860
0x01C4 1864
0x01C4 1868
0x01C4 186C
0x01C4 1870
0x01C4 1874 - 0x01C4 189B
0x01C4 189C
MDSTAT39
-
Module Status 39 Register (C64x+ CPU)
Reserved
0x01C4 18A0
0x01C4 18A4 - 0x01C4 19FF
0x01C4 1A00
-
Reserved
MDCTL0
MDCTL1
MDCTL2
Module Control 0 Register (VPSS DMA)
Module Control 1 Register (VPSS MMR)
Module Control 2 Register (EDMACC)
0x01C4 1A04
0x01C4 1A08
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Table 6-5. PSC Register Memory Map (continued)
REGISTER
ACRONYM
HEX ADDRESS RANGE
DESCRIPTION
0x01C4 1A0C
MDCTL3
MDCTL4
MDCTL5
MDCTL6
MDCTL7
MDCTL8
MDCTL9
-
Module Control 3 Register (EDMATC0)
0x01C4 1A10
0x01C4 1A14
0x01C4 1A18
0x01C4 1A1C
0x01C4 1A20
0x01C4 1A24
0x01C4 1A28
0x01C4 1A2C
0x01C4 1A30
0x01C4 1A34
0x01C4 1A38
0x01C4 1A3C
0x01C4 1A40
0x01C4 1A44
0x01C4 1A48
0x01C4 1A4C
0x01C4 1A50
0x01C4 1A54
0x01C4 1A58
0x01C4 1A5C
0x01C4 1A60
0x01C4 1A64
0x01C4 1A68
0x01C4 1A6C
0x01C4 1A70
0x01C4 1A74 - 0x01C4 1A9B
0x01C4 1A9C
0x01C4 1AA0
0x01C4 1AA4 - 0x01C4 1FFF
Module Control 4 Register (EDMATC1)
Module Control 5 Register (EMACTC2)
Module Control 6 Register (EMAC Memory Controller)
Module Control 7 Register (MDIO)
Module Control 8 Register (EMAC)
Module Control 9 Register (McASP0)
Reserved
MDCTL11
MDCTL12
MDCTL13
MDCTL14
-
Module Control 11 Register (VLYNQ)
Module Control 12 Register (HPI)
Module Control 13 Register (DDR2)
Module Control 14 Register (EMIFA)
Reserved
MDCTL16
-
Module Control 16 Register (McBSP0)
Reserved
MDCTL18
MDCTL19
MDCTL20
-
Module Control 18 Register (I2C)
Module Control 19 Register (UART0)
Module Control 20 Register (UART1)
Reserved
MDCTL22
MDCTL23
MDCTL24
MDCTL25
MDCTL26
MDCTL27
MDCTL28
-
Module Control 22 Register (HECC)
Module Control 23 Register (PWM0)
Module Control 24 Register (PWM1)
Module Control 25 Register (PWM2)
Module Control 26 Register (GPIO)
Module Control 27 Register (TIMER0)
Module Control 28 Register (TIMER1)
Reserved
MDCTL39
-
Module Control 39 Register (C64x+ CPU)
Reserved
-
Reserved
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6.4 Enhanced Direct Memory Access (EDMA3) Controller
The EDMA controller handles all data transfers between memories and the device slave peripherals on
the DM6435 device. These data transfers include cache servicing, non-cacheable memory accesses,
user-programmed data transfers, and host accesses. These are summarized as follows:
•
Transfer to/from on-chip memories
–
–
DSP L1D memory
DSP L2 memory
•
Transfer to/from external storage
–
–
–
DDR2 SDRAM
NAND flash
Asynchronous EMIF (EMIFA)
•
Transfer to/from peripherals/hosts
–
–
–
–
–
–
–
VLYNQ
HPI
McBSP0
McASP0
PWM
UART0/1
HECC
The EDMA supports two addressing modes: constant addressing and increment addressing. On the
DM6435, constant addressing mode is not supported by any peripheral or internal memory. For more
information on these two addressing modes, see the TMS320DM643x DMP Enhanced Direct Memory
Access (EDMA3) Controller User’s Guide (literature number SPRU987).
6.4.1 EDMA3 Channel Synchronization Events
The EDMA supports up to 64 EDMA channels which service peripheral devices and external memory.
Table 6-6 lists the source of EDMA synchronization events associated with each of the programmable
EDMA channels. For the DM6435 device, the association of an event to a channel is fixed; each of the
EDMA channels has one specific event associated with it. These specific events are captured in the
EDMA event registers (ER, ERH) even if the events are disabled by the EDMA event enable registers
(EER, EERH). For more detailed information on the EDMA module and how EDMA events are enabled,
captured, processed, linked, chained, and cleared, etc., see the TMS320DM643x DMP Enhanced Direct
Memory Access (EDMA3) Controller User’s Guide (literature number SPRU987).
Table 6-6. DM6435 EDMA Channel Synchronization Events(1)
EDMA
CHANNEL
EVENT NAME
EVENT DESCRIPTION
0-1
2
–
Reserved
McBSP0 Transmit Event
McBSP0 Receive Event
Reserved
XEVT0
REVT0
–
3
4
5
–
Reserved
6
HISTEVT
H3AEVT
PRVUEVT
RSZEVT
AXEVTE0
VPSS Histogram Event
VPSS H3A Event
7
8
VPSS Previewer Event
VPSS Resizer Event
McASP0 Transmit Event Even
9
10
(1) In addition to the events shown in this table, each of the 64 channels can also be synchronized with the transfer completion or alternate
transfer completion events. For more detailed information on EDMA event-transfer chaining, see the Document Support section for the
Enhanced Direct Memory Access (EDMA) Controller Reference Guide.
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Table 6-6. DM6435 EDMA Channel Synchronization Events (continued)
EDMA
CHANNEL
EVENT NAME
EVENT DESCRIPTION
11
12
AXEVTO0
AXEVT0
AREVTE0
AREVTO0
AREVT0
–
McASP0 Transmit Event Odd
McASP0 Transmit Event
McASP0 Receive Event Even
McASP0 Receive Event Odd
McASP0 Receive Event
Reserved
13
14
15
16-21
22
URXEVT0
UTXEVT0
URXEVT1
UTXEVT1
–
UART 0 Receive Event
UART 0 Transmit Event
UART 1 Receive Event
UART 1 Transmit Event
Reserved
23
24
25
26
27
–
Reserved
28
ICREVT
ICXEVT
–
I2C Receive Event
I2C Transmit Event
Reserved
29
30-31
32
GPINT0
GPINT1
GPINT2
GPINT3
GPINT4
GPINT5
GPINT6
GPINT7
GPBNKINT0
GPBNKINT1
GPBNKINT2
GPBNKINT3
GPBNKINT4
GPBNKINT5
GPBNKINT6
–
GPIO 0 Interrupt
33
GPIO 1 Interrupt
34
GPIO 2 Interrupt
35
GPIO 3 Interrupt
36
GPIO 4 Interrupt
37
GPIO 5 Interrupt
38
GPIO 6 Interrupt
39
GPIO 7 Interrupt
40
GPIO Bank 0 Interrupt
GPIO Bank 1 Interrupt
GPIO Bank 2 Interrupt
GPIO Bank 3 Interrupt
GPIO Bank 4 Interrupt
GPIO Bank 5 Interrupt
GPIO Bank 6 Interrupt
Reserved
41
42
43
44
45
46
47
48
TEVTL0
TEVTH0
TEVTL1
TEVTH1
PWM0
Timer 0 Event Low Interrupt
Timer 0 Event High Interrupt
Timer 1 Event Low Interrupt
Timer 1 Evemt High Interrupt
PWM 0 Event
49
50
51
52
53
PWM1
PWM 1 Event
54
PWM2
PWM 2 Event
55-63
–
Reserved
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6.4.2 EDMA Peripheral Register Description(s)
Table 6-7 lists the EDMA registers, their corresponding acronyms, and DM6435 device memory locations.
Table 6-7. DM6435 EDMA Registers
HEX ADDRESS
ACRONYM
Channel Controller Registers
Reserved
REGISTER NAME
0x01C0 0000 - 0x01C0 0003
0x01C0 0004
CCCFG
EDMA3CC Configuration Register
Reserved
0x01C0 0008 - 0x01C0 01FF
Global Registers
0x01C0 0200
0x01C0 0204
QCHMAP0
QCHMAP1
QCHMAP2
QCHMAP3
QCHMAP4
QCHMAP5
QCHMAP6
QCHMAP7
DMAQNUM0
DMAQNUM1
DMAQNUM2
DMAQNUM3
DMAQNUM4
DMAQNUM5
DMAQNUM6
DMAQNUM7
QDMAQNUM
–
QDMA Channel 0 Mapping to PaRAM Register
QDMA Channel 1 Mapping to PaRAM Register
QDMA Channel 2 Mapping to PaRAM Register
QDMA Channel 3 Mapping to PaRAM Register
QDMA Channel 4 Mapping to PaRAM Register
QDMA Channel 5 Mapping to PaRAM Register
QDMA Channel 6 Mapping to PaRAM Register
QDMA Channel 7 Mapping to PaRAM Register
DMA Queue Number Register 0 (Channels 00 to 07)
DMA Queue Number Register 1 (Channels 08 to 15)
DMA Queue Number Register 2 (Channels 16 to 23)
DMA Queue Number Register 3 (Channels 24 to 31)
DMA Queue Number Register 4 (Channels 32 to 39)
DMA Queue Number Register 5 (Channels 40 to 47)
DMA Queue Number Register 6 (Channels 48 to 55)
DMA Queue Number Register 7 (Channels 56 to 63)
CC QDMA Queue Number
0x01C0 0208
0x01C0 020C
0x01C0 0210
0x01C0 0214
0x01C0 0218
0x01C0 021C
0x01C0 0240
0x01C0 0244
0x01C0 0248
0x01C0 024C
0x01C0 0250
0x01C0 0254
0x01C0 0258
0x01C0 025C
0x01C0 0260
0x01C0 0264 - 0x01C0 0283
0x01C0 0284
Reserved
QUEPRI
–
Queue Priority Register
0x01C0 0288 - 0x01C0 02FF
0x01C0 0300
Reserved
EMR
Event Missed Register
0x01C0 0304
EMRH
Event Missed Register High
0x01C0 0308
EMCR
Event Missed Clear Register
0x01C0 030C
0x01C0 0310
EMCRH
QEMR
Event Missed Clear Register High
QDMA Event Missed Register
0x01C0 0314
QEMCR
CCERR
CCERRCLR
EEVAL
QDMA Event Missed Clear Register
EDMA3CC Error Register
0x01C0 0318
0x01C0 031C
0x01C0 0320
EDMA3CC Error Clear Register
Error Evaluate Register
0x01C0 0340
DRAE0
DMA Region Access Enable Register for Region 0
DMA Region Access Enable Register High for Region 0
DMA Region Access Enable Register for Region 1
DMA Region Access Enable Register High for Region 1
Reserved
0x01C0 0344
DRAEH0
DRAE1
0x01C0 0348
0x01C0 034C
0x01C0 0350
DRAEH1
–
0x01C0 0354
–
Reserved
0x01C0 0358
–
Reserved
0x01C0 035C
0x01C0 0360 - 0x01C0 037C
0x01C0 0380
–
Reserved
–
Reserved
QRAE0
QDMA Region Access Enable Register for Region 0
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
ACRONYM
QRAE1
–
REGISTER NAME
QDMA Region Access Enable Register for Region 1
Reserved
0x01C0 0384
0x01C0 0388
0x01C0 038C
0x01C0 0390 - 0x01C0 039C
0x01C0 0400
0x01C0 0404
0x01C0 0408
0x01C0 040C
0x01C0 0410
0x01C0 0414
0x01C0 0418
0x01C0 041C
0x01C0 0420
0x01C0 0424
0x01C0 0428
0x01C0 042C
0x01C0 0430
0x01C0 0434
0x01C0 0438
0x01C0 043C
0x01C0 0440
0x01C0 0444
0x01C0 0448
0x01C0 044C
0x01C0 0450
0x01C0 0454
0x01C0 0458
0x01C0 045C
0x01C0 0460
0x01C0 0464
0x01C0 0468
0x01C0 046C
0x01C0 0470
0x01C0 0474
0x01C0 0478
0x01C0 047C
0x01C0 0480
0x01C0 0484
0x01C0 0488
0x01C0 048C
0x01C0 0490
0x01C0 0494
0x01C0 0498
0x01C0 049C
0x01C0 04A0
0x01C0 04A4
0x01C0 04A8
–
Reserved
–
Reserved
Q0E0
Q0E1
Q0E2
Q0E3
Q0E4
Q0E5
Q0E6
Q0E7
Q0E8
Q0E9
Q0E10
Q0E11
Q0E12
Q0E13
Q0E14
Q0E15
Q1E0
Q1E1
Q1E2
Q1E3
Q1E4
Q1E5
Q1E6
Q1E7
Q1E8
Q1E9
Q1E10
Q1E11
Q1E12
Q1E13
Q1E14
Q1E15
Q2E0
Q2E1
Q2E2
Q2E3
Q2E4
Q2E5
Q2E6
Q2E7
Q2E8
Q2E9
Q2E10
Event Q0 Entry 0 Register
Event Q0 Entry 1 Register
Event Q0 Entry 2 Register
Event Q0 Entry 3 Register
Event Q0 Entry 4 Register
Event Q0 Entry 5 Register
Event Q0 Entry 6 Register
Event Q0 Entry 7 Register
Event Q0 Entry 8 Register
Event Q0 Entry 9 Register
Event Q0 Entry 10 Register
Event Q0 Entry 11 Register
Event Q0 Entry 12 Register
Event Q0 Entry 13 Register
Event Q0 Entry 14 Register
Event Q0 Entry 15 Register
Event Q1 Entry 0 Register
Event Q1 Entry 1 Register
Event Q1 Entry 2 Register
Event Q1 Entry 3 Register
Event Q1 Entry 4 Register
Event Q1 Entry 5 Register
Event Q1 Entry 6 Register
Event Q1 Entry 7 Register
Event Q1 Entry 8 Register
Event Q1 Entry 9 Register
Event Q1 Entry 10 Register
Event Q1 Entry 11 Register
Event Q1 Entry 12 Register
Event Q1 Entry 13 Register
Event Q1 Entry 14 Register
Event Q1 Entry 15 Register
Event Q2 Entry 0 Register
Event Q2 Entry 1 Register
Event Q2 Entry 2 Register
Event Q2 Entry 3 Register
Event Q2 Entry 4 Register
Event Q2 Entry 5 Register
Event Q2 Entry 6 Register
Event Q2 Entry 7 Register
Event Q2 Entry 8 Register
Event Q2 Entry 9 Register
Event Q2 Entry 10 Register
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
0x01C0 04AC
ACRONYM
Q2E11
REGISTER NAME
Event Q2 Entry 11 Register
Event Q2 Entry 12 Register
Event Q2 Entry 13 Register
Event Q2 Entry 14 Register
Event Q2 Entry 15 Register
Reserved
0x01C0 04B0
Q2E12
0x01C0 04B4
Q2E13
0x01C0 04B8
Q2E14
0x01C0 04BC
Q2E15
0x01C0 04C0 - 0x01C0 05FF
0x01C0 0600
QSTAT0
QSTAT1
QSTAT2
Queue 0 Status Register
Queue 1 Status Register
Queue 2 Status Register
Reserved
0x01C0 0604
0x01C0 0608
0x01C0 060C - 0x01C0 061F
0x01C0 0620
QWMTHRA
–
Queue Watermark Threshold A Register for Q[2:0]
0x01C0 0624
Reserved
0x01C0 0640
CCSTAT
EDMA3CC Status Register
Reserved
0x01C0 0644 - 0x01C0 0FFF
Global Channel Registers
0x01C0 1000
0x01C0 1004
0x01C0 1008
0x01C0 100C
0x01C0 1010
0x01C0 1014
0x01C0 1018
0x01C0 101C
0x01C0 1020
0x01C0 1024
0x01C0 1028
0x01C0 102C
0x01C0 1030
0x01C0 1034
0x01C0 1038
0x01C0 103C
0x01C0 1040
0x01C0 1044
0x01C0 1048 - 0x01C0 104F
0x01C0 1050
0x01C0 1054
0x01C0 1058
0x01C0 105C
0x01C0 1060
0x01C0 1064
0x01C0 1068
0x01C0 106C
0x01C0 1070
0x01C0 1074
0x01C0 1078
0x01C0 1080
0x01C0 1084
ER
ERH
Event Register
Event Register High
ECR
Event Clear Register
ECRH
ESR
Event Clear Register High
Event Set Register
ESRH
CER
Event Set Register High
Chained Event Register
CERH
EER
Chained Event Register High
Event Enable Register
EERH
EECR
EECRH
EESR
EESRH
SER
Event Enable Register High
Event Enable Clear Register
Event Enable Clear Register High
Event Enable Set Register
Event Enable Set Register High
Secondary Event Register
Secondary Event Register High
Secondary Event Clear Register
Secondary Event Clear Register High
Reserved
SERH
SECR
SECRH
IER
IERH
IECR
IECRH
IESR
IESRH
IPR
Interrupt Enable Register
Interrupt Enable Register High
Interrupt Enable Clear Register
Interrupt Enable Clear Register High
Interrupt Enable Set Register
Interrupt Enable Set Register High
Interrupt Pending Register
Interrupt Pending Register High
Interrupt Clear Register
IPRH
ICR
ICRH
IEVAL
QER
Interrupt Clear Register High
Interrupt Evaluate Register
QDMA Event Register
QEER
QDMA Event Enable Register
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
ACRONYM
QEECR
QEESR
QSER
REGISTER NAME
QDMA Event Enable Clear Register
0x01C0 1088
0x01C0 108C
QDMA Event Enable Set Register
QDMA Secondary Event Register
QDMA Secondary Event Clear Register
Reserved
0x01C0 1090
0x01C0 1094
QSECR
0x01C0 1098 - 0x01C0 1FFF
Shadow Region 0 Channel Registers
0x01C0 2000
0x01C0 2004
0x01C0 2008
0x01C0 200C
0x01C0 2010
0x01C0 2014
0x01C0 2018
0x01C0 201C
0x01C0 2020
0x01C0 2024
0x01C0 2028
0x01C0 202C
0x01C0 2030
0x01C0 2034
0x01C0 2038
0x01C0 203C
0x01C0 2040
0x01C0 2044
0x01C0 2048 - 0x01C0 204C
0x01C0 2050
0x01C0 2054
0x01C0 2058
0x01C0 205C
0x01C0 2060
0x01C0 2064
0x01C0 2068
0x01C0 206C
0x01C0 2070
0x01C0 2074
0x01C0 2078
0x01C0 207C
0x01C0 2080
0x01C0 2084
0x01C0 2088
0x01C0 208C
0x01C0 2090
0x01C0 2094
0x01C0 2098 - 0x01C0 21FC
ER
ERH
Event Register
Event Register High
ECR
Event Clear Register
ECRH
ESR
Event Clear Register High
Event Set Register
ESRH
CER
Event Set Register High
Chained Event Register
CERH
EER
Chained Event Register High
Event Enable Register
EERH
EECR
EECRH
EESR
EESRH
SER
Event Enable Register High
Event Enable Clear Register
Event Enable Clear Register High
Event Enable Set Register
Event Enable Set Register High
Secondary Event Register
Secondary Event Register High
Secondary Event Clear Register
Secondary Event Clear Register High
Reserved
SERH
SECR
SECRH
-
IER
Interrupt Enable Register
Interrupt Enable Register High
Interrupt Enable Clear Register
Interrupt Enable Clear Register High
Interrupt Enable Set Register
Interrupt Enable Set Register High
Interrupt Pending Register
Interrupt Pending Register High
Interrupt Clear Register
IERH
IECR
IECRH
IESR
IESRH
IPR
IPRH
ICR
ICRH
IEVAL
-
Interrupt Clear Register High
Interrupt Evaluate Register
Reserved
QER
QDMA Event Register
QEER
QEECR
QEESR
QSER
QSECR
-
QDMA Event Enable Register
QDMA Event Enable Clear Register
QDMA Event Enable Set Register
QDMA Secondary Event Register
QDMA Secondary Event Clear Register
Reserved
Shadow Region 1 Channel Registers
0x01C0 2200
0x01C0 2204
ER
Event Register
ERH
Event Register High
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
0x01C0 2208
ACRONYM
ECR
ECRH
ESR
ESRH
CER
CERH
EER
EERH
EECR
EECRH
EESR
EESRH
SER
SERH
SECR
SECRH
-
REGISTER NAME
Event Clear Register
Event Clear Register High
Event Set Register
0x01C0 220C
0x01C0 2210
0x01C0 2214
Event Set Register High
Chained Event Register
0x01C0 2218
0x01C0 221C
Chained Event Register High
Event Enable Register
Event Enable Register High
Event Enable Clear Register
Event Enable Clear Register High
Event Enable Set Register
Event Enable Set Register High
Secondary Event Register
Secondary Event Register High
Secondary Event Clear Register
Secondary Event Clear Register High
Reserved
0x01C0 2220
0x01C0 2224
0x01C0 2228
0x01C0 222C
0x01C0 2230
0x01C0 2234
0x01C0 2238
0x01C0 223C
0x01C0 2240
0x01C0 2244
0x01C0 2248 - 0x01C0 224C
0x01C0 2250
IER
Interrupt Enable Register
Interrupt Enable Register High
Interrupt Enable Clear Register
Interrupt Enable Clear Register High
Interrupt Enable Set Register
Interrupt Enable Set Register High
Interrupt Pending Register
Interrupt Pending Register High
Interrupt Clear Register
Interrupt Clear Register High
Interrupt Evaluate Register
Reserved
0x01C0 2254
IERH
IECR
IECRH
IESR
IESRH
IPR
0x01C0 2258
0x01C0 225C
0x01C0 2260
0x01C0 2264
0x01C0 2268
0x01C0 226C
IPRH
ICR
0x01C0 2270
0x01C0 2274
ICRH
IEVAL
-
0x01C0 2278
0x01C0 227C
0x01C0 2280
QER
QEER
QEECR
QEESR
QSER
QSECR
-
QDMA Event Register
QDMA Event Enable Register
QDMA Event Enable Clear Register
QDMA Event Enable Set Register
QDMA Secondary Event Register
QDMA Secondary Event Clear Register
Reserved
0x01C0 2284
0x01C0 2288
0x01C0 228C
0x01C0 2290
0x01C0 2294
0x01C0 2298 - 0x01C0 23FC
0x01C0 2400 - 0x01C0 25FC
0x01C0 2600 - 0x01C0 27FC
0x01C0 2800 - 0x01C0 29FC
0x01C0 2A00 - 0x01C0 2BFC
0x01C0 2C00 - 0x01C0 2DFC
0x01C0 2E00 - 0x01C0 2FFC
0x01C0 2FFD - 0x01C0 3FFF
0x01C0 4000 - 0x01C0 4FFF
0x01C0 5000 - 0x01C0 7FFF
0x01C0 8000 - 0x01C0 FFFF
-
Reserved
-
Reserved
-
Reserved
-
Reserved
-
Reserved
-
Reserved
-
Reserved
-
Parameter Set RAM (see Table 6-8)
Reserved
-
-
Reserved
Transfer Controller 0 Registers
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
ACRONYM
-
REGISTER NAME
0x01C1 0000
0x01C1 0004
Reserved
TCCFG
-
EDMA3 TC0 Configuration Register
Reserved
0x01C1 0008 - 0x01C1 00FF
0x01C1 0100
TCSTAT
-
EDMA3 TC0 Channel Status Register
Reserved
0x01C1 0104 - 0x01C1 0110
0x01C1 0114 - 0x01C1 011F
0x01C1 0120
-
Reserved
ERRSTAT
ERREN
ERRCLR
ERRDET
ERRCMD
-
EDMA3 TC0 Error Status Register
0x01C1 0124
EDMA3 TC0 Error Enable Register
EDMA3 TC0 Error Clear Register
0x01C1 0128
0x01C1 012C
EDMA3 TC0 Error Details Register
EDMA3 TC0 Error Interrupt Command Register
Reserved
0x01C1 0130
0x01C1 0134 - 0x01C1 013F
0x01C1 0140
RDRATE
-
EDMA3 TC0 Read Command Rate Register
Reserved
0x01C1 0144 - 0x01C1 01FF
0x01C1 0200 - 0x01C1 023F
0x01C1 0240
-
Reserved
SAOPT
SASRC
SACNT
SADST
SABIDX
SAMPPRXY
SACNTRLD
SASRCBREF
SADSTBREF
-
EDMA3 TC0 Source Active Options Register
EDMA3 TC0 Source Active Source Address Register
EDMA3 TC0 Source Active Count Register
EDMA3 TC0 Source Active Destination Address Register
EDMA3 TC0 Active B-Index Register
EDMA3 TC0 Source Active Memory Protection Proxy Register
EDMA3 TC0 Source Active Count Reload Register
EDMA3 TC0 Source Active Source Address B-Reference Register
EDMA3 TC0 Source Active Destination Address B-Reference Register
Reserved
0x01C1 0244
0x01C1 0248
0x01C1 024C
0x01C1 0250
0x01C1 0254
0x01C1 0258
0x01C1 025C
0x01C1 0260
0x01C1 0264 - 0x01C1 027F
0x01C1 0280
DFCNTRLD
DFSRCBREF
EDMA3 TC0 Destination FIFO Set Count Reload Register
EDMA3 TC0 Destination FIFO Set Source Address B-Reference Register
0x01C1 0284
EDMA3 TC0 Destination FIFO Set Destination Address B-Reference
Register
0x01C1 0288
DFDSTBREF
0x01C1 028C - 0x01C1 02FF
0x01C1 0300
-
Reserved
DFOPT0
DFSRC0
DFCNT0
DFDST0
DFBIDX0
DFMPPRXY0
-
EDMA3 TC0 Destination FIFO Options Register 0
EDMA3 TC0 Destination FIFO Source Address Register 0
EDMA3 TC0 Destination FIFO Count Register 0
EDMA3 TC0 Destination FIFO Destination Address Register 0
EDMA3 TC0 Destination FIFO B-Index Register 0
EDMA3 TC0 Destination FIFO Memory Protection Proxy Register 0
Reserved
0x01C1 0304
0x01C1 0308
0x01C1 030C
0x01C1 0310
0x01C1 0314
0x01C1 0318 - 0x01C1 033F
0x01C1 0340
DFOPT1
DFSRC1
DFCNT1
DFDST1
DFBIDX1
DFMPPRXY1
-
EDMA3 TC0 Destination FIFO Options Register 1
EDMA3 TC0 Destination FIFO Source Address Register 1
EDMA3 TC0 Destination FIFO Count Register 1
EDMA3 TC0 Destination FIFO Destination Address Register 1
EDMA3 TC0 Destination FIFO B-Index Register 1
EDMA3 TC0 Destination FIFO Memory Protection Proxy Register 1
Reserved
0x01C1 0344
0x01C1 0348
0x01C1 034C
0x01C1 0350
0x01C1 0354
0x01C1 0358 - 0x01C1 037F
0x01C1 0380
DFOPT2
DFSRC2
DFCNT2
EDMA3 TC0 Destination FIFO Options Register 2
EDMA3 TC0 Destination FIFO Source Address Register 2
EDMA3 TC0 Destination FIFO Count Register 2
0x01C1 0384
0x01C1 0388
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
0x01C1 038C
ACRONYM
DFDST2
DFBIDX2
DFMPPRXY2
-
REGISTER NAME
EDMA3 TC0 Destination FIFO Destination Address Register 2
EDMA3 TC0 Destination FIFO B-Index Register 2
EDMA3 TC0 Destination FIFO Memory Protection Proxy Register 2
Reserved
0x01C1 0390
0x01C1 0394
0x01C1 0398 - 0x01C1 03BF
0x01C1 03C0
DFOPT3
DFSRC3
DFCNT3
DFDST3
DFBIDX3
DFMPPRXY3
-
EDMA3 TC0 Destination FIFO Options Register 3
EDMA3 TC0 Destination FIFO Source Address Register 3
EDMA3 TC0 Destination FIFO Count Register 3
EDMA3 TC0 Destination FIFO Destination Address Register 3
EDMA3 TC0 Destination FIFO B-Index Register 3
EDMA3 TC0 Destination FIFO Memory Protection Proxy Register 3
Reserved
0x01C1 03C4
0x01C1 03C8
0x01C1 03CC
0x01C1 03D0
0x01C1 03D4
0x01C1 03D8 - 0x01C1 03FF
Transfer Controller 1 Registers
0x01C1 0400
0x01C1 0404
-
TCCFG
-
Reserved
EDMA3 TC1 Configuration Register
Reserved
0x01C1 0408 - 0x01C1 04FF
0x01C1 0500
TCSTAT
-
EDMA3 TC1 Channel Status Register
Reserved
0x01C1 0504 - 0x01C1 0510
0x01C1 0514 - 0x01C1 051F
0x01C1 0520
-
Reserved
ERRSTAT
ERREN
ERRCLR
ERRDET
ERRCMD
-
EDMA3 TC1 Error Status Register
EDMA3 TC1 Error Enable Register
EDMA3 TC1 Error Clear Register
0x01C1 0524
0x01C1 0528
0x01C1 052C
EDMA3 TC1 Error Details Register
EDMA3 TC1 Error Interrupt Command Register
Reserved
0x01C1 0530
0x01C1 0534 - 0x01C1 053F
0x01C1 0540
RDRATE
-
EDMA3 TC1 Read Command Rate Register
Reserved
0x01C1 0544 - 0x01C1 05FF
0x01C1 0600 - 0x01C1 063F
0x01C1 0640
-
Reserved
SAOPT
SASRC
SACNT
SADST
SABIDX
SAMPPRXY
SACNTRLD
SASRCBREF
SADSTBREF
-
EDMA3 TC1 Source Active Options Register
EDMA3 TC1 Source Active Source Address Register
EDMA3 TC1 Source Active Count Register
EDMA3 TC1 Source Active Destination Address Register
EDMA3 TC1 Active B-Index Register
EDMA3 TC1 Source Active Memory Protection Proxy Register
EDMA3 TC1 Source Active Count Reload Register
EDMA3 TC1 Source Active Source Address B-Reference Register
EDMA3 TC1 Source Active Destination Address B-Reference Register
Reserved
0x01C1 0644
0x01C1 0648
0x01C1 064C
0x01C1 0650
0x01C1 0654
0x01C1 0658
0x01C1 065C
0x01C1 0660
0x01C1 0664 - 0x01C1 067F
0x01C1 0680
DFCNTRLD
DFSRCBREF
EDMA3 TC1 Destination FIFO Set Count Reload Register
EDMA3 TC1 Destination FIFO Set Source Address B-Reference Register
0x01C1 0684
EDMA3 TC1 Destination FIFO Set Destination Address B-Reference
Register
0x01C1 0688
DFDSTBREF
0x01C1 068C - 0x01C1 06FF
0x01C1 0700
-
Reserved
DFOPT0
DFSRC0
DFCNT0
DFDST0
DFBIDX0
EDMA3 TC1 Destination FIFO Options Register 0
EDMA3 TC1 Destination FIFO Source Address Register 0
EDMA3 TC1 Destination FIFO Count Register 0
EDMA3 TC1 Destination FIFO Destination Address Register 0
EDMA3 TC1 Destination FIFO B-Index Register 0
0x01C1 0704
0x01C1 0708
0x01C1 070C
0x01C1 0710
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
ACRONYM
DFMPPRXY0
-
REGISTER NAME
EDMA3 TC1 Destination FIFO Memory Protection Proxy Register 0
Reserved
0x01C1 0714
0x01C1 0718 - 0x01C1 073F
0x01C1 0740
DFOPT1
DFSRC1
DFCNT1
DFDST1
DFBIDX1
DFMPPRXY1
-
EDMA3 TC1 Destination FIFO Options Register 1
EDMA3 TC1 Destination FIFO Source Address Register 1
EDMA3 TC1 Destination FIFO Count Register 1
EDMA3 TC1 Destination FIFO Destination Address Register 1
EDMA3 TC1 Destination FIFO B-Index Register 1
EDMA3 TC1 Destination FIFO Memory Protection Proxy Register 1
Reserved
0x01C1 0744
0x01C1 0748
0x01C1 074C
0x01C1 0750
0x01C1 0754
0x01C1 0758 - 0x01C1 077F
0x01C1 0780
DFOPT2
DFSRC2
DFCNT2
DFDST2
DFBIDX2
DFMPPRXY2
-
EDMA3 TC1 Destination FIFO Options Register 2
EDMA3 TC1 Destination FIFO Source Address Register 2
EDMA3 TC1 Destination FIFO Count Register 2
EDMA3 TC1 Destination FIFO Destination Address Register 2
EDMA3 TC1 Destination FIFO B-Index Register 2
EDMA3 TC1 Destination FIFO Memory Protection Proxy Register 2
Reserved
0x01C1 0784
0x01C1 0788
0x01C1 078C
0x01C1 0790
0x01C1 0794
0x01C1 0798 - 0x01C1 07BF
0x01C1 07C0
DFOPT3
DFSRC3
DFCNT3
DFDST3
DFBIDX3
DFMPPRXY3
-
EDMA3 TC1 Destination FIFO Options Register 3
EDMA3 TC1 Destination FIFO Source Address Register 3
EDMA3 TC1 Destination FIFO Count Register 3
EDMA3 TC1 Destination FIFO Destination Address Register 3
EDMA3 TC1 Destination FIFO B-Index Register 3
EDMA3 TC1 Destination FIFO Memory Protection Proxy Register 3
Reserved
0x01C1 07C4
0x01C1 07C8
0x01C1 07CC
0x01C1 07D0
0x01C1 07D4
0x01C1 07D8 - 0x01C1 07FF
Transfer Controller 2 Registers
0x01C1 0800
0x01C1 0804
-
TCCFG
-
Reserved
EDMA3 TC2 Configuration Register
Reserved
0x01C1 0808 - 0x01C1 08FF
0x01C1 0900
TCSTAT
-
EDMA3 TC2 Channel Status Register
Reserved
0x01C1 0904 - 0x01C1 0910
0x01C1 0914 - 0x01C1 091F
0x01C1 0920
-
Reserved
ERRSTAT
ERREN
ERRCLR
ERRDET
ERRCMD
-
EDMA3 TC2 Error Status Register
EDMA3 TC2 Error Enable Register
EDMA3 TC2 Error Clear Register
EDMA3 TC2 Error Details Register
EDMA3 TC2 Error Interrupt Command Register
Reserved
0x01C1 0924
0x01C1 0928
0x01C1 092C
0x01C1 0930
0x01C1 0934 - 0x01C1 093F
0x01C1 0940
RDRATE
