SCIMX6Q7CVT08AC [NXP]
i.MX 6Dual/6Quad Applications Processors for Industrial Products;型号: | SCIMX6Q7CVT08AC |
厂家: | NXP |
描述: | i.MX 6Dual/6Quad Applications Processors for Industrial Products |
文件: | 总162页 (文件大小:2579K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Document Number: IMX6DQIEC
Rev. 6, 11/2018
NXP Semiconductors
Data Sheet: Technical Data
MCIMX6QxCxxxxC
MCIMX6QxCxxxxD
MCIMX6QxCxxxxE
MCIMX6DxCxxxxC
MCIMX6DxCxxxxD
MCIMX6DxCxxxxE
i.MX 6Dual/6Quad
ApplicationsProcessorsfor
Industrial Products
Package Information
FCPBGA Package
21 x 21 mm, 0.8 mm pitch
Ordering Information
See Table 1
1
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.1 Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . 2
1.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.3 Signal Naming Convention . . . . . . . . . . . . . . . . . . . 7
Architectural Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
2.1 Block Diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Modules List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
3.1 Special Signal Considerations. . . . . . . . . . . . . . . . 17
3.2 Recommended Connections for Unused Analog
Interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1 Introduction
The i.MX 6Dual/6Quad processors represent the latest
achievement in integrated multimedia applications
processors. These processors are part of a growing
family of multimedia-focused products that offer high
performance processing and are optimized for lowest
2
3
power consumption.
4
Electrical Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . 18
4.1 Chip-Level Conditions . . . . . . . . . . . . . . . . . . . . . . 18
4.2 Power Supplies Requirements and Restrictions . . 31
4.3 Integrated LDO Voltage Regulator Parameters . . 32
4.4 PLL Electrical Characteristics . . . . . . . . . . . . . . . . 34
4.5 On-Chip Oscillators . . . . . . . . . . . . . . . . . . . . . . . . 35
4.6 I/O DC Parameters . . . . . . . . . . . . . . . . . . . . . . . . 36
4.7 I/O AC Parameters . . . . . . . . . . . . . . . . . . . . . . . . 41
4.8 Output Buffer Impedance Parameters. . . . . . . . . . 45
4.9 System Modules Timing . . . . . . . . . . . . . . . . . . . . 48
4.10 Multi-Mode DDR Controller (MMDC). . . . . . . . . . . 60
4.11 General-Purpose Media Interface (GPMI) Timing. 60
4.12 External Peripheral Interface Parameters . . . . . . . 69
Boot Mode Configuration . . . . . . . . . . . . . . . . . . . . . . . 130
5.1 Boot Mode Configuration Pins. . . . . . . . . . . . . . . 130
5.2 Boot Devices Interfaces Allocation . . . . . . . . . . . 131
Package Information and Contact Assignments. . . . . . 133
6.1 Signal Naming Convention . . . . . . . . . . . . . . . . . 133
6.2 21 x 21 mm Package Information . . . . . . . . . . . . 133
Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156
The i.MX 6Dual/6Quad processors feature advanced
®
®
implementation of the quad Arm Cortex -A9 core,
which operates at speeds up to 800 MHz. They include
2D and 3D graphics processors, 1080p video processing,
and integrated power management. Each processor
provides a 64-bit DDR3/DDR3L/LPDDR2-800 memory
interface and a number of other interfaces for connecting
®
peripherals, such as WLAN, Bluetooth , GPS, hard
drive, displays, and camera sensors.
5
6
7
NXP Reserves the right to change the production detail specifications as may be
required to permit improvements in the design of its products.
Introduction
The i.MX 6Dual/6Quad processors are specifically useful for applications such as the following:
The i.MX 6Dual/6Quad processors offers numerous advanced features, such as:
•
•
Multilevel memory system—The multilevel memory system of each processor is based on the L1
instruction and data caches, L2 cache, and internal and external memory. The processors support
many types of external memory devices, including DDR3, DDR3L, LPDDR2, NOR Flash,
PSRAM, cellular RAM, NAND Flash (MLC and SLC), OneNAND™, and managed NAND,
including eMMC up to rev 4.4/4.41.
Smart speed technology—The processors have power management throughout the device that
enables the rich suite of multimedia features and peripherals to consume minimum power in both
active and various low power modes. Smart speed technology enables the designer to deliver a
feature-rich product, requiring levels of power far lower than industry expectations.
•
•
Dynamic voltage and frequency scaling—The processors improve the power efficiency of devices
by scaling the voltage and frequency to optimize performance.
Multimedia powerhouse—The multimedia performance of each processor is enhanced by a
®
multilevel cache system, Neon MPE (Media Processor Engine) co-processor, a multi-standard
hardware video codec, 2 autonomous and independent image processing units (IPU), and a
programmable smart DMA (SDMA) controller.
•
•
Powerful graphics acceleration—Each processor provides three independent, integrated graphics
processing units: an OpenGL ES 2.0 3D graphics accelerator with four shaders (up to 200 MTri/s
and OpenCL support), 2D graphics accelerator, and dedicated OpenVG™ 1.1 accelerator.
®
Interface flexibility—Each processor supports connections to a variety of interfaces: LCD
controller for up to four displays (including parallel display, HDMI1.4, MIPI display, and LVDS
display), dual CMOS sensor interface (parallel or through MIPI), high-speed USB on-the-go with
PHY, high-speed USB host with PHY, multiple expansion card ports (high-speed MMC/SDIO host
and other), 10/100/1000 Mbps Gigabit Ethernet controller, and a variety of other popular interfaces
2
2
(such as UART, I C, and I S serial audio, SATA-II, and PCIe-II).
•
•
Advanced security—The processors deliver hardware-enabled security features that enable secure
e-commerce, digital rights management (DRM), information encryption, secure boot, and secure
software downloads. The security features are discussed in detail in the i.MX 6Dual/6Quad
security reference manual (IMX6DQ6SDLSRM).
Integrated power management—The processors integrate linear regulators and internally generate
voltage levels for different domains. This significantly simplifies system power management
structure.
1.1
Ordering Information
Table 1 shows examples of orderable part numbers covered by this data sheet. This table does not include
all possible orderable part numbers. The latest part numbers are available on nxp.com/imx6series. If your
desired part number is not listed in the table, or you have questions about available parts, see
nxp.com/imx6series or contact your NXP representative.
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
2
NXP Semiconductors
Introduction
Table 1. Example Orderable Part Numbers
Speed1
Grade
Temperature
Part Number
Quad/Dual CPU
Options
Package
Grade
MCIMX6Q7CVT08AC
i.MX 6Quad
Includes VPU, GPU
800 MHz
800 MHz
800 MHz
800 MHz
800 MHz
800 MHz
Industrial
21 mm x 21 mm, 0.8 mm
pitch, FCPBGA (lidded)
MCIMX6Q7CVT08AD
MCIMX6Q7CVT08AE
MCIMX6D7CVT08AC
MCIMX6D7CVT08AD
MCIMX6D7CVT08AE
i.MX 6Quad
i.MX 6Quad
i.MX 6Dual
i.MX 6Dual
i.MX 6Dual
Includes VPU, GPU
Includes VPU, GPU
Includes VPU, GPU
Includes VPU, GPU
Includes VPU, GPU
Industrial
Industrial
Industrial
Industrial
Industrial
21 mm x 21 mm, 0.8 mm
pitch, FCPBGA (lidded)
21 mm x 21 mm, 0.8 mm
pitch, FCPBGA (lidded)
21 mm x 21 mm, 0.8 mm
pitch, FCPBGA (lidded)
21 mm x 21 mm, 0.8 mm
pitch, FCPBGA (lidded)
21 mm x 21 mm, 0.8 mm
pitch, FCPBGA (lidded)
1
If a 24 MHz input clock is used (required for USB), the maximum SoC speed is limited to 792 MHz.
Figure 1 describes the part number nomenclature to identify the characteristics of the specific part number
you have (for example, cores, frequency, temperature grade, fuse options, silicon revision). Figure 1
applies to the i.MX 6Dual/6Quad.
The two characteristics that identify which data sheet a specific part applies to are the part number series
field and the temperature grade (junction) field:
•
•
•
The i.MX 6Dual/6Quad Automotive and Infotainment Applications Processors data sheet
(IMX6DQAEC) covers parts listed with “A (Automotive temp)”
The i.MX 6Dual/6Quad Applications Processors for Consumer Products data sheet (IMX6DQCEC)
covers parts listed with “D (Commercial temp)” or “E (Extended Commercial temp)”
The i.MX 6Dual/6Quad Applications Processors for Industrial Products data sheet (IMX6DQIEC)
covers parts listed with “C (Industrial temp)”
The Ensure that you have the right data sheet for your specific part by checking the temperature grade
(junction) field and matching it to the right data sheet. If you have questions, see nxp.com/imx6series or
contact your NXP representative.
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
3
Introduction
MC
IMX6 X @
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Qualification level
MC
Silicon revision1
Rev 1.2
A
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Prototype Samples
Mass Production
Special
PC
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Rev 1.3
Rev 1.6
Part # series
i.MX 6Quad
i.MX 6Dual
X
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Fusing
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A
Default setting
HDCP enabled
C
Part differentiator
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Frequency
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Industrial with VPU, GPU, no MLB
Automotive with VPU, GPU
Consumer with VPU, GPU
800 MHz2 (Industrial grade)
852 MHz (Automotive grade)
1 GHz3
08
08
10
12
6
5
Automotive with GPU, no VPU
4
1.2 GHz
Temperature Tj
RoHS
Package type
+
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C
A
Extended commercial: -20 to +105°C
Industrial: -40 to +105°C
FCPBGA 21x21 0.8mm (lidded)
VT
FCPBGA 21x21 0.8mm (non lidded)
YM
Automotive: -40 to +125°C
1. See the nxp.com\imx6series Web page for latest information on the available silicon revision.
2. If a 24 MHz input clock is used (required for USB), the maximum SoC speed is limited to 792 MHz.
3. If a 24 MHz input clock is used (required for USB), the maximum SoC speed is limited to 996 MHz.
Figure 1. Part Number Nomenclature—i.MX 6Quad and i.MX 6Dual
1.2
Features
The i.MX 6Dual/6Quad processors are based on Arm Cortex-A9 MPCore platform, which has the
following features:
®
•
•
Arm Cortex-A9 MPCore 4xCPU processor (with TrustZone )
The core configuration is symmetric, where each core includes:
— 32 KByte L1 Instruction Cache
— 32 KByte L1 Data Cache
— Private Timer and Watchdog
— Cortex-A9 NEON MPE (Media Processing Engine) Co-processor
The Arm Cortex-A9 MPCore complex includes:
•
•
•
•
•
General Interrupt Controller (GIC) with 128 interrupt support
Global Timer
Snoop Control Unit (SCU)
1 MB unified I/D L2 cache, shared by two/four cores
Two Master AXI (64-bit) bus interfaces output of L2 cache
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
4
NXP Semiconductors
Introduction
•
•
Frequency of the core (including Neon and L1 cache) as per Table 6.
NEON MPE coprocessor
— SIMD Media Processing Architecture
— NEON register file with 32x64-bit general-purpose registers
— NEON Integer execute pipeline (ALU, Shift, MAC)
— NEON dual, single-precision floating point execute pipeline (FADD, FMUL)
— NEON load/store and permute pipeline
The SoC-level memory system consists of the following additional components:
•
•
•
•
Boot ROM, including HAB (96 KB)
Internal multimedia / shared, fast access RAM (OCRAM, 256 KB)
Secure/non-secure RAM (16 KB)
External memory interfaces:
— 16-bit, 32-bit, and 64-bit DDR3-1066, DDR3L-1066, and 1/2 LPDDR2-800 channels,
supporting DDR interleaving mode, for dual x32 LPDDR2
— 8-bit NAND-Flash, including support for Raw MLC/SLC, 2 KB, 4 KB, and 8 KB page size,
BA-NAND, PBA-NAND, LBA-NAND, OneNAND™ and others. BCH ECC up to 40 bit.
— 16/32-bit NOR Flash. All EIMv2 pins are muxed on other interfaces.
— 16/32-bit PSRAM, Cellular RAM
Each i.MX 6Dual/6Quad processor enables the following interfaces to external devices (some of them are
muxed and not available simultaneously):
•
•
Hard Disk Drives—SATA II, 3.0 Gbps
Displays—Total five interfaces available. Total raw pixel rate of all interfaces is up to 450
Mpixels/sec, 24 bpp. Up to four interfaces may be active in parallel.