-
EDMA3 TC2 Read Command Rate Register
Reserved
0x01C1 0944 - 0x01C1 09FF
0x01C1 0A00 - 0x01C1 0A3F
0x01C1 0A40
-
Reserved
SAOPT
SASRC
SACNT
SADST
SABIDX
SAMPPRXY
SACNTRLD
SASRCBREF
EDMA3 TC2 Source Active Options Register
EDMA3 TC2 Source Active Source Address Register
EDMA3 TC2 Source Active Count Register
EDMA3 TC2 Source Active Destination Address Register
EDMA3 TC2 Active B-Index Register
EDMA3 TC2 Source Active Memory Protection Proxy Register
EDMA3 TC2 Source Active Count Reload Register
EDMA3 TC2 Source Active Source Address B-Reference Register
0x01C1 0A44
0x01C1 0A48
0x01C1 0A4C
0x01C1 0A50
0x01C1 0A54
0x01C1 0A58
0x01C1 0A5C
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Table 6-7. DM6435 EDMA Registers (continued)
HEX ADDRESS
0x01C1 0A60
ACRONYM
SADSTBREF
-
REGISTER NAME
EDMA3 TC2 Source Active Destination Address B-Reference Register
Reserved
0x01C1 0A64 - 0x01C1 0A7F
0x01C1 0A80
DFCNTRLD
DFSRCBREF
EDMA3 TC2 Destination FIFO Set Count Reload Register
EDMA3 TC2 Destination FIFO Set Source Address B-Reference Register
0x01C1 0A84
EDMA3 TC2 Destination FIFO Set Destination Address B-Reference
Register
0x01C1 0A88
DFDSTBREF
0x01C1 0A8C - 0x01C1 0AFF
0x01C1 0B00
-
Reserved
DFOPT0
DFSRC0
DFCNT0
DFDST0
DFBIDX0
DFMPPRXY0
-
EDMA3 TC2 Destination FIFO Options Register 0
EDMA3 TC2 Destination FIFO Source Address Register 0
EDMA3 TC2 Destination FIFO Count Register 0
EDMA3 TC2 Destination FIFO Destination Address Register 0
EDMA3 TC2 Destination FIFO B-Index Register 0
EDMA3 TC2 Destination FIFO Memory Protection Proxy Register 0
Reserved
0x01C1 0B04
0x01C1 0B08
0x01C1 0B0C
0x01C1 0B10
0x01C1 0B14
0x01C1 0B18 - 0x01C1 0B3F
0x01C1 0B40
DFOPT1
DFSRC1
DFCNT1
DFDST1
DFBIDX1
DFMPPRXY1
-
EDMA3 TC2 Destination FIFO Options Register 1
EDMA3 TC2 Destination FIFO Source Address Register 1
EDMA3 TC2 Destination FIFO Count Register 1
EDMA3 TC2 Destination FIFO Destination Address Register 1
EDMA3 TC2 Destination FIFO B-Index Register 1
EDMA3 TC2 Destination FIFO Memory Protection Proxy Register 1
Reserved
0x01C1 0B44
0x01C1 0B48
0x01C1 0B4C
0x01C1 0B50
0x01C1 0B54
0x01C1 0B58 - 0x01C1 0B7F
0x01C1 0B80
DFOPT2
DFSRC2
DFCNT2
DFDST2
DFBIDX2
DFMPPRXY2
-
EDMA3 TC2 Destination FIFO Options Register 2
EDMA3 TC2 Destination FIFO Source Address Register 2
EDMA3 TC2 Destination FIFO Count Register 2
EDMA3 TC2 Destination FIFO Destination Address Register 2
EDMA3 TC2 Destination FIFO B-Index Register 2
EDMA3 TC2 Destination FIFO Memory Protection Proxy Register 2
Reserved
0x01C1 0B84
0x01C1 0B88
0x01C1 0B8C
0x01C1 0B90
0x01C1 0B94
0x01C1 0B98 - 0x01C1 0BBF
0x01C1 0BC0
DFOPT3
DFSRC3
DFCNT3
DFDST3
DFBIDX3
DFMPPRXY3
-
EDMA3 TC2 Destination FIFO Options Register 3
EDMA3 TC2 Destination FIFO Source Address Register 3
EDMA3 TC2 Destination FIFO Count Register 3
EDMA3 TC2 Destination FIFO Destination Address Register 3
EDMA3 TC2 Destination FIFO B-Index Register 3
EDMA3 TC2 Destination FIFO Memory Protection Proxy Register 3
Reserved
0x01C1 0BC4
0x01C1 0BC8
0x01C1 0BCC
0x01C1 0BD0
0x01C1 0BD4
0x01C1 0BD8 - 0x01C1 0BFF
Table 6-8 shows an abbreviation of the set of registers which make up the parameter set for each of 128
EDMA events. Each of the parameter register sets consist of 8 32-bit word entries. Table 6-9 shows the
parameter set entry registers with relative memory address locations within each of the parameter sets.
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Table 6-8. EDMA Parameter Set RAM
HEX ADDRESS RANGE
DESCRIPTION
0x01C0 4000 - 0x01C0 401F
0x01C0 4020 - 0x01C0 403F
0x01C0 4040 - 0x01C0 405F
0x01C0 4060 - 0x01C0 407F
0x01C0 4080 - 0x01C0 409F
0x01C0 40A0 - 0x01C0 40BF
...
Parameters Set 0 (8 32-bit words)
Parameters Set 1 (8 32-bit words)
Parameters Set 2 (8 32-bit words)
Parameters Set 3 (8 32-bit words)
Parameters Set 4 (8 32-bit words)
Parameters Set 5 (8 32-bit words)
...
0x01C0 4FC0 - 0x01C0 4FDF
0x01C0 4FE0 - 0x01C0 4FFF
Parameters Set 126 (8 32-bit words)
Parameters Set 127 (8 32-bit words)
Table 6-9. Parameter Set Entries
HEX OFFSET ADDRESS
WITHIN THE PARAMETER SET
ACRONYM
PARAMETER ENTRY
0x0000
0x0004
0x0008
0x000C
0x0010
0x0014
0x0018
0x001C
OPT
SRC
Option
Source Address
A_B_CNT
DST
A Count, B Count
Destination Address
SRC_DST_BIDX
LINK_BCNTRLD
SRC_DST_CIDX
CCNT
Source B Index, Destination B Index
Link Address, B Count Reload
Source C Index, Destination C Index
C Count
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6.5 Reset
The reset controller detects the different type of resets supported on the DM6435 device and manages the
distribution of those resets throughout the device.
The DM6435 device has several types of device-level global resets - power-on reset, warm reset, and
max reset. Table 6-10 explains further the types of reset, the reset initiator, and the effects of each reset
on the chip. See Section 6.5.9, Reset Electrical Data/Timing, for more information on the effects of each
reset on the PLL controllers and their clocks.
Table 6-10. Device-Level Global Reset Types
TYPE
INITIATOR
EFFECT(s)
POR pin
Global chip reset (Cold reset). Activates the POR signal on chip,
which resets the entire chip including the emulation logic.
The power-on reset (POR) pin must be driven low during power
ramp of the device.
Power-on Reset
(POR)
Device boot and configuration pin are latched.
Resets everything except for the emulation logic. Emulator stays
alive during Warm Reset.
Device boot and configuration pin are latched.
Warm Reset
Max Reset
RESET pin
Same as a Warm Reset, except the DM6435 device boot and
configuration pins are not re-latched.
Emulator, WD Timer (Timer 2)
In addition to device-level global resets, the PSC provides the capability to cause local resets to
peripherals and/or the CPU.
6.5.1 Power-on Reset (POR Pin)
Power-on Reset (POR) is initiated by the POR pin and is used to reset the entire chip, including the
emulation logic. Power-on Reset is also referred to as a cold reset since the device usually goes through a
power-up cycle. During power-up, the POR pin must be asserted (driven low) until the power supplies
have reached their normal operating conditions. If an external 27-MHz oscillator is used on the MXI/CLKIN
pin, the source clock should also be running at the correct frequency prior to de-asserting the POR pin.
Note: A device power-up cycle is not required to initiate a Power-on Reset.
The following sequence must be followed during a Power-on Reset.
1. Wait for the power supplies to reach normal operating conditions while keeping the POR pin asserted
(driven low).
2. Wait for the input clock source to be stable while keeping the POR pin asserted (low).
3. Once the power supplies and the input clock source are stable, the POR pin must remain asserted
(low) for a minimum of 12 MXI cycles.
Within the low period of the POR pin, the following happens:
–
The reset signals flow to the entire chip (including the emulation logic), resetting the modules on
chip.
–
The PLL Controller clocks start at the frequency of the MXI clock. The clocks are propagated
throughout the chip to reset the chip synchronously. By default, both PLL1 and PLL2 are in reset
and unlocked. The PLL Controllers default to PLL Bypass Mode.
–
The RESETOUT pin stays asserted (low), indicating the device is in reset.
4. The POR pin may now be deasserted (driven high).
When the POR pin is deasserted (high), the configuration pin values are latched and the PLL
Controllers changed their system clocks to their default divide-down values. Both PLL Controllers are
still in PLL Bypass Mode. Other device initialization also begins.
5. After device initialization is complete, the PLL Controllers pause the system clocks for 10 cycles. At the
end of these 10 cycles, the RESETOUT pin is deasserted (driven high).
At this point:
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–
–
The I/O pins are controlled by the default peripherals (default peripherals are determined by
PINMUX0 and PINMUX1 registers).
The clock and reset of each peripheral is determined by the default settings of the Power and Sleep
Controller (PSC).
–
–
The PLL Controllers are operating in PLL Bypass Mode.
The C64x+ begins executing from DSPBOOTADDR (determined by bootmode selection).
After the reset sequence, the boot sequence begins. For more details on the boot sequence, see the
Using the TMS320DM643x Bootloader Application Report (literature number SPRAAG0).
After the boot sequence, follow the software initialization sequence described in Section 3.8, Device
Initialization Sequence After Reset.
6.5.1.1 Usage of POR versus RESET Pins
POR and RESET are independent resets.
If the device needs to go through a power-up cycle, POR (not RESET) must be used to fully reset the
device.
In functional end-system, emulation/debugger logic is typically not needed; therefore, the recommendation
for functional end-system is to use the POR pin for full device reset. If RESET pin is not needed, it can be
pulled inactive (high) via an external pullup resistor.
In a debug system, it is typically desirable to allow the reset of the device without crashing an emulation
session. In this case, the user can use the POR pin to achieve full device reset and use the RESET pin to
achieve a debug reset—which resets the entire device except emulation logic.
6.5.1.2 Latching Boot and Configuration Pins
Internal to the chip, the two device reset pins RESET and POR are logically AND’d together only for the
purpose of latching device boot and configuration pins. The values on all device and boot configuration
pins are latched into the BOOTCFG register when the logical AND of RESET and POR transitions from
low-to-high.
6.5.2 Warm Reset (RESET Pin)
A Warm Reset is activated by driving the RESET pin active low. This resets everything in the device
except the emulation logic. An emulator session will stay alive during warm reset.
For more information on POR vs. RESET usage, see Section 6.5.1.1, Usage of POR versus RESET Pins
and Section 6.5.1.2, Latching Boot and Configuration Pins.
The following sequence must be followed during a Warm Reset:
1. Power supplies and input clock source should already be stable.
2. The RESET pin must be asserted (low) for a minimum of 12 MXI cycles.
Within the low period of the RESET pin, the following happens:
–
–
–
The reset signals flow to the entire chip resetting all the modules on chip, except the emulation
logic.
The PLL Controllers are reset thereby, switching back to PLL Bypass Mode and resetting all their
registers to default values. Both PLL1 and PLL2 are placed in reset and lose lock.
The RESETOUT pin becomes asserted (low), indicating the device is in reset.
3. The RESET pin may now be deasserted (driven high).
When the RESET pin is deasserted (high), the configuration pin values are latched and the PLL
Controllers changed their system clocks to their default divide-down values. Both PLL Controllers are
still in PLL Bypass Mode. Other device initialization also begins.
4. After device initialization is complete, the PLL Controllers pause the system clocks for 10 cycles. At the
end of these 10 cycles, the RESETOUT pin is deasserted (driven high).
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At this point:
–
The I/O pins are controlled by the default peripherals (default peripherals are determined by
PINMUX0 and PINMUX1 registers).
–
The clock and reset of each peripheral is determined by the default settings of the Power and Sleep
Controller (PSC).
–
–
The PLL Controllers are operating in PLL Bypass Mode.
The C64x+ begins executing from DSPBOOTADDR (determined by bootmode selection).
After the reset sequence, the boot sequence begins. For more details on the boot sequence, see the
Using the TMS320DM643x Bootloader Application Report (literature number SPRAAG0)).
After the boot sequence, follow the software initialization sequence described in Section 3.8, Device
Initialization Sequence After Reset.
6.5.3 Maximum Reset
A Maximum (Max) Reset is initiated by the emulator or the watchdog timer (Timer 2). The effects are the
same as a warm reset, except the device boot and configuration pins are not re-latched. The emulator
initiates a maximum reset via the ICEPICK module. This ICEPICK initiated reset is non-maskable. When
the watchdog timer counter reaches zero, this will also initiate a maximum reset to recover from a runaway
condition. The watchdog timeout reset condition is masked if the TIMERCTL.WDRST bit is cleared to "0".
To invoke the maximum reset via the ICEPICK module, the user can perform the following from the Code
Composer Studio™ IDE menu: Debug→Advanced Resets→System Reset
This is the Max Reset sequence:
1. Max Reset is initiated by the emulator or the watchdog timer.
During this time, the following happens:
–
–
–
The reset signals flow to the entire chip resetting all the modules on chip except the emulation
logic.
The PLL Controllers are reset thereby, switching back to PLL Bypass Mode and resetting all their
registers to default values. Both PLL1 and PLL2 are placed in reset and lose lock.
The RESETOUT pin becomes asserted (low), indicating the device is in reset.
2. After device initialization is complete, the PLL Controllers pause the system clocks for 10 cycles. At the
end of these 10 cycles, the RESETOUT pin is deasserted (driven high).
At this point:
–
The I/O pins are controlled by the default peripherals (default peripherals are determined by
PINMUX0 and PINMUX1 registers).
–
The clock and reset of each peripheral is determined by the default settings of the Power and Sleep
Controller (PSC).
–
–
The PLL Controllers are operating in PLL Bypass Mode.
The C64x+ begins executing from DSPBOOTADDR (determined by bootmode selection).
After the reset sequence, the boot sequence begins. Since the boot and configuration pins are not latched
with a Max Reset, the previous values (as shown in the BOOTCFG register) are used to select the boot
mode. For more details on the boot sequence, see the Using the TMS320DM643x Bootloader Application
Report (literature number SPRAAG0).
After the boot sequence, follow the software initialization sequence described in Section 3.8, Device
Initialization Sequence After Reset.
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6.5.4 CPU Local Reset
The C64x+ DSP CPU has an internal reset input that allows a host (HPI) to control it. This reset is
configured through a register bit (MDCTL[39].LRST) in the Power Sleep Controller (PSC) module. When in
C64x+ local reset, the slave DMA port on C64x+ will remain active and the internal memory will be
accessible. For procedures on asserting and de-asserting CPU local reset by the host, see the
TMS320DM643x DMP DSP Subsystem Reference Guide (literature number SPRU978).
For information on peripheral selection at the rising edge of POR or RESET, see Section 3, Device
Configurations of this data manual.
6.5.5 Peripheral Local Reset
The user can configure the local reset and clock state of a peripheral through programming the PSC.
Table 6-4, DM6435 LPSC Assignments identifies the LPSC numbers and the peripherals capable of being
locally reset by the PSC. For more detailed information on the programming of these peripherals by the
PSC, see the TMS320DM643x DMP DSP Subsystem Reference Guide (literature number SPRU978).
6.5.6 Reset Priority
If any of the above reset sources occur simultaneously, the PLLC only processes the highest priority reset
request. The reset request priorities are as follows (high to low):
•
•
•
•
Power-on Reset
Maximum Reset
Warm Reset
CPU Reset
6.5.7 Reset Controller Register
The Reset Type Status (RSTYPE) register (01C4 00E4) is the only register for the reset controller. This
register falls in the same memory range as the PLL1 controller registers (see Table 6-18 for the PLL1
Controller Registers (including Reset Controller)). For more details on the RSTYPE register, see the
TMS320DM643x DMP DSP Subsystem Reference Guide (literature number SPRU978).
6.5.8 Pin Behaviors at Reset
During normal operations, pins are controlled by the respective peripheral selected in the PINMUX0 or
PINMUX1 register. During device level global reset, the pin behaves as follows:
Multiplexed Boot and Configuration Pins
These pins are forced 3-stated when RESETOUT is asserted (low). This is to ensure the proper boot and
configuration values can be latched on these multiplexed pins. This is particularly useful in the case where
the boot and configuration values are driven by an external control device. After RESETOUT is
deasserted (high), these pins are controlled by their respective default peripheral.
•
Boot and Configuration Pins Group: GP[28], GP[27], GP[26]/(FASTBOOT), GP[25]/(BOOTMODE3),
GP[24]/(BOOTMODE2), GP[23]/(BOOTMODE1), GP[22]/(BOOTMODE0),
EM_A[4]/GP[10]/(AEAW2/PLLMS2), EM_A[1]/(ALE)/GP[9]/(AEAW1/PLLMS1),
EM_A[2]/(CLE)/GP[8]/(AEAW0/PLLMS0), EM_A[0]/GP[7]/(AEM2), EM_BA[0]/GP[6]/(AEM1), and
EM_BA[1]/GP[5]/(AEM0).
For information on whether external pullup/pulldown resistors should be used on the boot and
configuration pins, see Section 3.9.1, Pullup/Pulldown Resistors.
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Default Power Down Pins
As discussed in Section 3.2, Power Considerations, the VDD3P3V_PWDN register controls power to the
3.3-V pins. The VDD3P3V_PWDN register defaults to powering down some 3.3-V pins to save power. For
more details on the VDD3P3V_PWDN register and which 3.3-V pins default to powerup or powerdown,
Section 3.2, Power Considerations. The pins that default to powerdown, are both reset to powerdown and
high-impedance. They remain in that state until configured otherwise by VDD3P3_PWDN and
PINMUX0/PINMUX1 programming.
•
Default Power Down Pin Group: GP[4]/PWM1, ACLKR0/CLKX0/GP[99], AFSR0/DR0/GP[100],
AHCLKR0/CLKR0/GP[101], AXR0[3]/FSR0/GP[102], AXR0[2]/FSX0/GP[103], AXR0[1]/DX0/GP[104],
AXR0/GP[105], ACLKX0/GP[106], AFSX0/GP[107], AHCLKX0/GP[108], AMUTEIN0/GP[109],
AMUTE0/GP[110], HECC_TX/TOUT1L/UTXD1/GP[55], HECC_RX/TINP1L/URXD1/GP[56],
CLKS0/TOUT0L/GP[97], TINP0L/GP[98], URXD0/GP[85], UTXD0/GP[86], UCTS0/GP[87], and
URTS0/PWM0/GP[88].
All Other Pins
During RESETOUT assertion (low), all other pins are controlled by the default peripheral. The default
peripheral is determined by the default settings of the PINMUX0 or PINMUX1 registers.
Some of the PINMUX0/PINMUX1 settings are determined by configuration pins latched at reset. To
determine the reset behavior of these pins, see Section 3.7, Multiplexed Pin Configurations and read the
rest of the this subsection to understand how that default peripheral controls the pin.
The reset behaviors for all these other pins are categorized as follows (also see Figure 6-7 and Figure 6-8
in Section 6.5.9, Reset Electrical Data/Timing):
•
•
•
Z+/Low Group (Z Longer-to-Low Group): These pins are 3-stated when device-level global reset
source (e.g., POR, RESET, or Max Reset) is asserted. These pins remain 3-stated throughout
RESETOUT assertion. When RESETOUT is deasserted, these pins drive a logic low.
Z+/High Group (Z Longer-to-High Group): These pins are 3-stated when device-level global reset
source (e.g., POR, RESET, or Max Reset) is asserted. These pins remain 3-stated throughout
RESETOUT assertion. When RESETOUT is deasserted, these pins drive a logic high.
Z+/Invalid Group (Z Longer-to-Invalid Group): These pins are 3-stated when device-level global
reset source (e.g., POR, RESET, or Max Reset) is asserted. These pins remain 3-stated throughout
RESETOUT assertion. When RESETOUT is deasserted, these pins drive an invalid value until
configured otherwise by their respective peripheral (after the peripheral is enabled by the PSC).
•
Z Group: These pins are 3-stated by default, and these pins remain 3-stated throughout RESETOUT
assertion. When RESETOUT is deasserted, these pins remain 3-stated until configured otherwise by
their respective peripheral (after the peripheral is enabled by the PSC).
•
•
•
Low Group: These pins are low by default, and remain low until configured otherwise by their
respective peripheral (after the peripheral is enabled by the PSC).
High Group: These pins are high by default, and remain high until configured otherwise by their
respective peripheral (after the peripheral is enabled by the PSC).
Z/Low Group (Z-to-Low Group): These pins are 3-stated when device-level global reset source (e.g.,
POR, RESET, or Max Reset) is asserted. When the reset source is deasserted, these pins drive a
logic low.
•
•
Z/High Group (Z-to-High Group): These pins are 3-stated when device-level global reset source
(e.g., POR, RESET, or Max Reset) is asserted. When reset source is deasserted, these pins drive a
logic high.
Clock Group: These clock pins are toggling by default. They paused momentarily before RESETOUT
is deasserted (high). The only pin in the Clock Group is CLKOUT0.
This is a list of possible default peripherals and how they control the pins during reset:
•
GPIO: All GPIO pins behave according to Z Group.
Note: The following EMIFA list only includes pins that can default to function as EMIFA signals.
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•
EMIFA: These EMIFA signals are multiplexed with boot and configuration pins: EM_A[4], EM_A[2:0],
EM_BA[0], EM_BA[1]; therefore, they are forced 3-stated throughout RESETOUT.
–
–
–
–
–
–
Z+/Low Group: EM_A[4], EM_A[2:0]
Z+/High Group: EM_BA[0], EM_BA[1], EM_OE, EM_WE
Z+/Invalid Group: EM_D[7:0]
Z/Low Group: EM_A[21:5], EM_A[3], EM_R/W
Z/High Group: EM_CS2
Z Group: EM_WAIT/(RDY/BSY)
•
DDR2 Memory Controller:
–
–
–
–
Clock Group: DDR_CLK, DDR_CLK
DDR2 Z Group: DDR_DQM[3:0], DDR_DQS[3:0], DDR_D[31:0]
DDR2 Low Group: DDR_CKE, DDR_BA[2:0], DDR_A[12:0]
DDR2 High Group: DDR_CS, DDR_WE, DDR_RAS, DDR_CAS
•
•
I2C: All I2C pins behave according to Z Group.
JTAG: TDO, EMU0, and EMU1 pins behave according to Z Group. TCK, TDI, TMS, and TRST are
input-only pins.
•
Clock: CLKOUT0
For more information on the pin behaviors during device-level global reset, see Figure 6-7 and Figure 6-8
in Section 6.5.9, Reset Electrical Data/Timing.
6.5.9 Reset Electrical Data/Timing
Note: If a configuration pin must be routed out from the device, the internal pullup/pulldown (IPU/IPD)
resistor should not be relied upon; TI recommends the use of an external pullup/pulldown resistor.
Table 6-11. Timing Requirements for Reset (see Figure 6-7 and Figure 6-8)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
UNIT
-6
MIN
MAX
1
4
tw(RESET)
Pulse duration, POR low or RESET low
12C(1)
12C(1)
ns
ns
Setup time, boot and configuration pins valid before POR high or RESET
high(2)
tsu(CONFIG)
Hold time, boot and configuration pins valid after POR high or RESET
high(2)
5
th(CONFIG)
0
ns
(1) C = 1/MXI clock frequency in ns. The device clock source must be stable and at a valid frequency prior to meeting the tw(RESET)
requirement.
(2) For the list of boot and configuration pins, see Table 2-5, Boot Terminal Functions.
Table 6-12. Switching Characteristics Over Recommended Operating Conditions During Reset(1)
(see Figure 6-8)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
1900C
10C
20
2
3
6
7
8
9
td(RSTH-RSTOUTH)
tw(PAUSE)
Delay time, POR high or RESET high to RESETOUT high
Pulse duration, SYSCLKs paused (low) before RESETOUT high
Delay time, POR low or RESET low to pins invalid
Delay time, POR high or RESET high to pins valid
Delay time, RESETOUT high to pins valid
ns
ns
ns
ns
ns
ns
10C
td(RSTL-IV)
td(RSTH-V)
20
td(RSTOUTH-V)
td(RSTOUTH-IV)
0
Delay time, RESETOUT high to pins invalid
12C
(1) C = 1/CLKIN1 clock frequency in ns.
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Figure 6-7 shows the Power-Up Timing. Figure 6-8 shows the Warm Reset (RESET) Timing. Max Reset
Timing is identical to Warm Reset Timing, except the boot and configuration pins are not relatched and
the BOOTCFG register retains its previous value latched before the Max Reset was initiated.
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Power
Supplies
Ramping
Power Supplies Stable
Clock Source Stable
MXI(A)
CLKOUT0
POR
1
RESET
2
RESETOUT
3
SYSCLKREFCLK
(PLLC1)
SYSCLK1
SYSCLK2
SYSCLK3
5
4
8
Boot and
Configuration Pins
Config
Driven or Hi-Z
8
Hi-Z
Z+/Low Group
(Z longer-to-low)
8
9
Hi-Z
Hi-Z
Hi-Z
Z+/High Group
(Z longer-to-low)
Z+/Invalid Group
(Z longer-to-Invalid)
Invalid
Z Group
7
7
Z/Low Group
(Z-to-low)
Z/High Group
(Z-to-high)
7
DDR2 Z Group
7
7
DDR2 Low Group
DDR2 High Group
A. Power supplies and MXI must be stable before the start of tW(RESET).
.