— One Parallel 24-bit display port, up to 225 Mpixels/sec (for example, WUXGA at 60 Hz or dual
HD1080 and WXGA at 60 Hz)
— LVDS serial ports—One port up to 170 Mpixels/sec (for example, WUXGA at 60 Hz) or two
ports up to 85 MP/sec each
— HDMI 1.4 port
— MIPI/DSI, two lanes at 1 Gbps
Camera sensors:
•
•
— Parallel Camera port (up to 20 bit and up to 240 MHz peak)
— MIPI CSI-2 serial camera port, supporting up to 1000 Mbps/lane in 1/2/3-lane mode and up to
800 Mbps/lane in 4-lane mode. The CSI-2 Receiver core can manage one clock lane and up to
four data lanes. Each i.MX 6Dual/6Quad processor has four lanes.
Expansion cards:
— Four MMC/SD/SDIO card ports all supporting:
– 1-bit or 4-bit transfer mode specifications for SD and SDIO cards up to UHS-I SDR-104
mode (104 MB/s max)
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
5
Introduction
– 1-bit, 4-bit, or 8-bit transfer mode specifications for MMC cards up to 52 MHz in both SDR
and DDR modes (104 MB/s max)
•
USB:
— One High Speed (HS) USB 2.0 OTG (Up to 480 Mbps), with integrated HS USB PHY
— Three USB 2.0 (480 Mbps) hosts:
– One HS host with integrated High Speed PHY
– Two HS hosts with integrated High Speed Inter-Chip (HS-IC) USB PHY
Expansion PCI Express port (PCIe) v2.0 one lane
•
•
— PCI Express (Gen 2.0) dual mode complex, supporting Root complex operations and Endpoint
operations. Uses x1 PHY configuration.
Miscellaneous IPs and interfaces:
— SSI block capable of supporting audio sample frequencies up to 192 kHz stereo inputs and
2
outputs with I S mode
— ESAI is capable of supporting audio sample frequencies up to 260 kHz in I2S mode with
7.1 multi channel outputs
— Five UARTs, up to 5.0 Mbps each:
– Providing RS232 interface
– Supporting 9-bit RS485 multidrop mode
– One of the five UARTs (UART1) supports 8-wire while the other four support 4-wire. This
is due to the SoC IOMUX limitation, because all UART IPs are identical.
— Five eCSPI (Enhanced CSPI)
— Three I2C, supporting 400 kbps
1
— Gigabit Ethernet Controller (IEEE1588 compliant), 10/100/1000 Mbps
— Four Pulse Width Modulators (PWM)
— System JTAG Controller (SJC)
— GPIO with interrupt capabilities
— 8x8 Key Pad Port (KPP)
— Sony Philips Digital Interconnect Format (SPDIF), Rx and Tx
— Two Controller Area Network (FlexCAN), 1 Mbps each
— Two Watchdog timers (WDOG)
— Audio MUX (AUDMUX)
The i.MX 6Dual/6Quad processors integrate advanced power management unit and controllers:
•
•
•
•
Provide PMU, including LDO supplies, for on-chip resources
Use Temperature Sensor for monitoring the die temperature
Support DVFS techniques for low power modes
Use Software State Retention and Power Gating for Arm and MPE
1. The theoretical maximum performance of 1 Gbps ENET is limited to 470 Mbps (total for Tx and Rx) due to internal bus
throughput limitations. The actual measured performance in optimized environment is up to 400 Mbps. For details, see the
ERR004512 erratum in the i.MX 6Dual/6Quad errata document (IMX6DQCE).
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
6
NXP Semiconductors
Introduction
•
•
Support various levels of system power modes
Use flexible clock gating control scheme
The i.MX 6Dual/6Quad processors use dedicated hardware accelerators to meet the targeted multimedia
performance. The use of hardware accelerators is a key factor in obtaining high performance at low power
consumption numbers, while having the CPU core relatively free for performing other tasks.
The i.MX 6Dual/6Quad processors incorporate the following hardware accelerators:
•
•
•
•
•
•
VPU—Video Processing Unit
IPUv3H—Image Processing Unit version 3H (2 IPUs)
GPU3Dv4—3D Graphics Processing Unit (OpenGL ES 2.0) version 4
GPU2Dv2—2D Graphics Processing Unit (BitBlt) version 2
GPUVG—OpenVG 1.1 Graphics Processing Unit
ASRC—Asynchronous Sample Rate Converter
Security functions are enabled and accelerated by the following hardware:
•
•
Arm TrustZone including the TZ architecture (separation of interrupts, memory mapping, etc.)
SJC—SystemJTAGController. ProtectingJTAGfromdebugportattacks by regulating or blocking
the access to the system debug features.
•
CAAM—Cryptographic Acceleration and Assurance Module, containing 16 KB secure RAM and
True and Pseudo Random Number Generator (NIST certified)
•
•
SNVS—Secure Non-Volatile Storage, including Secure Real Time Clock
CSU—Central Security Unit. Enhancement for the IC Identification Module (IIM). Will be
configured during boot and by eFUSEs and will determine the security level operation mode as
well as the TZ policy.
•
A-HAB—Advanced High Assurance Boot—HABv4 with the new embedded enhancements:
SHA-256, 2048-bit RSA key, version control mechanism, warm boot, CSU, and TZ initialization.
1.3
Signal Naming Convention
Throughout this document, the updated signal names are used except where referenced as a ball name
(such as the Functional Contact Assignments table, Ball Map table, and so on). A master list of the signal
name changes is in the document, IMX 6 Series Standardized Signal Name Map (EB792). This list can be
used to map the signal names used in older documentation to the new standardized naming conventions.
The signal names of the i.MX6 series of products are standardized to align the signal names within the
family and across the documentation. Benefits of this standardization are as follows:
•
•
•
•
Signal names are unique within the scope of an SoC and within the series of products
Searches will return all occurrences of the named signal
Signal names are consistent between i.MX 6 series products implementing the same modules
The module instance is incorporated into the signal name
This standardization applies only to signal names. The ball names are preserved to prevent the need to
change schematics, BSDL models, IBIS models, and so on.
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
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7
Architectural Overview
2 Architectural Overview
The following subsections provide an architectural overview of the i.MX 6Dual/6Quad processor system.
2.1
Block Diagram
Figure 2 shows the functional modules in the i.MX 6Dual/6Quad processor system.
MIPI
Raw/ONFI 2.2 LPDDR2 (400MHz) NOR Flash Battery Ctrl 4x Camera 1 / 2 LVDS 1 / 2 LCD HDMI 1.4
Display
Nand-Flash
DDR3 (532MHz)
PSRAM
Device
Parallel/MIPI (WUXGA+) Displays
Display
Application Processor
Domain (AP)
CSI2/MIPI LDB
HDMI
DSI/MIPI
External
Memory
Interface
Digital
Audio
GPMI
MMDC
EIM
Internal
RAM
(272KB)
Clock and Reset
PLL (8)
Crystals
& Clock sources
Image Processing
Subsystem
2x IPUv3H
CCM
Boot
ROM
GPC
SRC
(96KB)
SATA II
3.0Gbps
ARM Cortex A9
MPCore Platform
Smart DMA
(SDMA)
XTALOSC
OSC32K
Debug
DAP
4x
A9-Core
L1 I/D Cache
Timer, Wdog
TPIU
CTIs
SJC
SPBA
MMC/SD
eMMC/eSD
2xCAN
Interface
AP Peripherals
1MB L2 cache
SCU, Timer
PTM’s CTI’s
uSDHC (4)
MMC/SD
SDXC
Shared Peripherals
AUDMUX
2
Security
I C(3)
Video
eCSPI (5)
ESAI
SSI (3)
CAAM
(16KB Ram)
Proc. Unit
PWM (4)
OCOTP
IOMUXC
KPP
5xFast-UART
SPDIF Rx/Tx
Modem IC
PCIe Bus
GPS
(VPU + Cache)
SNVS
(SRTC)
ASRC
3D Graphics
Proc. Unit
(GPU3D)
CSU
Fuse Box
2D Graphics
Proc. Unit
(GPU2D)
Keypad
GPIO
CAN(2)
Industrial
Standard
Block Diagram
Timers/Control
WDOG (2)
GPT
OpenVG 1.1
Proc. Unit
(GPUVG)
1-Gbps ENET
HSI/MIPI
Ethernet
10/100/1000
Mbps
EPIT (2)
Audio,
Power
USB OTG +
3 HS Ports
Temp Monitor
Mngmnt
.
OTG PHY1
Host PHY2
2xHSIC
PHY
USB OTG
(dev/host)
JTAG
(IEEE1149.6)
Bluetooth
WLAN
Figure 2. i.MX 6Dual/6Quad Industrial Grade System Block Diagram
NOTE
The numbers in brackets indicate number of module instances. For example,
PWM (4) indicates four separate PWM peripherals.
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
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Modules List
3 Modules List
The i.MX 6Dual/6Quad processors contain a variety of digital and analog modules. Table 2 describes these
modules in alphabetical order.
Table 2. i.MX 6Dual/6Quad Modules List
Block
Mnemonic
Block Name
Subsystem
Brief Description
512 x 8 Fuse Electrical Fuse Array Security
Box
Electrical Fuse Array. Enables to setup Boot Modes, Security Levels,
Security Keys, and many other system parameters.
The i.MX 6Dual/6Quad processors consist of 512x8-bit fuse box
accessible through OCOTP_CTRL interface.
APBH-DMA NAND Flash and
BCH ECC DMA
System
Control
DMA controller used for GPMI2 operation.
Controller
Peripherals
Arm
Arm Platform
Arm
The Arm Cortex-A9 platform consists of 4x (four) Cortex-A9 cores version
r2p10 and associated sub-blocks, including Level 2 Cache Controller,
SCU (Snoop Control Unit), GIC (General Interrupt Controller), private
timers, Watchdog, and CoreSight debug modules.
ASRC
Asynchronous
Sample Rate
Converter
Multimedia
Peripherals
The Asynchronous Sample Rate Converter (ASRC) converts the
sampling rate of a signal associated to an input clock into a signal
associated to a different output clock. The ASRC supports concurrent
sample rate conversion of up to 10 channels of about -120dB THD+N. The
sample rate conversion of each channel is associated to a pair of
incoming and outgoing sampling rates. The ASRC supports up to three
sampling rate pairs.
AUDMUX
Digital Audio Mux
Multimedia
Peripherals
The AUDMUX is a programmable interconnect for voice, audio, and
synchronous data routing between host serial interfaces (for example,
SSI1, SSI2, and SSI3) and peripheral serial interfaces (audio and voice
codecs). The AUDMUX has seven ports with identical functionality and
programming models. A desired connectivity is achieved by configuring
two or more AUDMUX ports.
BCH40
CAAM
Binary-BCH ECC
Processor
System
Control
Peripherals
The BCH40 module provides up to 40-bit ECC error correction for NAND
Flash controller (GPMI).
Cryptographic
Accelerator and
Assurance Module
Security
CAAM is a cryptographic accelerator and assurance module. CAAM
implements several encryption and hashing functions, a run-time integrity
checker, and a Pseudo Random Number Generator (PRNG). The pseudo
random number generator is certified by Cryptographic Algorithm
Validation Program (CAVP) of National Institute of Standards and
Technology (NIST). Its DRBG validation number is 94 and its SHS
validation number is 1455.
CAAM also implements a Secure Memory mechanism. In i.MX
6Dual/6Quad processors, the security memory provided is 16 KB.
CCM
GPC
SRC
Clock Control
Module, General
Power Controller,
System Reset
Controller
Clocks,
These modules are responsible for clock and reset distribution in the
Resets, and system, and also for the system power management.
Power Control
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
9
Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block
Mnemonic
Block Name
Subsystem
Brief Description
CSI
MIPI CSI-2 Interface Multimedia
Peripherals
The CSI IP provides MIPI CSI-2 standard camera interface port. The
CSI-2 interface supports up to 1 Gbps for up to 3 data lanes and up to 800
Mbps for 4 data lanes.
CSU
Central Security Unit Security
The Central Security Unit (CSU) is responsible for setting comprehensive
security policy within the i.MX 6Dual/6Quad platform. The Security
Control Registers (SCR) of the CSU are set during boot time by the HAB
and are locked to prevent further writing.
CTI-0
CTI-1
CTI-2
CTI-3
CTI-4
Cross Trigger
Interfaces
Debug / Trace Cross Trigger Interfaces allows cross-triggering based on inputs from
masters attached to CTIs. The CTI module is internal to the Cortex-A9
Core Platform.
CTM
Cross Trigger Matrix Debug / Trace Cross Trigger Matrix IP is used to route triggering events between CTIs.
The CTM module is internal to the Cortex-A9 Core Platform.
DAP
Debug Access Port System
Control
The DAP provides real-time access for the debugger without halting the
core to:
Peripherals
• System memory and peripheral registers
• All debug configuration registers
The DAP also provides debugger access to JTAG scan chains. The DAP
module is internal to the Cortex-A9 Core Platform.