B. Pin reset behavior depends on which peripheral defaults to controlling the multiplexed pin. For more details on what
pin group (e.g., Z Group, Z/Low Group, Z/High Group, etc.) each pin belongs to, see Section 6.5.8, Pin Behaviors at
Reset.
Figure 6-7. Power-Up Timing(B)
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Power Supplies Stable
MXI
CLKOUT0
POR
1
RESET
2
RESETOUT
3
SYSCLKREFCLK
PLL1 Clock
(PLLC1)
SYSCLK1
SYSCLK2
SYSCLK3
Div1 Clock
Div3 Clock
Div6 Clock
5
6
8
4
Boot and
Configuration Pins
Driven or Hi-Z
8
Config
Driven or Hi-Z
Z+/Low Group
(Z longer-to-low)
8
Z+/High Group
(Z longer-to-high)
9
Z+/Invalid Group
(Z longer-to-invalid)
Invalid
Z Group
Driven or Hi-Z
6
7
7
Z/Low Group
(Z-to-low)
Driven or Hi-Z
6
Z/High Group
(Z-to-high)
Driven or Hi-Z
6
DDR2 Z Group
DDR2 Low Group
DDR2 High Group
6
6
A. Pin reset behavior depends on which peripheral defaults to controlling the multiplexed pin. For more details on what
pin group (e.g., Z Group, Z/Low Group, Z/High Group, etc.) each pin belongs to, see Section 6.5.8, Pin Behaviors at
Reset.
Figure 6-8. Warm Reset (RESET) Timing(A)
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6.6 External Clock Input From MXI/CLKIN Pin
The DM6435 device includes two options to provide an external clock input:
•
•
Use an on-chip oscillator with external crystal.
Use an external 1.8-V LVCMOS-compatible clock input.
The optimal external clock input frequency is 27 MHz. Section 6.6.1 provides more details on Option 1,
using an on-chip oscillator with external crystal. Section 6.6.2 provides details on Option 2, using an
external 1.8-V LVCMOS-compatible clock input.
6.6.1 Clock Input Option 1—Crystal
In this option, a crystal is used as the external clock input to the DM6435.
The 27-MHz oscillator provides the reference clock for all DM6435 subsystems and peripherals. The
on-chip oscillator requires an external 27-MHz crystal connected across the MXI and MXO pins, along
with two load capacitors, as shown in Figure 6-9. The external crystal load capacitors must be connected
only to the 27-MHz oscillator ground pin (MXVSS). Do not connect to board ground (VSS). The MXVDD pin
can be connected to the same 1.8 V power supply as DVDDR2
.
MXI/CLKIN
MXO
MXVSS
MXVDD
Crystal
27 MHz
C1
C2
1.8 V
Figure 6-9. 27-MHz System Oscillator
The load capacitors, C1 and C2, should be chosen such that the equation is satisfied (typical values are
C1 = C2 = 10 pF). CL in the equation is the load specified by the crystal manufacturer. All discrete
components used to implement the oscillator circuit should be placed as close as possible to the
associated oscillator pins (MXI and MXO) and to the MXVSS pin.
C1C2
CL +
(C1 ) C2)
Table 6-13. Input Requirements for Crystal
PARAMETER
MIN
TYP
MAX
UNIT
Start-up time (from power up until oscillating at stable frequency of 27
MHz)
4
ms
Oscillaton frequency
ESR
27
MHz
Ω
60
Frequency Stability(1)
±50
ppm
(1) For video and audio applications, stability of the input clock is very important. The user should select crystals with low enough ppm to
ensure good video and audio quality for the specific application.
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6.6.2 Clock Input Option 2—1.8-V LVCMOS-Compatible Clock Input
In this option, a 1.8-V LVCMOS-Compatible Clock Input is used as the external clock input to the DM6435.
The external connections are shown in Figure 6-10. The MXI/CLKIN pin is connected to the 1.8-V
LVCMOS-Compatible clock source. The MXO pin is left unconnected. The MXVSS pin is connected to
board ground (VSS). The MXVDD pin can be connected to the same 1.8-V power supply as DVDDR2
.
MXI/CLKIN
MXO
NC
MXVSS
MXVDD
1.8 V
Figure 6-10. 1.8-V LVCMOS-Compatible Clock Input
The clock source must meet the MXI/CLKIN timing requirements in Section 6.7.4, Clock PLL Electrical
Data/Timing (Input and Output Clocks).
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6.7 Clock PLLs
There are two independently controlled PLLs on DM6435. PLL1 generates the frequencies required for the
DSP, DMA, VPFE, and other peripherals. PLL2 generates the frequencies required for the DDR2
interface. The recommended reference clock for both PLLs is the 27-MHz crystal input.
6.7.1 PLL1 and PLL2
Both PLL1 and PLL2 power is supplied externally via the 1.8 V PLL power-supply pin (PLLPWR18). An
external EMI filter circuit must be added to PLLPWR18, as shown in Figure 6-11. The 1.8-V supply of the
EMI filter must be from the same 1.8-V power plane supplying the device’s 1.8-V I/O power-supply pins
(DVDDDR2). TI requires EMI filter manufacturer Murata, part number NFM18CC222R1C3.
All PLL external components (C1, C2, and the EMI Filter) must be placed as close to the device as
possible. For the best performance, TI recommends that all the PLL external components be on a single
side of the board without jumpers, switches, or components other than the ones shown in Figure 6-11. For
reduced PLL jitter, maximize the spacing between switching signals and the PLL external components
(C1, C2, and the EMI Filter).
DM643x
PLL1
PLL
+1.8 V
PWR18
C2
0.01 mF
C1
EMI Filter
0.1 mF
PLL2
Figure 6-11. PLL1 and PLL2 External Connection
The minimum CLKIN rise and fall times should also be observed. For the input clock timing requirements,
see Section 6.7.4, Clock PLL Electrical Data/Timing (Input and Output Clocks).
There is an allowable range for PLL multiplier (PLLM). There is a minimum and maximum operating
frequency for MXI/CLKIN, PLLOUT, and the device clocks (SYSCLKs). The PLL Controllers must be
configured not to exceed any of these constraints documented in this section (certain combinations of
external clock inputs, internal dividers, and PLL multiply ratios might not be supported). For these
constraints (ranges), see Table 6-14 through Table 6-16.
Table 6-14. PLL1 and PLL2 Multiplier Ranges
PLL MULTIPLIER (PLLM)
PLL1 Multiplier
MIN
x14
x14
MAX
x30
PLL2 Multiplier
x32
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Table 6-15. PLLC1 Clock Frequency Ranges
CLOCK SIGNAL NAME
MIN
20
MAX
30
UNIT
MXI/CLKIN(1)
PLLOUT
MHz
MHz
MHz
At 1.2-V CVDD
At 1.05-V CVDD
300
300
600
520
-6 devices at
1.2-V CVDD
600
400
500
400
MHz
MHz
MHz
MHz
-6 devices at
1.05-V CVDD
SYSCLK1 (CLKDIV1 Domain)
-5, -5Q, -5S
devices
-4, -4Q, -4S
devices
(1) MXI/CLKIN input clock is used for both PLL Controllers (PLLC1 and PLLC2).
Table 6-16. PLLC2 Clock Frequency Ranges
CLOCK SIGNAL NAME
MIN
20
MAX
30
UNIT
MHz
MHz
MHz
MHz
MXI/CLKIN(1)
PLLOUT
At 1.2-V CVDD
At 1.05-V CVDD
300
300
900
666
333
PLL2_SYSCLK1 (to DDR2 PHY)
(1) MXI/CLKIN input clock is used for both PLL Controllers (PLLC1 and PLLC2).
Both PLL1 and PLL2 have stabilization, lock, and reset timing requirements that must be followed.
The PLL stabilization time is the amount of time that must be allotted for the internal PLL regulators to
become stable after the PLL is powered up (after PLLCTL.PLLPWRDN bit goes through a 1-to-0
transition). The PLL should not be operated until this stabilization time has expired. This stabilization step
must be applied after these resets—a Power-on Reset, a Warm Reset, or a Max Reset, as the
PLLCTL.PLLPWRDN bit resets to a "1". For the PLL stabliziation time value, see Table 6-17.
The PLL reset time is the amount of wait time needed for the PLL to properly reset (writing PLLRST = 0)
before bringing the PLL out of reset (writing PLLRST = 1). For the PLL reset time value, see Table 6-17.
The PLL lock time is the amount of time needed from when the PLL is taken out of reset (PLLRST = 1
with PLLEN = 0) to when to when the PLL controller can be switched to PLL mode (PLLEN = 1). For the
PLL lock time value, see Table 6-17.
Table 6-17. PLL1 and PLL2 Stabilization, Lock, and Reset Times
PLL STABILIZATION/LOCK/RESET
MIN
TYP
MAX
UNIT
TIME
PLL Stabilization Time
150
µs
ns
ns
PLL Lock Time
PLL Reset Time
2000C(1)
128C(1)
(1) C = CLKIN cycle time in ns. For example, when MXI/CLKIN frequency is 27 MHz, use C = 37.037 ns.
For details on the PLL initialization software sequence, see theTMS320DM643x DMP DSP Subsystem
Reference Guide (literature number SPRU978).
For more information on the clock domains and their clock ratio restrictions, see Section 6.3.4, DM6435
Power and Clock Domains.
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6.7.2 PLL Controller Register Description(s)
A summary of the PLL controller registers is shown in Table 6-18. For more details, see the
TMS320DM643x DMP DSP Subsystem Reference Guide (literature number SPRU978).
Table 6-18. PLL and Reset Controller Registers Memory Map
HEX ADDRESS RANGE
REGISTER ACRONYM
DESCRIPTION
Controller Registers
Peripheral ID Register
Reset Type Register
0x01C4 0800
0x01C4 08E4
0x01C4 0900
0x01C4 0910
0x01C4 0918
0x01C4 091C
0x01C4 0920
0x01C4 0924
0x01C4 0928
0x01C4 092C
0x01C4 0938
0x01C4 093C
PID
RSTYPE
PLLCTL
PLLM
PLL Controller 1 PLL Control Register
PLL Controller 1 PLL Multiplier Control Register
PLL Controller 1 Divider 1 Register (SYSCLK1)
PLL Controller 1 Divider 2 Register (SYSCLK2)
PLL Controller 1 Divider 3 Register (SYSCLK3)
PLL Controller 1 Oscillator Divider 1 Register (OBSCLK) [CLKOUT0 pin]
Reserved
PLLDIV1
PLLDIV2
PLLDIV3
OSCDIV1
–
–
Reserved
PLLCMD
PLLSTAT
PLL Controller 1 Command Register
PLL Controller 1 Status Register (Shows PLLC1 Status)
PLL Controller 1 Clock Align Control Register
(Indicates Which SYSCLKs Need to be Aligned for Proper Device Operation)
0x01C4 0940
0x01C4 0944
ALNCTL
PLL Controller 1 PLLDIV Divider Ratio Change Status Register
(Indicates if SYSCLK Divide Ratio has Been Modified)
DCHANGE
0x01C4 0948
0x01C4 094C
0x01C4 0950
0x01C4 0960
0x01C4 0964
CKEN
CKSTAT
SYSTAT
–
PLL Controller 1 Clock Enable Control Register
PLL Controller 1 Clock Status Register (For All Clocks Except SYSCLKx)
PLL Controller 1 SYSCLK Status Register (Indicates SYSCLK on/off Status)
Reserved
Reserved
–
PLL2 Controller Registers
0x01C4 0C00
0x01C4 0D00
PID
PLLCTL
PLLM
PLLDIV1
–
Peripheral ID Register
PLL Controller 2 PLL Control Register
PLL Controller 2 PLL Multiplier Control Register
PLL Controller 2 Divider 1 Register (SYSCLK1)
Reserved
0x01C4 0D10
0x01C4 0D18
0x01C4 0D1C
0x01C4 0D20 - 0x01C4 0D2C
0x01C4 0D2C
–
Reserved
BPDIV
PLLCMD
PLLSTAT
PLL Controller 2 Bypass Divider Register (SYSCLKBP)
PLL Controller 2 Command Register
PLL Controller 2 Status Register (Shows PLLC2 Status)
0x01C4 0D38
0x01C4 0D3C
PLL Controller 2 Clock Align Control Register
(Indicates Which SYSCLKs Need to be Aligned for Proper Device Operation)
0x01C4 0D40
0x01C4 0D44
ALNCTL
PLL Controller 2 PLLDIV Divider Ratio Change Status Register
(Indicates if SYSCLK Divide Ratio has Been Modified)
DCHANGE
0x01C4 0D48
0x01C4 0D4C
–
Reserved
CKSTAT
SYSTAT
–
PLL Controller 2 Clock Status Register (For All Clocks Except SYSCLKx)
PLL Controller 2 SYSCLK Status Register (Indicates SYSCLK on/off Status)
Reserved
0x01C4 0D50
0x01C4 0D54 - 0x01C4 0FFF
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6.7.3 Clock PLL Considerations with External Clock Sources
If the internal oscillator is bypassed, to minimize the clock jitter a single clean power supply should power
both the DM6435 device and the external clock oscillator circuit. The minimum CLKIN rise and fall times
should also be observed. For the input clock timing requirements, see Section 6.7.4, Clock PLL Electrical
Data/Timing (Input and Output Clocks).
Rise/fall times, duty cycles (high/low pulse durations), and the load capacitance of the external clock
source must meet the device requirements in this data manual (see Section 5.3, Electrical Characteristics
Over Recommended Ranges of Supply Voltage and Operating Temperature and Section 6.7.4, Clock PLL
Electrical Data/Timing (Input and Output Clocks).
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6.7.4 Clock PLL Electrical Data/Timing (Input and Output Clocks)
Table 6-19. Timing Requirements for MXI/CLKIN (-4 -4Q,-4S,-5,-5Q,-5S,-6) Devices(1)(2)(3)(4) (see
Figure 6-12)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
UNIT
-6
MIN
33.3
MAX
50
1
2
3
4
5
tc(MXI)
tw(MXIH)
tw(MXIL)
tt(MXI)
Cycle time, MXI/CLKIN
ns
ns
Pulse duration, MXI/CLKIN high
Pulse duration, MXI/CLKIN low
Transition time, MXI/CLKIN
Period jitter, MXI/CLKIN
Frequency Stability
0.45C
0.45C
0.55C
0.55C
0.05C
0.02C
±50
ns
ns
tJ(MXI)
ns
ppm
(1) The MXI/CLKIN frequency and PLL multiply factor should be chosen such that the resulting clock frequency is within the specific range
for CPU operating frequency. For example, for a -6 speed device with a 27 MHz CLKIN frequency, the PLL multiply factor should be
≤ 22.
(2) The reference points for the rise and fall transitions are measured at VIL MAX and VIH MIN.
(3) For more details on the PLL multiplier factors, see the TMS320DM63x DMP DSP Subsystem Reference Guide (literature number
SPRU978).
(4) C = CLKIN cycle time in ns. For example, when MXI/CLKIN frequency is 27 MHz, use C = 37.037 ns.
1
5
4
2
MXI/CLKIN
3
4
Figure 6-12. MXI/CLKIN Timing
Table 6-20. Switching Characteristics Over Recommended Operating Conditions for CLKOUT0(1)(2)
(see Figure 6-13)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
50 ns
1
2
3
4
tC
Cycle time, CLKOUT0
33.3
0.45P
0.45P
tw(CLKOUT0H)
tw(CLKOUT0L)
tt(CLKOUT0)
Pulse duration, CLKOUT0 high
Pulse duration, CLKOUT0 low
Transition time, CLKOUT0
0.55P ns
0.55P ns
0.05P ns
(1) The reference points for the rise and fall transitions are measured at VOL MAX and VOH MIN.
(2) P = 1/CLKOUT0 clock frequency in nanoseconds (ns). For example, when CLKOUT0 frequency is 27 MHz, use P = 37.04 ns.
2
1
4
CLK_OUT0
(Divide-by-1)
4
3
Figure 6-13. CLKOUT0 Timing
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6.8 Interrupts
The C64x+ DSP interrupt controller combines device events into 12 prioritized interrupts. The source for
each of the 12 CPU interrupts is user programmable and is listed in Table 6-21. Also, the interrupt
controller controls the generation of the CPU exception and emulation interrupts. The NMI input to the
C64x+ DSP interrupt controller is not connected internally; therefore, the NMI interrupt is not available.
Table 6-22 summarizes the C64x+ interrupt controller registers and memory locations. For more details on
DSP interrupt controller, see the TMS320DM643x DMP DSP Subsystem Reference Guide (literature
number SPRU978).
Table 6-21. DM6435 DSP System Event Mapping
DSP
SYSTEM
EVENT
DSP
INTERRUPT
NUMBER
ACRONYM
SOURCE
ACRONYM
SOURCE
NUMBER
0
EVT0
C64x+ Int Ctl 0
C64x+ Int Ctl 1
C64x+ Int Ctl 2
C64x+ Int Ctl 3
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
GPIO0
GPIO1
GPIO2
GPIO3
GPIO4
GPIO5
GPIO6
GPIO7
GPIO
1
EVT1
GPIO
2
EVT2
GPIO
3
EVT3
GPIO
4
TINTL0
TINTH0
TINTL1
TINTH1
WDINT
Timer 0 – TINT12
Timer 0 – TINT34
Timer 1 – TINT12
Timer 1 – TINT34
Timer 2 – TINT12
C64x+ EMC
GPIO
5
GPIO
6
GPIO
7
GPIO
8
GPIOBNK0
GPIOBNK1
GPIOBNK2
GPIOBNK3
GPIOBNK4
GPIOBNK5
GPIOBNK6
GPIO
9
EMU_DTDMA
GPIO
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
Reserved
GPIO
EMU_RTDXRX
EMU_RTDXTX
IDMAINT0
C64x+ RTDX
C64x+ RTDX
C64x+ EMC 0
C64x+ EMC 1
Reserved
GPIO
GPIO
GPIO
IDMAINT1
GPIO
Reserved
PWM0
PWM1
PWM2
I2C
Reserved
PWM0
Reserved
PWM1
Reserved
PWM2
Reserved
IICINT0
UARTINT0
UARTINT1
Reserved
UART0
UART1
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
VDINT0
VDINT1
VDINT2
HISTINT
H3AINT
PRVUINT
RSZINT
VPSS – CCDC 0
VPSS – CCDC 1
VPSS – CCDC 2
VPSS – Histogram
VPSS – AE/AWB/AF
VPSS – Previewer
VPSS – Resizer
Reserved
C64x+ Interrupt Controller Dropped CPU
Interrupt Event
32
Reserved
96
INTERR
33
34
35
36
37
38
39
40
41
42
Reserved
97
98
EMC_IDMAERR
C64x+ EMC Invalid IDMA Parameters
EDMA3CC_INTG
EDMA3CC_INT0
EDMA3CC_INT1
EDMA3CC_ERRINT
EDMA3TC_ERRINT0
EDMA3TC_ERRINT1
EDMA3TC_ERRINT2
PSCINT
EDMACC Global Interupt
EDMACC Interrupt Region 0
EDMACC Interrupt Region 1
EDMA CC Error
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
99
100
101
102
103
104
105
106
EDMA TC0 Error
EDMA TC1 Error
EDMA TC2 Error
PSC ALLINT
Reserved
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Table 6-21. DM6435 DSP System Event Mapping (continued)
DSP
SYSTEM
EVENT
DSP
INTERRUPT
NUMBER
ACRONYM
SOURCE
ACRONYM
SOURCE
NUMBER
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
EMACINT
EMAC Memory Controller
Reserved
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
HPIINT
HPI
Reserved
MBXINT0
MBRINT0
McBSP0 Transmit
McBSP0 Receive
Reserved
Reserved
PMC_ED
C64x+ PMC
Reserved
Reserved
Reserved
Reserved
UMCED1
C64x+ UMC 1
C64x+ UMC 2
C64x+ PDC
C64x+ SYS
C64x+ PMC
C64x+ PMC
C64x+ DMC
C64x+ DMC
C64x+ UMC
C64x+ UMC
C64x+ EMC
C64x+ EMC
DDRINT
DDR2 Memory Controller
EMIFA
UMCED2
EMIFAINT
VLQINT
PDCINT
VLYNQ
SYSCMPA
PMCCMPA
PMCDMPA
DMCCMPA
DMCDMPA
UMCCMPA
UMCDMPA
EMCCMPA
EMCBUSERR
Reserved
HECC0INT
HECC1INT
AXINT0
HECC Interrupt 0
HECC Interrupt 1
McASP0 Transmit
McASP0 Receive
Reserved
ARINT0
Reserved
Reserved
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Table 6-22. C64x+ Interrupt Controller Registers
HEX ADDRESS
0x0180 0000
0x0180 0004
0x0180 0008
0x0180 000C
0x0180 0020
0x0180 0024
0x0180 0028
0x0180 002C
0x0180 0040
0x0180 0044
0x0180 0048
0x0180 004C
0x0180 0080
0x0180 0084
0x0180 0088
0x0180 008C
0x0180 00A0
0x0180 00A4
0x0180 00A8
0x0180 00AC
0x0180 00C0
0x0180 00C4
0x0180 00C8
0x0180 00CC
0x0180 00E0
0x0180 00E4
0x0180 00E8
0x0180 00EC
0x0180 0104
0x0180 0108
0x0180 010C
0x0180 0180
0x0180 0184
0x0180 0188
ACRONYM
EVTFLAG0
EVTFLAG1
EVTFLAG2
EVTFLAG3
EVTSET0
REGISTER DESCRIPTION
Event flag register 0
Event flag register 1
Event flag register 2
Event flag register 3
Event set register 0
EVTSET1
Event set register 1
EVTSET2
Event set register 2
EVTSET3
Event set register 3
EVTCLR0
Event clear register 0
EVTCLR1
Event clear register 1
EVTCLR2
Event clear register 2
EVTCLR3
Event clear register 3
EVTMASK0
EVTMASK1
EVTMASK2
EVTMASK3
MEVTFLAG0
MEVTFLAG1
MEVTFLAG2
MEVTFLAG3
EXPMASK0
EXPMASK1
EXPMASK2
EXPMASK3
MEXPFLAG0
MEXPFLAG1
MEXPFLAG2
MEXPFLAG3
INTMUX1
Event mask register 0
Event mask register 1
Event mask register 2
Event mask register 3
Masked event flag register 0
Masked event flag register 1
Masked event flag register 2
Masked event flag register 3
Exception mask register 0
Exception mask register 1
Exception mask register 2
Exception mask register 3
Masked exception flag register 0
Masked exception flag register 1
Masked exception flag register 2
Masked exception flag register 3
Interrupt mux register 1
Interrupt mux register 2
Interrupt mux register 3
Interrupt exception status
Interrupt exception clear
Dropped interrupt mask register
INTMUX2
INTMUX3
INTXSTAT
INTXCLR
INTDMASK
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6.9 External Memory Interface (EMIF)
DM6435 supports several memory and external device interfaces, including:
•
•
Asynchronous EMIF (EMIFA) for interfacing to NOR Flash, SRAM, etc.
NAND Flash
6.9.1 Asynchronous EMIF (EMIFA)
The DM6435 Asynchronous EMIF (EMIFA) provides an 8-bit data bus, an address bus width up to 24-bits,
and 4 chip selects, along with memory control signals. These signals are multiplexed between these
peripherals:
•
•
•
EMIFA and NAND interfaces
VPFE (CCDC)
GPIO
6.9.2 NAND (NAND, SmartMedia, xD)
The EMIFA interface provides both the asynchronous EMIF and NAND interfaces. Four chip selects are
provided and each are individually configurable to provide either EMIFA or NAND support. The NAND
features supported are as follows.
•
•
•
•
•
•
NAND flash on up to 4 asynchronous chip selects.
8-bit data bus width
Programmable cycle timings.
Performs ECC calculation.
NAND Mode also supports SmartMedia and xD memory cards
Boot ROM supports booting of the DM6435 from NAND flash located at CS2
The memory map for EMIFA and NAND registers is shown in Table 6-23. For more details on the EMIFA
and NAND interfaces, see Section 2.9, Documentation Support for the link to the TMS320DM643x DMP
Peripherals Overview Reference Guide (literature number SPRU983) for the TMS320DM643x
Asynchronous External Memory Interface (EMIF) User's Guide (literature number SPRU984).
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Table 6-23. EMIFA/NAND Registers
HEX ADDRESS RANGE
0x01E0 0000
ACRONYM
RCSR
REGISTER NAME
Revision Code and Status Register
0x01E0 0004
AWCCR
-
Asynchronous Wait Cycle Configuration Register
Reserved
0x01E0 0008 - 0x01E0 000F
0x01E0 0010
A1CR
Asynchronous 1 Configuration Register (CS2 Space)
Asynchronous 2 Configuration Register (CS3 Space)
Asynchronous 3 Configuration Register (CS4 Space)
Asynchronous 4 Configuration Register (CS5 Space)
Reserved
0x01E0 0014
A2CR
0x01E0 0018
A3CR
0x01E0 001C
A4CR
0x01E0 0020 - 0x01E0 003F
0x01E0 0040
-
EIRR
EMIF Interrupt Raw Register
0x01E0 0044
EIMR
EMIF Interrupt Mask Register
0x01E0 0048
EIMSR
EIMCR
-
EMIF Interrupt Mask Set Register
EMIF Interrupt Mask Clear Register
Reserved
0x01E0 004C
0x01E0 0050 - 0x01E0 005F
0x01E0 0060
NANDFCR
NANDFSR
NANDF1ECC
NANDF2ECC
NANDF3ECC
NANDF4ECC
-
NAND Flash Control Register
0x01E0 0064
NAND Flash Status Register
0x01E0 0070
NAND Flash 1 ECC Register (CS2 Space)
NAND Flash 2 ECC Register (CS3 Space)
NAND Flash 3 ECC Register (CS4 Space)
NAND Flash 4 ECC Register (CS5 Space)
Reserved
0x01E0 0074
0x01E0 0078
0x01E0 007C
0x01E0 0080 - 0x01E0 0FFF
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6.9.3 EMIFA Electrical Data/Timing
Table 6-24. Timing Requirements for Asynchronous Memory Cycles for EMIFA Module(1)
(see Figure 6-14 and Figure 6-15)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
NOM
MAX
READS and WRITES
Pulse duration, EM_WAIT assertion and deassertion
READS
2
tw(EM_WAIT)
2E
ns
12 tsu(EMDV-EMOEH) Setup time, EM_D[7:0] valid before EM_OE high
5
0
ns
ns
13 th(EMOEH-EMDIV)
Hold time, EM_D[7:0] valid after EM_OE high
Setup time, EM_WAIT asserted before EM_OE high(2)
WRITES
tsu(EMWAIT-
EMOEH)
14
4E + 5
ns
tsu(EMWAIT-
EMWEH)
28
Setup time, EM_WAIT asserted before EM_WE high(2)
4E + 5
ns
(1) E = SYSCLK3 period in ns for EMIFA. For example, when running the DSP CPU at 600 MHz, use E = 10 ns.
(2) Setup before end of STROBE phase (if no extended wait states are inserted) by which EM_WAIT must be asserted to add extended
wait states. Figure 6-16 and Figure 6-17 describe EMIF transactions that include extended wait states inserted during the STROBE
phase. However, cycles inserted as part of this extended wait period should not be counted; the 4E requirement is to the start of where
the HOLD phase would begin if there were no extended wait cycles.
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Table 6-25. Switching Characteristics Over Recommended Operating Conditions for Asynchronous
Memory Cycles for EMIFA Module(1)(2) (see Figure 6-14 and Figure 6-15)
-4/-4Q/-4S
-5/-5Q/-5S
NO
.
PARAMETER
UNIT
-6
MIN
NOM
MAX
READS and WRITES
1
3
td(TURNAROUND)
Turn around time
(TA + 1) * E
ns
ns
READS
(RS + RST + RH +
TA + 4) * E(3)
tc(EMRCYCLE)
EMIF read cycle time
Output setup time, EM_CS[5:2] low to
EM_OE low (SS = 0)
(RS + 1) * E - 4
-4
(RS + 1) * E + 4 ns
ns
(RH + 1) * E + 4 ns
ns
4
5
tsu(EMCSL-EMOEL)
Output setup time, EM_CS[5:2] low to
EM_OE low (SS = 1)
4
Output hold time, EM_OE high to
EM_CS[5:2] high (SS = 0)
(RH + 1) * E - 4
-4
th(EMOEH-EMCSH)
Output hold time, EM_OE high to
EM_CS[5:2] high (SS = 1)
4
Output setup time, EM_BA[1:0] valid to
EM_OE low
6
7
8
9
tsu(EMBAV-EMOEL)
th(EMOEH-EMBAIV)
tsu(EMBAV-EMOEL)
th(EMOEH-EMBAIV)
(RS + 1) * E - 4
(RH + 1) * E - 4
(RS + 1) * E - 4
(RH + 1) * E - 4
(RS + 1) * E + 4 ns
(RH + 1) * E + 4 ns
(RS + 1) * E + 4 ns
Output hold time, EM_OE high to
EM_BA[1:0] invalid
Output setup time, EM_A[21:0] valid to
EM_OE low
Output hold time, EM_OE high to
EM_A[21:0] invalid
(RH + 1) * E + 4 ns
10 tw(EMOEL)
EM_OE active low width
(RST + 1) * E(3)
ns
Delay time from EM_WAIT deasserted
to EM_OE high
11 td(EMWAITH-EMOEH)
4E + 4 ns
WRITES
(WS + WST + WH +
TA + 4) * E(3)
15 tc(EMWCYCLE)
EMIF write cycle time
ns
Output setup time, EM_CS[5:2] low to
EM_WE low (SS = 0)
(WS + 1) * E - 4
-4
(WS + 1) * E + 4 ns
16 tsu(EMCSL-EMWEL)
Output setup time, EM_CS[5:2] low to
EM_WE low (SS = 1)
4
ns
(WH + 1) * E + 4 ns
ns
Output hold time, EM_WE high to
EM_CS[5:2] high (SS = 0)
(WH + 1) * E - 4
-4
17 th(EMWEH-EMCSH)
Output hold time, EM_WE high to
EM_CS[5:2] high (SS = 1)
4
Output setup time, EM_R/W valid to
EM_WE low
18 tsu(EMRNW-EMWEL)
19 th(EMWEH-EMRNW)
20 tsu(EMBAV-EMWEL)
21 th(EMWEH-EMBAIV)
22 tsu(EMAV-EMWEL)
(WS + 1) * E - 4
(WH + 1) * E - 4
(WS + 1) * E - 4
(WH + 1) * E - 4
(WS + 1) * E - 4
(WS + 1) * E + 4 ns
(WH + 1) * E + 4 ns
(WS + 1) * E + 4 ns
(WH + 1) * E + 4 ns
(WS + 1) * E + 4 ns
Output hold time, EM_WE high to
EM_R/W invalid
Output setup time, EM_BA[1:0] valid to
EM_WE low
Output hold time, EM_WE high to
EM_BA[1:0] invalid
Output setup time, EM_A[21:0] valid to
EM_WE low
(1) RS = Read setup, RST = Read STrobe, RH = Read Hold, WS = Write Setup, WST = Write STrobe, WH = Write Hold, TA = Turn
Around, EW = Extend Wait mode, SS = Select Strobe mode. These parameters are programmed via the Asynchronous n Configuration
and Asynchronous Wait Cycle Configuration Registers.