DCIC-0
DCIC-1
Display Content
Integrity Checker
Automotive IP The DCIC provides integrity check on portion(s) of the display. Each i.MX
6Dual/6Quad processor has two such modules, one for each IPU.
DSI
MIPI DSI interface
Multimedia
Peripherals
The MIPI DSI IP provides DSI standard display port interface. The DSI
interface support 80 Mbps to 1 Gbps speed per data lane.
eCSPI1-5
Configurable SPI
Connectivity Full-duplex enhanced Synchronous Serial Interface. It is configurable to
Peripherals
support Master/Slave modes, four chip selects to support multiple
peripherals.
ENET
Ethernet Controller Connectivity The Ethernet Media Access Controller (MAC) is designed to support
Peripherals
10/100/1000 Mbps Ethernet/IEEE 802.3 networks. An external
transceiver interface and transceiver function are required to complete the
interface to the media. The i.MX 6Dual/6Quad processors also consist of
hardware assist for IEEE 1588 standard. For details, see the ENET
chapter of the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
Note: The theoretical maximum performance of 1 Gbps ENET is limited
to 470 Mbps (total for Tx and Rx) due to internal bus throughput
limitations. The actual measured performance in optimized environment
is up to 400 Mbps. For details, see the ERR004512 erratum in the i.MX
6Dual/6Quad errata document (IMX6DQCE).
EPIT-1
EPIT-2
Enhanced Periodic Timer
Interrupt Timer Peripherals
Each EPIT is a 32-bit “set and forget” timer that starts counting after the
EPIT is enabled by software. It is capable of providing precise interrupts
at regular intervals with minimal processor intervention. It has a 12-bit
prescaler for division of input clock frequency to get the required time
setting for the interrupts to occur, and counter value can be programmed
on the fly.
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block Name Subsystem Brief Description
Connectivity The Enhanced Serial Audio Interface (ESAI) provides a full-duplex serial
Block
Mnemonic
ESAI
Enhanced Serial
Audio Interface
Peripherals
port for serial communication with a variety of serial devices, including
industry-standard codecs, SPDIF transceivers, and other processors.
The ESAI consists of independent transmitter and receiver sections, each
section with its own clock generator. All serial transfers are synchronized
to a clock. Additional synchronization signals are used to delineate the
word frames. The normal mode of operation is used to transfer data at a
periodic rate, one word per period. The network mode is also intended for
periodic transfers; however, it supports up to 32 words (time slots) per
period. This mode can be used to build time division multiplexed (TDM)
networks. In contrast, the on-demand mode is intended for non-periodic
transfers of data and to transfer data serially at high speed when the data
becomes available.
The ESAI has 12 pins for data and clocking connection to external
devices.
FlexCAN-1 Flexible Controller
FlexCAN-2 Area Network
Connectivity The CAN protocol was primarily, but not only, designed to be used as a
Peripherals
vehicle serial data bus, meeting the specific requirements of this field:
real-time processing, reliable operation in the Electromagnetic
interference (EMI) environment of a vehicle, cost-effectiveness and
required bandwidth. The FlexCAN module is a full implementation of the
CAN protocol specification, Version 2.0 B, which supports both standard
and extended message frames.
GPIO-1
GPIO-2
GPIO-3
GPIO-4
GPIO-5
GPIO-6
GPIO-7
General Purpose I/O System
Used for general purpose input/output to external devices. Each GPIO
module supports 32 bits of I/O.
Modules
Control
Peripherals
GPMI
General Purpose
Media Interface
Connectivity The GPMI module supports up to 8x NAND devices. 40-bit ECC error
Peripherals
correction for NAND Flash controller (GPMI2). The GPMI supports
separate DMA channels per NAND device.
GPT
General Purpose
Timer
Timer
Peripherals
Each GPT is a 32-bit “free-running” or “set and forget” mode timer with
programmable prescaler and compare and capture register. A timer
counter value can be captured using an external event and can be
configured to trigger a capture event on either the leading or trailing edges
of an input pulse. When the timer is configured to operate in “set and
forget” mode, it is capable of providing precise interrupts at regular
intervals with minimal processor intervention. The counter has output
compare logic to provide the status and interrupt at comparison. This
timer can be configured to run either on an external clock or on an internal
clock.
GPU2Dv2
GPU3Dv4
Graphics Processing Multimedia
Unit-2D, ver. 2 Peripherals
The GPU2Dv2 provides hardware acceleration for 2D graphics
algorithms, such as Bit BLT, stretch BLT, and many other 2D functions.
Graphics Processing Multimedia
Unit-3D, ver. 4 Peripherals
The GPU2Dv4 provides hardware acceleration for 3D graphics algorithms
with sufficient processor power to run desktop quality interactive graphics
applications on displays up to HD1080 resolution. The GPU3D provides
OpenGL ES 2.0, including extensions, OpenGL ES 1.1, and OpenVG 1.1
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block
Mnemonic
Block Name
Subsystem
Brief Description
GPUVGv2
Vector Graphics
Processing Unit,
ver. 2
Multimedia
Peripherals
OpenVG graphics accelerator provides OpenVG 1.1 support as well as
other accelerations, including Real-time hardware curve tesselation of
lines, quadratic and cubic Bezier curves, 16x Line Anti-aliasing, and
various Vector Drawing functions.
HDMI Tx
HSI
HDMI Tx interface
MIPI HSI interface
I2C Interface
Multimedia
Peripherals
The HDMI module provides HDMI standard interface port to an HDMI 1.4
compliant display.
Connectivity The MIPI HSI provides a standard MIPI interface to the applications
Peripherals processor.
I2C-1
I2C-2
I2C-3
Connectivity I2C provide serial interface for external devices. Data rates of up to 400
Peripherals
kbps are supported.
IOMUXC
IOMUX Control
System
Control
Peripherals
This module enables flexible IO multiplexing. Each IO pad has default and
several alternate functions. The alternate functions are software
configurable.
IPUv3H-1
IPUv3H-2
Image Processing
Unit, ver. 3H
Multimedia
Peripherals
IPUv3H enables connectivity to displays and video sources, relevant
processing and synchronization and control capabilities, allowing
autonomous operation.
The IPUv3H supports concurrent output to two display ports and
concurrent input from two camera ports, through the following interfaces:
• Parallel Interfaces for both display and camera
• Single/dual channel LVDS display interface
• HDMI transmitter
• MIPI/DSI transmitter
• MIPI/CSI-2 receiver
The processing includes:
• Image conversions: resizing, rotation, inversion, and color space
conversion
• A high-quality de-interlacing filter
• Video/graphics combining
• Image enhancement: color adjustment and gamut mapping, gamma
correction, and contrast enhancement
• Support for display backlight reduction
KPP
LDB
Key Pad Port
Connectivity KPP Supports 8 x 8 external key pad matrix. KPP features are:
Peripherals
• Open drain design
• Glitch suppression circuit design
• Multiple keys detection
• Standby key press detection
LVDS Display Bridge Connectivity LVDS Display Bridge is used to connect the IPU (Image Processing Unit)
Peripherals
to External LVDS Display Interface. LDB supports two channels; each
channel has following signals:
• One clock pair
• Four data pairs
Each signal pair contains LVDS special differential pad (PadP, PadM).
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block
Mnemonic
Block Name
Subsystem
Brief Description
MMDC
Multi-Mode DDR
Controller
Connectivity DDR Controller has the following features:
Peripherals
• Supports 16/32/64-bit DDR3 / DDR3L or LPDDR2
• Supports both dual x32 for LPDDR2 and x64 DDR3 / LPDDR2
configurations (including 2x32 interleaved mode)
• Supports up to 4 GByte DDR memory space
OCOTP_CTRL OTP Controller
Security
The On-Chip OTP controller (OCOTP_CTRL) provides an interface for
reading, programming, and/or overriding identification and control
information stored in on-chip fuse elements. The module supports
electrically-programmable poly fuses (eFUSEs). The OCOTP_CTRL also
provides a set of volatile software-accessible signals that can be used for
software control of hardware elements, not requiring non-volatility. The
OCOTP_CTRL provides the primary user-visible mechanism for
interfacing with on-chip fuse elements. Among the uses for the fuses are
unique chip identifiers, mask revision numbers, cryptographic keys, JTAG
secure mode, boot characteristics, and various control signals, requiring
permanent non-volatility.
OCRAM
On-Chip Memory
Controller
Data Path
Clocking
The On-Chip Memory controller (OCRAM) module is designed as an
interface between system’s AXI bus and internal (on-chip) SRAM memory
module.
In i.MX 6Dual/6Quad processors, the OCRAM is used for controlling the
256 KB multimedia RAM through a 64-bit AXI bus.
OSC 32 kHz OSC 32 kHz
Generates 32.768 kHz clock from an external crystal.
PCIe
PCI Express 2.0
Connectivity The PCIe IP provides PCI Express Gen 2.0 functionality.
Peripherals
PMU
Power-Management Data Path
Functions
Integrated power management unit. Used to provide power to various
SoC domains.
PWM-1
PWM-2
PWM-3
PWM-4
Pulse Width
Modulation
Connectivity The pulse-width modulator (PWM) has a 16-bit counter and is optimized
Peripherals
to generate sound from stored sample audio images and it can also
generate tones. It uses 16-bit resolution and a 4x16 data FIFO to generate
sound.
RAM
Secure/non-secure Secured
Secure/non-secure Internal RAM, interfaced through the CAAM.
16 KB
RAM
Internal
Memory
RAM
256 KB
Internal RAM
Boot ROM
Internal
Memory
Internal RAM, which is accessed through OCRAM memory controllers.
ROM
96 KB
Internal
Memory
Supports secure and regular Boot Modes. Includes read protection on 4K
region for content protection
ROMCP
ROM Controller with Data Path
Patch
ROM Controller with ROM Patch support
SATA
Serial ATA
Connectivity The SATA controller and PHY is a complete mixed-signal IP solution
Peripherals designed to implement SATA II, 3.0 Gbps HDD connectivity.
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block Name Subsystem Brief Description
Smart Direct Memory System
Block
Mnemonic
SDMA
The SDMA is multi-channel flexible DMA engine. It helps in maximizing
system performance by off-loading the various cores in dynamic data
routing. It has the following features:
Access
Control
Peripherals
• Powered by a 16-bit Instruction-Set micro-RISC engine
• Multi-channel DMA supporting up to 32 time-division multiplexed DMA
channels
• 48 events with total flexibility to trigger any combination of channels
• Memory accesses including linear, FIFO, and 2D addressing
• Shared peripherals between Arm and SDMA
• Very fast context-switching with 2-level priority based preemptive
multi-tasking
• DMA units with auto-flush and prefetch capability
• Flexible address management for DMA transfers (increment,
decrement, and no address changes on source and destination
address)
• DMA ports can handle unit-directional and bi-directional flows (copy
mode)
• Up to 8-word buffer for configurable burst transfers
• Support of byte-swapping and CRC calculations
• Library of Scripts and API is available
SJC
System JTAG
Controller
System
Control
Peripherals
The SJC provides JTAG interface, which complies with JTAG TAP
standards, to internal logic. The i.MX 6Dual/6Quad processors use JTAG
port for production, testing, and system debugging. In addition, the SJC
provides BSR (Boundary Scan Register) standard support, which
complies with IEEE1149.1 and IEEE1149.6 standards.
The JTAG port must be accessible during platform initial laboratory
bring-up, for manufacturing tests and troubleshooting, as well as for
software debugging by authorized entities. The i.MX 6Dual/6Quad SJC
incorporates three security modes for protecting against unauthorized
accesses. Modes are selected through eFUSE configuration.
SNVS
SPDIF
Secure Non-Volatile Security
Storage
Secure Non-Volatile Storage, including Secure Real Time Clock, Security
State Machine, Master Key Control, and Violation/Tamper Detection and
reporting.
Sony Philips Digital Multimedia
Interconnect Format Peripherals
A standard audio file transfer format, developed jointly by the Sony and
Phillips corporations. It supports Transmitter and Receiver functionality.
SSI-1
SSI-2
SSI-3
I2S/SSI/AC97
Interface
Connectivity The SSI is a full-duplex synchronous interface, which is used on the
Peripherals
processor to provide connectivity with off-chip audio peripherals. The SSI
supports a wide variety of protocols (SSI normal, SSI network, I2S, and
AC-97), bit depths (up to 24 bits per word), and clock / frame sync options.
The SSI has two pairs of 8x24 FIFOs and hardware support for an
external DMA controller to minimize its impact on system performance.
The second pair of FIFOs provides hardware interleaving of a second
audio stream that reduces CPU overhead in use cases where two time
slots are being used simultaneously.
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block Name Subsystem Brief Description
Block
Mnemonic
TEMPMON Temperature Monitor System
Control
The temperature monitor/sensor IP module for detecting high temperature
conditions. The temperature read out does not reflect case or ambient
temperature. It reflects the temperature in proximity of the sensor location
on the die. Temperature distribution may not be uniformly distributed;
therefore, the read out value may not be the reflection of the temperature
value for the entire die.
Peripherals
TZASC
Trust-Zone Address Security
Space Controller
The TZASC (TZC-380 by Arm) provides security address region control
functions required for intended application. It is used on the path to the
DRAM controller.
UART-1
UART-2
UART-3
UART-4
UART-5
UART Interface
Connectivity Each of the UARTv2 modules support the following serial data
Peripherals
transmit/receive protocols and configurations:
• 7- or 8-bit data words, 1 or 2 stop bits, programmable parity (even, odd
or none)
• Programmable baud rates up to 5 MHz
• 32-byte FIFO on Tx and 32 half-word FIFO on Rx supporting auto-baud
• IrDA 1.0 support (up to SIR speed of 115200 bps)
• Option to operate as 8-pins full UART, DCE, or DTE
USBOH3A USB 2.0 High Speed Connectivity USBOH3 contains:
OTG and 3x HS
Hosts
Peripherals
• One high-speed OTG module with integrated HS USB PHY
• One high-speed Host module with integrated HS USB PHY
• Two identical high-speed Host modules connected to HSIC USB ports.
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block
Mnemonic
Block Name
Subsystem
Brief Description
uSDHC-1
uSDHC-2
uSDHC-2
uSDHC-4
SD/MMC and SDXC Connectivity i.MX 6Dual/6Quad specific SoC characteristics:
Enhanced
Peripherals
All four MMC/SD/SDIO controller IPs are identical and are based on the
uSDHC IP. They are:
Multi-Media Card /
Secure Digital Host
Controller
• Conforms to the SD Host Controller Standard Specification version 3.0
• Fully compliant with MMC command/response sets and Physical Layer
as defined in the Multimedia Card System Specification,
v4.2/4.3/4.4/4.41 including high-capacity (size > 2 GB) cards HC MMC.
Hardware reset as specified for eMMC cards is supported at ports #3
and #4 only.
• Fully compliant with SD command/response sets and Physical Layer
as defined in the SD Memory Card Specifications, v3.0 including
high-capacity SDHC cards up to 32 GB and SDXC cards up to 2TB.
• Fully compliant with SDIO command/response sets and
interrupt/read-wait mode as defined in the SDIO Card Specification,
Part E1, v1.10
• Fully compliant with SD Card Specification, Part A2, SD Host
Controller Standard Specification, v2.00
All four ports support:
• 1-bit or 4-bit transfer mode specifications for SD and SDIO cards up to
UHS-I SDR104 mode (104 MB/s max)
• 1-bit, 4-bit, or 8-bit transfer mode specifications for MMC cards up to 52
MHz in both SDR and DDR modes (104 MB/s max)
However, the SoC-level integration and I/O muxing logic restrict the
functionality to the following:
• Instances #1 and #2 are primarily intended to serve as external slots or
interfaces to on-board SDIO devices. These ports are equipped with
“Card Detection” and “Write Protection” pads and do not support
hardware reset.
• Instances #3 and #4 are primarily intended to serve interfaces to
embedded MMC memory or interfaces to on-board SDIO devices.
These ports do not have “Card detection” and “Write Protection” pads
and do support hardware reset.
• All ports can work with 1.8 V and 3.3 V cards. There are two completely
independent I/O power domains for Ports #1 and #2 in four bit
configuration (SD interface). Port #3 is placed in his own independent
power domain and port #4 shares power domain with some other
interfaces.
VDOA
VPU
VDOA
Multimedia
Peripherals
The Video Data Order Adapter (VDOA) is used to re-order video data from
the “tiled” order used by the VPU to the conventional raster-scan order
needed by the IPU.
Video Processing
Unit
Multimedia
Peripherals
A high-performing video processing unit (VPU), which covers many
SD-level and HD-level video decoders and SD-level encoders as a
multi-standard video codec engine as well as several important video
processing, such as rotation and mirroring.
See the i.MX 6Dual/6Quad reference manual (IMX6DQRM) for complete
list of VPU’s decoding/encoding capabilities.
WDOG-1
Watchdog
Timer
Peripherals
The Watchdog Timer supports two comparison points during each
counting period. Each of the comparison points is configurable to evoke
an interrupt to the Arm core, and a second point evokes an external event
on the WDOG line.
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Modules List
Table 2. i.MX 6Dual/6Quad Modules List (continued)
Block
Mnemonic
Block Name
Subsystem
Brief Description
The TrustZone Watchdog (TZ WDOG) timer module protects against
WDOG-2
(TZ)
Watchdog
(TrustZone)
Timer
Peripherals
TrustZone starvation by providing a method of escaping normal mode and
forcing a switch to the TZ mode. TZ starvation is a situation where the
normal OS prevents switching to the TZ mode. Such a situation is
undesirable as it can compromise the system’s security. Once the TZ
WDOG module is activated, it must be serviced by TZ software on a
periodic basis. If servicing does not take place, the timer times out. Upon
a time-out, the TZ WDOG asserts a TZ mapped interrupt that forces
switching to the TZ mode. If it is still not served, the TZ WDOG asserts a
security violation signal to the CSU. The TZ WDOG module cannot be
programmed or deactivated by a normal mode Software.
EIM
NOR-Flash /PSRAM Connectivity The EIM NOR-FLASH / PSRAM provides:
interface
Peripherals
• Support 16-bit (in muxed IO mode only) PSRAM memories (sync and
async operating modes), at slow frequency
• Support 16-bit (in muxed IO mode only) NOR-Flash memories, at slow
frequency
• Multiple chip selects
XTALOSC
Crystal Oscillator
interface
—
The XTALOSC module enables connectivity to external crystal oscillator
device. In a typical application use-case, it is used for 24 MHz oscillator.
3.1
Special Signal Considerations
The package contact assignments can be found in Section 6, “Package Information and Contact
Assignments.” Signal descriptions are defined in the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
Special signal consideration information is contained in the Hardware Development Guide for i.MX
6Quad, 6Dual, 6DualLite, 6Solo Families of Applications Processors (IMX6DQ6SDLHDG).
3.2
Recommended Connections for Unused Analog Interfaces
The recommended connections for unused analog interfaces can be found in the section, “Unused analog
interfaces,” of the Hardware Development Guide for i.MX 6Quad, 6Dual, 6DualLite, 6Solo Families of
Applications Processors (IMX6DQ6SDLHDG).
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Electrical Characteristics
4 Electrical Characteristics
This section provides the device and module-level electrical characteristics for the i.MX 6Dual/6Quad
processors.
4.1
Chip-Level Conditions
This section provides the device-level electrical characteristics for the SoC. See Table 3 for a quick
reference to the individual tables and sections.
Table 3. i.MX 6Dual/6Quad Chip-Level Conditions
For these characteristics, …
Absolute Maximum Ratings
Topic appears …
on page 19
on page 20
on page 21
on page 23
on page 25
on page 26
on page 28
on page 28
on page 29
on page 30
FCPBGA Package Thermal Resistance
Operating Ranges
External Clock Sources
Maximum Measured Supply Currents
Low Power Mode Supply Currents
USB PHY Current Consumption
SATA Typical Power Consumption
PCIe 2.0 Maximum Power Consumption
HDMI Maximum Power Consumption
4.1.1
Absolute Maximum Ratings
CAUTION
Stresses beyond those listed under Table 4 may affect reliability or cause
permanent damage to the device. These are stress ratings only. Functional
operation of the device at these or any other conditions beyond those
indicated in the Operating Ranges or Parameters tables is not implied.
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Electrical Characteristics
Table 4. Absolute Maximum Ratings
Symbol
Parameter Description
Min
Max
Unit
Core supply input voltage (LDO enabled)
VDD_ARM_IN
VDD_ARM23_IN
VDD_SOC_IN
-0.3
1.6
V
Core supply input voltage (LDO bypass)
Core supply output voltage (LDO enabled)
VDD_ARM_IN
VDD_ARM23_IN
VDD_SOC_IN
-0.3
-0.3
1.4
1.4
V
V
VDD_ARM_CAP
VDD_SOC_CAP
VDD_PU_CAP
NVCC_PLL_OUT
VDD_HIGH_IN supply voltage
DDR I/O supply voltage
VDD_HIGH_IN
NVCC_DRAM
-0.3
-0.4
3.7
V
V
1.975 (See note 1)
GPIO I/O supply voltage
NVCC_CSI
NVCC_EIM
NVCC_ENET
NVCC_GPIO
NVCC_LCD
NVCC_NAND
NVCC_SD
-0.5
3.7
V
NVCC_JTAG
HDMI, PCIe, and SATA PHY high (VPH) supply voltage
HDMI, PCIe, and SATA PHY low (VP) supply voltage
LVDS and MIPI I/O supply voltage (2.5V supply)
HDMI_VPH
PCIE_VPH
SATA_VPH
-0.3
2.85
V
HDMI_VP
PCIE_VP
SATA_VP
-0.3
-0.3
1.4
V
V
NVCC_LVDS_2P5
NVCC_MIPI
2.85
PCIe PHY supply voltage
RGMII I/O supply voltage
PCIE_VPTX
NVCC_RGMII
VDD_SNVS_IN
-0.3
-0.5
-0.3
1.4
2.725
3.4
V
V
V
SNVS IN supply voltage
(Secure Non-Volatile Storage and Real Time Clock)
USB I/O supply voltage
USB_H1_DN
USB_H1_DP
USB_OTG_DN
USB_OTG_DP
USB_OTG_CHD_B
-0.3
—
3.73
5.35
V
V
USB VBUS supply voltage
USB_H1_VBUS
USB_OTG_VBUS
Vin/Vout input/output voltage range (non-DDR pins)
Vin/Vout input/output voltage range (DDR pins)
ESD immunity (HBM)
Vin/Vout
Vin/Vout
-0.5
-0.5
—
OVDD+0.3 (See note 2)
OVDD+0.4 (See notes1&2)
V
V
Vesd_HBM
Vesd_CDM
Tstorage
2000
500
V
ESD immunity (CDM)
—
V
Storage temperature range
-40
150
°C
1
The absolute maximum voltage includes an allowance for 400 mV of overshoot on the IO pins. Per JEDEC standards, the
allowed signal overshoot must be derated if NVCC_DRAM exceeds 1.575V.
2
OVDD is the I/O supply voltage.
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Electrical Characteristics
4.1.2
Thermal Resistance
NOTE
Per JEDEC JESD51-2, the intent of thermal resistance measurements is
solely for a thermal performance comparison of one package to another in a
standardized environment. This methodology is not meant to and will not
predict the performance of a package in an application-specific
environment.
4.1.2.1
FCPBGA Package Thermal Resistance
Table 5 provides the FCPBGA package thermal resistance data.
Table 5. FCPBGA Package Thermal Resistance Data
Value
No Lid
Thermal Parameter
Test Conditions
Symbol
Unit
Lid
Junction to Ambient1
Single-layer board (1s); natural convection2
RθJA
RθJA
31
22
24
15
17
12
5
°C/W
°C/W
°C/W
°C/W
°C/W
°C/W
Four-layer board (2s2p); natural convection2
Junction to Ambient1
Single-layer board (1s); air flow 200 ft/min3
RθJMA
RθJMA
RθJB
24
Four-layer board (2s2p); air flow 200 ft/min3
18
Junction to Board1,4
—
—
12
Junction to Case (top)1,5
RθJCtop
<0.1
1
1
Junction temperature is a function of die size, on-chip power dissipation, package thermal resistance, mounting site (board)
temperature, ambient temperature, air flow, power dissipation of other components on the board, and board thermal
resistance.
2
Per JEDEC JESD51-3 with the single layer board horizontal. Thermal test board meets JEDEC specification for the specified
package.
3
4
Per JEDEC JESD51-6 with the board horizontal.
Thermal resistance between the die and the printed circuit board per JEDEC JESD51-8. Board temperature is measured on
the top surface of the board near the package.
5
Thermal resistance between the die and the case top surface as measured by the cold plate method (MIL SPEC-883 Method
1012.1). The cold plate temperature is used for the case temperature. Reported value includes the thermal resistance of the
interface layer.
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Electrical Characteristics
4.1.3
Operating Ranges
Table 6 provides the operating ranges of the i.MX 6Dual/6Quad processors.