(2) E = SYSCLK3 period in ns for EMIFA. For example, when running the DSP CPU at 600 MHz, use E = 10 ns.
(3) When EW = 1, the EMIF will extend the strobe period up to 4,096 additional cycles when the EM_WAIT pin is asserted by the external
device.
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Table 6-25. Switching Characteristics Over Recommended Operating Conditions for Asynchronous
Memory Cycles for EMIFA Module (see Figure 6-14 and Figure 6-15) (continued)
-4/-4Q/-4S
-5/-5Q/-5S
NO
.
PARAMETER
UNIT
-6
MIN
NOM
MAX
Output hold time, EM_WE high to
EM_A[21:0] invalid
23 th(EMWEH-EMAIV)
24 tw(EMWEL)
(WH + 1) * E - 4
(WH + 1) * E + 4 ns
ns
EM_WE active low width
(WST + 1) * E(3)
Delay time from EM_WAIT deasserted
to EM_WE high
25 td(EMWAITH-EMWEH)
4E + 4 ns
Output setup time, EM_D[7:0] valid to
EM_WE low
26 tsu(EMDV-EMWEL)
27 th(EMWEH-EMDIV)
(WS + 1) * E - 4
(WH + 1) * E - 4
(WS + 1) * E + 4 ns
(WH + 1) * E + 4 ns
Output hold time, EM_WE high to
EM_D[7:0] invalid
3
1
EM_CS[5:2]
EM_R/W
EM_BA[1:0]
EM_A[21:0]
4
8
5
9
7
6
10
EM_OE
13
12
EM_D[7:0]
EM_WE
Figure 6-14. Asynchronous Memory Read Timing for EMIF
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15
1
EM_CS[5:2]
EM_R/W
EM_BA[1:0]
EM_A[21:0]
16
18
20
22
17
19
21
23
24
EM_WE
27
26
EM_D[7:0]
EM_OE
Figure 6-15. Asynchronous Memory Write Timing for EMIF
SETUP
STROBE
Extended Due to EM_WAIT
STROBE HOLD
EM_CS[5:2]
EM_BA[1:0]
EM_A[21:0]
EM_D[7:0]
14
11
EM_OE
2
2
Asserted
Deasserted
EM_WAIT
Figure 6-16. EM_WAIT Read Timing Requirements
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SETUP
STROBE
Extended Due to EM_WAIT
STROBE HOLD
EM_CS[5:2]
EM_BA[1:0]
EM_A[21:0]
EM_D[7:0]
28
25
EM_WE
2
2
Asserted
Deasserted
EM_WAIT
Figure 6-17. EM_WAIT Write Timing Requirements
6.9.4 DDR2 Memory Controller
The DDR2 Memory Controller is a dedicated interface to DDR2 SDRAM. It supports JESD79D-2A
standard compliant DDR2 SDRAM Devices and can interface to either 16-bit or 32-bit DDR2 SDRAM
devices. For details on the DDR2 Memory Controller, see Section 2.9, Document Support for the link to
the TMS320DM643x DMP Peripherals Overview Reference Guide (literature number SPRU983) for the
TMS320C642x/DM643x DMP DDR2 Memory Controller User's Guide (literature number SPRU986).
DDR2 SDRAM plays a key role in a DaVinci-based system. Such a system is expected to require a
significant amount of high-speed external memory for:
•
•
•
Buffering of input image data from sensors or video sources
Intermediate buffering for processing/resizing of image data in the VPFE
Intermediate buffering for large raw Bayer data image files while performing image processing
functions
•
•
Buffering for intermediate data while performing video encode and decode functions
Storage of executable code for the DSP
A memory map of the DDR2 Memory Controller registers is shown in Table 6-26.
Table 6-26. DDR2 Memory Controller Registers
HEX ADDRESS RANGE
0x01C4 004C
ACRONYM
DDRVTPER
DDRVTPR
-
REGISTER NAME
DDR2 VTP Enable Register
DDR2 VTP Register
Reserved
0x01C4 2038
0x2000 0000 - 0x2000 0003
0x2000 0004
SDRSTAT
SDBCR
SDRCR
SDTIMR
SDTIMR2
PBBPR
-
SDRAM Status Register
0x2000 0008
SDRAM Bank Configuration Register
SDRAM Refresh Control Register
SDRAM Timing Register
0x2000 000C
0x2000 0010
0x2000 0014
SDRAM Timing Register 2
Peripheral Bus Burst Priority Register
Reserved
0x2000 0020
0x2000 0024 - 0x2000 00BF
0x2000 00C0
IRR
Interrupt Raw Register
0x2000 00C4
IMR
Interrupt Masked Register
Interrupt Mask Set Register
Interrupt Mask Clear Register
0x2000 00C8
IMSR
0x2000 00CC
IMCR
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Table 6-26. DDR2 Memory Controller Registers (continued)
HEX ADDRESS RANGE
0x2000 00D0 - 0x2000 00E3
0x2000 00E4
ACRONYM
REGISTER NAME
-
Reserved
DDRPHYCR
DDR PHY Control Register
Reserved
0x2000 00E8 - 0x2000 00EF
0x2000 00F0
-
VTPIOCR
-
DDR VTP IO Control Register
Reserved
0x2000 00F4 - 0x2000 7FFF
6.9.4.1 DDR2 Memory Controller Electrical Data/Timing
The Implementing DDR2 PCB Layout on the TMS320DM643x DMP DMSoC Application Report (literature
number SPRAAL6) specifies a complete DDR2 interface solution for the DM6435 as well as a list of
compatible DDR2 devices. TI has performed the simulation and system characterization to ensure all
DDR2 interface timings in this solution are met.
TI only supports board designs that follow the guidelines outlined in the Implementing DDR2 PCB Layout
on the TMS320DM643x DMP DMSoC Application Report (literature number SPRAAL6).
Table 6-27. Switching Characteristics Over Recommended Operating Conditions for DDR2 Memory
Controller(1)(2)(see Figure 6-18)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
1
tc(DDR_CLK)
Cycle time, DDR_CLK
6
8
ns
(1) DDR_CLK cycle time = 2 x PLL2 _SYSCLK1 cycle time.
(2) The PLL2 Controller must be programmed such that the resulting DDR_CLK clock frequency is within the specified range.
1
DDR_CLK
Figure 6-18. DDR2 Memory Controller Clock Timing
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6.10 Video Processing Sub-System (VPSS) Overview
The DM6435 Video Processing Sub-System (VPSS) provides a Video Processing Front End (VPFE) input
interface for external imaging peripherals (i.e., image sensors, video decoders, etc.); the DM6435 VPSS
does not support a Video Processing Back End (VPBE) output interface.
The VPSS register memory mapping is shown in Table 6-28.
Table 6-28. VPSS Register Descriptions
HEX ADDRESS RANGE
0x01C7 3400
REGISTER ACRONYM
Description
Peripheral Revision and Class Information
VPSS Control Register
PID
PCR
-
0x01C7 3404
0x01C7 3408
Reserved
0x01C7 3508
SDR_REG_EXP
-
SDRAM Non Real-Time Read Request Expand
Reserved
0x01C7 350C -
0x01C7 3FFF
6.10.1 Video Processing Front-End (VPFE)
The Video Processing Front-End (VPFE) consists of the CCD Controller (CCDC), Preview Engine,
Resizer, Hardware 3A (H3A) Statistic Generator, and Histogram blocks. Together, these modules provide
DM6435 with a powerful and flexible front-end interface. These modules are briefly described below:
•
•
The CCDC provides an interface to image sensors and digital video sources.
The Preview Engine is a parameterized hardwired image processing block which is used for converting
RAW color data from a Bayer pattern to YUV 4:2:2.
•
•
The Resizer module re-sizes the input image data to the desired display or video encoding resolution.
The H3A module provides control loops for Auto Focus (AF), Auto White Balance (AWB) and Auto
Exposure (AE).
•
The Histogram module bins input color pixels, depending on the amplitude, and provides statistics
required to implement various 3A (AE/AF/AWB) algorithms and tune the final image/video output.
The VPFE register memory mapping is shown in Table 6-29.
Table 6-29. VPFE Register Address Range Descriptions
HEX ADDRESS RANGE
0x01C7 0400 – 0x01C7 07FF
0x01C7 0800 – 0x01C7 0BFF
0x01C7 0C00 – 0x01C7 09FF
0x01C7 1000 – 0x01C7 13FF
0x01C7 1400 – 0x01C7 17FF
0x01C7 3400 – 0x01C7 3FFF
ACRONYM
CCDC
REGISTER NAME
VPFE – CCD Controller
PREV
RESZ
HIST
H3A
VPFE – Preview Engine/Image Signal Processor
VPFE – Resizer
VPFE – Histogram
VPFE – Hardware 3A (Auto-Focus/WB/Exposure)
VPSS Shared Buffer Logic Registers
VPSS
6.10.1.1 CCD Controller (CCDC)
The CCDC receives raw image/video data from sensors (CMOS or CCD) or YUV video data in numerous
formats from video decoder devices. The following features are supported by the CCDC module.
•
•
Conventional Bayer pattern format.
Generates HD/VD timing signals and field ID to an external timing generator or can synchronize to an
external timing generator.
•
•
•
•
Interface to progressive and interlaced sensors.
REC656/CCIR-656 standard (YCbCr 4:2:2 format, either 8- or 16-bit).
YCbCr 4:2:2 format, either 8- or 16-bit with discrete H and VSYNC signals.
Up to 16-bit input.
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•
•
•
•
•
Optical black clamping signal generation.
Shutter signal control.
Digital clamping and black level compensation.
10-bit to 8-bit A-law compression.
Low-pass filter prior to writing to SDRAM. If this filter is enabled, 2 pixels each in the left and right
edges of each line are cropped from the output.
•
•
•
•
Output range from 16-bits to 8-bits wide (8-bits wide allows for 50% saving in storage area).
Downsampling via programmable culling patterns.
Control output to the DDR2 via an external write enable signal.
Up to 16K pixels (image size) in both the horizontal and vertical direction.
The CCDC register memory mapping is shown in Table 6-30.
Table 6-30. CCDC Register Descriptions
HEX ADDRESS RANGE
REGISTER ACRONYM
DESCRIPTION
0x01C7 0400
0x01C7 0404
0x01C7 0408
0x01C7 040C
0x01C7 0410
0x01C7 0414
0x01C7 0418
0x01C7 041C
0x01C7 0420
0x01C7 0424
0x01C7 0428
0x01C7 042C
0x01C7 0430
0x01C7 0434
0x01C7 0438
0x01C7 043C
0x01C7 0440
0x01C7 0444
0x01C7 0448
0x01C7 044C
0x01C7 0450
0x01C7 0454
0x01C7 0458
0x01C7 045C
0x01C7 0460
0x01C7 0464
0x01C7 0468
0x01C7 046C
0x01C7 0470
0x01C7 0474
0x01C7 0478
0x01C7 047C
0x01C7 0480
0x01C7 0484
PID
Peripheral Revision and Class Information
Peripheral Control Register
SYNC and Mode Set Register
HD and VD Signal Width
PCR
SYN_MODE
HD_VD_WID
PIX_LINES
HORZ_INFO
VERT_START
VERT_LINES
CULLING
Number of Pixels in a Horizontal Line and Number of Lines in a Frame
Horizontal Pixel Information
Vertical Line - Settings for the Starting Pixel
Number of Vertical Lines
Culling Information in Horizontal and Vertical Directions
Horizontal Size
HSIZE_OFF
SDOFST
SDRAM/DDRAM Line Offset
SDRAM Address
SDR_ADDR
CLAMP
Optical Black Clamping Settings
DC Clamp
DCSUB
COLPTN
CCD Color Pattern
BLKCMP
Black Compensation
-
Reserved
-
Reserved
VDINT
VD Interrupt Timing
ALAW
A-Law Setting
REC656IF
CCDCFG
REC656 Interface
CCD Configuration
FMTCFG
Data Reformatter/Video Port Configuration
Data Reformatter/Video Input Interface Horizontal Information
Data Reformatter/Video Input Interface Vertical Information
Address Pointer 0 Setup
FMT_HORZ
FMT_VERT
FMT_ADDR0
FMT_ADDR1
FMT_ADDR2
FMT_ADDR3
FMT_ADDR4
FMT_ADDR5
FMT_ADDR6
FMT_ADDR7
PRGEVEN_0
Address Pointer 1 Setup
Address Pointer 2 Setup
Address Pointer 3 Setup
Address Pointer 4 Setup
Address Pointer 5 Setup
Address Pointer 6 Setup
Address Pointer 7 Setup
Program Entries 0-7 for Even Line
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Table 6-30. CCDC Register Descriptions (continued)
HEX ADDRESS RANGE
0x01C7 0488
REGISTER ACRONYM
RRGEVEN_1
DESCRIPTION
Program Entries 8-15 for Even Line
0x01C7 048C
PRGGODD_0
PRGGODD_1
VP_OUT
Program Entries 0-7 for Odd Line
Program Entries 8-15 for Odd Line
Video Port Output Settings
0x01C7 0490
0x01C7 0494
6.10.1.2 Preview Engine
The preview engine transforms raw unprocessed image/video data from a sensor (CMOS or CCD) into
YCbCr 4:2:2 data. The output of the preview engine is used for both video compression and external
display devices such as a NTSC/PAL analog encoder or a digital LCD. The following features are
supported by the preview engine.
•
•
•
•
Accepts conventional Bayer pattern formats.
Input image/video data from either the CCD/CMOS controller or the DDR2 memory.
Output width up to 1280 pixels wide.
Automatic/mandatory cropping of pixels/lines when edge processing is performed. If all the
corresponding modules are enabled, a total of 14 pixels per line (7 left most and 7 right most) and 8
lines (4 top most and 4 bottom most) will not be output.
•
Simple horizontal averaging (by factors of 2, 4, or 8) to handle input widths that are greater than 1280
(plus the cropped number) pixels wide.
•
•
Dark frame capture to DDR2.
Dark frame subtraction for every input raw data frame, fetched from DDR2, pixel-by-pixel to improve
video quality.
•
•
Lens shading compensation. Each input pixel is multiplied with a corresponding 8-bit gain value and
the result is right shifted by a programmable parameter (0-7 bits).
A-law decompression to transform non-linear 8-bit data to 10-bit linear data. This feature allows data in
DDR2 to be 8-bits, which saves 50% of the area if the input to the preview engine is from the DDR2.
•
•
Horizontal median filter for reducing temperature induced noise in pixels.
Programmable noise filter that operates on a 3x3 grid of the same color (effectively, this is a five line
storage requirement).
•
•
•
•
Digital gain and white balance (color separate gain for white balance).
Programmable CFA interpolation that operates on a 5x5 grid.
Conventional Bayer pattern RGB and complementary color sensors.
Support for an image that is downsampled by 2x in the horizontal direction (with and without phase
correction). In this case, the image is 2/3 populated instead of the conventional 1/3 colors.
•
Support for an image that is downsampled by 2x in both the horizontal and vertical direction. In this
case, the image is fully populated instead of the conventional 1/3 colors.
•
•
•
•
Programmable RGB-to-RGB blending matrix (9 coefficients for the 3x3 matrix).
Fully programmable gamma correction (1024 entries for each color held in an on-chip RAM).
Programmable color conversion (RGB to YUV) coefficients (9 coefficients for the 3x3 matrix).
Luminance enhancement (non-linear) and chrominance suppression & offset.
The Preview Engine register memory mapping is shown in Table 6-31.
Table 6-31. Preview Engine Register Descriptions
HEX ADDRESS RANGE
REGISTER ACRONYM
DESCRIPTION
0x01C7 0800
0x01C7 0804
0x01C7 0808
PID
Peripheral Revision and Class Information
Peripheral Control Register
PCR
HORZ_INFO
Horizontal Information/Setup
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Table 6-31. Preview Engine Register Descriptions (continued)
HEX ADDRESS RANGE
0x01C7 080C
0x01C7 0810
0x01C7 0814
0x01C7 0818
0x01C7 081C
0x01C7 0820
0x01C7 0824
0x01C7 0828
0x01C7 082C
0x01C7 0830
0x01C7 0834
0x01C7 0838
0x01C7 083C
0x01C7 0840
0x01C7 0844
0x01C7 0848
0x01C7 084C
0x01C7 0850
0x01C7 0854
0x01C7 0858
0x01C7 085C
0x01C7 0860
0x01C7 0864
0x01C7 0868
0x01C7 086C
0x01C7 0870
0x01C7 0874
0x01C7 0878
0x01C7 087C
0x01C7 0880
0x01C7 0884
REGISTER ACRONYM
VERT_INFO
DESCRIPTION
Vertical Information/Setup
RSDR_ADDR
RADR_OFFSET
DSDR_ADDR
DRKF_OFFSET
WSDR_ADDR
WADD_OFFSET
AVE
Read Address From SDRAM
Line Offset for the Read Data
Dark Frame Address From SDRAM
Line Offset for the Dark Frame Data
Write Address to the SDRAM
Line Offset for the Write Data
Input Formatter/Averager
HMED
Horizontal Median Filter
NF
Noise Filter
WB_DGAIN
WBGAIN
White Balance Digital Gain
White Balance Coefficients
WBSEL
White Balance Coefficients Selection
CFA Register
CFA
BLKADJOFF
RGB_MAT1
RGB_MAT2
RGB_MAT3
RGB_MAT4
RGB_MAT5
RGB_OFF1
RGB_OFF2
CSC0
Black Adjustment Offset
RGB2RGB Blending Matrix Coefficients
RGB2RGB Blending Matrix Coefficients
RGB2RGB Blending Matrix Coefficients
RGB2RGB Blending Matrix Coefficients
RGB2RGB Blending Matrix Coefficients
RGB2RGB Blending Matrix Offsets
RGB2RGB Blending Matrix Offsets
Color Space Conversion Coefficients
Color Space Conversion Coefficients
Color Space Conversion Coefficients
Color Space Conversion Offsets
Contrast and Brightness Settings
Chrominance Suppression Settings
Maximum/Minimum Y and C Settings
Setup Table Addresses
CSC1
CSC2
CSC_OFFSET
CNT_BRT
CSUP
SETUP_YC
SET_TBL_ADDRESS
SET_TBL_DATA
Setup Table Data
6.10.1.3 Resizer
The resizer module can accept input image/video data from either the preview engine or DDR2. The
output of the resizer module is sent to DDR2. The following features are supported by the resizer module.
•
•
•
•
An output width up to 1280 horizontal pixels.
Input from external DDR2.
Up to 4x upsampling (digital zoom).
Bi-cubic interpolation (4-tap horizontal, 4-tap vertical) can be implemented with the programmable filter
coefficients.
•
•
•
•
•
•
8 phases of filter coefficients.
Optional bi-linear interpolation for the chrominance components.
Up to 1/4x downsampling
4-tap horizontal and 4-tap vertical filter coefficients (with 8-phases) for 1x to 1/2x downsampling
1/2x to 1/4x downsampling, for 7-tap mode with 4-phases.
Resizing either YUV 4:2:2 packed data (16-bits) or color separate data (8-bit data within DDR) that is
contiguous.
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•
•
•
Separate/independent resizing factor for the horizontal and vertical directions.
Upsampling and downsampling ratios that are available are: 256/N, with N ranging from 64 to 1024.
Programmable luminance sharpening after the horizontal resizing and before the vertical resizing step.
The Resizer register memory mapping is shown in Table 6-32.
Table 6-32. Resizer Register Descriptions
HEX ADDRESS RANGE
REGISTER ACRONYM
DESCRIPTION
0x01C7 0C00
0x01C7 0C04
0x01C7 0C08
0x01C7 0C0C
0x01C7 0C10
0x01C7 0C14
0x01C7 0C18
0x01C7 0C1C
0x01C7 0C20
0x01C7 0C24
0x01C7 0C28
0x01C7 0C2C
0x01C7 0C30
0x01C7 0C34
0x01C7 0C38
0x01C7 0C3C
0x01C7 0C40
0x01C7 0C44
0x01C7 0C48
0x01C7 0C4C
0x01C7 0C50
0x01C7 0C54
0x01C7 0C58
0x01C7 0C5C
0x01C7 0C60
0x01C7 0C64
0x01C7 0C68
0x01C7 0C6C
0x01C7 0C70
0x01C7 0C74
0x01C7 0C78
0x01C7 0C7C
0x01C7 0C80
0x01C7 0C84
0x01C7 0C88
0x01C7 0C8C
0x01C7 0C90
0x01C7 0C94
0x01C7 0C98
0x01C7 0C9C
0x01C7 0CA0
0x01C7 0CA4
PID
Peripheral Revision and Class Information
Peripheral Control Register
PCR
RSZ_CNT
OUT_SIZE
IN_START
IN_SIZE
Resizer Control Bits
Output Width and Height After Resizing
Input Starting Information
Input Width and Height Before Resizing
Input SDRAM Address
SDR_INADD
SDR_INOFF
SDR_OUTADD
SDR_OUTOFF
HFILT10
SDRAM Offset for the Input Line
Output SDRAM Address
SDRAM Offset for the Output Line
Horizontal Filter Coefficients 1 and 0
Horizontal Filter Coefficients 3 and 2
Horizontal Filter Coefficients 5 and 4
Horizontal Filter Coefficients 7 and 6
Horizontal Filter Coefficients 9 and 8
Horizontal Filter Coefficients 11 and 10
Horizontal Filter Coefficients 13 and 12
Horizontal Filter Coefficients 15 and 14
Horizontal Filter Coefficients 17 and 16
Horizontal Filter Coefficients 19 and 18
Horizontal Filter Coefficients 21 and 20
Horizontal Filter Coefficients 23 and 22
Horizontal Filter Coefficients 25 and 24
Horizontal Filter Coefficients 27 and 26
Horizontal Filter Coefficients 29 and 28
Horizontal Filter Coefficients 31 and 30
Vertical Filter Coefficients 1 and 0
Vertical Filter Coefficients 3 and 2
Vertical Filter Coefficients 5 and 4
Vertical Filter Coefficients 7 and 6
Vertical Filter Coefficients 9 and 8
Vertical Filter Coefficients 11 and 10
Vertical Filter Coefficients 13 and 12
Vertical Filter Coefficients 15 and 14
Vertical Filter Coefficients 17 and 16
Vertical Filter Coefficients 19 and 18
Vertical Filter Coefficients 21 and 20
Vertical Filter Coefficients 23 and 22
Vertical Filter Coefficients 25 and 24
Vertical Filter Coefficients 27 and 26
Vertical Filter Coefficients 29 and 28
Vertical Filter Coefficients 31 and 30
HFILT32
HFILT54
HFILT76
HFILT98
HFILT1110
HFILT1312
HFILT1514
HFILT1716
HFILT1918
HFILT2120
HFILT2322
HFILT2524
HFILT2726
HFILT2928
HFILT3130
VFILT10
VFILT32
VFILT54
VFILT76
VFILT98
VFILT1110
VFILT1312
VFILT1514
VFILT1716
VFILT1918
VFILT2120
VFILT2322
VFILT2524
VFILT2726
VFILT2928
VFILT3130
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Table 6-32. Resizer Register Descriptions (continued)
HEX ADDRESS RANGE
REGISTER ACRONYM
DESCRIPTION
0x01C7 0CA8
YENH
Luminance Enhancer
6.10.1.4 Hardware 3A (H3A)
The Hardware 3A (H3A) module provides control loops for Auto Focus, Auto White Balance and Auto
Exposure. There are 2 main components of the H3A module:
•
•
Auto Focus (AF) Engine
Auto Exposure (AE) & Auto White Balance (AWB) Engine
The AF engine extracts and filters the red, green, and blue data from the input image/video data and
provides either the accumulation or peaks of the data in a specified region. The specified region is a two
dimensional block of data and is referred to as a “paxel” for the case of AF.
The AE/AWB Engine accumulates the values and checks for saturated values in a sub sampling of the
video data. In the case of the AE/AWB, the two-dimensional block of data is referred to as a “window”.
The number, dimensions, and starting position of the AF paxels and the AE/AWB windows are separately
programmable.
The H3A register memory mapping is shown in Table 6-33.
Table 6-33. H3A Register Descriptions
HEX ADDRESS RANGE
0x01C7 1400
0x01C7 1404
0x01C7 1408
0x01C7 140C
0x01C7 1410
0x01C7 1414
0x01C7 1418
0x01C7 141C
0x01C7 1420
0x01C7 1424
0x01C7 1428
0x01C7 142C
0x01C7 1430
0x01C7 1434
0x01C7 1438
0x01C7 143C
0x01C7 1440
0x01C7 1444
0x01C7 1448
0x01C7 144C
0x01C7 1450
0x01C7 1454
0x01C7 1458
0x01C7 145C
REGISTER ACRONYM
DESCRIPTION
Peripheral Revision and Class Information
Peripheral Control Register
PID
PCR
AFPAX1
Setup for the AF Engine Paxel Configuration
Setup for the AF Engine Paxel Configuration
Start Position for AF Engine Paxels
AFPAX2
AFPAXSTART
AFIIRSH
Start Position for IIRSH
AFBUFST
SDRAM/DDRAM Start Address for AF Engine
IIR Filter Coefficient Data for SET 0
IIR Filter Coefficient Data for SET 0
IIR Filter Coefficient Data for SET 0
IIR Filter Coefficient Data for SET 0
IIR Filter Coefficient Data for SET 0
IIR Filter Coefficient Data for SET 0
IIR Filter Coefficient Data for SET 1
IIR Filter Coefficient Data for SET 1
IIR Filter Coefficient Data for SET 1
IIR Filter Coefficient Data for SET 1
IIR Filter Coefficient Data for SET 1
IIR Filter Coefficient Data for SET 1
Configuration for AE/AWB Windows
Start Position for AE/AWB Windows
Start Position and Height for Black Line of AE/AWB Windows
Configuration for Subsample Data in AE/AWB Window
SDRAM/DDRAM Start Address for AE/AWB Engine
AFCOEF010
AFCOEF032
AFCOEFF054
AFCOEFF076
AFCOEFF098
AFCOEFF0010
AFCOEF110
AFCOEF132
AFCOEFF154
AFCOEFF176
AFCOEFF198
AFCOEFF1010
AEWWIN1
AEWINSTART
AEWINBLK
AEWSUBWIN
AEWBUFST
6.10.1.4.1 Auto Focus (AF) Engine
The following features are supported by the Auto Focus (AF) Engine.
•
•
Peak Mode in a Paxel (a Paxel is defined as a two dimensional block of pixels).
Accumulate the maximum Focus Value of each line in a Paxel
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•
•
•
•
•
•
•
•
Accumulation/Sum Mode (instead of Peak mode).
Accumulate Focus Value in a Paxel.
Up to 36 Paxels in the horizontal direction and up to 128 Paxels in the vertical direction.
Programmable width and height for the Paxel. All paxels in the frame will be of same size.
Programmable red, green, and blue position within a 2x2 matrix.
Separate horizontal start for paxel and filtering.
Programmable vertical line increments within a paxel.
Parallel IIR filters configured in a dual-biquad configuration with individual coefficients (2 filters with 11
coefficients each). The filters are intended to compute the sharpness/peaks in the frame to focus on.
6.10.1.4.2 Auto Exposure (AE) and Auto White Balance (AWB) Engine
The following features are supported by the Auto Exposure (AE) and Auto White Balance (AWB) Engine.
•
•
•
•
•
Accumulate clipped pixels along with all non-saturated pixels.
Up to 36 horizontal windows.
Up to 128 vertical windows.
Programmable width and height for the windows. All windows in the frame will be of same size.
Separate vertical start coordinate and height for a black row of paxels that is different than the
remaining color paxels.
•
•
Programmable Horizontal Sampling Points in a window.
Programmable Vertical Sampling Points in a window.
6.10.1.5 Histogram
The histogram module accepts raw image/video data and bins the pixels on a value (and color separate)
basis. The value of the pixel itself is not stored, but each bin contains the number of pixels that are within
the appropriate set range. The source of the raw data for the histogram is typically a CCD/CMOS sensor
(via the CCDC module) or optionally from DDR2. The following features are supported by the histogram
module.
•
•
•
Up to four regions/areas.
Separate horizontal/vertical start and end position for each region.
Pixels from overlapping regions are accumulated into the highest priority region. The priority is: region0
> region1 > region2 > region3.
•
•
•
•
•
•
Interface to conventional Bayer pattern. Each region can accumulate either 3 or 4 colors.
32, 64, 128, or 256 bins per color per region.
32, 64, or 128 bins per color for 2 regions.
32 or 64 bins per color for 3 or 4 regions.
Automatic clear of histogram RAM after an ARM read.
Saturation of the pixel count if the count exceeds the maximum value (each memory location is 20-bit
wide).
•
•
Downshift ranging from 0 to 7 bits (maximum bin range 128).
The last bin (highest range of values) will accumulate any value that is higher than the lower bound.
The Histogram register memory mapping is shown in Table 6-34.