Table 6. Operating Ranges
Parameter
Description
Symbol
Min
Typ
Max1
Unit
Comment2
Run mode:
LDO enabled
VDD_ARM_IN
1.2754
—
1.5
V
LDO Output Set Point (VDD_ARM_CAP5) of
1.150 V minimum for operation up to 792 MHz.
VDD_ARM23_IN3
1.054
—
—
1.5
1.5
V
V
LDO Output Set Point (VDD_ARM_CAP5) of
0.925 V minimum for operation up to 396 MHz.
VDD_SOC_IN6
1.3504
264 MHz < VPU ≤ 352 MHz; VDDSOC and
VDDPU LDO outputs (VDD_SOC_CAP and
VDD_PU_CAP) require 1.225 V minimum.
1.2754,7
—
1.5
V
VPU ≤ 264 MHz; VDDSOC and VDDPU LDO
outputs (VDD_SOC_CAP and VDD_PU_CAP)
require 1.15 V minimum.
Run mode:
VDD_ARM_IN
1.150
0.925
1.225
1.15
—
—
—
—
—
1.3
1.3
1.3
1.3
1.3
V
V
V
V
V
LDO bypassed for operation up to 792 MHz.
LDO bypassed for operation up to 396 MHz.
264 MHz < VPU ≤ 352 MHz
LDO bypassed8
VDD_ARM23_IN3
VDD_SOC_IN6
VPU ≤ 264 MHz
Standby/DSM mode
VDD_ARM_IN
0.9
See Table 9, “Stop Mode Current and Power
Consumption,” on page 26.
VDD_ARM23_IN3
VDD_SOC_IN
VDD_HIGH_IN9
0.9
2.7
—
—
1.3
3.3
V
V
VDD_HIGH internal
regulator
Must match the range of voltages that the
rechargeable backup battery supports.
Backup battery supply VDD_SNVS_IN9
range
2.8
—
3.3
V
Should be supplied from the same supply as
VDD_HIGH_IN, if the system does not require
keeping real time and other data on OFF state.
USB supply voltages USB_OTG_VBUS
USB_H1_VBUS
4.4
4.4
—
—
5.25
5.25
1.3
V
V
V
V
V
V
—
—
DDR I/O supply
NVCC_DRAM
1.14
1.425
1.283
1.15
1.2
1.5
1.35
—
LPDDR2
1.575
1.45
2.625
DDR3
DDR3L
Supply for RGMII I/O
power group10
NVCC_RGMII
• 1.15 V – 1.30 V in HSIC 1.2 V mode
• 1.43 V – 1.58 V in RGMII 1.5 V mode
• 1.70 V – 1.90 V in RGMII 1.8 V mode
• 2.25 V – 2.625 V in RGMII 2.5 V mode
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
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Electrical Characteristics
Table 6. Operating Ranges (continued)
Parameter
Description
Symbol
Min
Typ
Max1
Unit
Comment2
GPIO supplies10
NVCC_CSI,
NVCC_EIM0,
NVCC_EIM1,
NVCC_EIM2,
1.65
1.8,
2.8,
3.3
3.6
V
Isolation between the NVCC_EIMx and
NVCC_SDx different supplies allow them to
operate at different voltages within the specified
range.
NVCC_ENET,
NVCC_GPIO,
NVCC_LCD,
NVCC_NANDF,
NVCC_SD1,
NVCC_SD2,
NVCC_SD3,
NVCC_JTAG
Example: NVCC_EIM1 can operate at 1.8 V
while NVCC_EIM2 operates at 3.3 V.
NVCC_LVDS_2P511
NVCC_MIPI
2.25
2.5
2.75
V
—
HDMI supply voltages
PCIe supply voltages
HDMI_VP
HDMI_VPH
PCIE_VP
PCIE_VPH
PCIE_VPTX
SATA_VP
SATA_VPH
TJ
0.99
2.25
1.023
2.325
1.023
0.99
2.25
-40
1.1
2.5
1.1
2.5
1.1
1.1
2.5
90
1.3
2.75
1.3
V
V
V
V
V
V
V
—
—
—
—
—
—
—
2.75
1.3
SATA Supply voltages
Junction temperature
1.3
2.75
105
°C See i.MX 6Dual/6Quad Product Lifetime Usage
Estimates Application Note, AN4724, for
information on product lifetime (power-on
years) for this processor.
1
2
3
Applying the maximum voltage results in maximum power consumption and heat generation. NXP recommends a voltage set
point = (Vmin + the supply tolerance). This results in an optimized power/speed ratio.
See the Hardware Development Guide for i.MX 6Quad, 6Dual, 6DualLite, 6Solo Families of Applications Processors
(IMX6DQ6SDLHDG) for bypass capacitors requirements for each of the *_CAP supply outputs.
For Quad core system, connect to VDD_ARM_IN. For Dual core system, may be shorted to GND together with
VDD_ARM23_CAP to reduce leakage.
4
5
VDD_ARM_IN and VDD_SOC_IN must be at least 125 mV higher than the LDO Output Set Point for correct voltage regulation.
VDD_ARM_CAP must not exceed VDD_CACHE_CAP by more than +50 mV. VDD_CACHE_CAP must not exceed
VDD_ARM_CAP by more than 200 mV.
6
7
VDDSOC and VDDPU output voltages must be set according to this rule: VDDARM-VDDSOC/PU<50mV.
In LDO enabled mode, the internal LDO output set points must be configured such that the:
VDD_ARM LDO output set point does not exceed the VDD_SOC LDO output set point by more than 100 mV.
VDD_SOC LDO output set point is equal to the VDD_PU LDO output set point.
The VDD_ARM LDO output set point can be lower than the VDD_SOC LDO output set point, however, the minimum output set
points shown in this table must be maintained.
8
9
In LDO bypassed mode, the external power supply must ensure that VDD_ARM_IN does not exceed VDD_SOC_IN by more
than 100 mV. The VDD_ARM_IN supply voltage can be lower than the VDD_SOC_IN supply voltage. The minimum voltages
shown in this table must be maintained.
To set VDD_SNVS_IN voltage with respect to Charging Currents and RTC, see the Hardware Development Guide for i.MX
6Dual, 6Quad, 6Solo, 6DualLite Families of Applications Processors (IMX6DQ6SDLHDG).
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
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NXP Semiconductors
Electrical Characteristics
10 All digital I/O supplies (NVCC_xxxx) must be powered under normal conditions whether the associated I/O pins are in use or
not, and associated I/O pins need to have a pull-up or pull-down resistor applied to limit any floating gate current.
11 This supply also powers the pre-drivers of the DDR I/O pins; therefore, it must always be provided, even when LVDS is not used.
4.1.4
External Clock Sources
Each i.MX 6Dual/6Quad processor has two external input system clocks: a low frequency (RTC_XTALI)
and a high frequency (XTALI).
The RTC_XTALI is used for low-frequency functions. It supplies the clock for wake-up circuit,
power-down real time clock operation, and slow system and watchdog counters. The clock input can be
connected to either an external oscillator or a crystal using the internal oscillator amplifier. Additionally,
there is an internal ring oscillator, that can be used instead of RTC_XTALI when accuracy is not important.
The system clock input XTALI is used to generate the main system clock. It supplies the PLLs and other
peripherals. The system clock input can be connected to either an external oscillator or a crystal using the
internal oscillator amplifier.
NOTE
The internal RTC oscillator does not provide an accurate frequency and is
affected by process, voltage and temperature variations. NXP strongly
recommends using an external crystal as the RTC_XTALI reference. If the
internal oscillator is used instead, careful consideration should be given to
the timing implications on all of the SoC modules dependent on this clock.
Table 7 shows the interface frequency requirements.
Table 7. External Input Clock Frequency
Parameter Description
Symbol
Min
Typ
Max
Unit
RTC_XTALI Oscillator1,2
XTALI Oscillator2,4
fckil
fxtal
—
—
32.7683/32.0
24
—
—
kHz
MHz
1
External oscillator or a crystal with internal oscillator amplifier.
2
The required frequency stability of this clock source is application dependent. For recommendations, see the Hardware
Development Guide for i.MX 6Dual, 6Quad, 6Solo, 6DualLite Families of Applications Processors (IMX6DQ6SDLHDG).
3
4
Recommended nominal frequency 32.768 kHz.
External oscillator or a fundamental frequency crystal with internal oscillator amplifier.
The typical values shown in Table 7 are required for use with NXP BSPs to ensure precise time keeping
and USB operation. For RTC_XTALI operation, two clock sources are available:
•
•
On-chip 40 kHz ring oscillator: This clock source has the following characteristics:
— Approximately 25 μA more Idd than crystal oscillator
— Approximately 50ꢀ tolerance
— No external component required
— Starts up quicker than 32 kHz crystal oscillator
External crystal oscillator with on-chip support circuit
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NXP Semiconductors
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Electrical Characteristics
— At power up, an internal ring oscillator is used. After crystal oscillator is stable, the clock circuit
switches over to the crystal oscillator automatically.
— Higher accuracy than ring oscillator.
— If no external crystal is present, then the ring oscillator is used.
The decision to choose a clock source should be based on real-time clock use and precision timeout.
4.1.5
Maximum Measured Supply Currents
Power consumption is highly dependent on the application. Estimating the maximum supply currents
required for power supply design is difficult because the use case that requires maximum supply current is
not a realistic use case.
To help illustrate the effect of the application on power consumption, data was collected while running
industry standard benchmarks that are designed to be compute and graphic intensive. The results provided
are intended to be used as guidelines for power supply design.
Description of test conditions:
•
The Power Virus data shown in Table 8 represent a use case designed specifically to show the
maximum current consumption possible for the Arm core complex. All cores are running at the
defined maximum frequency and are limited to L1 cache accesses only to ensure no pipeline stalls.
Although a valid condition, it would have a very limited, if any, practical use case, and be limited
to an extremely low duty cycle unless the intention was to specifically cause the worst case power
consumption.
•
EEMBC CoreMark: Benchmark designed specifically for the purpose of measuring the
performance of a CPU core. More information available at www.eembc.org/coremark. Note that
this benchmark is designed as a core performance benchmark, not a power benchmark. This use
case is provided as an example of power consumption that would be typical in a
computationally-intensive application rather than the Power Virus.
•
•
3DMark Mobile 2011: Suite of benchmarks designed for the purpose of measuring graphics and
overall system performance. Note that this benchmark is designed as a graphics performance
benchmark, not a power benchmark. This use case is provided as an example of power
consumption that would be typical in a very graphics-intensive application.
Devices used for the tests were from the high current end of the expected process variation.
The NXP power management IC, MMPF0100xxxx, which is targeted for the i.MX 6 series processor
family, supports the power consumption shown in Table 8, however a robust thermal design is required for
the increased system power dissipation.
See the i.MX 6Dual/6Quad Power Consumption Measurement Application Note (AN4509) for more
details on typical power consumption under various use case definitions.
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NXP Semiconductors
Electrical Characteristics
Table 8. Maximum Supply Currents
Conditions
Maximum Current
Power Supply
Unit
Power Virus
CoreMark
i.MX 6Quad:
VDD_ARM_IN + VDD_ARM23_IN
• ARM frequency = 792 MHz
• ARM LDOs set to 1.3V
• Tj = 105°C
3270
2090
mA
i.MX 6Dual: VDD_ARM_IN
• ARM frequency = 792 MHz
• ARM LDOs set to 1.3V
• Tj = 105°C
1960
1250
mA
mA
i.MX 6Dual or i.MX 6Quad:
VDD_SOC_IN
• GPU frequency = 600 MHz
• SOC LDO set to 1.3 V
• Tj = 105°C
2370
VDD_HIGH_IN
VDD_SNVS_IN
—
—
—
1251
2752
253
mA
μA
USB_OTG_VBUS/
mA
USB_H1_VBUS (LDO 3P0)
Primary Interface (IO) Supplies
NVCC_DRAM
NVCC_ENET
NVCC_LCD
NVCC_GPIO
NVCC_CSI
—
(see note4)
N=10
N=29
N=24
N=20
N=19
N=14
N=20
N=6
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
Use maximum IO equation5
25.5
NVCC_EIM0
NVCC_EIM1
NVCC_EIM2
NVCC_JTAG
NVCC_RGMII
NVCC_SD1
N=6
N=6
NVCC_SD2
N=6
NVCC_SD3
N=11
N=26
—
NVCC_NANDF
NVCC_MIPI
NVCC_LVDS2P5
mA
—
NVCC_LVDS2P5 is connected to
VDD_HIGH_CAP at the board
level. VDD_HIGH_CAP is capable
of handing the current required by
NVCC_LVDS2P5.
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Electrical Characteristics
Power Supply
Table 8. Maximum Supply Currents (continued)
Maximum Current
Power Virus CoreMark
Conditions
Unit
MISC
DRAM_VREF
—
1
mA
1
The actual maximum current drawn from VDD_HIGH_IN will be as shown plus any additional current drawn from the
VDD_HIGH_CAP outputs, depending upon actual application configuration (for example, NVCC_LVDS_2P5, NVCC_MIPI, or
HDMI, PCIe, and SATA VPH supplies).
2
Under normal operating conditions, the maximum current on VDD_SNVS_IN is shown Table 8. The maximum VDD_SNVS_IN
current may be higher depending on specific operating configurations, such as BOOT_MODE[1:0] not equal to 00, or use of
the Tamper feature. During initial power on, VDD_SNVS_IN can draw up to 1 mA if the supply is capable of sourcing that
current. If less than 1 mA is available, the VDD_SNVS_CAP charge time will increase.
3
4
This is the maximum current per active USB physical interface.
The DRAM power consumption is dependent on several factors such as external signal termination. DRAM power calculators
are typically available from memory vendors which take into account factors such as signal termination.
See the i.MX 6Dual/6Quad Power Consumption Measurement Application Note (AN4509) for examples of DRAM power
consumption during specific use case scenarios.
5
General equation for estimated, maximum power consumption of an IO power supply:
Imax = N x C x V x (0.5 x F)
Where:
N—Number of IO pins supplied by the power line
C—Equivalent external capacitive load
V—IO voltage
(0.5 xF)—Data change rate. Up to 0.5 of the clock rate (F)
In this equation, Imax is in Amps, C in Farads, V in Volts, and F in Hertz.
4.1.6
Low Power Mode Supply Currents
Table 9 shows the current core consumption (not including I/O) of the i.MX 6Dual/6Quad processors in
selected low power modes.
Table 9. Stop Mode Current and Power Consumption
Mode
Test Conditions
Supply
Typical1
Unit
WAIT
• Arm, SoC, and PU LDOs are set to 1.225 V
• HIGH LDO set to 2.5 V
• Clocks are gated
• DDR is in self refresh
• PLLs are active in bypass (24 MHz)
• Supply voltages remain ON
VDD_ARM_IN (1.4 V)
VDD_SOC_IN (1.4 V)
VDD_HIGH_IN (3.0 V)
Total
6
mA
mA
mA
mW
mA
mA
mA
mW
23
3.7
52
7.5
22
3.7
52
STOP_ON
• Arm LDO set to 0.9 V
• SoC and PU LDOs set to 1.225 V
• HIGH LDO set to 2.5 V
• PLLs disabled
VDD_ARM_IN (1.4 V)
VDD_SOC_IN (1.4 V)
VDD_HIGH_IN (3.0 V)
Total
• DDR is in self refresh
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
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Electrical Characteristics
Table 9. Stop Mode Current and Power Consumption (continued)
Mode
Test Conditions
• Arm LDO set to 0.9 V
• SoC LDO set to 1.225 V
• PU LDO is power gated
• HIGH LDO set to 2.5 V
• PLLs disabled
Supply
Typical1
Unit
STOP_OFF
VDD_ARM_IN (1.4 V)
VDD_SOC_IN (1.4 V)
VDD_HIGH_IN (3.0 V)
Total
7.5
13.5
3.7
41
mA
mA
mA
mW
mA
mA
mA
mW
• DDR is in self refresh
STANDBY
• Arm and PU LDOs are power gated
• SoC LDO is in bypass
• HIGH LDO is set to 2.5 V
• PLLs are disabled
• Low voltage
• Well Bias ON
VDD_ARM_IN (0.9 V)
VDD_SOC_IN (0.9 V)
VDD_HIGH_IN (3.0 V)
Total
0.1
13
3.7
22
• Crystal oscillator is enabled
Deep Sleep Mode
(DSM)
• Arm and PU LDOs are power gated
• SoC LDO is in bypass
• HIGH LDO is set to 2.5 V
• PLLs are disabled
• Low voltage
• Well Bias ON
VDD_ARM_IN (0.9 V)
VDD_SOC_IN (0.9 V)
VDD_HIGH_IN (3.0 V)
Total
0.1
2
mA
mA
mA
mW
0.5
3.4
• Crystal oscillator and bandgap are disabled
SNVS Only
• VDD_SNVS_IN powered
• All other supplies off
• SRTC running
VDD_SNVS_IN (2.8V)
Total
41
μA
115
μW
1
The typical values shown here are for information only and are not guaranteed. These values are average values measured
on a worst-case wafer at 25°C.
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
27
Electrical Characteristics
4.1.7
USB PHY Current Consumption
4.1.7.1
Power Down Mode
In power down mode, everything is powered down, including the VBUS valid detectors, typical condition.
Table 10 shows the USB interface current consumption in power down mode.
Table 10. USB PHY Current Consumption in Power Down Mode
VDD_USB_CAP (3.0 V)
VDD_HIGH_CAP (2.5 V)
NVCC_PLL_OUT (1.1 V)
Current
5.1 μA
1.7 μA
<0.5 μA
NOTE
The currents on the VDD_HIGH_CAP and VDD_USB_CAP were
identified to be the voltage divider circuits in the USB-specific level shifters.
4.1.8
SATA Typical Power Consumption
Table 11 provides SATA PHY currents for certain Tx operating modes.
NOTE
Tx power consumption values are provided for a single transceiver. If
T = single transceiver power and C = Clock module power, the total power
required for N lanes = N x T + C.
Table 11. SATA PHY Current Drain
Mode
Test Conditions
Supply
Typical Current
Unit
P0: Full-power state1
Single Transceiver
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
11
13
mA
Clock Module
Single Transceiver
Clock Module
6.9
6.2
11
P0: Mobile2
mA
mA
11
6.9
6.2
9.4
2.9
6.9
6.2
P0s: Transmitter idle
Single Transceiver
Clock Module
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Electrical Characteristics
Table 11. SATA PHY Current Drain (continued)
Mode
Test Conditions
Supply
Typical Current
Unit
P1: Transmitter idle, Rx powered
down, LOS disabled
Single Transceiver
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
SATA_VP
SATA_VPH
0.67
0.23
6.9
mA
Clock Module
Single Transceiver
Clock Module
6.2
P2: Powered-down state, only
LOS and POR enabled
0.53
0.11
0.036
0.12
0.13
0.012
0.008
0.004
mA
mA
PDDQ mode3
Single Transceiver
Clock Module
1
Programmed for 1.0 V peak-to-peak Tx level.
2
3
Programmed for 0.9 V peak-to-peak Tx level with no boost or attenuation.
LOW power non-functional.
4.1.9
PCIe 2.0 Maximum Power Consumption
Table 12 provides PCIe PHY currents for certain operating modes.
Table 12. PCIe PHY Current Drain
Mode
Test Conditions
Supply
Max Current
Unit
P0: Normal Operation
5G Operations
PCIE_VP (1.1 V)
PCIE_VPTX (1.1 V)
PCIE_VPH (2.5 V)
PCIE_VP (1.1 V)
PCIE_VPTX (1.1 V)
PCIE_VPH (2.5 V)
PCIE_VP (1.1 V)
PCIE_VPTX (1.1 V)
PCIE_VPH (2.5 V)
PCIE_VP (1.1 V)
PCIE_VPTX (1.1 V)
PCIE_VPH (2.5 V)
40
20
21
27
20
20
30
2.4
18
20
2.4
18
mA
2.5G Operations
5G Operations
2.5G Operations
P0s: Low Recovery Time
Latency, Power Saving State
mA
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Electrical Characteristics
Mode
Table 12. PCIe PHY Current Drain (continued)
Test Conditions
Supply
Max Current
Unit
P1: Longer Recovery Time
Latency, Lower Power State
—
PCIE_VP (1.1 V)
PCIE_VPTX (1.1 V)
PCIE_VPH (2.5 V)
PCIE_VP (1.1 V)
12
2.4
mA
12
Power Down
—
1.3
mA
PCIE_VPTX (1.1 V)
PCIE_VPH (2.5 V)
0.18
0.36
4.1.10 HDMI Maximum Power Consumption
Table 13 provides HDMI PHY currents for both Active 3D Tx with LFSR15 data pattern and Power-down
modes.
Table 13. HDMI PHY Current Drain
Mode
Test Conditions
Supply
Max Current
Unit
Active
Bit rate 251.75 Mbps
HDMI_VPH
HDMI_VP
HDMI_VPH
HDMI_VP
HDMI_VPH
HDMI_VP
HDMI_VPH
HDMI_VP
HDMI_VPH
HDMI_VP
HDMI_VPH
HDMI_VP
HDMI_VPH
HDMI_VP
14
4.1
14
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
μA
Bit rate 279.27 Mbps
Bit rate 742.5 Mbps
Bit rate 1.485 Gbps
Bit rate 2.275 Gbps
Bit rate 2.97 Gbps
—
4.2
17
7.5
17
12
16
17
19
22
Power-down
49
1100
μA
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Electrical Characteristics
4.2
Power Supplies Requirements and Restrictions
The system design must comply with power-up sequence, power-down sequence, and steady state
guidelines as described in this section to ensure the reliable operation of the device. Any deviation from
these sequences may result in the following situations:
•
•
•
Excessive current during power-up phase
Prevention of the device from booting
Irreversible damage to the processor
4.2.1
Power-Up Sequence
For power-up sequence, the restrictions are as follows:
•
•
•
VDD_SNVS_IN supply must be turned ON before any other power supply. It may be connected
(shorted) with VDD_HIGH_IN supply.
If a coin cell is used to power VDD_SNVS_IN, then ensure that it is connected before any other
supply is switched on.
The SRC_POR_B signal controls the processor POR and must be immediately asserted at
power-up and remain asserted until the VDD_ARM_CAP, VDD_SOC_CAP, and VDD_PU_CAP
supplies are stable. VDD_ARM_IN and VDD_SOC_IN may be applied in either order with no
restrictions.
NOTE
Ensure that there is no back voltage (leakage) from any supply on the board
towards the 3.3 V supply (for example, from the external components that
use both the 1.8 V and 3.3 V supplies).
NOTE
USB_OTG_VBUS and USB_H1_VBUS are not part of the power supply
sequence and can be powered at any time.
4.2.2
Power-Down Sequence
There are no special restrictions for i.MX 6Dual/6Quad SoC.
4.2.3
Power Supplies Usage
•
All I/O pins must not be externally driven while the I/O power supply for the pin (NVCC_xxx) is
OFF. This can cause internal latch-up and malfunctions due to reverse current flows. For
information about I/O power supply of each pin, see the “Power Group” column of Table 87, “21
x 21 mm Functional Contact Assignments”.
•
WhentheSATAinterfaceisnotused, theSATA_VPandSATA_VPHsuppliesshouldbegrounded.
The input and output supplies for rest of the ports (SATA_REXT, SATA_PHY_RX_N,
SATA_PHY_RX_P, and SATA_PHY_TX_N) can remain unconnected. It is recommended not to
turn OFF the SATA_VPH supply while the SATA_VP supply is ON, as it may lead to excessive
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Electrical Characteristics
power consumption. If boundary scan test is used, SATA_VP and SATA_VPH must remain
powered.
•
When the PCIE interface is not used, the PCIE_VP, PCIE_VPH, and PCIE_VPTX supplies should
be grounded. The input and output supplies for rest of the ports (PCIE_REXT, PCIE_RX_N,
PCIE_RX_P, PCIE_TX_N, and PCIE_TX_P) can remain unconnected. It is recommended not to
turn the PCIE_VPH supply OFF while the PCIE_VP supply is ON, as it may lead to excessive
power consumption. If boundary scan test is used, PCIE_VP, PCIE_VPH, and PCIE_VPTX must
remain powered.
4.3
Integrated LDO Voltage Regulator Parameters
Various internal supplies can be powered ON from internal LDO voltage regulators. All the supply pins
named *_CAP must be connected to external capacitors. The onboard LDOs are intended for internal use
only and should not be used to power any external circuitry. See the i.MX 6Dual/6Quad reference manual
(IMX6DQRM) for details on the power tree scheme recommended operation.
NOTE
The *_CAP signals should not be powered externally. These signals are
intended for internal LDO or LDO bypass operation only.
4.3.1
Digital Regulators (LDO_ARM, LDO_PU, LDO_SOC)
There are three digital LDO regulators (“Digital”, because of the logic loads that they drive, not because
of their construction). The advantages of the regulators are to reduce the input supply variation because of
their input supply ripple rejection and their on die trimming. This translates into more voltage for the die
producing higher operating frequencies. These regulators have three basic modes.
•
Bypass. The regulation FET is switched fully on passing the external voltage, DCDC_LOW, to the
load unaltered. The analog part of the regulator is powered down in this state, removing any loss
other than the IR drop through the power grid and FET.
•
•
Power Gate. The regulation FET is switched fully off limiting the current draw from the supply.
The analog part of the regulator is powered down here limiting the power consumption.
Analog regulation mode. The regulation FET is controlled such that the output voltage of the
regulator equals the programmed target voltage. The target voltage is fully programmable in 25 mV
steps.