Table 6-34. Histogram Register Descriptions
HEX ADDRESS RANGE
REGISTER ACRONYM
DESCRIPTION
0x01C7 1000
0x01C7 1004
0x01C7 1008
0x01C7 100C
PID
Peripheral Revision and Class Information Register
Peripheral Control Register
PCR
HIST_CNT
WB_GAIN
Histogram Control Bits Register
White/Channel Balance Settings Register
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Table 6-34. Histogram Register Descriptions (continued)
HEX ADDRESS RANGE
0x01C7 1010
0x01C7 1014
0x01C7 1018
0x01C7 101C
0x01C7 1020
0x01C7 1024
0x01C7 1028
0x01C7 102C
0x01C7 1030
0x01C7 1034
0x01C7 1038
0x01C7 103C
0x01C7 1040
REGISTER ACRONYM
R0_HORZ
DESCRIPTION
Region 0 Horizontal Information Register
Region 0 Vertical Information Register
R0_VERT
R1_HORZ
R1_VERT
R2_HORZ
R2_VERT
R3_HORZ
R3_VERT
HIST_ADDR
HIST_DATA
RADD
Region 1 Horizontal Information Register
Region 1 Vertical Information Register
Region 2 Horizontal Information Register
Region 2 Vertical Information Register
Region 3 Horizontal Information Register
Region 3 Vertical Information Register
Histogram Address for Data to be Read Register
Histogram Data That is Read From the Memory Register
Read Address From DDR2 Memory Register
RADD_OFF
H_V_INFO
Read Address Offset for Each Line in the DDR2 Memory Register
Horizontal/Vertical Information Register (Horizontal/Vertical Number of
Pixels When Data is Read From DDR2 Memory Information Register)
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6.10.1.6 VPFE Electrical Data/Timing
Table 6-35. Timing Requirements for VPFE PCLK Master/Slave Mode(1) (see Figure 6-19)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
10.204
0.4P
MAX
1
2
3
4
tc(PCLK)
tw(PCLKH)
tw(PCLKL)
tt(PCLK)
Cycle time, PCLK
ns
ns
ns
ns
Pulse duration, PCLK high
Pulse duration, PCLK low
Transition time, PCLK
0.4P
7
(1) P = PCLK period in ns.
2
3
1
PCLK
4
4
Figure 6-19. VPFE PCLK Timing
Table 6-36. Timing Requirements for VPFE (CCD) Slave Mode(1) (see Figure 6-20)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
5
6
tsu(CCDV-PCLK)
th(PCLK-CCDV)
tsu(HDV-PCLK)
th(PCLK-HDV)
Setup time, CCD valid before PCLK edge
Hold time, CCD valid after PCLK edge
Setup time, HD valid before PCLK edge
Hold time, HD valid after PCLK edge
Setup time, VD valid before PCLK edge
Hold time, VD valid after PCLK edge
Setup time, C_WE valid before PCLK edge
Hold time, C_WE valid after PCLK edge
4.5
1
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
7
4.5
1
8
9
tsu(VDV-PCLK)
th(PCLK-VDV)
tsu(C_WEV-PCLK)
th(PCLK-C_WEV)
4.5
1
10
11
12
13
14
4.5
1
tsu(C_FIELDV-PCLK) Setup time, C_FIELD valid before PCLK edge
th(PCLK-C_FIELDV) Hold time, C_FIELD valid after PCLK edge
4.5
1
(1) The VPFE may be configured to operate in either positive or negative edge clocking mode. When in positive edge clocking mode the
rising edge of PCLK is referenced. When in negative edge clocking mode the falling edge of PCLK is referenced.
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PCLK
(Positive Edge Clocking)
PCLK
(Negative Edge Clocking)
8, 10
7, 9
HD/VD
11, 13
12, 14
C_WE/C_FIELD
CCD[15:0]
5
6
Figure 6-20. VPFE (CCD) Slave Mode Input Data Timing
Table 6-37. Timing Requirements for VPFE (CCD) Master Mode(1) (see Figure 6-21)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
4.5
1
MAX
15
16
23
24
tsu(CCDV-PCLK)
th(PCLK-CCDV)
tsu(CWEV-PCLK)
th(PCLK-CWEV)
Setup time, CCD valid before PCLK edge
Hold time, CCD valid after PCLK edge
Setup time, C_WE valid before PCLK edge
Hold time, C_WE valid after PCLK edge
ns
ns
ns
ns
4.5
1
(1) The VPFE may be configured to operate in either positive or negative edge clocking mode. When in positive edge clocking mode the
rising edge of PCLK is referenced. When in negative edge clocking mode the falling edge of PCLK is referenced.
PCLK
(Positive Edge Clocking)
PCLK
(Positive Edge Clocking)
15
16
CCD[15:0]
23
24
C_WE/C_FIELD
Figure 6-21. VPFE (CCD) Master Mode Input Data Timing
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Table 6-38. Switching Characteristics Over Recommended Operating Conditions for VPFE (CCD) Master
Mode(1) (see Figure 6-22)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
9.5
18
20
22
td(PCLK-HDV)
Delay time, PCLK edge to HD valid
Delay time, PCLK edge to VD valid
Delay time, PCLK edge to C_FIELD valid
2
2
2
ns
ns
ns
td(PCLK-VDV)
9.5
td(PCLK-C_FIELDV)
9.5
(1) The VPFE may be configured to operate in either positive or negative edge clocking mode. When in positive edge clocking mode the
rising edge of PCLK is referenced. When in negative edge clocking mode the falling edge of PCLK is referenced.
PCLK
18
HD
20
VD
22
C_FIELD
Figure 6-22. VPFE (CCD) Master Mode Control Output Data Timing
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6.11 Universal Asynchronous Receiver/Transmitter (UART)
DM6435 has 2 UART peripherals. Each UART has the following features:
•
•
•
•
•
•
•
16-byte storage space for both the transmitter and receiver FIFOs
1, 4, 8, or 14 byte selectable receiver FIFO trigger level for autoflow control and DMA
DMA signaling capability for both received and transmitted data
Programmable auto-rts and auto-cts for autoflow control
Frequency pre-scale values from 1 to 65,535 to generate appropriate baud rates
Prioritized interrupts
Programmable serial data formats
–
–
–
5, 6, 7, or 8-bit characters
Even, odd, or no parity bit generation and detection
1, 1.5, or 2 stop bit generation
•
•
•
False start bit detection
Line break generation and detection
Internal diagnostic capabilities
–
–
Loopback controls for communications link fault isolation
Break, parity, overrun, and framing error simulation
•
Modem control functions (CTS, RTS) on UART0 only.
The UART0/1 registers are listed in Table 6-39 and Table 6-40 .
6.11.1 UART Peripheral Register Description(s)
Table 6-39. UART0 Register Descriptions
HEX ADDRESS RANGE
0x01C2 0000
ACRONYM
REGISTER NAME
RBR
UART0 Receiver Buffer Register (Read Only)
UART0 Transmitter Holding Register (Write Only)
UART0 Interrupt Enable Register
UART0 Interrupt Identification Register (Read Only)
UART0 FIFO Control Register (Write Only)
UART0 Line Control Register
UART0 Modem Control Register
UART0 Line Status Register
0x01C2 0000
THR
0x01C2 0004
IER
0x01C2 0008
IIR
0x01C2 0008
FCR
0x01C2 000C
0x01C2 0010
LCR
MCR
0x01C2 0014
LSR
0x01C2 0018
-
Reserved
0x01C2 001C
0x01C2 0020
-
Reserved
DLL
UART0 Divisor Latch (LSB)
0x01C2 0024
DLH
UART0 Divisor Latch (MSB)
0x01C2 0028
PID1
Peripheral Identification Register 1
Peripheral Identification Register 2
UART0 Power and Emulation Management Register
Reserved
0x01C2 002C
0x01C2 0030
PID2
PWREMU_MGMT
-
0x01C2 0034 - 0x01C2 03FF
Table 6-40. UART1 Register Descriptions
HEX ADDRESS RANGE
0x01C2 0400
ACRONYM
RBR
REGISTER NAME
UART1 Receiver Buffer Register (Read Only)
UART1 Transmitter Holding Register (Write Only)
UART1 Interrupt Enable Register
0x01C2 0400
THR
0x01C2 0404
IER
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Table 6-40. UART1 Register Descriptions (continued)
HEX ADDRESS RANGE
0x01C2 0408
ACRONYM
REGISTER NAME
IIR
UART1 Interrupt Identification Register (Read Only)
UART1 FIFO Control Register (Write Only)
UART1 Line Control Register
UART1 Modem Control Register
UART1 Line Status Register
Reserved
0x01C2 0408
FCR
0x01C2 040C
LCR
0x01C2 0410
MCR
0x01C2 0414
LSR
0x01C2 0418
-
0x01C2 041C
-
Reserved
0x01C2 0420
DLL
UART1 Divisor Latch (LSB)
UART1 Divisor Latch (MSB)
Peripheral Identification Register 1
Peripheral Identification Register 2
UART1 Power and Emulation Management Register
Reserved
0x01C2 0424
DLH
0x01C2 0428
PID1
0x01C2 042C
PID2
0x01C2 0430
PWREMU_MGMT
-
0x01C2 0434 - 0x01C2 07FF
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6.11.2 UART Electrical Data/Timing
Table 6-41. Timing Requirements for UARTx Receive(1) (see Figure 6-23)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
1.05U
1.05U
4
5
tw(URXDB)
tw(URXSB)
Pulse duration, receive data bit (URXDx) [15/30/100 pF]
Pulse duration, receive start bit [15/30/100 pF]
0.96U
0.96U
ns
ns
(1) U = UART baud time = 1/programmed baud rate.
Table 6-42. Switching Characteristics Over Recommended Operating Conditions for UARTx Transmit(1)
(see Figure 6-23)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
128
1
2
3
f(baud)
Maximum programmable baud rate
kHz
ns
tw(UTXDB)
tw(UTXSB)
Pulse duration, transmit data bit (UTXDx) [15/30/100 pF]
Pulse duration, transmit start bit [15/30/100 pF]
U - 2
U - 2
U + 2
U + 2
ns
(1) U = UART baud time = 1/programmed baud rate.
3
2
Start
Bit
UTXDx
Data Bits
5
4
Start
Bit
URXDx
Data Bits
Figure 6-23. UART Transmit/Receive Timing
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6.12 Inter-Integrated Circuit (I2C)
The inter-integrated circuit (I2C) module provides an interface between DM6435 and other devices
compliant with Philips Semiconductors Inter-IC bus (I2C-bus™) specification version 2.1. External
components attached to this 2-wire serial bus can transmit/receive up to 8-bit data to/from the DSP
through the I2C module. The I2C port does not support CBUS compatible devices.
The I2C port supports:
•
•
•
•
•
•
•
Compatible with Philips I2C Specification Revision 2.1 (January 2000)
Fast Mode up to 400 Kbps (no fail-safe I/O buffers)
Noise Filter to Remove Noise 50 ns or less
Seven- and Ten-Bit Device Addressing Modes
Master (Transmit/Receive) and Slave (Transmit/Receive) Functionality
Events: DMA, Interrupt, or Polling
Slew-Rate Limited Open-Drain Output Buffers
I2C Module
Clock
Prescale
Peripheral Clock
(DSP/18)
ICPSC
Control
Bit Clock
Generator
Own
Address
ICOAR
ICSAR
ICMDR
ICCNT
SCL
Noise
Filter
I2C Clock
Slave
ICCLKH
ICCLKL
Address
Mode
Data
Count
Transmit
ICXSR
Transmit
Shift
Extended
Mode
ICEMDR
Transmit
Buffer
ICDXR
SDA
Interrupt/DMA
ICIMR
Noise
Filter
I2C Data
Interrupt
Receive
ICDRR
Mask/Status
Receive
Buffer
Interrupt
Status
ICSTR
ICIVR
Interrupt
Vector
Receive
Shift
ICRSR
Shading denotes control/status registers.
Figure 6-24. I2C Module Block Diagram
For more detailed information on the I2C peripheral, see Section 2.9, Documentation Support section of
this document for the TMS320DM643x DMP Peripherals Overview Reference Guide (literature number
SPRU983).
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6.12.1 I2C Peripheral Register Description(s)
Table 6-43. I2C Registers
HEX ADDRESS RANGE
0x1C2 1000
0x1C2 1004
0x1C2 1008
0x1C2 100C
0x1C2 1010
0x1C2 1014
0x1C2 1018
0x1C2 101C
0x1C2 1020
0x1C2 1024
0x1C2 1028
0x1C2 102C
0x1C2 1030
0x1C2 1034
0x1C2 1038
ACRONYM
ICOAR
ICIMR
REGISTER NAME
I2C Own Address Register
I2C Interrupt Mask Register
I2C Interrupt Status Register
ICSTR
ICCLKL
ICCLKH
ICCNT
ICDRR
ICSAR
ICDXR
ICMDR
ICIVR
I2C Clock Divider Low Register
I2C Clock Divider High Register
I2C Data Count Register
I2C Data Receive Register
I2C Slave Address Register
I2C Data Transmit Register
I2C Mode Register
I2C Interrupt Vector Register
I2C Extended Mode Register
I2C Prescaler Register
ICEMDR
ICPSC
ICPID1
ICPID2
I2C Peripheral Identification Register 1
I2C Peripheral Identification Register 2
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6.12.2 I2C Electrical Data/Timing
6.12.2.1 Inter-Integrated Circuits (I2C) Timing
Table 6-44. Timing Requirements for I2C Timings(1) (see Figure 6-25)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
STANDARD
MODE
FAST MODE
MIN
MAX
MIN
MAX
1
2
tc(SCL)
Cycle time, SCL
10
2.5
µs
µs
Setup time, SCL high before SDA low (for a repeated START
condition)
tsu(SCLH-SDAL)
4.7
4
0.6
0.6
Hold time, SCL low after SDA low (for a START and a repeated
START condition)
3
th(SCLL-SDAL)
µs
4
5
6
7
tw(SCLL)
Pulse duration, SCL low
4.7
4
1.3
0.6
100(2)
µs
µs
ns
µs
tw(SCLH)
Pulse duration, SCL high
tsu(SDAV-SCLH)
th(SDA-SCLL)
Setup time, SDA valid before SCL high
Hold time, SDA valid after SCL low
250
0(3)
0(3) 0.9(4)
Pulse duration, SDA high between STOP and START
conditions
8
tw(SDAH)
4.7
1.3
µs
(5)
9
tr(SDA)
Rise time, SDA
1000 20 + 0.1Cb
1000 20 + 0.1Cb
300 20 + 0.1Cb
300 20 + 0.1Cb
300
300
300
300
ns
ns
ns
ns
µs
ns
pF
(5)
(5)
(5)
10
11
12
13
14
15
tr(SCL)
Rise time, SCL
tf(SDA)
Fall time, SDA
tf(SCL)
Fall time, SCL
tsu(SCLH-SDAH)
tw(SP)
Setup time, SCL high before SDA high (for STOP condition)
Pulse duration, spike (must be suppressed)
Capacitive load for each bus line
4
0.6
0
50
(5)
Cb
400
400
(1) The I2C pins SDA and SCL do not feature fail-safe I/O buffers. These pins could potentially draw current when the device is powered
down.
(2) A Fast-mode I2C-bus™ device can be used in a Standard-mode I2C-bus system, but the requirement tsu(SDA-SCLH)≥ 250 ns must then be
met. This will automatically be the case if the device does not stretch the LOW period of the SCL signal. If such a device does stretch
the LOW period of the SCL signal, it must output the next data bit to the SDA line tr max + tsu(SDA-SCLH)= 1000 + 250 = 1250 ns
(according to the Standard-mode I2C-Bus Specification) before the SCL line is released.
(3) A device must internally provide a hold time of at least 300 ns for the SDA signal (referred to the VIHmin of the SCL signal) to bridge the
undefined region of the falling edge of SCL.
(4) The maximum th(SDA-SCLL) has only to be met if the device does not stretch the low period [tw(SCLL)] of the SCL signal.
(5) Cb = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed.
11
9
SDA
6
8
14
4
13
5
10
SCL
1
12
3
2
7
3
Stop
Start
Repeated
Start
Stop
Figure 6-25. I2C Receive Timings
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Table 6-45. Switching Characteristics for I2C Timings(1) (see Figure 6-26)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
PARAMETER
UNIT
STANDARD
MODE
FAST MODE
MIN
MAX
MIN
MAX
16
17
tc(SCL)
Cycle time, SCL
10
2.5
µs
µs
Delay time, SCL high to SDA low (for a repeated START
condition)
td(SCLH-SDAL)
4.7
4
0.6
0.6
Delay time, SDA low to SCL low (for a START and a repeated
START condition)
18
td(SDAL-SCLL)
µs
19
20
21
22
tw(SCLL)
Pulse duration, SCL low
4.7
4
1.3
0.6
100
0
µs
µs
ns
µs
tw(SCLH)
Pulse duration, SCL high
td(SDAV-SCLH)
tv(SCLL-SDAV)
Delay time, SDA valid to SCL high
Valid time, SDA valid after SCL low
250
0
0.9
Pulse duration, SDA high between STOP and START
conditions
23
tw(SDAH)
4.7
1.3
µs
(1)
24
25
26
27
28
29
tr(SDA)
tr(SCL)
Rise time, SDA
1000 20 + 0.1Cb
1000 20 + 0.1Cb
300 20 + 0.1Cb
300 20 + 0.1Cb
300
300
300
300
ns
ns
ns
ns
µs
pF
(1)
(1)
(1)
Rise time, SCL
tf(SDA)
Fall time, SDA
tf(SCL)
Fall time, SCL
td(SCLH-SDAH)
Cp
Delay time, SCL high to SDA high (for STOP condition)
Capacitance for each I2C pin
4
0.6
10
10
(1) Cb = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times are allowed.
26
24
SDA
21
23
19
28
20
25
SCL
16
27
18
17
22
18
Stop
Start
Repeated
Start
Stop
Figure 6-26. I2C Transmit Timings
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6.13 Host-Port Interface (HPI) Peripheral
6.13.1 HPI Device-Specific Information
The DM6435 device includes a user-configurable 16-bit Host-port interface (HPI16).
Software handshaking via the HRDY bit of the Host Port Control Register (HPIC) is not supported on the
DM6435.
The DM6435 HPI does not support the HAS feature. For proper device operation, the HAS pin must be
pulled up via an external resistor.
6.13.2 HPI Peripheral Register Description(s)
Table 6-46. HPI Control Registers
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
COMMENTS
01C6 7800
PID
Peripheral Identification Register
The CPU has read/write
access to the
01C6 7804
PWREMU_MGMT
HPI power and emulation management register
PWREMU_MGMT register.
01C6 7808 - 01C6 7824
01C6 7828
-
-
-
Reserved
Reserved
Reserved
01C6 782C
The Host and the CPU both
have read/write access to the
HPIC register.
01C6 7830
01C6 7834
HPIC
HPI control register
HPIA
HPI address register
(Write)
The Host has read/write
access to the HPIA registers.
The CPU has only read
(HPIAW)(1)
HPIA
HPI address register
(Read)
01C6 7838
(HPIAR)(1)
access to the HPIA registers.
01C6 780C - 01C6 7FFF
-
Reserved
(1) There are two 32-bit HPIA registers: HPIAR for read operations and HPIAW for write operations. The HPI can be configured such that
HPIAR and HPIAW act as a single 32-bit HPIA (single-HPIA mode) or as two separate 32-bit HPIAs (dual-HPIA mode) from the
perspective of the Host. The CPU can access HPIAW and HPIAR independently. For more details about the HPIA registers and their
modes, see the TMS320C643x DMP Host Port Interface (HPI) User's Guide (literature number SPRU998).
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6.13.3 HPI Electrical Data/Timing
Table 6-47. Timing Requirements for Host-Port Interface Cycles(1)(2) (see Figure 6-27 and Figure 6-28)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
UNIT
-6
MIN
MAX
1
2
tsu(SELV-HSTBL)
th(HSTBL-SELV)
tw(HSTBL)
Setup time, select signals(3) valid before HSTROBE low
Hold time, select signals(3) valid after HSTROBE low
Pulse duration, HSTROBE active low
5
2
ns
ns
ns
ns
ns
ns
3
15
2M
5
4
tw(HSTBH)
Pulse duration, HSTROBE inactive high between consecutive accesses
Setup time, host data valid before HSTROBE high
Hold time, host data valid after HSTROBE high
11
12
tsu(HDV-HSTBH)
th(HSTBH-HDV)
0
Hold time, HSTROBE high after HRDY low. HSTROBE should not be
inactivated until HRDY is active (low); otherwise, HPI writes will not
complete properly.
13
th(HRDYL-HSTBL)
0
ns
(1) HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
(2) M = SYSCLK3 period = (CPU clock frequency)/6 in ns. For example, when running parts at 600 MHz, use 10 ns.
(3) Select signals include: HCNTL[1:0], HR/W and HHWIL.
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Table 6-48. Switching Characteristics for Host-Port Interface Cycles(1)(2)(3)
(see Figure 6-27 and Figure 6-28)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
PARAMETER
UNIT
MIN
MAX
For HPI Write, HRDY can go high (not
ready) for these HPI Write conditions;
otherwise, HRDY stays low (ready):
Case 1: Back-to-back HPIA writes (can
be either first or second half-word)
Case 2: HPIA write following a
PREFETCH command (can be either
first or second half-word)
Case 3: HPID write when FIFO is full
or flushing (can be either first or
second half-word)
Case 4: HPIA write and Write FIFO not
empty
For HPI Read, HRDY can go high (not
ready) for these HPI Read conditions:
Case 1: HPID read (with
Delay time, HSTROBE low to
HRDY valid
5
td(HSTBL-HRDYV)
12
ns
auto-increment) and data not in Read
FIFO (can only happen to first
half-word of HPID access)
Case 2: First half-word access of HPID
Read without auto-increment
For HPI Read, HRDY stays low (ready)
for these HPI Read conditions:
Case 1: HPID read with auto-increment
and data is already in Read FIFO
(applies to either half-word of HPID
access)
Case 2: HPID read without
auto-increment and data is already in
Read FIFO (always applies to second
half-word of HPID access)
Case 3: HPIC or HPIA read (applies to
either half-word access)
6
7
ten(HSTBL-HD)
td(HRDYL-HDV)
toh(HSTBH-HDV)
tdis(HSTBH-HDV)
Enable time, HD driven from HSTROBE low
Delay time, HRDY low to HD valid
2
ns
ns
ns
ns
0
8
Output hold time, HD valid after HSTROBE high
Disable time, HD high-impedance from HSTROBE high
1.5
14
12
For HPI Read. Applies to conditions
where data is already residing in
HPID/FIFO:
Case 1: HPIC or HPIA read
Case 2: First half-word of HPID read
with auto-increment and data is
already in Read FIFO
Delay time, HSTROBE low to
HD valid
15
td(HSTBL-HDV)
15
ns
Case 3: Second half-word of HPID
read with or without auto-increment
For HPI Write, HRDY can go high (not
ready) for these HPI Write conditions;
otherwise, HRDY stays low (ready):
Case 1: HPID write when Write FIFO is
Delay time, HSTROBE high to full (can happen to either half-word)
18
td(HSTBH-HRDYV)
12
ns
HRDY valid
Case 2: HPIA write (can happen to
either half-word)
Case 3: HPID write without
auto-increment (only happens to
second half-word)
(1) M = SYSCLK3 period = (CPU clock frequency)/6 in ns. For example, when running parts at 600 MHz, use 10 ns.
(2) HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
(3) By design, whenever HCS is driven inactive (high), HPI will drive HRDY active (low).
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HCS
(D)
HAS
2
2
1
1
1
1
HCNTL[1:0]
2
2
2
1
HR/W
2
1
HHWIL
4
3
3
(A)(C)
HSTROBE
15
6
15
14
14
8
6
8
HD[15:0]
(output)
13
7
1st Half-Word
2nd Half-Word
5
(B)
HRDY
A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
B. Depending on the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with
auto-incrementing)and the state of the FIFO, transitions on HRDY may or may not occur.
For more detailed information on the HPI peripheral, see the TMS320DM643x Host Port Interface (HPI) User’s Guide
(literaturenumber SPRU998).
C. HCS reflects typical HCS behavior when HSTROBE assertion is caused by HDS1 or HDS2. HCS timing requirements are
reflected by parameters for HSTROBE.
D
For proper HPI operation, HAS must be pulled up via an external resistor.
Figure 6-27. HPI16 Read Timing (HAS Not Used, Tied High)
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HCS
(D)
HAS
1
1
1
1
2
2
2
2
HCNTL[1:0]
HR/W
1
2
1
2
HHWIL
(A)(C)
3
3
4
HSTROBE
11
11
12
12
2nd Half-Word
18
HD[15:0]
(input)
1st Half-Word
18
5
13
13
5
(B)
HRDY
A. HSTROBE refers to the following logical operation on HCS, HDS1, and HDS2: [NOT(HDS1 XOR HDS2)] OR HCS.
B. Dependingon the type of write or read operation (HPID without auto-incrementing; HPIA, HPIC, or HPID with auto-incrementing) and the
state of the FIFO, transitions on HRDY may or may not occur.
For more detailed information on the HPI peripheral, see the TMS320DM643x Host Port Interface (HPI) User’s Guide (literature number
SPRU998).
C. HCS reflects typical HCS behavior when HSTROBE assertion is caused by HDS1 or HDS2. HCS timing requirements are reflected by
parameters for HSTROBE.
D
For proper HPI operation, HAS must be pulled up via an external resistor.
Figure 6-28. HPI16 Write Timing (HAS Not Used, Tied High)
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6.14 Multichannel Buffered Serial Port (McBSP)
The McBSP provides these functions:
•
•
•
•
Full-duplex communication
Double-buffered data registers, which allow a continuous data stream
Independent framing and clocking for receive and transmit
Direct interface to industry-standard codecs, analog interface chips (AICs), and other serially
connected analog-to-digital (A/D) and digital-to-analog (D/A) devices
•
External shift clock or an internal, programmable frequency shift clock for data transfer
If internal clock source is used, the CLKGDV field of the Sample Rate Generator Register (SRGR) must
always be set to a value of 1 or greater.
For more detailed information on the McBSP peripheral, see the TMS320DM643x DMP Multichannel
Buffered Serial Port (McBSP) User's Guide (literature number SPRU943).
6.14.1 McBSP Peripheral Register Description(s)
Table 6-49. McBSP 0 Registers
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
COMMENTS
The CPU and EDMA3
controller can only read
this register; they cannot
write to it.
01D0 0000
DRR0
McBSP0 Data Receive Register
01D0 0004
01D0 0008
01D0 000C
01D0 0010
01D0 0014
01D0 0018
DXR0
SPCR0
RCR0
McBSP0 Data Transmit Register
McBSP0 Serial Port Control Register
McBSP0 Receive Control Register
McBSP0 Transmit Control Register
McBSP0 Sample Rate Generator register
McBSP0 Multichannel Control Register
XCR0
SRGR0
MCR0
McBSP0 Enhanced Receive Channel Enable Register
0 Partition A/B
01D0 001C
RCERE00
McBSP0 Enhanced Transmit Channel Enable Register
0 Partition A/B
01D0 0020
01D0 0024
01D0 0028
XCERE00
PCR0
McBSP0 Pin Control Register
McBSP0 Enhanced Receive Channel Enable Register
1 Partition C/D
RCERE10
McBSP0 Enhanced Transmit Channel Enable Register
1 Partition C/D
01D0 002C
01D0 0030
01D0 0034
01D0 0038
XCERE10
RCERE20
XCERE20
RCERE30
McBSP0 Enhanced Receive Channel Enable Register
2 Partition E/F
McBSP0 Enhanced Transmit Channel Enable Register
2 Partition E/F
McBSP0 Enhanced Receive Channel Enable Register
3 Partition G/H
McBSP0 Enhanced Transmit Channel Enable Register
3 Partition G/H
01D0003C
XCERE30
-
01D0 0040 - 01D0 07FF
Reserved
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6.14.2 McBSP Electrical Data/Timing
6.14.2.1 Multichannel Buffered Serial Port (McBSP) Timing
Table 6-50. Timing Requirements for McBSP(1) (see Figure 6-29)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
2
3
tc(CKRX)
tw(CKRX)
Cycle time, CLKR/X
CLKR/X ext
CLKR/X ext
CLKR int
CLKR ext
CLKR int
CLKR ext
CLKR int
CLKR ext
CLKR int
CLKR ext
CLKX int
CLKX ext
CLKX int
CLKX ext
2P(2)(3)
P - 1(4)
ns
ns
Pulse duration, CLKR/X high or CLKR/X low
14
4
5
6
tsu(FRH-CKRL)
th(CKRL-FRH)
tsu(DRV-CKRL)
th(CKRL-DRV)
tsu(FXH-CKXL)
th(CKXL-FXH)
Setup time, external FSR high before CLKR low
Hold time, external FSR high after CLKR low
Setup time, DR valid before CLKR low
ns
ns
ns
ns
ns
ns
6
4
14
4
7
3
8
Hold time, DR valid after CLKR low
3.5
14
4
10
11
Setup time, external FSX high before CLKX low
Hold time, external FSX high after CLKX low
6
3
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(3) Use whichever value is greater. Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock
source. The minimum CLKR/X cycle times are based on internal logic speed; the maximum usable speed may be lower due to EDMA
limitations and AC timing requirements.
(4) This parameter applies to the maximum McBSP frequency. Operate serial clocks (CLKR/X) in the reasonable range of 40/60 duty cycle.
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Table 6-51. Switching Characteristics Over Recommended Operating Conditions for McBSP(1)(2)
(see Figure 6-29)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
Delay time, CLKS high to CLKR/X high for internal CLKR/X
generated from CLKS input
1
td(CKSH-CKRXH)
3
10
ns
2
3
4
tc(CKRX)
Cycle time, CLKR/X
CLKR/X int
CLKR/X int
CLKR int
CLKX int
CLKX ext
CLKX int
CLKX ext
CLKX int
CLKX ext
FSX int
2P(3)(4)(5)
C - 2(6)
-4
ns
ns
ns
tw(CKRX)
Pulse duration, CLKR/X high or CLKR/X low
Delay time, CLKR high to internal FSR valid
C + 2(6)
5.5
td(CKRH-FRV)
-4
5.5
9
td(CKXH-FXV)
tdis(CKXH-DXHZ)
td(CKXH-DXV)
Delay time, CLKX high to internal FSX valid
ns
ns
ns
2.5
14.5
-5.5
7.5
Disable time, DX high impedance following
last data bit from CLKX high
12
13
-2.1
-4 + D1(7)
2.5 + D1(7) 14.5 + D2(7)
16
5.5 + D2(7)
Delay time, CLKX high to DX valid
Delay time, FSX high to DX valid
-4(8)
5(8)
14
td(FXH-DXV)
ns
ONLY applies when in data
delay 0 (XDATDLY = 00b) mode
FSX ext
1(8)
14.5(8)
(1) CLKRP = CLKXP = FSRP = FSXP = 0. If polarity of any of the signals is inverted, then the timing references of that signal are also
inverted.
(2) Minimum delay times also represent minimum output hold times.
(3) Minimum CLKR/X cycle times must be met, even when CLKR/X is generated by an internal clock source. Minimum CLKR/X cycle times
are based on internal logic speed; the maximum usable speed may be lower due to EDMA limitations and AC timing requirements.
(4) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(5) Use whichever value is greater.
(6) C = H or L
S = sample rate generator input clock = P if CLKSM = 1 (P = SYSCLK3 period)
S = sample rate generator input clock = P_clks if CLKSM = 0 (P_clks = CLKS period)
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
CLKGDV should be set appropriately to ensure the McBSP bit rate does not exceed the maximum limit (see (4) above).
(7) Extra delay from CLKX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
(8) Extra delay from FSX high to DX valid applies only to the first data bit of a device, if and only if DXENA = 1 in SPCR.
if DXENA = 0, then D1 = D2 = 0
if DXENA = 1, then D1 = 6P, D2 = 12P
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CLKS
1
2
3
3
CLKR
FSR (int)
FSR (ext)
DR
4
4
5
6
7
8
Bit(n-1)
(n-2)
(n-3)
2
3
3
CLKX
9
FSX (int)
11
10
FSX (ext)
FSX (XDATDLY=00b)
(A)
13
14
13
(A)
12
DX
Bit 0
Bit(n-1)
(n-2)
(n-3)
A. Parameter No. 13 applies to the first data bit only when XDATDLY ≠ 0.
Figure 6-29. McBSP Timing(B)
Table 6-52. Timing Requirements for FSR When GSYNC = 1 (see Figure 6-30)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
1
2
tsu(FRH-CKSH)
th(CKSH-FRH)
Setup time, FSR high before CLKS high
Hold time, FSR high after CLKS high
4
4
ns
ns
CLKS
1
2
FSR external
CLKR/X (no need to resync)
CLKR/X (needs resync)
Figure 6-30. FSR Timing When GSYNC = 1
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Table 6-53. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 10b, CLKXP = 0(1)(2)
(see Figure 6-31)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MASTER
SLAVE
MIN
MIN
14
4
MAX
MAX
4
5
tsu(DRV-CKXL)
th(CKXL-DRV)
Setup time, DR valid before CLKX low
Hold time, DR valid after CLKX low
2 - 3P
5 + 6P
ns
ns
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
Table 6-54. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI
Master or Slave: CLKSTP = 10b, CLKXP = 0(1)(2) (see Figure 6-31)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
PARAMETER
UNIT
MASTER(3)
MIN
SLAVE
MIN
MAX
MAX
1
2
3
th(CKXL-FXL)
td(FXL-CKXH)
td(CKXH-DXV)
Hold time, FSX low after CLKX low(4)
Delay time, FSX low to CLKX high(5)
Delay time, CLKX high to DX valid
T - 4
L - 4
-4
T + 5.5
L + 4
5.5
ns
ns
ns
3P + 2.8
5P + 17
Disable time, DX high impedance following
last data bit from CLKX low
6
tdis(CKXL-DXHZ)
L - 6
L + 7.5
ns
Disable time, DX high impedance following
last data bit from FSX high
7
8
tdis(FXH-DXHZ)
td(FXL-DXV)
P + 3
3P + 17
4P + 17
ns
ns
Delay time, FSX low to DX valid
2P + 1.8
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
(3) S = Sample rate generator input clock = 2P if CLKSM = 1 (P = SYSCLK3 period)
S = Sample rate generator input clock = 2P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
(4) FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input
on FSX and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP
(5) FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master
clock (CLKX).
CLKX
1
2
8
FSX
7
6
3
DX
DR
Bit 0
Bit(n-1)
Bit(n-1)
(n-2)
(n-3)
(n-3)
(n-4)
4
5
Bit 0
(n-2)
(n-4)
Figure 6-31. McBSP Timing as SPI Master or Slave: CLKSTP = 10b, CLKXP = 0
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Table 6-55. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 11b, CLKXP = 0(1)(2)
(see Figure 6-32)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MASTER
SLAVE
MIN
MIN
14
4
MAX
MAX
4
5
tsu(DRV-CKXH)
th(CKXH-DRV)
Setup time, DR valid before CLKX high
Hold time, DR valid after CLKX high
2 - 3P
5 + 6P
ns
ns
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
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Table 6-56. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI
Master or Slave: CLKSTP = 11b, CLKXP = 0(1)(2) (see Figure 6-32)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
PARAMETER
UNIT
MASTER(3)
MIN
SLAVE
MIN
MAX
MAX
1
2
3
th(CKXL-FXL)
td(FXL-CKXH)
td(CKXL-DXV)
Hold time, FSX low after CLKX low(4)
Delay time, FSX low to CLKX high(5)
Delay time, CLKX low to DX valid
L - 4
T - 4
-4
L + 5.5
T + 4
5.5
ns
ns
ns
3P + 2.8
3P + 2
2P + 2
5P + 17
5P + 17
4P + 17
Disable time, DX high impedance following
last data bit from CLKX low
6
7
tdis(CKXL-DXHZ)
td(FXL-DXV)
-6
7.5
ns
ns
Delay time, FSX low to DX valid
H - 4
H + 5.5
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
(3) S = Sample rate generator input clock = 2P if CLKSM = 1 (P = SYSCLK3 period)
S = Sample rate generator input clock = 2P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
(4) FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input
on FSX and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP
(5) FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master
clock (CLKX).
CLKX
1
2
7
FSX
DX
6
3
Bit 0
Bit(n-1)
Bit(n-1)
(n-2)
(n-3)
(n-3)
(n-4)
4
5
DR
Bit 0
(n-2)
(n-4)
Figure 6-32. McBSP Timing as SPI Master or Slave: CLKSTP = 11b, CLKXP = 0
Table 6-57. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 10b, CLKXP = 1(1)(2)
(see Figure 6-33)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MASTER
SLAVE
MIN
MIN
14
4
MAX
MAX
4
5
tsu(DRV-CKXH)
th(CKXH-DRV)
Setup time, DR valid before CLKX high
Hold time, DR valid after CLKX high
2 - 3P
5 + 6P
ns
ns
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
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Table 6-58. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI
Master or Slave: CLKSTP = 10b, CLKXP = 1(1)(2) (see Figure 6-33)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
PARAMETER
UNIT
MASTER(3)
MIN
SLAVE
MIN
MAX
MAX
1
2
3
th(CKXH-FXL)
td(FXL-CKXL)
td(CKXL-DXV)
Hold time, FSX low after CLKX high(4)
Delay time, FSX low to CLKX low(5)
Delay time, CLKX low to DX valid
T - 4
H - 4
-4
T + 5.5
H + 4
5.5
ns
ns
ns
3P + 2.8
5P + 17
Disable time, DX high impedance following
last data bit from CLKX high
6
tdis(CKXH-DXHZ)
H - 6
H + 7.5
ns
Disable time, DX high impedance following
last data bit from FSX high
7
8
tdis(FXH-DXHZ)
td(FXL-DXV)
P + 3
3P + 17
4P + 17
ns
ns
Delay time, FSX low to DX valid
2P + 2
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
(3) S = Sample rate generator input clock = 2P if CLKSM = 1 (P = SYSCLK3 period)
S = Sample rate generator input clock = 2P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
(4) FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input
on FSX and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP
(5) FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master
clock (CLKX).
CLKX
1
2
8
FSX
7
6
3
DX
DR
Bit 0
Bit(n-1)
Bit(n-1)
(n-2)
(n-3)
(n-4)
4
5
Bit 0
(n-2)
(n-3)
(n-4)
Figure 6-33. McBSP Timing as SPI Master or Slave: CLKSTP = 10b, CLKXP = 1
Table 6-59. Timing Requirements for McBSP as SPI Master or Slave: CLKSTP = 11b, CLKXP = 1(1)(2)
(see Figure 6-34)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MASTER
SLAVE
MIN
MIN
14
4
MAX
MAX
4
5
tsu(DRV-CKXH)
th(CKXH-DRV)
Setup time, DR valid before CLKX high
Hold time, DR valid after CLKX high
2 - 3P
5+ 6P
ns
ns
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
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Table 6-60. Switching Characteristics Over Recommended Operating Conditions for McBSP as SPI
Master or Slave: CLKSTP = 11b, CLKXP = 1(1)(2) (see Figure 6-34)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
PARAMETER
UNIT
MASTER(3)
MIN
SLAVE
MIN
MAX
MAX
1
2
3
th(CKXH-FXL)
td(FXL-CKXL)
td(CKXH-DXV)
Hold time, FSX low after CLKX high(4)
Delay time, FSX low to CLKX low(5)
Delay time, CLKX high to DX valid
H - 4
T - 4
-4
H + 5.5
T + 4
5.5
ns
ns
ns
3P + 2.8
3P + 2
2P + 2
5P + 17
5P + 17
4P + 17
Disable time, DX high impedance following
last data bit from CLKX high
6
7
tdis(CKXH-DXHZ)
td(FXL-DXV)
-6
7.5
ns
ns
Delay time, FSX low to DX valid
L - 4
L+ 5.5
(1) P = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use P = 10 ns.
(2) For all SPI Slave modes, the rate of the internal clock CLKG must be at least 8 times faster than that of the SPI data rate. User should
program sample rate generator to achieve maximum CLKG by setting CLKSM = CLKGDV = 1.
(3) S = Sample rate generator input clock = 2P if CLKSM = 1 (P = SYSCLK3 period)
S = Sample rate generator input clock = 2P_clks if CLKSM = 0 (P_clks = CLKS period)
T = CLKX period = (1 + CLKGDV) * S
H = CLKX high pulse width = (CLKGDV/2 + 1) * S if CLKGDV is even
H = (CLKGDV + 1)/2 * S if CLKGDV is odd
L = CLKX low pulse width = (CLKGDV/2) * S if CLKGDV is even
L = (CLKGDV + 1)/2 * S if CLKGDV is odd
(4) FSRP = FSXP = 1. As a SPI Master, FSX is inverted to provide active-low slave-enable output. As a Slave, the active-low signal input
on FSX and FSR is inverted before being used internally.
CLKXM = FSXM = 1, CLKRM = FSRM = 0 for Master McBSP
CLKXM = CLKRM = FSXM = FSRM = 0 for Slave McBSP
(5) FSX should be low before the rising edge of clock to enable Slave devices and then begin a SPI transfer at the rising edge of the Master
clock (CLKX).
CLKX
1
2
FSX
DX
7
6
3
Bit 0
Bit 0
Bit(n-1)
Bit(n-1)
(n-2)
(n-3)
(n-4)
4
5
DR
(n-2)
(n-3)
(n-4)
Figure 6-34. McBSP Timing as SPI Master or Slave: CLKSTP = 11b, CLKXP = 1
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6.15 Multichannel Audio Serial Port (McASP0) Peripheral
The McASP functions as a general-purpose audio serial port optimized for the needs of multichannel
audio applications. The McASP is useful for time-division multiplexed (TDM) stream, Inter-Integrated
Sound (I2S) protocols, and intercomponent digital audio interface transmission (DIT).
6.15.1 McASP0 Device-Specific Information
The DM6435 device includes one multichannel audio serial port (McASP) interface peripheral (McASP0).
The McASP0 is a serial port optimized for the needs of multichannel audio applications.
The McASP0 consists of a transmit and receive section. These sections can operate completely
independently with different data formats, separate master clocks, bit clocks, and frame syncs or
alternatively, the transmit and receive sections may be synchronized. The McASP module also includes a
pool of 16 shift registers that may be configured to operate as either transmit data or receive data.
The transmit section of the McASP can transmit data in either a time-division-multiplexed (TDM)
synchronous serial format or in a digital audio interface (DIT) format where the bit stream is encoded for
S/PDIF, AES-3, IEC-60958, CP-430 transmission. The receive section of the McASP supports the TDM
synchronous serial format.
The McASP can support one transmit data format (either a TDM format or DIT format) and one receive
format at a time. All transmit shift registers use the same format and all receive shift registers use the
same format. However, the transmit and receive formats need not be the same.
Both the transmit and receive sections of the McASP also support burst mode which is useful for
non-audio data (for example, passing control information between two DSPs).
The McASP peripheral has additional capability for flexible clock generation, and error detection/handling,
as well as error management.
For more detailed information on and the functionality of the McASP0 peripheral, see the TMS320DM643x
DMP Multichannel Audio Serial Port (McASP) User's Guide (literature number SPRU980).
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6.15.1.1 McASP Block Diagram
Figure 6-35 illustrates the major blocks along with external signals of the TMS320DM6435 McASP0
peripheral; and shows the 4 serial data [AXR] pins.
McASP0
Transmit
DIT
RAM
Frame Sync
Generator
AFSX0
T
ransmit
Clock Check
(High-
Transmit
Clock
Generator
AHCLKX0
ACLKX0
Frequency)
AMUTE0
Error
Detect
AMUTEIN0
Receive
Clock Check
(High-
Receive
Clock
Generator
AHCLKR0
ACLKR0
Frequency)
Transmit
Data
Formatter
Receive
Frame Sync
Generator
AFSR0
Serializer 0
AXR0[0]
AXR0[1]
AXR0[2]
AXR0[3]
Serializer 1
Serializer 2
Serializer 3
Receive
Data
Formatter
GPIO
Control
Figure 6-35. McASP0 Configuration
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6.15.1.2 McASP0 Peripheral Register Description(s)
Table 6-61. McASP0 Control Registers
HEX ADDRESS RANGE
01D0 1000
ACRONYM
REGISTER NAME
PID
Peripheral Identification register [Register value: 0x0010 0101]
01D0 1004
–
Reserved
01D0 1008
–
Reserved
01D0 100C
–
Reserved
01D0 1010
PFUNC
Pin function register
Pin direction register
Reserved
01D0 1014
PDIR
01D0 1018
–
01D0 101C
–
–
Reserved
01D0 1020
Reserved
01D0 1024 – 01D0 1040
01D0 1044
–
Reserved
GBLCTL
AMUTE
DLBCTL
DITCTL
–
Global control register
Mute control register
Digital Loop-back control register
DIT mode control register
Reserved
01D0 1048
01D0 104C
01D0 1050
01D0 1054 – 01D0 105C
Alias of GBLCTL containing only Receiver Reset bits, allows transmit to be reset
independently from receive.
01D0 1060
RGBLCTL
01D0 1064
01D0 1068
RMASK
RFMT
Receiver format UNIT bit mask register
Receive bit stream format register
Receive frame sync control register
Receive clock control register
High-frequency receive clock control register
Receive TDM slot 0–31 register
Receiver interrupt control register
Status register – Receiver
01D0 106C
AFSRCTL
ACLKRCTL
AHCLKRCTL
RTDM
01D0 1070
01D0 1074
01D0 1078
01D0 107C
RINTCTL
RSTAT
01D0 1080
01D0 1084
RSLOT
Current receive TDM slot register
Receiver clock check control register
Reserved
01D0 1088
RCLKCHK
–
01D0 108C – 01D0 109C
Alias of GBLCTL containing only Transmitter Reset bits, allows transmit to be reset
independently from receive.
01D0 10A0
XGBLCTL
01D0 10A4
01D0 10A8
01D0 10AC
01D0 10B0
01D0 10B4
01D0 10B8
01D0 10BC
01D0 10C0
01D0 10C4
01D0 10C8
XMASK
XFMT
Transmit format UNIT bit mask register
Transmit bit stream format register
Transmit frame sync control register
Transmit clock control register
AFSXCTL
ACLKXCTL
AHCLKXCTL
XTDM
High-frequency Transmit clock control register
Transmit TDM slot 0–31 register
Transmit interrupt control register
Status register – Transmitter
XINTCTL
XSTAT
XSLOT
Current transmit TDM slot
XCLKCHK
Transmit clock check control register
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Table 6-61. McASP0 Control Registers (continued)
HEX ADDRESS RANGE
01D0 10CC – 01D0 10FC
01D0 1100
ACRONYM
–
REGISTER NAME
Reserved
DITCSRA0
DITCSRA1
DITCSRA2
DITCSRA3
DITCSRA4
DITCSRA5
DITCSRB0
DITCSRB1
DITCSRB2
DITCSRB3
DITCSRB4
DITCSRB5
DITUDRA0
DITUDRA1
DITUDRA2
DITUDRA3
DITUDRA4
DITUDRA5
DITUDRB0
DITUDRB1
DITUDRB2
DITUDRB3
DITUDRB4
DITUDRB5
–
Left (even TDM slot) channel status register file
Left (even TDM slot) channel status register file
Left (even TDM slot) channel status register file
Left (even TDM slot) channel status register file
Left (even TDM slot) channel status register file
Left (even TDM slot) channel status register file
Right (odd TDM slot) channel status register file
Right (odd TDM slot) channel status register file
Right (odd TDM slot) channel status register file
Right (odd TDM slot) channel status register file
Right (odd TDM slot) channel status register file
Right (odd TDM slot) channel status register file
Left (even TDM slot) user data register file
Left (even TDM slot) user data register file
Left (even TDM slot) user data register file
Left (even TDM slot) user data register file
Left (even TDM slot) user data register file
Left (even TDM slot) user data register file
Right (odd TDM slot) user data register file
Right (odd TDM slot) user data register file
Right (odd TDM slot) user data register file
Right (odd TDM slot) user data register file
Right (odd TDM slot) user data register file
Right (odd TDM slot) user data register file
Reserved
01D0 1104
01D0 1108
01D0 110C
01D0 1110
01D0 1114
01D0 1118
01D0 111C
01D0 1120
01D0 1124
01D0 1128
01D0 112C
01D0 1130
01D0 1134
01D0 1138
01D0 113C
01D0 1140
01D0 1144
01D0 1148
01D0 114C
01D0 1150
01D0 1154
01D0 1158
01D0 115C
01D0 1160 – 01D0 117C
01D0 1180
SRCTL0
SRCTL1
SRCTL2
SRCTL3
–
Serializer 0 control register
01D0 1184
Serializer 1 control register
01D0 1188
Serializer 2 control register
01D0 118C
Serializer 3 control register
01D0 1190 – 01D0 11FC
01D0 1200
Reserved
XBUF0
Transmit Buffer for Serializer 0
01D0 1204
XBUF1
Transmit Buffer for Serializer 1
01D0 1208
XBUF2
Transmit Buffer for Serializer 2
01D0 120C
XBUF3
Transmit Buffer for Serializer 3
01D0 1210 – 01D0 127C
01D0 1280
–
Reserved
RBUF0
Receive Buffer for Serializer 0
01D0 1284
RBUF1
Receive Buffer for Serializer 1
01D0 1288
RBUF2
Receive Buffer for Serializer 2
01D0 128C
RBUF3
Receive Buffer for Serializer 3
01D0 1290 – 01D0 13FF
–
Reserved
Table 6-62. McASP0 Data Registers
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
COMMENTS
(Used when RSEL or XSEL
bits = 0 [these bits are located
in the RFMT or XFMT registers,
respectively].)
McASP0 receive buffers or McASP0 transmit buffers via
the Peripheral Data Bus.
01D0 1400 – 01D0 17FF
RBUF/XBUF
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6.15.1.3 McASP0 Electrical Data/Timing
6.15.1.3.1 Multichannel Audio Serial Port (McASP) Timing
Table 6-63. Timing Requirements for McASP (see Figure 6-36 and Figure 6-37)(1)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN MAX
1
2
3
4
tc(AHCKRX)
tw(AHCKRX)
tc(CKRX)
Cycle time, AHCLKR/X
25
10
25
10
11
3
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Pulse duration, AHCLKR/X high or low
Cycle time, ACLKR/X
ACLKR/X ext
tw(CKRX)
Pulse duration, ACLKR/X high or low
ACLKR/X ext
ACLKR/X int
5
6
7
8
tsu(FRX-CKRX)
th(CKRX-FRX)
tsu(AXR-CKRX)
th(CKRX-AXR)
Setup time, AFSR/X input valid before ACLKR/X latches data
Hold time, AFSR/X input valid after ACLKR/X latches data
Setup time, AXR input valid before ACLKR/X latches data
Hold time, AXR input valid after ACLKR/X latches data
ACLKR/X ext
ACLKR/X int
0
ACLKR/X ext input
ACLKR/X ext output
ACLKR/X int
4
6
11
3
ACLKR/X ext
ACLKR/X int
3
ACLKR/X ext input
ACLKR/X ext output
4
6
(1) ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
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Table 6-64. Switching Characteristics Over Recommended Operating Conditions for McASP(1)(2)
(see Figure 6-36 and Figure 6-37)(3)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
9
tc(AHCKRX)
Cycle time, AHCLKR/X
25
ns
ns
10 tw(AHCKRX)
Pulse duration, AHCLKR/X high or low
AH - 2.5
ACLKR/X
int
11 tc(CKRX)
Cycle time, ACLKR/X
25
ns
ns
ns
ns
ACLKR/X
int
12 tw(CKRX)
Pulse duration, ACLKR/X high or low
A - 2.5
-2.25
0
ACLKR/X
int
5.5
ACLKR/X
ext input
13 td(CKRX-FRX)
Delay time, ACLKR/X transmit edge to AFSX/R output valid
12.5
ACLKR/X
ext output
0
-2.25
0
14
5.5
ns
ns
ns
ACLKX int
ACLKX
ext input
12.5
14 td(CKX-AXRV)
Delay time, ACLKX transmit edge to AXR output valid
ACLKX
ext output
0
14
8
ns
ns
ns
ACLKR/X
int
-4.5
Disable time, AXR high impedance following last data bit from
ACLKR/X transmit edge
15 tdis(CKRX-AXRHZ)
ACLKR/X
ext
-4.5 12.5
(1) A = (ACLKR/X period)/2 in ns. For example, when ACLKR/X period is 25 ns, use A = 12.5 ns.
(2) AH = (AHCLKR/X period)/2 in ns. For example, when AHCLKR/X period is 25 ns, use AH = 12.5 ns.
(3) ACLKX internal: ACLKXCTL.CLKXM=1, PDIR.ACLKX = 1
ACLKX external input: ACLKXCTL.CLKXM=0, PDIR.ACLKX=0
ACLKX external output: ACLKXCTL.CLKXM=0, PDIR.ACLKX=1
ACLKR internal: ACLKRCTL.CLKRM=1, PDIR.ACLKR = 1
ACLKR external input: ACLKRCTL.CLKRM=0, PDIR.ACLKR=0
ACLKR external output: ACLKRCTL.CLKRM=0, PDIR.ACLKR=1
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2
1
2
AHCLKR/X (Falling Edge Polarity)
AHCLKR/X (Rising Edge Polarity)
4
3
4
(A)
ACLKR/X (CLKRP = CLKXP = 0)
(B)
ACLKR/X (CLKRP = CLKXP = 1)
6
5
AFSR/X (Bit Width, 0 Bit Delay)
AFSR/X (Bit Width, 1 Bit Delay)
AFSR/X (Bit Width, 2 Bit Delay)
AFSR/X (Slot Width, 0 Bit Delay)
AFSR/X (Slot Width, 1 Bit Delay)
AFSR/X (Slot Width, 2 Bit Delay)
8
7
AXR[n] (Data In/Receive)
A0 A1
A30 A31 B0 B1
B30 B31 C0 C1 C2 C3
C31
A. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP
receiver is configured for falling edge (to shift data in).
B. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP
receiver is configured for rising edge (to shift data in).
Figure 6-36. McASP Input Timings
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10
10
9
AHCLKR/X (Falling Edge Polarity)
AHCLKR/X (Rising Edge Polarity)
12
11
12
(A)
ACLKR/X (CLKRP = CLKXP = 1)
(B)
ACLKR/X (CLKRP = CLKXP = 0)
13
13
13
13
AFSR/X (Bit Width, 0 Bit Delay)
AFSR/X (Bit Width, 1 Bit Delay)
AFSR/X (Bit Width, 2 Bit Delay)
13
13
13
AFSR/X (Slot Width, 0 Bit Delay)
AFSR/X (Slot Width, 1 Bit Delay)
AFSR/X (Slot Width, 2 Bit Delay)
AXR[n] (Data Out/Transmit)
14
15
A0 A1
A30 A31 B0 B1
B30 B31 C0 C1 C2 C3
C31
A. For CLKRP = CLKXP = 1, the McASP transmitter is configured for falling edge (to shift data out) and the McASP
receiver is configured for rising edge (to shift data in).
B. For CLKRP = CLKXP = 0, the McASP transmitter is configured for rising edge (to shift data out) and the McASP
receiver is configured for falling edge (to shift data in).
Figure 6-37. McASP Output Timings
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6.16 High-End Controller Area Network Controller (HECC)
The DM6435 device has a High-End Controller Area Network Controllers (HECC). The HECC uses
established protocol to communicate serially with other controllers in harsh environments. The HECC is
fully compliant with the Controller Area Network (CAN) protocol, version 2.0B.
Key features of the HECC include the following:
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
CAN, version 2.0B compliant
32 RX/TX message objects
32 receive identifier masks
Programmable wake-up on bus activity
Programmable interrupt scheme
Automatic reply to a remote request
Automatic re-transmission in case of error or loss of arbitration
Protection against reception of a new message
32-bit time stamp
Local network time counter
Programmable priority register for each message
Programmable transmission and reception time-out
HECC/SCC mode of operation
Standard-Extended Identifier
Self-test mode
For more details on the HECC, see the TMS320DM643x High-End CAN Controller (HECC) User's Guide
(literature number SPRU981).
6.16.1 HECC Device-Specific Information
Software must not access "Reserved" locations of the HECC. Access to HECC "Reserved" locations may
hang the device.
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6.16.2 HECC Peripheral Register Description(s)
Table 6-65 through Table 6-68 show the High-End CAN Controller (HECC) registers. For more detailed
information, see the TMS320DM643x DMP High-End CAN Controller User’s Guide (literature number
SPRU981).
Table 6-65. HECC Control and Status Registers
HEX ADDRESS RANGE
01C2 3000
ACRONYM
CANME
CANMD
CANTRS
CANTRR
CANTA
CANAA
CANRMP
CANRML
CANRFP
CANGAM
CANMC
CANBTC
CANES
CANTEC
CANREC
CANGIF0
CANGIM
CANGIF1
CANMIM
CANMIL
CANOPC
CANTIOC
CANRIOC
CANLNT
CANTOC
CANTOS
–
REGISTER NAME
Mailbox Enable Register
01C2 3004
Mailbox Direction Register
Transmission Request Set Register
01C2 3008
01C2 300C
Transmission Request Reset Register
Transmission Acknowledge Register
Abort Acknowledge Register
01C2 3010
01C2 3014
01C2 3018
Receive Message Pending Register
Receive Message Lost Register
Remote Frame Pending Register
Global Acceptance Mask Register (SCC Mode Only)
Master Control Register
01C2 301C
01C2 3020
01C2 3024
01C2 3028
01C2 302C
Bit-Timing Configuration Register
Error and Status Register
01C2 3030
01C2 3034
Transmit Error Counter Register
Receive Error Counter Register
Global Interrupt Flag 0 Register
Global Interrupt Mask Register
Global Interrupt Flag 1 Register
Mailbox Interrupt Mask Register
Mailbox Interrupt Level Register
Overwrite Protection Control Register
Transmit I/O Control Register
01C2 3038
01C2 303C
01C2 3040
01C2 3044
01C2 3048
01C2 304C
01C2 3050
01C2 3054
01C2 3058
Receive I/O Control Register
01C2 305C
Local Network Time Register (HECC Mode Only)
Time-Out Control Register (HECC Mode Only)
Time-Out Status Register (HECC Mode Only)
Reserved
01C2 3060
01C2 3064
01C2 3068 – 01C2 306C
01C2 3070
CANETC
–
Error Test Control Register
01C2 3074 – 01C2 307C
01C2 3080
Reserved
SCCLAM0
–
SCC Local Acceptance Mask Register 0 (SCC Mode Only)
Reserved
01C2 3084 – 01C2 3088
01C2 308C
SSCLAM3
–
SCC Local Acceptance Mask Register 3 (SCC Mode Only)
Reserved
01C2 3090 – 01C2 4FFF
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Table 6-66. HECC Message Object Registers(1)
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
HECC Local Acceptance Mask Registers
01C2 5000
01C2 5004
01C2 5008
01C2 500C
01C2 5010
01C2 5014
01C2 5018
01C2 501C
01C2 5020
01C2 5024
01C2 5028
01C2 502C
01C2 5030
01C2 5034
01C2 5038
01C2 503C
01C2 5040
01C2 5044
01C2 5048
01C2 504C
01C2 5050
01C2 5054
01C2 5058
01C2 505C
01C2 5060
01C2 5064
01C2 5068
01C2 506C
01C2 5070
01C2 5074
01C2 5078
01C2 507C
LAM0
LAM1
HECC Local Acceptance Mask Register for Mailbox 0
HECC Local Acceptance Mask Register for Mailbox 1
HECC Local Acceptance Mask Register for Mailbox 2
HECC Local Acceptance Mask Register for Mailbox 3
HECC Local Acceptance Mask Register for Mailbox 4
HECC Local Acceptance Mask Register for Mailbox 5
HECC Local Acceptance Mask Register for Mailbox 6
HECC Local Acceptance Mask Register for Mailbox 7
HECC Local Acceptance Mask Register for Mailbox 8
HECC Local Acceptance Mask Register for Mailbox 9
HECC Local Acceptance Mask Register for Mailbox 10
HECC Local Acceptance Mask Register for Mailbox 11
HECC Local Acceptance Mask Register for Mailbox 12
HECC Local Acceptance Mask Register for Mailbox 13
HECC Local Acceptance Mask Register for Mailbox 14
HECC Local Acceptance Mask Register for Mailbox 15
HECC Local Acceptance Mask Register for Mailbox 16
HECC Local Acceptance Mask Register for Mailbox 17
HECC Local Acceptance Mask Register for Mailbox 18
HECC Local Acceptance Mask Register for Mailbox 19
HECC Local Acceptance Mask Register for Mailbox 20
HECC Local Acceptance Mask Register for Mailbox 21
HECC Local Acceptance Mask Register for Mailbox 22
HECC Local Acceptance Mask Register for Mailbox 23
HECC Local Acceptance Mask Register for Mailbox 24
HECC Local Acceptance Mask Register for Mailbox 25
HECC Local Acceptance Mask Register for Mailbox 26
HECC Local Acceptance Mask Register for Mailbox 27
HECC Local Acceptance Mask Register for Mailbox 28
HECC Local Acceptance Mask Register for Mailbox 29
HECC Local Acceptance Mask Register for Mailbox 30
HECC Local Acceptance Mask Register for Mailbox 31
Message Object Time-Stamp Registers
LAM2
LAM3
LAM4
LAM5
LAM6
LAM7
LAM8
LAM9
LAM10
LAM11
LAM12
LAM13
LAM14
LAM15
LAM16
LAM17
LAM18
LAM19
LAM20
LAM21
LAM22
LAM23
LAM24
LAM25
LAM26
LAM27
LAM28
LAM29
LAM30
LAM31
01C2 5080
01C2 5084
01C2 5088
01C2 508C
01C2 5090
01C2 5094
01C2 5098
01C2 509C
01C2 50A0
01C2 50A4
01C2 50A8
01C2 50AC
MOTS0
MOTS1
MOTS2
MOTS3
MOTS4
MOTS5
MOTS6
MOTS7
MOTS8
MOTS9
MOTS10
MOTS11
Message Object Time-Stamp Register for Mailbox 0
Message Object Time-Stamp Register for Mailbox 1
Message Object Time-Stamp Register for Mailbox 2
Message Object Time-Stamp Register for Mailbox 3
Message Object Time-Stamp Register for Mailbox 4
Message Object Time-Stamp Register for Mailbox 5
Message Object Time-Stamp Register for Mailbox 6
Message Object Time-Stamp Register for Mailbox 7
Message Object Time-Stamp Register for Mailbox 8
Message Object Time-Stamp Register for Mailbox 9
Message Object Time-Stamp Register for Mailbox 10
Message Object Time-Stamp Register for Mailbox 11
(1) All registers in this table apply to HECC mode only, they do not apply to SCC mode.