Optionally LDO_SOC/VDD_SOC_CAP can be used to power the HDMI, PCIe, and SATA PHY's through
external connections.
For additional information, see the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
4.3.2
Regulators for Analog Modules
LDO_1P1 / NVCC_PLL_OUT
4.3.2.1
The LDO_1P1 regulator implements a programmable linear-regulator function from VDD_HIGH_IN (see
Table 6 for minimum and maximum input requirements). Typical Programming Operating Range is 1.0 V
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Electrical Characteristics
to 1.2 V with the nominal default setting as 1.1 V. The LDO_1P1 supplies the 24 MHz oscillator, PLLs,
and USB PHY. A programmable brown-out detector is included in the regulator that can be used by the
system to determine when the load capability of the regulator is being exceeded to take the necessary steps.
Current-limiting can be enabled to allow for in-rush current requirements during start-up, if needed.
Active-pull-down can also be enabled for systems requiring this feature.
For information on external capacitor requirements for this regulator, see the Hardware Development
Guide for i.MX 6Quad, 6Dual, 6DualLite, 6Solo Families of Applications Processors
(IMX6DQ6SDLHDG).
For additional information, see the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
4.3.2.2
LDO_2P5
The LDO_2P5 module implements a programmable linear-regulator function from VDD_HIGH_IN (see
Table 6 for min and max input requirements). Typical Programming Operating Range is 2.25 V to 2.75 V
with the nominal default setting as 2.5 V. The LDO_2P5 supplies the SATA PHY, USB PHY, LVDS PHY,
HDMI PHY, MIPI PHY, E-fuse module and PLLs. A programmable brown-out detector is included in the
regulator that can be used by the system to determine when the load capability of the regulator is being
exceeded, to take the necessary steps. Current-limiting can be enabled to allow for in-rush current
requirements during start-up, if needed. Active-pull-down can also be enabled for systems requiring this
feature. An alternate self-biased low-precision weak-regulator is included that can be enabled for
applications needing to keep the output voltage alive during low-power modes where the main regulator
driver and its associated global bandgap reference module are disabled. The output of the weak-regulator
is not programmable and is a function of the input supply as well as the load current. Typically, with a 3 V
input supply the weak-regulator output is 2.525 V and its output impedance is approximately 40 Ω.
For information on external capacitor requirements for this regulator, see the Hardware Development
Guide for i.MX 6Quad, 6Dual, 6DualLite, 6Solo Families of Applications Processors
(IMX6DQ6SDLHDG).
For additional information, see the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
4.3.2.3
LDO_USB
The LDO_USB module implements a programmable linear-regulator function from the
USB_OTG_VBUS and USB_H1_VBUS voltages (4.4 V–5.25 V) to produce a nominal 3.0 V output
voltage. A programmable brown-out detector is included in the regulator that can be used by the system to
determine when the load capability of the regulator is being exceeded, to take the necessary steps. This
regulator has a built in power-mux that allows the user to select to run the regulator from either VBUS
supply, when both are present. If only one of the VBUS voltages is present, then the regulator
automatically selects this supply. Current limit is also included to help the system meet in-rush current
targets. If no VBUS voltage is present, then the VBUSVALID threshold setting will prevent the regulator
from being enabled.
For information on external capacitor requirements for this regulator, see the Hardware Development
Guide for i.MX 6Quad, 6Dual, 6DualLite, 6Solo Families of Applications Processors
(IMX6DQ6SDLHDG).
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Electrical Characteristics
For additional information, see the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
4.4
PLL Electrical Characteristics
4.4.1
Audio/Video PLL Electrical Parameters
Table 14. Audio/Video PLL Electrical Parameters
Parameter
Value
Clock output range
Reference clock
Lock time
650 MHz ~1.3 GHz
24 MHz
<11250 reference cycles
4.4.2
4.4.3
4.4.4
528 MHz PLL
Table 15. 528 MHz PLL Electrical Parameters
Parameter
Value
Clock output range
Reference clock
Lock time
528 MHz PLL output
24 MHz
<11250 reference cycles
Ethernet PLL
Table 16. Ethernet PLL Electrical Parameters
Parameter
Value
Clock output range
Reference clock
Lock time
500 MHz
24 MHz
<11250 reference cycles
480 MHz PLL
Table 17. 480 MHz PLL Electrical Parameters
Parameter
Value
Clock output range
Reference clock
Lock time
480 MHz PLL output
24 MHz
<383 reference cycles
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Electrical Characteristics
4.4.5
Arm PLL
Table 18. Arm PLL Electrical Parameters
Parameter
Value
Clock output range
Reference clock
Lock time
650 MHz~1.3 GHz
24 MHz
<2250 reference cycles
4.5
On-Chip Oscillators
OSC24M
4.5.1
This block implements an amplifier that when combined with a suitable quartz crystal and external load
capacitors implements an oscillator. The oscillator is powered from NVCC_PLL_OUT.
The system crystal oscillator consists of a Pierce-type structure running off the digital supply. A straight
forward biased-inverter implementation is used.
4.5.2
OSC32K
This block implements an amplifier that when combined with a suitable quartz crystal and external load
capacitors implements a low power oscillator. It also implements a power mux such that it can be powered
from either a ~3 V backup battery (VDD_SNVS_IN) or VDD_HIGH_IN such as the oscillator consumes
power from VDD_HIGH_IN when that supply is available and transitions to the back up battery when
VDD_HIGH_IN is lost.
In addition, if the clock monitor determines that the OSC32K is not present, then the source of the 32 kHz
clock will automatically switch to the internal ring oscillator.
CAUTION
The internal RTC oscillator does not provide an accurate frequency and is
affected by process, voltage, and temperature variations. NXP strongly
recommends using an external crystal as the RTC_XTALI reference. If the
internal oscillator is used instead, careful consideration must be given to the
timing implications on all of the SoC modules dependent on this clock.
The OSC32k runs from VDD_SNVS_CAP, which comes from the VDD_HIGH_IN/VDD_SNVS_IN
power mux.
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Electrical Characteristics
Table 19. OSC32K Main Characteristics
Max Comments
Parameter Min
Typ
Fosc
—
32.768 kHz
—
This frequency is nominal and determined mainly by the crystal selected. 32.0 K
would work as well.
Current
consumption
—
4 μA
—
The typical value shown is only for the oscillator, driven by an external crystal.
If the internal ring oscillator is used instead of an external crystal, then
approximately 25 μA must be added to this value.
Bias resistor
—
14 MΩ
—
—
This the integrated bias resistor that sets the amplifier into a high gain state. Any
leakage through the ESD network, external board leakage, or even a scope probe
that is significant relative to this value will debias the amplifier. The debiasing will
result in low gain, and will impact the circuit's ability to start up and maintain
oscillations.
Target Crystal Properties
Cload
ESR
—
—
10 pF
Usually crystals can be purchased tuned for different Cloads. This Cload value is
typically 1/2 of the capacitances realized on the PCB on either side of the quartz.
A higher Cload will decrease oscillation margin, but increases current oscillating
through the crystal.
50 kΩ
100 kΩ Equivalent series resistance of the crystal. Choosing a crystal with a higher value
will decrease the oscillating margin.
4.6
I/O DC Parameters
This section includes the DC parameters of the following I/O types:
•
•
•
General Purpose I/O (GPIO)
Double Data Rate I/O (DDR) for LPDDR2 and DDR3/DDR3L modes
LVDS I/O
NOTE
The term ‘OVDD’ in this section refers to the associated supply rail of an
input or output.
ovdd
pmos (Rpu)
Voh min
1
Vol max
or
0
pdat
pad
Predriver
nmos (Rpd)
ovss
Figure 3. Circuit for Parameters Voh and Vol for I/O Cells
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Electrical Characteristics
4.6.1
XTALI and RTC_XTALI (Clock Inputs) DC Parameters
Table 20 shows the DC parameters for the clock inputs.
Table 20. XTALI and RTC_XTALI DC Parameters
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
XTALI high-level DC input voltage
XTALI low-level DC input voltage
Vih
Vil
—
—
—
0.8 x NVCC_PLL_OUT — NVCC_PLL_ OUT
V
V
V
0
—
—
0.2
RTC_XTALI high-level DC input
voltage
Vih
0.8
1.1(See note 1)
RTC_XTALI low-level DC input
voltage
Vil
—
0
—
0.2
V
Input capacitance
CIN
Simulated data
—
—
5
—
pF
XTALI input leakage current at
startup
IXTALI_STARTUP Power-on startup for
0.15 msecwithadriven
24 MHz clock
—
600
μA
at 1.1 V. 2
DC input current
IXTALI_DC
—
—
—
2.5
μA
1
This voltage specification must not be exceeded and, as such, is an absolute maximum specification.
This current draw is present even if an external clock source directly drives XTALI.
2
NOTE
The Vil and Vih specifications only apply when an external clock source is
used. If a crystal is used, Vil and Vih do not apply.
4.6.2
General Purpose I/O (GPIO) DC Parameters
Table 21 shows DC parameters for GPIO pads. The parameters in Table 21 are guaranteed per the
operating ranges in Table 6, unless otherwise noted.
Table 21. GPIO I/O DC Parameters
Parameter
Symbol
Test Conditions
Min
Max
Unit
High-level output voltage1
Voh
Ioh = -0.1 mA (DSE2 = 001, 010)
Ioh = -1 mA
OVDD – 0.15
—
V
(DSE = 011, 100, 101, 110, 111)
Low-level output voltage1
Vol
Iol = 0.1 mA (DSE2 = 001, 010)
Iol = 1mA
—
0.15
V
(DSE = 011, 100, 101, 110, 111)
High-Level DC input voltage1, 3
Low-Level DC input voltage1, 3
Input Hysteresis
Vih
Vil
—
—
0.7 × OVDD
OVDD
0.3 × OVDD
—
V
V
V
0
Vhys
OVDD = 1.8 V
OVDD = 3.3 V
0.25
Schmitt trigger VT+3, 4
Schmitt trigger VT–3, 4
VT+
VT–
—
—
0.5 × OVDD
—
V
V
—
0.5 × OVDD
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Electrical Characteristics
Parameter
Table 21. GPIO I/O DC Parameters (continued)
Symbol
Test Conditions
Min
Max
Unit
Input current (no pull-up/down)
Iin
Iin
Vin = OVDD or 0
-1
1
μA
Input current (22 kΩ pull-up)
Vin = 0 V
Vin = OVDD
—
212
1
μA
μA
μA
μA
kΩ
Input current (47 kΩ pull-up)
Input current (100 kΩ pull-up)
Input current (100 kΩ pull-down)
Keeper circuit resistance
Iin
Iin
Vin = 0 V
Vin = OVDD
—
—
100
1
Vin = 0 V
Vin= OVDD
48
1
Iin
Vin = 0 V
Vin = OVDD
—
1
48
Rkeep
Vin = 0.3 x OVDD
Vin = 0.7 x OVDD
105
175
1
Overshoot and undershoot conditions (transitions above OVDD and below GND) on switching pads must be held below 0.6 V,
and the duration of the overshoot/undershoot must not exceed 10% of the system clock cycle. Overshoot/ undershoot must be
controlled through printed circuit board layout, transmission line impedance matching, signal line termination, or other methods.
Non-compliance to this specification may affect device reliability or cause permanent damage to the device.
2
3
DSE is the Drive Strength Field setting in the associated IOMUX control register.
To maintain a valid level, the transition edge of the input must sustain a constant slew rate (monotonic) from the current DC
level through to the target DC level, Vil or Vih. Monotonic input transition time is from 0.1 ns to 1 s.
4
Hysteresis of 250 mV is guaranteed over all operating conditions when hysteresis is enabled.
4.6.3
DDR I/O DC Parameters
The DDR I/O pads support LPDDR2 and DDR3/DDR3L operational modes.
4.6.4
RGMII I/O 2.5V I/O DC Electrical Parameters
The RGMII interface complies with the RGMII standard version 1.3. The parameters in Table 22 are
guaranteed per the operating ranges in Table 6, unless otherwise noted.