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Table 6-66. HECC Message Object Registers (continued)
HEX ADDRESS RANGE
01C2 50B0
01C2 50B4
01C2 50B8
01C2 50BC
01C2 50C0
01C2 50C4
01C2 50C8
01C2 50CC
01C2 50D0
01C2 50D4
01C2 50D8
01C2 50DC
01C2 50E0
01C2 50E4
01C2 50E8
01C2 50EC
01C2 50F0
01C2 50F4
01C2 50F8
01C2 50FC
ACRONYM
MOTS12
MOTS13
MOTS14
MOTS15
MOTS16
MOTS17
MOTS18
MOTS19
MOTS20
MOTS21
MOTS22
MOTS23
MOTS24
MOTS25
MOTS26
MOTS27
MOTS28
MOTS29
MOTS30
MOTS31
REGISTER NAME
Message Object Time-Stamp Register for Mailbox 12
Message Object Time-Stamp Register for Mailbox 13
Message Object Time-Stamp Register for Mailbox 14
Message Object Time-Stamp Register for Mailbox 15
Message Object Time-Stamp Register for Mailbox 16
Message Object Time-Stamp Register for Mailbox 17
Message Object Time-Stamp Register for Mailbox 18
Message Object Time-Stamp Register for Mailbox 19
Message Object Time-Stamp Register for Mailbox 20
Message Object Time-Stamp Register for Mailbox 21
Message Object Time-Stamp Register for Mailbox 22
Message Object Time-Stamp Register for Mailbox 23
Message Object Time-Stamp Register for Mailbox 24
Message Object Time-Stamp Register for Mailbox 25
Message Object Time-Stamp Register for Mailbox 26
Message Object Time-Stamp Register for Mailbox 27
Message Object Time-Stamp Register for Mailbox 28
Message Object Time-Stamp Register for Mailbox 29
Message Object Time-Stamp Register for Mailbox 30
Message Object Time-Stamp Register for Mailbox 31
Message Object Time-Out Registers
01C2 5100
01C2 5104
01C2 5108
01C2 510C
01C2 5110
01C2 5114
01C2 5118
01C2 511C
01C2 5120
01C2 5124
01C2 5128
01C2 512C
01C2 5130
01C2 5134
01C2 5138
01C2 513C
01C2 5140
01C2 5144
01C2 5148
01C2 514C
01C2 5150
01C2 5154
01C2 5158
01C2 515C
01C2 5160
01C2 5164
MOTO0
MOTO1
MOTO2
MOTO3
MOTO4
MOTO5
MOTO6
MOTO7
MOTO8
MOTO9
MOTO10
MOTO11
MOTO12
MOTO13
MOTO14
MOTO15
MOTO16
MOTO17
MOTO18
MOTO19
MOTO20
MOTO21
MOTO22
MOTO23
MOTO24
MOTO25
Message Object Time-Out Register for Mailbox 0
Message Object Time-Out Register for Mailbox 1
Message Object Time-Out Register for Mailbox 2
Message Object Time-Out Register for Mailbox 3
Message Object Time-Out Register for Mailbox 4
Message Object Time-Out Register for Mailbox 5
Message Object Time-Out Register for Mailbox 6
Message Object Time-Out Register for Mailbox 7
Message Object Time-Out Register for Mailbox 8
Message Object Time-Out Register for Mailbox 9
Message Object Time-Out Register for Mailbox 10
Message Object Time-Out Register for Mailbox 11
Message Object Time-Out Register for Mailbox 12
Message Object Time-Out Register for Mailbox 13
Message Object Time-Out Register for Mailbox 14
Message Object Time-Out Register for Mailbox 15
Message Object Time-Out Register for Mailbox 16
Message Object Time-Out Register for Mailbox 17
Message Object Time-Out Register for Mailbox 18
Message Object Time-Out Register for Mailbox 19
Message Object Time-Out Register for Mailbox 20
Message Object Time-Out Register for Mailbox 21
Message Object Time-Out Register for Mailbox 22
Message Object Time-Out Register for Mailbox 23
Message Object Time-Out Register for Mailbox 24
Message Object Time-Out Register for Mailbox 25
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Table 6-66. HECC Message Object Registers (continued)
HEX ADDRESS RANGE
01C2 5168
ACRONYM
MOTO26
MOTO27
MOTO28
MOTO29
MOTO30
MOTO31
REGISTER NAME
Message Object Time-Out Register for Mailbox 26
Message Object Time-Out Register for Mailbox 27
Message Object Time-Out Register for Mailbox 28
Message Object Time-Out Register for Mailbox 29
Message Object Time-Out Register for Mailbox 30
Message Object Time-Out Register for Mailbox 31
01C2 516C
01C2 5170
01C2 5174
01C2 5178
01C2 517C
Table 6-67. HECC Message Mailbox RAM(1)(2)
HEX ADDRESS RANGE
DESCRIPTION
01C2 4000 – 01C2 400F
01C2 4010 – 01C2 401F
01C2 4020 – 01C2 402F
01C2 4030 – 01C2 403F
01C2 4040 – 01C2 404F
...
Mailbox 0 (4 32-bit Registers)
Mailbox 1 (4 32-bit Registers)
Mailbox 2 (4 32-bit Registers)
Mailbox 3 (4 32-bit Registers)
Mailbox 4 (4 32-bit Registers)
...
01C2 41E0 – 01C2 41EF
01C2 41F0 – 01C2 41FF
Mailbox 30 (4 32-bit Registers)
Mailbox 31 (4 32-bit Registers)
(1) This table summarizes the address ranges for the Message Mailboxes 0 to 31. For the contents within each Message Mailbox RAM, see
Table 6-68, Message Mailbox n RAM Entries.
(2) For SCC mode, only Mailboxes 0 to 15 are supported.
Table 6-68. HECC Message Mailbox n RAM Entries(1)
HEX ADDRESS
OFFSET (within RAM)
ACRONYM(2)
MAILBOX REGISTER NAME
0
4
MIDn
Message Identifier Register for Mailbox n
MCFn
MDLn
MDHn
Message Control Field Register for Mailbox n
Message Data Low-Word Register for Mailbox n
Message Data High-Word Register for Mailbox n
8
C
(1) For the hex address range of Mailbox n, see Table 6-67, Message Mailbox RAM. For example, Message Mailbox 0 occupies hex
address range 0x01C2 4000 – 0x01C2 400F.
(2) The suffix "n" indicates the Message Mailbox number. For example, Message Mailbox 0 has the following Message Mailbox Registers:
MID0, MCF0, MDL0, and MDH0.
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6.16.3 HECC Electrical Data/Timing
Table 6-69. Timing Requirements for HECC Receive(1) (see Figure 6-38)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
1
1
2
f(baud)
Maximum programmable baud rate
Pulse duration, receive data bit
Mbps
ns
tw(HECC_RX)
H - 2
H + 2
(1) H = HECC baud time = 1/programmed baud rate.
Table 6-70. Switching Characteristics Over Recommended Operating Conditions for HECC Transmit(1)
(see Figure 6-38)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
3
4
f(baud)
Maximum programmable baud rate
Pulse duration, transmit data bit
1
Mbps
ns
tw(HECC_TX)
H - 2
H + 2
(1) H = HECC baud time = 1/programmed baud rate.
2
HECCx_RX
4
HECCx_TX
Figure 6-38. HECC Transmit/Receive Timing
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6.17 Ethernet Media Access Controller (EMAC)
The Ethernet Media Access Controller (EMAC) provides an efficient interface between DM6435 and the
network. The DM6435 EMAC supports both 10Base-T (10 Mbits/second [Mbps]) and 100Base-TX (100
Mbps) in either half- or full-duplex mode. The EMAC module also supports hardware flow control and
quality of service (QOS) support.
The EMAC controls the flow of packet data from the DM6435 device to the PHY. The MDIO module
controls PHY configuration and status monitoring.
The EMAC module conforms to the IEEE 802.3-2002 standard, describing the “Carrier Sense Multiple
Access with Collision Detection (CSMA/CD) Access Method and Physical Layer” specifications. The IEEE
802.3 standard has also been adopted by ISO/IEC and re-designated as ISO/IEC 8802-3:2000(E).
Deviation from this standard, the EMAC module does not use the Transmit Coding Error signal MTXER.
Instead of driving the error pin when an underflow condition occurs on a transmitted frame, the EMAC will
intentionally generate an incorrect checksum by inverting the frame CRC, so that the transmitted frame
will be detected as an error by the network.
Both the EMAC and the MDIO modules interface to the DM6435 device through a custom interface that
allows efficient data transmission and reception. This custom interface is referred to as the EMAC control
module, and is considered integral to the EMAC/MDIO peripheral. The control module is also used to
multiplex and control interrupts.
For the DM6435 Ethernet Media Access Controller (EMAC)/Management Data Input/Output (MDIO)
Module User's Guide (literature number SPRU941) which describes the DM6435 EMAC peripheral in
detail, see Section 2.9, Documentation Support section . For a list of supported registers and register
fields, see Table 6-71 [Ethernet MAC (EMAC) Control Registers] and Table 6-72 [EMAC Statistics
Registers] in this data manual.
6.17.1 EMAC Peripheral Register Description(s)
Table 6-71. Ethernet MAC (EMAC) Control Registers
HEX ADDRESS RANGE
01C8 0000
01C8 0004
01C8 0008
01C8 0010
01C8 0014
01C8 0018
01C8 0080
01C8 0084
01C8 0088
01C8 008C
01C8 0090
01C8 00A0
01C8 00A4
01C8 00A8
01C8 00AC
01C8 00B0
01C8 00B4
01C8 00B8
01C8 00BC
01C8 0100
01C8 0104
ACRONYM
TXIDVER
REGISTER NAME
Transmit Identification and Version Register
Transmit Control Register
TXCONTROL
TXTEARDOWN
Transmit Teardown Register
RXIDVER
Receive Identification and Version Register
Receive Control Register
RXCONTROL
RXTEARDOWN
TXINTSTATRAW
TXINTSTATMASKED
TXINTMASKSET
TXINTMASKCLEAR
MACINVECTOR
RXINTSTATRAW
RXINTSTATMASKED
RXINTMASKSET
RXINTMASKCLEAR
MACINTSTATRAW
MACINTSTATMASKED
MACINTMASKSET
MACINTMASKCLEAR
RXMBPENABLE
RXUNICASTSET
Receive Teardown Register
Transmit Interrupt Status (Unmasked) Register
Transmit Interrupt Status (Masked) Register
Transmit Interrupt Mask Set Register
Transmit Interrupt Mask Clear Register
MAC Input Vector Register
Receive Interrupt Status (Unmasked) Register
Receive Interrupt Status (Masked) Register
Receive Interrupt Mask Set Register
Receive Interrupt Mask Clear Register
MAC Interrupt Status (Unmasked) Register
MAC Interrupt Status (Masked) Register
MAC Interrupt Mask Set Register
MAC Interrupt Mask Clear Register
Receive Multicast/Broadcast/Promiscuous Channel Enable Register
Receive Unicast Enable Set Register
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Table 6-71. Ethernet MAC (EMAC) Control Registers (continued)
HEX ADDRESS RANGE
01C8 0108
01C8 010C
01C8 0110
01C8 0114
01C8 0120
01C8 0124
01C8 0128
01C8 012C
01C8 0130
01C8 0134
01C8 0138
01C8 013C
01C8 0140
01C8 0144
01C8 0148
01C8 014C
01C8 0150
01C8 0154
01C8 0158
01C8 015C
01C8 0160
01C8 0164
01C8 0168
01C8 016C
01C8 0170
01C8 0174
01C8 01D0
01C8 01D4
01C8 01D8
01C8 01DC
01C8 01E0
01C8 01E4
01C8 01E8
01C8 01EC
01C8 0200 - 01C8 02FC
01C8 0500
01C8 0504
01C8 0508
01C8 0600
01C8 0604
01C8 0608
01C8 060C
01C8 0610
01C8 0614
01C8 0618
01C8 061C
01C8 0620
ACRONYM
RXUNICASTCLEAR
RXMAXLEN
REGISTER NAME
Receive Unicast Clear Register
Receive Maximum Length Register
RXBUFFEROFFSET
RXFILTERLOWTHRESH
RX0FLOWTHRESH
RX1FLOWTHRESH
RX2FLOWTHRESH
RX3FLOWTHRESH
RX4FLOWTHRESH
RX5FLOWTHRESH
RX6FLOWTHRESH
RX7FLOWTHRESH
RX0FREEBUFFER
RX1FREEBUFFER
RX2FREEBUFFER
RX3FREEBUFFER
RX4FREEBUFFER
RX5FREEBUFFER
RX6FREEBUFFER
RX7FREEBUFFER
MACCONTROL
MACSTATUS
Receive Buffer Offset Register
Receive Filter Low Priority Frame Threshold Register
Receive Channel 0 Flow Control Threshold Register
Receive Channel 1 Flow Control Threshold Register
Receive Channel 2 Flow Control Threshold Register
Receive Channel 3 Flow Control Threshold Register
Receive Channel 4 Flow Control Threshold Register
Receive Channel 5 Flow Control Threshold Register
Receive Channel 6 Flow Control Threshold Register
Receive Channel 7 Flow Control Threshold Register
Receive Channel 0 Free Buffer Count Register
Receive Channel 1 Free Buffer Count Register
Receive Channel 2 Free Buffer Count Register
Receive Channel 3 Free Buffer Count Register
Receive Channel 4 Free Buffer Count Register
Receive Channel 5 Free Buffer Count Register
Receive Channel 6 Free Buffer Count Register
Receive Channel 7 Free Buffer Count Register
MAC Control Register
MAC Status Register
EMCONTROL
FIFOCONTROL
MACCONFIG
Emulation Control Register
FIFO Control Register (Transmit and Receive)
MAC Configuration Register
SOFTRESET
Soft Reset Register
MACSRCADDRLO
MACSRCADDRHI
MACHASH1
MAC Source Address Low Bytes Register (Lower 32-bits)
MAC Source Address High Bytes Register (Upper 16-bits)
MAC Hash Address Register 1
MACHASH2
MAC Hash Address Register 2
BOFFTEST
Back Off Test Register
TPACETEST
Transmit Pacing Algorithm Test Register
RXPAUSE
Receive Pause Timer Register
TXPAUSE
Transmit Pause Timer Register
(see Table 6-72)
MACADDRLO
MACADDRHI
EMAC Statistics Registers
MAC Address Low Bytes Register
MAC Address High Bytes Register
MACINDEX
MAC Index Register
TX0HDP
Transmit Channel 0 DMA Head Descriptor Pointer Register
Transmit Channel 1 DMA Head Descriptor Pointer Register
Transmit Channel 2 DMA Head Descriptor Pointer Register
Transmit Channel 3 DMA Head Descriptor Pointer Register
Transmit Channel 4 DMA Head Descriptor Pointer Register
Transmit Channel 5 DMA Head Descriptor Pointer Register
Transmit Channel 6 DMA Head Descriptor Pointer Register
Transmit Channel 7 DMA Head Descriptor Pointer Register
Receive Channel 0 DMA Head Descriptor Pointer Register
TX1HDP
TX2HDP
TX3HDP
TX4HDP
TX5HDP
TX6HDP
TX7HDP
RX0HDP
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Table 6-71. Ethernet MAC (EMAC) Control Registers (continued)
HEX ADDRESS RANGE
01C8 0624
ACRONYM
RX1HDP
RX2HDP
RX3HDP
RX4HDP
RX5HDP
RX6HDP
RX7HDP
REGISTER NAME
Receive Channel 1 DMA Head Descriptor Pointer Register
Receive Channel 2 DMA Head Descriptor Pointer Register
Receive Channel 3 DMA Head Descriptor Pointer Register
Receive Channel 4 DMA Head Descriptor Pointer Register
Receive Channel 5 DMA Head Descriptor Pointer Register
Receive Channel 6 DMA Head Descriptor Pointer Register
Receive Channel 7 DMA Head Descriptor Pointer Register
01C8 0628
01C8 062C
01C8 0630
01C8 0634
01C8 0638
01C8 063C
Transmit Channel 0 Completion Pointer (Interrupt Acknowledge)
Register
01C8 0640
01C8 0644
01C8 0648
01C8 064C
01C8 0650
01C8 0654
01C8 0658
01C8 065C
01C8 0660
01C8 0664
01C8 0668
01C8 066C
01C8 0670
01C8 0674
01C8 0678
01C8 067C
TX0CP
TX1CP
TX2CP
TX3CP
TX4CP
TX5CP
TX6CP
TX7CP
RX0CP
RX1CP
RX2CP
RX3CP
RX4CP
RX5CP
RX6CP
RX7CP
Transmit Channel 1 Completion Pointer (Interrupt Acknowledge)
Register
Transmit Channel 2 Completion Pointer (Interrupt Acknowledge)
Register
Transmit Channel 3 Completion Pointer (Interrupt Acknowledge)
Register
Transmit Channel 4 Completion Pointer (Interrupt Acknowledge)
Register
Transmit Channel 5 Completion Pointer (Interrupt Acknowledge)
Register
Transmit Channel 6 Completion Pointer (Interrupt Acknowledge)
Register
Transmit Channel 7 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 0 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 1 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 2 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 3 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 4 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 5 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 6 Completion Pointer (Interrupt Acknowledge)
Register
Receive Channel 7 Completion Pointer (Interrupt Acknowledge)
Register
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Table 6-72. EMAC Statistics Registers
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
01C8 0200
RXGOODFRAMES
Good Receive Frames Register
Broadcast Receive Frames Register
(Total number of good broadcast frames received)
01C8 0204
RXBCASTFRAMES
Multicast Receive Frames Register
(Total number of good multicast frames received)
01C8 0208
01C8 020C
01C8 0210
RXMCASTFRAMES
RXPAUSEFRAMES
RXCRCERRORS
Pause Receive Frames Register
Receive CRC Errors Register (Total number of frames received with
CRC errors)
Receive Alignment/Code Errors Register
(Total number of frames received with alignment/code errors)
01C8 0214
01C8 0218
01C8 021C
01C8 0220
RXALIGNCODEERRORS
RXOVERSIZED
Receive Oversized Frames Register
(Total number of oversized frames received)
Receive Jabber Frames Register
(Total number of jabber frames received)
RXJABBER
Receive Undersized Frames Register
(Total number of undersized frames received)
RXUNDERSIZED
01C8 0224
01C8 0228
01C8 022C
RXFRAGMENTS
RXFILTERED
Receive Frame Fragments Register
Filtered Receive Frames Register
Received QOS Filtered Frames Register
RXQOSFILTERED
Receive Octet Frames Register
(Total number of received bytes in good frames)
01C8 0230
01C8 0234
RXOCTETS
Good Transmit Frames Register
(Total number of good frames transmitted)
TXGOODFRAMES
01C8 0238
01C8 023C
01C8 0240
01C8 0244
01C8 0248
01C8 024C
01C8 0250
01C8 0254
01C8 0258
01C8 025C
01C8 0260
01C8 0264
01C8 0268
01C8 026C
01C8 0270
01C8 0274
01C8 0278
01C8 027C
01C8 0280
01C8 0284
01C8 0288
TXBCASTFRAMES
TXMCASTFRAMES
TXPAUSEFRAMES
TXDEFERRED
Broadcast Transmit Frames Register
Multicast Transmit Frames Register
Pause Transmit Frames Register
Deferred Transmit Frames Register
TXCOLLISION
Transmit Collision Frames Register
TXSINGLECOLL
TXMULTICOLL
TXEXCESSIVECOLL
TXLATECOLL
Transmit Single Collision Frames Register
Transmit Multiple Collision Frames Register
Transmit Excessive Collision Frames Register
Transmit Late Collision Frames Register
TXUNDERRUN
TXCARRIERSENSE
TXOCTETS
Transmit Underrun Error Register
Transmit Carrier Sense Errors Register
Transmit Octet Frames Register
FRAME64
Transmit and Receive 64 Octet Frames Register
Transmit and Receive 65 to 127 Octet Frames Register
Transmit and Receive 128 to 255 Octet Frames Register
Transmit and Receive 256 to 511 Octet Frames Register
Transmit and Receive 512 to 1023 Octet Frames Register
Transmit and Receive 1024 to 1518 Octet Frames Register
Network Octet Frames Register
FRAME65T127
FRAME128T255
FRAME256T511
FRAME512T1023
FRAME1024TUP
NETOCTETS
RXSOFOVERRUNS
RXMOFOVERRUNS
Receive FIFO or DMA Start of Frame Overruns Register
Receive FIFO or DMA Middle of Frame Overruns Register
Receive DMA Start of Frame and Middle of Frame Overruns
Register
01C8 028C
RXDMAOVERRUNS
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Table 6-73. EMAC Control Module Registers
HEX ADDRESS RANGE
0x01C8 1004
ACRONYM
EWCTL
REGISTER NAME
Interrupt control register
Interrupt timer count
0x01C8 1008
EWINTTCNT
Table 6-74. EMAC Control Module RAM
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
EMAC Control Module Descriptor Memory
0x01C8 2000 - 0x01C8 3FFF
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6.17.2 EMAC Electrical Data/Timing
Table 6-75. Timing Requirements for MRCLK (see Figure 6-39)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
10 Mbps
100 Mbps
MIN MAX MIN MAX
1
2
3
tc(MRCLK)
Cycle time, MRCLK
400
140
140
40
14
14
ns
ns
ns
tw(MRCLKH) Pulse duration, MRCLK high
tw(MRCLKL) Pulse duration, MRCLK low
1
2
3
MRCLK
Figure 6-39. MRCLK Timing (EMAC - Receive)
Table 6-76. Timing Requirements for MTCLK (see Figure 6-39)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
10 Mbps
100 Mbps
MIN MAX MIN MAX
1
2
3
tc(MTCLK)
Cycle time, MTCLK
400
140
140
40
14
14
ns
ns
ns
tw(MTCLKH) Pulse duration, MTCLK high
tw(MTCLKL)
Pulse duration, MTCLK low
1
2
3
MTCLK
Figure 6-40. MTCLK Timing (EMAC - Transmit)
Table 6-77. Timing Requirements for EMAC MII Receive 10/100 Mbit/s(1) (see Figure 6-41)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
8
MAX
1
2
tsu(MRXD-MRCLKH)
th(MRCLKH-MRXD)
Setup time, receive selected signals valid before MRCLK high
Hold time, receive selected signals valid after MRCLK high
ns
ns
8
(1) Receive selected signals include: MRXD3-MRXD0, MRXDV, and MRXER.
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1
2
MRCLK (Input)
MRXD3−MRXD0,
MRXDV, MRXER (Inputs)
Figure 6-41. EMAC Receive Interface Timing
Table 6-78. Switching Characteristics Over Recommended Operating Conditions for EMAC MII Transmit
10/100 Mbit/s(1) (see Figure 6-42)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
UNIT
-6
MIN
MAX
1
td(MTCLKH-MTXD)
Delay time, MTCLK high to transmit selected signals valid
2
25
ns
(1) Transmit selected signals include: MTXD3-MTXD0, and MTXEN.
1
MTCLK (Input)
MTXD3−MTXD0,
MTXEN (Outputs)
Figure 6-42. EMAC Transmit Interface Timing
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6.18 Management Data Input/Output (MDIO)
The Management Data Input/Output (MDIO) module continuously polls all 32 MDIO addresses in order to
enumerate all PHY devices in the system.
The Management Data Input/Output (MDIO) module implements the 802.3 serial management interface to
interrogate and control Ethernet PHY(s) using a shared two-wire bus. Host software uses the MDIO
module to configure the auto-negotiation parameters of each PHY attached to the EMAC, retrieve the
negotiation results, and configure required parameters in the EMAC module for correct operation. The
module is designed to allow almost transparent operation of the MDIO interface, with very little
maintenance from the core processor. Only one PHY may be connected at any given time.
For more detailed information on the MDIO peripheral, see the Documentation Support section for the
Ethernet Media Access Controller (EMAC)/Management Data Input/Output (MDIO) Module Reference
Guide. For a list of supported registers and register fields, see Table 6-79 [MDIO Registers] in this data
manual.
6.18.1 Peripheral Register Description(s)
Table 6-79. MDIO Registers
HEX ADDRESS RANGE
0x01C8 4000
ACRONYM
–
REGISTER NAME
Reserved
0x01C8 4004
CONTROL
ALIVE
MDIO Control Register
0x01C8 4008
MDIO PHY Alive Status Register
0x01C8 400C
LINK
MDIO PHY Link Status Register
0x01C8 4010
LINKINTRAW
LINKINTMASKED
–
MDIO Link Status Change Interrupt (Unmasked) Register
MDIO Link Status Change Interrupt (Masked) Register
Reserved
0x01C8 4014
0x01C8 4018
0x01C8 4020
USERINTRAW
USERINTMASKED
USERINTMASKSET
MDIO User Command Complete Interrupt (Unmasked) Register
MDIO User Command Complete Interrupt (Masked) Register
MDIO User Command Complete Interrupt Mask Set Register
0x01C8 4024
0x01C8 4028
0x01C8 402C
USERINTMASKCLEAR MDIO User Command Complete Interrupt Mask Clear Register
0x01C8 4030 - 0x01C8 407C
0x01C8 4080
–
Reserved
USERACCESS0
USERPHYSEL0
USERACCESS1
USERPHYSEL1
–
MDIO User Access Register 0
MDIO User PHY Select Register 0
MDIO User Access Register 1
MDIO User PHY Select Register 1
Reserved
0x01C8 4084
0x01C8 4088
0x01C8 408C
0x01C8 4090 - 0x01C8 47FF
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6.18.2 Management Data Input/Output (MDIO) Electrical Data/Timing
Table 6-80. Timing Requirements for MDIO Input (see Figure 6-43 and Figure 6-44)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
400
180
MAX
1
2
3
4
5
tc(MDCLK)
Cycle time, MDCLK
ns
ns
ns
ns
ns
tw(MDCLK)
Pulse duration, MDCLK high/low
tt(MDCLK)
Transition time, MDCLK
5
tsu(MDIO-MDCLKH)
th(MDCLKH-MDIO)
Setup time, MDIO data input valid before MDCLK high
Hold time, MDIO data input valid after MDCLK high
10
10
1
3
3
MDCLK
4
5
MDIO
(input)
Figure 6-43. MDIO Input Timing
Table 6-81. Switching Characteristics Over Recommended Operating Conditions for MDIO Output
(see Figure 6-44)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
UNIT
-6
MIN
MAX
7
td(MDCLKL-MDIO)
Delay time, MDCLK low to MDIO data output valid
100
ns
1
MDCLK
7
MDIO
(output)
Figure 6-44. MDIO Output Timing
6.19 Timers
The DM6435 device has 3 64-bit general-purpose timers which have the following features:
•
•
64-bit count-up counter
Timer modes:
–
–
–
64-bit general-purpose timer mode (Timer 0 and 1)
Dual 32-bit general-purpose timer mode (Timer 0 and 1)
Watchdog timer mode (Timer 2)
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•
•
2 possible clock sources:
–
–
Internal clock
External clock input via timer input pin TINPL (Timer 0 and 1 only)
2 operation modes:
–
–
One-time operation (timer runs for one period then stops)
Continuous operation (timer automatically resets after each period)
•
•
•
Generates interrupts to the DSP
Generates sync event to EDMA
Causes device global reset upon watchdog timer timeout (Timer 2 only)
For more detailed information, see Section 2.9, Documentation Support for the TMS320DM643x DMP
64-Bit Timer User's Guide (literature number SPRU989).
6.19.1 Timer Peripheral Register Description(s)
Table 6-82. Timer 0 Registers
HEX ADDRESS RANGE
0x01C2 1400
ACRONYM
DESCRIPTION
-
Reserved
0x01C2 1404
EMUMGT_CLKSPD
Timer 0 Emulation Management/Clock Speed Register
Timer 0 Counter Register 12
Timer 0 Counter Register 34
Timer 0 Period Register 12
Timer 0 Period Register 34
Timer 0 Control Register
0x01C2 1410
TIM12
TIM34
PRD12
PRD34
TCR
0x01C2 1414
0x01C2 1418
0x01C2 141C
0x01C2 1420
0x01C2 1424
TGCR
-
Timer 0 Global Control Register
Reserved
0x01C2 1428 - 0x01C2 17FF
Table 6-83. Timer 1 Registers
HEX ADDRESS RANGE
0x01C2 1800
ACRONYM
DESCRIPTION
-
Reserved
0x01C2 1804
EMUMGT_CLKSPD
Timer 1 Emulation Management/Clock Speed Register
Timer 1 Counter Register 12
Timer 1 Counter Register 34
Timer 1 Period Register 12
Timer 1 Period Register 34
Timer 1 Control Register
0x01C2 1810
TIM12
TIM34
PRD12
PRD34
TCR
0x01C2 1814
0x01C2 1818
0x01C2 181C
0x01C2 1820
0x01C2 1824
TGCR
-
Timer 1 Global Control Register
Reserved
0x01C2 1828 - 0x01C2 1BFF
Table 6-84. Timer 2 (Watchdog) Registers
HEX ADDRESS RANGE
0x01C2 1C00
0x01C2 1C04
0x01C2 1C10
0x01C2 1C14
0x01C2 1C18
0x01C2 1C1C
0x01C2 1C20
0x01C2 1C24
ACRONYM
DESCRIPTION
-
EMUMGT_CLKSPD
TIM12
Reserved
Timer 2 Emulation Management/Clock Speed Register
Timer 2 Counter Register 12
TIM34
Timer 2 Counter Register 34
PRD12
Timer 2 Period Register 12
PRD34
Timer 2 Period Register 34
TCR
Timer 2 Control Register
TGCR
Timer 2 Global Control Register
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Table 6-84. Timer 2 (Watchdog) Registers (continued)
HEX ADDRESS RANGE
ACRONYM
DESCRIPTION
Timer 2 Watchdog Timer Control Register
Reserved
0x01C2 1C28
WDTCR
-
0x01C2 1C2C - 0x01C2 1FFF
6.19.2 Timer Electrical Data/Timing
Table 6-85. Timing Requirements for Timer Input(1)(2)(3) (see Figure 6-45)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
TINP0L, if TIMERCTL.TINP0SEL = 0
[default]
2P
ns
1
tw(TINPH)
Pulse duration, TINPxL high
TINP0L, if TIMERCTL.TINP0SEL = 1
0.33P
2P
ns
ns
TINP1L
TINP0L, if TIMERCTL.TINP0SEL = 0
[default]
2P
ns
2
tw(TINPL)
Pulse duration, TINPxL low
TINP0L, if TIMERCTL.TINP0SEL = 1
0.33P
2P
ns
ns
TINP1L
(1) P = MXI/CLKIN cycle time in ns. For example, when MXI/CLKIN frequency is 27 MHz, use P = 37.037 ns.
(2) The TIMERCTL.TINP0SEL field in the System Module determines if the TINP0L input directly goes to Timer 0
(TIMERCTL.TINP0SEL=0), or if the TINP0L input is first divided down by 6 before going to Timer 0 (TIMERCTL.TINP0SEL=1).
(3) TINP1L input goes directly to Timer 1.
Table 6-86. Switching Characteristics Over Recommended Operating Conditions for Timer Output(1) (see
Figure 6-45)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
UNIT
-6
MIN
MAX
3
4
tw(TOUTH)
tw(TOUTL)
Pulse duration, TOUTxL high
Pulse duration, TOUTxL low
P
P
ns
ns
(1) P = MXI/CLKIN cycle time in ns. For example, when MXI/CLKIN frequency is 27 MHz, use P = 37.037 ns.
1
2
TINPxL
3
4
TOUTxL
Figure 6-45. Timer Timing
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6.20 Pulse Width Modulator (PWM)
The 3 DM6435 Pulse Width Modulator (PWM) peripherals support the following features:
•
•
•
•
•
•
Period counter
First-phase duration counter
Repeat count for one-shot operation
Configurable to operate in either one-shot or continuous mode
Buffered period and first-phase duration registers
One-shot operation triggerable by hardware events with programmable edge transitions. (low-to-high or
high-to-low).
•
•
One-shot operation generates N+1 periods of waveform, N being the repeat count register value
Emulation support
The register memory maps for PWM0/1/2 are shown in Table 6-87, Table 6-88, and Table 6-89.
Table 6-87. PWM0 Register Memory Map
HEX ADDRESS RANGE
0x01C2 2000
ACRONYM
REGISTER NAME
Reserved
0x01C2 2004
PCR
CFG
START
RPT
PER
PH1D
-
PWM0 Peripheral Control Register
PWM0 Configuration Register
PWM0 Start Register
0x01C2 2008
0x01C2 200C
0x01C2 2010
PWM0 Repeat Count Register
PWM0 Period Register
0x01C2 2014
0x01C2 2018
PWM0 First-Phase Duration Register
Reserved
0x01C2 201C - 0x01C2 23FF
Table 6-88. PWM1 Register Memory Map
HEX ADDRESS RANGE
0x01C2 2400
ACRONYM
REGISTER NAME
Reserved
0x01C2 2404
PCR
CFG
START
RPT
PER
PH1D
-
PWM1 Peripheral Control Register
0x01C2 2408
PWM1 Configuration Register
PWM1 Start Register
0x01C2 240C
0x01C2 2410
PWM1 Repeat Count Register
PWM1 Period Register
PWM1 First-Phase Duration Register
Reserved
0x01C2 2414
0x01C2 2418
0x01C2 241C -0x01C2 27FF
Table 6-89. PWM2 Register Memory Map
HEX ADDRESS RANGE
0x01C2 2800
ACRONYM
REGISTER NAME
Reserved
0x01C2 2804
PCR
CFG
START
RPT
PER
PH1D
-
PWM2 Peripheral Control Register
PWM2 Configuration Register
PWM2 Start Register
0x01C2 2808
0x01C2 280C
0x01C2 2810
PWM2 Repeat Count Register
PWM2 Period Register
0x01C2 2814
0x01C2 2818
PWM2 First-Phase Duration Register
Reserved
0x01C2 281C - 0x01C2 2BFF
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6.20.1 PWM0/1/2 Electrical Data/Timing
Table 6-90. Switching Characteristics Over Recommended Operating Conditions for PWM0/1/2 Outputs
(see Figure 6-46 and Figure 6-47)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
1
2
3
4
tw(PWMH)
tw(PWML)
Pulse duration, PWMx high
37
37
ns
ns
ns
ns
Pulse duration, PWMx low
tt(PWM)
Transition time, PWMx
5
td(CCDC-PWMV)
Delay time, CCDC(VD) trigger event to PWMx valid
2
10
1
2
PWM0/1/2
3
3
Figure 6-46. PWM Output Timing
VD(CCDC)
4
INVALID
VALID
PWM0
PWM1
4
INVALID
VALID
4
INVALID
VALID
PWM2
Figure 6-47. PWM Output Delay Timing
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6.21 VLYNQ
The DM6435 VLYNQ peripheral provides a high speed serial communications interface with the following
features.
•
•
•
Low Pin Count
Scalable Performance / Support
Simple Packet Based Transfer Protocol for Memory Mapped Access
–
–
–
–
Write Request / Data Packet
Read Request Packet
Read Response Data Packet
Interrupt Request Packet
•
Supports both Symmetric and Asymmetric Operation
–
–
–
Tx pins on first device connect to Rx pins on second device and vice versa
Data pin widths are automatically detected after reset
Request packets, response packets, and flow control information are all multiplexed and sent
across the same physical pins
–
Supports both Host/Peripheral and Peer to Peer communication
•
•
Simple Block Code Packet Formatting (8b/10b)
In Band Flow Control
–
–
–
No extra pins needed
Allows receiver to momentarily throttle back transmitter when overflow is about to occur
Uses built in special code capability of block code to seamlessly interleave flow control information
with user data
–
Allows system designer to balance cost of data buffering versus performance
•
•
•
Multiple outstanding transactions
Automatic packet formatting optimizations
Internal loop-back mode
6.21.1 VLYNQ Peripheral Register Description(s)
Table 6-91. VLYNQ Registers
HEX ADDRESS RANGE
0x01E0 1000
0x01E0 1004
0x01E0 1008
0x01E0 100C
0x01E0 1010
0x01E0 1014
0x01E0 1018
0x01E0 101C
0x01E0 1020
0x01E0 1024
0x01E0 1028
0x01E0 102C
0x01E0 1030
0x01E0 1034
0x01E0 1038
0x01E0 103C
ACRONYM
REGISTER NAME
-
CTRL
Reserved
VLYNQ Local Control Register
VLYNQ Local Status Register
STAT
INTPRI
VLYNQ Local Interrupt Priority Vector Status/Clear Register
VLYNQ Local Unmasked Interrupt Status/Clear Register
VLYNQ Local Interrupt Pending/Set Register
INTSTATCLR
INTPENDSET
INTPTR
XAM
VLYNQ Local Interrupt Pointer Register
VLYNQ Local Transmit Address Map Register
RAMS1
RAMO1
RAMS2
RAMO2
RAMS3
RAMO3
RAMS4
RAMO4
VLYNQ Local Receive Address Map Size 1 Register
VLYNQ Local Receive Address Map Offset 1 Register
VLYNQ Local Receive Address Map Size 2 Register
VLYNQ Local Receive Address Map Offset 2 Register
VLYNQ Local Receive Address Map Size 3 Register
VLYNQ Local Receive Address Map Offset 3 Register
VLYNQ Local Receive Address Map Size 4 Register
VLYNQ Local Receive Address Map Offset 4 Register
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Table 6-91. VLYNQ Registers (continued)
HEX ADDRESS RANGE
0x01E0 1040
ACRONYM
REGISTER NAME
VLYNQ Local Chip Version Register
CHIPVER
0x01E0 1044
AUTNGO
VLYNQ Local Auto Negotiation Register
0x01E0 1048
-
Reserved
0x01E0 104C
-
Reserved
0x01E0 1050 - 0x01E0 105C
0x01E0 1060
-
Reserved
-
Reserved
01E0 10C00 0064
0x01E0 1068 - 0x01E0 107C
0x01E0 1080
-
Reserved
-
Reserved for future use
RREVID
RCTRL
RSTAT
RINTPRI
VLYNQ Remote Revision Register
VLYNQ Remote Control Register
VLYNQ Remote Status Register
VLYNQ Remote Interrupt Priority Vector Status/Clear Register
0x01E0 1084
0x01E0 1088
0x01E0 108C
0x01E0 1090
RINTSTATCLR VLYNQ Remote Unmasked Interrupt Status/Clear Register
RINTPENDSET VLYNQ Remote Interrupt Pending/Set Register
0x01E0 1094
0x01E0 1098
RINTPTR
RXAM
VLYNQ Remote Interrupt Pointer Register
0x01E0 109C
VLYNQ Remote Transmit Address Map Register
0x01E0 10A0
RRAMS1
RRAMO1
RRAMS2
RRAMO2
RRAMS3
RRAMO3
RRAMS4
RRAMO4
VLYNQ Remote Receive Address Map Size 1 Register
VLYNQ Remote Receive Address Map Offset 1 Register
VLYNQ Remote Receive Address Map Size 2 Register
VLYNQ Remote Receive Address Map Offset 2 Register
VLYNQ Remote Receive Address Map Size 3 Register
VLYNQ Remote Receive Address Map Offset 3 Register
VLYNQ Remote Receive Address Map Size 4 Register
VLYNQ Remote Receive Address Map Offset 4 Register
0x01E0 10A4
0x01E0 10A8
0x01E0 10AC
0x01E0 10B0
0x01E0 10B4
0x01E0 10B8
0x01E0 10BC
VLYNQ Remote Chip Version Register (values on the device_id and
device_rev pins of remote VLYNQ)
0x01E0 10C0
RCHIPVER
0x01E0 10C4
0x01E0 10C8
RAUTNGO
RMANNGO
RNGOSTAT
-
VLYNQ Remote Auto Negotiation Register
VLYNQ Remote Manual Negotiation Register
VLYNQ Remote Negotiation Status Register
Reserved
0x01E0 10CC
0x01E0 10D0 - 0x01E0 10DC
VLYNQ Remote Interrupt Vectors 3 - 0 (sourced from vlynq_int_i[3:0] port of
remote VLYNQ)
0x01E0 10E0
0x01E0 10E4
RINTVEC0
RINTVEC1
VLYNQ Remote Interrupt Vectors 7 - 4 (sourced from vlynq_int_i[7:4] port of
remote VLYNQ)
0x01E0 10E8 - 0x01E0 10FC
0x01E0 1100 - 0x01E0 1FFF
-
-
Reserved for future use
Reserved
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6.21.2 VLYNQ Electrical Data/Timing
Table 6-92. Timing Requirements for VLYNQ_CLK Input (see Figure 6-48)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
10
3
MAX
1
2
3
tc(VCLK)
Cycle time, VLYNQ_CLK
ns
ns
ns
tw(VCLKH)
tw(VCLKL)
Pulse duration, VLYNQ_CLK high
Pulse duration, VLYNQ_CLK low
3
Table 6-93. Switching Characteristics Over Recommended Operating Conditions for VLYNQ_CLK Output
(see Figure 6-48)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
1
2
3
tc(VCLK)
Cycle time, VLYNQ_CLK
10
4
ns
ns
ns
tw(VCLKH)
tw(VCLKL)
Pulse duration, VLYNQ_CLK high
Pulse duration, VLYNQ_CLK low
4
1
2
VLYNQ_CLK
3
Figure 6-48. VLYNQ_CLK Timing for VLYNQ
Table 6-94. Switching Characteristics Over Recommended Operating Conditions for Transmit Data for the
VLYNQ Module (see Figure 6-49)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
td(VCLKH-
TXDI)
1
2
Delay time, VLYNQ_CLK high to VLYNQ_TXD[3:0] invalid
Delay time, VLYNQ_CLK high to VLYNQ_TXD[3:0] valid
2.25
ns
ns
td(VCLKH-
TXDV)
12
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Table 6-95. Timing Requirements for Receive Data for the VLYNQ Module(1) (see Figure 6-49)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
MAX
RTM disabled, RTM sample = 3
RTM enabled
1.75
(1)
ns
ns
ns
ns
Setup time, VLYNQ_RXD[3:0] valid before
VLYNQ_CLK high
3
4
tsu(RXDV-VCLKH)
RTM disabled, RTM sample = 3
RTM enabled
3
(1)
Hold time, VLYNQ_RXD[3:0] valid after
VLYNQ_CLK high
th(VCLKH-RXDV)
(1) The VLYNQ receive timing manager (RTM) is a serial receive logic designed to eliminate setup and hold violations that could occur in
traditional input signals. RTM logic automatically selects the setup and hold timing from one of eight data flops (see Table 6-96). When
RTM logic is disabled, the setup and hold timing from the default data flop (3) is used.
Table 6-96. RTM RX Data Flop Hold/Setup Timing
Constraints (Typical Values)
RX Data Flop
HOLD (Y)
1.3
SETUP (X)
0.9
0
1
2
3
4
5
6
7
1.4
0.7
1.5
-0.4
1.6
-0.6
1.8
-0.8
2.0
-1.0
2.2
-1.1
2.4
-1.2
1
VLYNQ_CLK
2
Data
Data
VLYNQ_TXD[3:0]
VLYNQ_RXD[3:0]
4
3
Figure 6-49. VLYNQ Transmit/Receive Timing
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6.22 General-Purpose Input/Output (GPIO)
The GPIO peripheral provides general-purpose pins that can be configured as either inputs or outputs.
When configured as an output, a write to an internal register can control the state driven on the output pin.
When configured as an input, the state of the input is detectable by reading the state of an internal
register. In addition, the GPIO peripheral can produce CPU interrupts and EDMA events in different
interrupt/event generation modes. The GPIO peripheral provides generic connections to external devices.
The GPIO pins are grouped into banks of 16 pins per bank (i.e., bank 0 consists of GP[0:15]).
The DM6435 GPIO peripheral supports the following:
•
•
Up to 111 3.3-V GPIO pins, GP[0:110]
Interrupts:
–
–
–
Up to 8 unique GP[0:7] interrupts from Bank 0
7 GPIO bank (aggregated) interrupt signals from each of the 7 banks of GPIOs
Interrupts can be triggered by rising and/or falling edge, specified for each interrupt capable GPIO
signal
•
•
DMA events:
–
–
Up to 8 unique GPIO DMA events from Bank 0
7 GPIO bank (aggregated) DMA event signals from each of the 7 banks of GPIOs
Set/clear functionality: Firmware writes 1 to corresponding bit position(s) to set or to clear GPIO
signal(s). This allows multiple firmware processes to toggle GPIO output signals without critical section
protection (disable interrupts, program GPIO, re-enable interrupts, to prevent context switching to
anther process during GPIO programming).
•
•
Separate Input/Output registers
Output register in addition to set/clear so that, if preferred by firmware, some GPIO output signals can
be toggled by direct write to the output register(s).
•
Output register, when read, reflects output drive status. This, in addition to the input register reflecting
pin status and open-drain I/O cell, allows wired logic be implemented.
The memory map for the GPIO registers is shown in Table 6-97. For more detailed information on GPIOs,
see the TMS320DM643x DMP General-Purpose Input/Output (GPIO) User's Guide (literature number
SPRU988).
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6.22.1 GPIO Peripheral Register Description(s)
Table 6-97. GPIO Registers
HEX ADDRESS RANGE
0x01C6 7000
ACRONYM
REGISTER NAME
Peripheral Identification Register
PID
-
0x01C6 7004
Reserved
0x01C6 7008
BINTEN
GPIO interrupt per-bank enable
GPIO Banks 0 and 1
0x01C6 700C
0x01C6 7010
0x01C6 7014
0x01C6 7018
0x01C6 701C
0x01C6 7020
0x01C6 7024
0x01C6 7028
0x01C6 702C
0x01C6 7030
0x01C6 7034
-
Reserved
DIR01
GPIO Banks 0 and 1 Direction Register (GP[0:31])
GPIO Banks 0 and 1 Output Data Register (GP[0:31])
GPIO Banks 0 and 1 Set Data Register (GP[0:31])
GPIO Banks 0 and 1 Clear data for banks 0 and 1 (GP[0:31])
GPIO Banks 0 and 1 Input Data Register (GP[0:31])
OUT_DATA01
SET_DATA01
CLR_DATA01
IN_DATA01
SET_RIS_TRIG01 GPIO Banks 0 and 1 Set Rising Edge Interrupt Register (GP[0:31])
CLR_RIS_TRIG01 GPIO Banks 0 and 1 Clear Rising Edge Interrupt Register (GP[0:31])
SET_FAL_TRIG01 GPIO Banks 0 and 1 Set Falling Edge Interrupt Register (GP[0:31])
CLR_FAL_TRIG01 GPIO Banks 0 and 1 Clear Falling Edge Interrupt Register (GP[0:31])
INSTAT01
GPIO Banks 0 and 1 Interrupt Status Register (GP[0:31])
GPIO Banks 2 and 3
0x01C6 7038
0x01C6 703C
0x01C6 7040
0x01C6 7044
0x01C6 7048
0x01C6 704C
0x01C6 7050
0x01C6 7054
0x01C6 7058
0x01C6 705C
DIR23
GPIO Banks 2 and 3 Direction Register (GP[32:63])
GPIO Banks 2 and 3 Output Data Register (GP[32:63])
GPIO Banks 2 and 3 Set Data Register (GP[32:63])
GPIO Banks 2 and 3 Clear Data Register (GP[32:63])
GPIO Banks 2 and 3 Input Data Register (GP[32:63])
OUT_DATA23
SET_DATA23
CLR_DATA23
IN_DATA23
SET_RIS_TRIG23 GPIO Banks 2 and 3 Set Rising Edge Interrupt Register (GP[32:63])
CLR_RIS_TRIG23 GPIO Banks 2 and 3 Clear Rising Edge Interrupt Register (GP[32:63])
SET_FAL_TRIG23 GPIO Banks 2 and 3 Set Falling Edge Interrupt Register (GP[32:63])
CLR_FAL_TRIG23 GPIO Banks 2 and 3 Clear Falling Edge Interrupt Register (GP[32:63])
INSTAT23
GPIO Banks 2 and 3 Interrupt Status Register (GP[32:63])
GPIO Bank 4 and 5
0x01C6 7060
0x01C6 7064
0x01C6 7068
0x01C6 706C
0x01C6 7070
0x01C6 7074
0x01C6 7078
0x01C6 707C
0x01C6 7080
0x01C6 7084
DIR45
GPIO Bank 4 and 5 Direction Register (GP[64:95])
GPIO Bank 4 and 5 Output Data Register (GP[64:95])
GPIO Bank 4 and 5 Set Data Register (GP[64:95])
GPIO Bank 4 and 5 Clear Data Register (GP[64:95])
GPIO Bank 4 and 5 Input Data Register (GP[64:95])
OUT_DATA45
SET_DATA45
CLR_DATA45
IN_DATA45
SET_RIS_TRIG45 GPIO Bank 4 and 5 Set Rising Edge Interrupt Register (GP[64:95])
CLR_RIS_TRIG45 GPIO Bank 4 and 5 Clear Rising Edge Interrupt Register (GP[64:95])
SET_FAL_TRIG45 GPIO Bank 4 and 5 Set Falling Edge Interrupt Register (GP[64:95])
CLR_FAL_TRIG45 GPIO Bank 4 and 5 Clear Falling Edge Interrupt Register (GP[64:95])
INSTAT45
GPIO Bank 4 and 5 Interrupt Status Register (GP[64:95])
GPIO Bank 6
0x01C6 7088
0x01C6 708C
0x01C6 7090
0x01C6 7094
0x01C6 7098
0x01C6 709C
0x01C6 70A0
DIR6
GPIO Bank 6 Direction Register (GP[96:110])
GPIO Bank 6 Output Data Register (GP[96:110])
GPIO Bank 6 Set Data Register (GP[96:110])
GPIO Bank 6 Clear Data Register (GP[96:110])
GPIO Bank 6 Input Data Register (GP[96:110])
GPIO Bank 6 Set Rising Edge Interrupt Register (GP[96:110])
GPIO Bank 6 Clear Rising Edge Interrupt Register (GP[96:110])
OUT_DATA6
SET_DATA6
CLR_DATA6
IN_DATA6
SET_RIS_TRIG6
CLR_RIS_TRIG6
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Table 6-97. GPIO Registers (continued)
HEX ADDRESS RANGE
0x01C6 70A4
ACRONYM
SET_FAL_TRIG6
CLR_FAL_TRIG6 GPIO Bank 6 Clear Falling Edge Interrupt Register (GP[96:110])
REGISTER NAME
GPIO Bank 6 Set Falling Edge Interrupt Register (GP[96:110])
0x01C6 70A8
0x01C6 70AC
INSTAT6
-
GPIO Bank 6 Interrupt Status Register (GP[96:110])
Reserved
0x01C6 70B0 - 0x01C6 7FFF
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6.22.2 GPIO Peripheral Input/Output Electrical Data/Timing
Table 6-98. Timing Requirements for GPIO Inputs(1) (see Figure 6-50)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
2C(2)
2C(2)
MAX
1
2
tw(GPIH)
tw(GPIL)
Pulse duration, GP[x] input high
Pulse duration, GP[x] input low
ns
ns
(1) The pulse width given is sufficient to generate a CPU interrupt or an EDMA event. However, if a user wants to have DM6435 recognize
the GP[x] input changes through software polling of the GPIO register, the GP[x] input duration must be extended to allow DM6435
enough time to access the GPIO register through the internal bus.
(2) C = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use C = 10ns.
Table 6-99. Switching Characteristics Over Recommended Operating Conditions for GPIO Outputs
(see Figure 6-50)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
3
4
tw(GPOH)
tw(GPOL)
Pulse duration, GP[x] output high
Pulse duration, GP[x] output low
2C(1)(2)
2C(1)(2)
ns
ns
(1) This parameter value should not be used as a maximum performance specification. Actual performance of back-to-back accesses of the
GPIO is dependent upon internal bus activity.
(2) C = SYSCLK3 period in ns. For example, when running parts at 600 MHz, use C = 10ns.
2
1
GP[x]
Input
4
3
GP[x]
Output
Figure 6-50. GPIO Port Timing
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6.23 IEEE 1149.1 JTAG
The JTAG(3) interface is used for BSDL testing and emulation of the DM6435 device.
TRST only needs to be released when it is necessary to use a JTAG controller to debug the device or
exercise the device's boundary scan functionality. Note: TRST is synchronous and must be clocked by
TCK; otherwise, the boundary scan logic may not respond as expected after TRST is asserted.
For maximum reliability, DM6435 includes an internal pulldown (IPD) on the TRST pin to ensure that
TRST will always be asserted upon power up and the device's internal emulation logic will always be
properly initialized.
JTAG controllers from Texas Instruments actively drive TRST high. However, some third-party JTAG
controllers may not drive TRST high but expect the use of a pullup resistor on TRST.
When using this type of JTAG controller, assert TRST to initialize the device after powerup and externally
drive TRST high before attempting any emulation or boundary scan operations.
(3) IEEE Standard 1149.1-1990 Standard-Test-Access Port and Boundary Scan Architecture.
6.23.1 JTAG ID (JTAGID) Register Description(s)
Table 6-100. JTAG ID (JTAGID) Register
HEX ADDRESS RANGE
ACRONYM
REGISTER NAME
COMMENTS
Read-only. Provides 32-bit
JTAG ID of the device.
0x01C4 0028
JTAGID
JTAG Identification Register
The JTAG ID register is a read-only register that identifies to the customer the JTAG/Device ID. For the
DM6435 device, the JTAG ID register resides at address location 0x01C4 0028. For the actual register bit
names and their associated bit field descriptions, see Figure 6-51 and Table 6-101.
31-28
VARIANT (4-Bit)
R-n
27-12
11-1
0
PART NUMBER (16-Bit)
R-1011 0111 0010 0001
MANUFACTURER (11-Bit)
R-0000 0010 111
LSB
R-1
LEGEND: R = Read, W = Write, n = value at reset
Figure 6-51. JTAG ID (JTAGID) Register—0x01C4 0028
Table 6-101. JTAG ID (JTAGID) Register Selection Bit Descriptions
BIT
31:28
27:12
11-1
0
NAME
DESCRIPTION
Variant (4-Bit) value. A read from this field always returns 0b0000.
Part Number (16-Bit) value. DM6435 value: 1011 0111 0010 0001.
VARIANT
PART NUMBER
MANUFACTURER Manufacturer (11-Bit) value. DM6435 value: 0000 0010 111.
LSB LSB. This bit is read as a "1" for DM6435.
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6.23.2 JTAG Electrical Data/Timing
Table 6-102. Timing Requirements for JTAG Test Port (see Figure 6-52)
-4/-4Q/-4S
-5/-5Q/-5S
-6
NO.
UNIT
MIN
33
MAX
1
3
4
tc(TCK)
Cycle time, TCK
ns
ns
ns
tsu(TDIV-TCKH)
th(TCKH-TDIV)
Setup time, TDI/TMS/TRST valid before TCK high
Hold time, TDI/TMS/TRST valid after TCK high
2.5
16.5
Table 6-103. Switching Characteristics Over Recommended Operating Conditions for JTAG Test Port
(see Figure 6-52)
-4/-4Q/-4S
-5/-5Q/-5S
NO.
PARAMETER
UNIT
-6
MIN
MAX
2
td(TCKL-TDOV)
Delay time, TCK low to TDO valid
0
14
ns
1
TCK
TDO
2
2
4
3
TDI/TMS/TRST
Figure 6-52. JTAG Test-Port Timing
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7 Mechanical Data
The following table(s) show the thermal resistance characteristics for the PBGA–ZWT and ZDU
mechanical package(s). For more details, see the Thermal Considerations for TMS320DM64xx,
TMS320DM64x, and TMS320C6000 Devices Application Report (literature number SPRAAL9).
7.1 Thermal Data for ZWT
Table 7-1. Thermal Resistance Characteristics (PBGA Package) [ZWT]
NO.
1
°C/W(1)
AIR FLOW (m/s)(2)
RΘJC
RΘJB
Junction-to-case
Junction-to-board
5.4
N/A
N/A
0.00
1.0
2
16.0
26.6
21.9
20.4
0.0
3
4
RΘJA
PsiJT
PsiJB
Junction-to-free air
Junction-to-package top
Junction-to-board
5
2.00
0.00
1.0
7
8
0.1
9
0.2
2.00
0.00
1.0
11
12
13
15.9
15.8
15.3
2.00
(1) The junction-to-case measurement was conducted in a JEDEC defined 1S0P system. Other measurements were conducted in a JEDEC
defined 1S2P system and will change based on environment as well as application.
For more information, see these three EIA/JEDEC standards:
•
•
EIA/JESD51-2, Integrated Circuits Thermal Test Method Environment Conditions - Natural Convection (Still Air)
EIA/JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
•
.
(2) m/s = meters per second
248
Mechanical Data
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7.1.1 Thermal Data for ZDU
Table 7-2. Thermal Resistance Characteristics (PBGA Package) [ZDU]
NO.
1
°C/W(1)
AIR FLOW (m/s)(2)
RΘJC
RΘJB
Junction-to-case
Junction-to-board
7.7
N/A
N/A
0.00
1.0
2
10.5
19.7
15.5
14.3
4.9
3
4
RΘJA
PsiJT
PsiJB
Junction-to-free air
Junction-to-package top
Junction-to-board
5
2.00
0.00
1.0
7
8
5.1
9
5.2
2.00
0.00
1.0
11
12
13
10.4
9.8
9.6
2.00
(1) The junction-to-case measurement was conducted in a JEDEC defined 1S0P system. Other measurements were conducted in a JEDEC
defined 1S2P system and will change based on environment as well as application.
For more information, see these three EIA/JEDEC standards:
•
•
•
EIA/JESD51-2, Integrated Circuits Thermal Test Method Environment Conditions - Natural Convection (Still Air)
EIA/JESD51-3, Low Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
JESD51-7, High Effective Thermal Conductivity Test Board for Leaded Surface Mount Packages
(2) m/s = meters per second
7.1.2 Packaging Information
The following packaging information and addendum reflect the most current data available for the
designated device(s). This data is subject to change without notice and without revision of this document.
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