1
Table 22. RGMII I/O 2.5V I/O DC Electrical Parameters
Parameter
Symbol
Test Conditions
Min
Max
Units
High-level output voltage1
VOH
Ioh= -0.1 mA (DSE=001,010)
—
V
OVDD-0.15
Ioh= -1.0 mA (DSE=011,100,101,110,111)
Low-level output voltage1
VOL
Iol= 0.1 mA (DSE=001,010)
—
0.15
V
Iol= 1.0 mA (DSE=011,100,101,110,111)
0.49xOVDD 0.51xOVDD
Input Reference Voltage
High-Level input voltage 2, 3
Low-Level input voltage 2, 3
Vref
VIH
VIL
—
—
V
V
0.7xOVDD
OVDD
0.3xOVDD
—
—
0
V
Input Hysteresis(OVDD=1.8V) VHYS_HighVDD
Input Hysteresis(OVDD=2.5V) VHYS_HighVDD
OVDD=1.8V
OVDD=2.5V
250
250
mV
mV
—
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Electrical Characteristics
Table 22. RGMII I/O 2.5V I/O DC Electrical Parameters (continued)
1
Schmitt trigger VT+ 3, 4
VTH+
VTH-
—
—
0.5xOVDD
—
mV
Schmitt trigger VT- 3, 4
—
—
0.5xOVDD mV
Pull-up resistor (22 kΩ PU)
Pull-up resistor (22 kΩ PU)
Pull-up resistor (47 kΩ PU)
Pull-up resistor (47 kΩ PU)
Pull-up resistor (100 kΩ PU)
Pull-up resistor (100 kΩ PU)
Pull-down resistor (100 kΩ PD)
Pull-down resistor (100 kΩ PD)
Keeper Circuit Resistance
Input current (no pull-up/down)
RPU_22K
RPU_22K
RPU_47K
RPU_47K
RPU_100K
RPU_100K
RPD_100K
RPD_100K
Rkeep
Vin=0V
212
1
μA
μA
μA
μA
μA
μA
μA
μA
kΩ
μA
Vin=OVDD
Vin=0V
—
—
100
1
Vin=OVDD
Vin=0V
—
—
48
1
Vin=OVDD
Vin=OVDD
Vin=0V
—
—
48
1
—
—
105
-2.9
165
2.9
Iin
VI = 0,VI = OVDD
1
Input Mode Selection: SW_PAD_CTL_GRP_DDR_TYPE_RGMII = 10 (1.8V Mode)
SW_PAD_CTL_GRP_DDR_TYPE_RGMII = 11 (2.5V Mode).
2
Overshoot and undershoot conditions (transitions above OVDD and below GND) on switching pads must be held below 0.6
V, and the duration of the overshoot/undershoot must not exceed 10% of the system clock cycle. Overshoot/ undershoot must
be controlled through printed circuit board layout, transmission line impedance matching, signal line termination, or other
methods. Non-compliance to this specification may affect device reliability or cause permanent damage to the device.
3
4
To maintain a valid level, the transition edge of the input must sustain a constant slew rate (monotonic) from the current DC
level through to the target DC level, Vil or Vih. Monotonic input transition time is from 0.1 ns to 1 s.
Hysteresis of 250 mV is guaranteed over all operating conditions when hysteresis is enabled
(register IOMUXC_SW_PAD_CTL_PAD_RGMII_TXC[HYS]= 0).
4.6.4.1
LPDDR2 Mode I/O DC Parameters
For details on supported DDR memory configurations, see Section 4.10.2, “MMDC Supported
DDR3/DDR3L/LPDDR2 Configurations.”
The parameters in Table 23 are guaranteed per the operating ranges in Table 6, unless otherwise noted.
1
Table 23. LPDDR2 I/O DC Electrical Parameters
Parameters
Symbol
Test Conditions
Min
Max
Unit
High-level output voltage
Low-level output voltage
Input reference voltage
DC input High Voltage
Voh
Vol
Ioh = -0.1 mA
0.9 × OVDD
—
—
V
V
Iol = 0.1 mA
0.1 × OVDD
0.51 × OVDD
OVDD
Vref
—
0.49 × OVDD
Vref+0.13V
OVSS
Vih(dc)
Vil(dc)
Vih(diff)
Vil(diff)
Iin
—
V
V
DC input Low Voltage
—
Vref-0.13V
See Note 2
-0.26
Differential Input Logic High
Differential Input Logic Low
Input current (no pull-up/down)
—
—
0.26
—
—
μA
See Note 2
-2.5
Vin = 0 or OVDD
2.5
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Electrical Characteristics
Parameters
1
Table 23. LPDDR2 I/O DC Electrical Parameters (continued)
Symbol
Test Conditions
Min
Max
Unit
Pull-up/pull-down impedance mismatch
MMpupd
Rres
—
—
—
-15
—
+15
10
%
Ω
240 Ω unit calibration resolution
Keeper circuit resistance
Rkeep
110
175
kΩ
1
Note that the JEDEC LPDDR2 specification (JESD209_2B) supersedes any specification in this document.
2
The single-ended signals need to be within the respective limits (Vih(dc) max, Vil(dc) min) for single-ended signals as well as
the limitations for overshoot and undershoot (see Table 28).
4.6.4.2
DDR3/DDR3L Mode I/O DC Parameters
For details on supported DDR memory configurations, see Section 4.10.2, “MMDC Supported
DDR3/DDR3L/LPDDR2 Configurations.”
The parameters in Table 24 are guaranteed per the operating ranges in Table 6, unless otherwise noted.
Table 24. DDR3/DDR3L I/O DC Electrical Parameters
Parameters
Symbol
Test Conditions
Min
Max
Unit
High-level output voltage
Ioh = -0.1 mA
Voh (DSE = 001)
Voh
0.8 × OVDD1
—
V
Ioh = -1 mA
Voh (for all except DSE = 001)
Low-level output voltage
Iol = 0.1 mA
Vol (DSE = 001)
Vol
—
0.2 × OVDD
V
Iol = 1 mA
Vol (for all except DSE = 001)
Input reference voltage
Vref2
Vih(dc)
Vil(dc)
Vih(diff)
Vil(diff)
Vtt
—
0.49 × OVDD 0.51 × OVDD
DC input Logic High
—
Vref+0.1
OVSS
OVDD
Vref-0.1
See Note3
-0.2
V
V
DC input Logic Low
—
Differential input Logic High
Differential input Logic Low
Termination Voltage
—
0.2
V
—
See Note3
V
Vtt tracking OVDD/2
0.49 × OVDD 0.51 × OVDD
V
Input current (no pull-up/down)
Pull-up/pull-down impedance mismatch
240 Ω unit calibration resolution
Keeper circuit resistance
Iin
Vin = 0 or OVDD
-2.9
-10
—
2.9
10
μA
%
Ω
MMpupd
Rres
—
—
—
10
Rkeep
105
175
kΩ
1
OVDD – I/O power supply (1.425 V–1.575 V for DDR3 and 1.283 V–1.45 V for DDR3L).
Vref – DDR3/DDR3L external reference voltage.
2
3
The single-ended signals need to be within the respective limits (Vih(dc) max, Vil(dc) min) for single-ended signals as well as
the limitations for overshoot and undershoot (see Table 29).
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4.6.5
LVDS I/O DC Parameters
The LVDS interface complies with TIA/EIA 644-A standard. See TIA/EIA STANDARD 644-A,
“Electrical Characteristics of Low Voltage Differential Signaling (LVDS) Interface Circuits” for details.
Table 25 shows the Low Voltage Differential Signaling (LVDS) I/O DC parameters.
Table 25. LVDS I/O DC Parameters
Parameter
Symbol
Test Conditions
Min
Max
Unit
Output Differential Voltage
Output High Voltage
Output Low Voltage
Offset Voltage
VOD
VOH
VOL
VOS
Rload=100 Ω between padP and padN
250
1.25
0.9
450
1.6
mV
IOH = 0 mA
IOL = 0 mA
—
1.25
1.375
V
1.125
4.7
I/O AC Parameters
This section includes the AC parameters of the following I/O types:
•
•
•
General Purpose I/O (GPIO)
Double Data Rate I/O (DDR) for LPDDR2 and DDR3/DDR3L modes
LVDS I/O
The GPIO and DDR I/O load circuit and output transition time waveforms are shown in Figure 4 and
Figure 5.
From Output
Under Test
Test Point
CL
CL includes package, probe and fixture capacitance
Figure 4. Load Circuit for Output
OVDD
0 V
80%
20%
80%
20%
tr
Output (at pad)
tf
Figure 5. Output Transition Time Waveform
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Electrical Characteristics
4.7.1
General Purpose I/O AC Parameters
The I/O AC parameters for GPIO in slow and fast modes are presented in the Table 26 and Table 27,
respectively. Note that the fast or slow I/O behavior is determined by the appropriate control bits in the
IOMUXC control registers.
Table 26. General Purpose I/O AC Parameters 1.8 V Mode
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Output Pad Transition Times, rise/fall
(Max Drive, DSE=111)
tr, tf
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
2.72/2.79
1.51/1.54
—
—
Output Pad Transition Times, rise/fall
(High Drive, DSE=101)
tr, tf
tr, tf
tr, tf
trm
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
3.20/3.36
1.96/2.07
—
—
—
—
ns
ns
Output Pad Transition Times, rise/fall
(Medium Drive, DSE=100)
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
3.64/3.88
2.27/2.53
Output Pad Transition Times, rise/fall
(Low Drive. DSE=011)
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
4.32/4.50
3.16/3.17
—
—
—
—
Input Transition Times1
—
25
1
Hysteresis mode is recommended for inputs with transition times greater than 25 ns.
Table 27. General Purpose I/O AC Parameters 3.3 V Mode
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Output Pad Transition Times, rise/fall
(Max Drive, DSE=101)
tr, tf
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
1.70/1.79
1.06/1.15
—
—
Output Pad Transition Times, rise/fall
(High Drive, DSE=011)
tr, tf
tr, tf
tr, tf
trm
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
2.35/2.43
1.74/1.77
—
—
—
—
ns
Output Pad Transition Times, rise/fall
(Medium Drive, DSE=010)
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
3.13/3.29
2.46/2.60
Output Pad Transition Times, rise/fall
(Low Drive. DSE=001)
15 pF Cload, slow slew rate
15 pF Cload, fast slew rate
5.14/5.57
4.77/5.15
—
—
—
—
Input Transition Times1
—
25
ns
1
Hysteresis mode is recommended for inputs with transition times greater than 25 ns.
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4.7.2
DDR I/O AC Parameters
For details on supported DDR memory configurations, see Section 4.10.2, “MMDC Supported
DDR3/DDR3L/LPDDR2 Configurations.”
Table 28 shows the AC parameters for DDR I/O operating in LPDDR2 mode.
1
Table 28. DDR I/O LPDDR2 Mode AC Parameters
Parameter
AC input logic high
Symbol
Test Condition
Min
Typ
Max
Unit
Vih(ac)
Vil(ac)
—
Vref + 0.22
—
—
—
—
—
—
—
OVDD
Vref – 0.22
—
V
V
AC input logic low
—
0
0.44
—
AC differential input high voltage2
AC differential input low voltage
Input AC differential cross point voltage3
Over/undershoot peak
Vidh(ac)
Vidl(ac)
Vix(ac)
Vpeak
—
V
—
Relative to Vref
—
0.44
V
-0.12
—
0.12
V
0.35
V
Over/undershoot area (above OVDD
or below OVSS)
Varea
400 MHz
—
0.2
V-ns
Single output slew rate, measured
between Vol(ac) and Voh(ac)
tsr
50 Ω to Vref.
5 pF load.
Drive impedance = 4 0 Ω 30%
1.5
1
—
—
—
3.5
2.5
0.1
V/ns
50 Ω to Vref.
5pF load.
Drive impedance = 60 Ω 30%
Skew between pad rise/fall asymmetry +
skew caused by SSN
tSKD
clk = 400 MHz
ns
—
1
2
Note that the JEDEC LPDDR2 specification (JESD209_2B) supersedes any specification in this document.
Vid(ac) specifies the input differential voltage |Vtr – Vcp| required for switching, where Vtr is the “true” input signal and Vcp is
the “complementary” input signal. The Minimum value is equal to Vih(ac) – Vil(ac).
3
The typical value of Vix(ac) is expected to be about 0.5 × OVDD. and Vix(ac) is expected to track variation of OVDD. Vix(ac)
indicates the voltage at which differential input signal must cross.
Table 29 shows the AC parameters for DDR I/O operating in DDR3/DDR3L mode.
1
Table 29. DDR I/O DDR3/DDR3L Mode AC Parameters
Parameter
AC input logic high
Symbol
Test Condition
Min
Typ
Max
Unit
Vih(ac)
Vil(ac)
Vid(ac)
Vix(ac)
Vpeak
Varea
—
Vref + 0.175
—
—
—
—
—
—
OVDD
Vref – 0.175
—
V
V
AC input logic low
—
0
0.35
AC differential input voltage2
Input AC differential cross point voltage3
Over/undershoot peak
—
Relative to Vref
—
V
Vref – 0.15
—
Vref + 0.15
0.4
V
V
Over/undershoot area (above OVDD
or below OVSS)
533 MHz
—
0.5
V-ns
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Table 29. DDR I/O DDR3/DDR3L Mode AC Parameters (continued)
1
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Single output slew rate, measured between
Vol(ac) and Voh(ac)
tsr
Driver impedance =
2.5
—
5
V/ns
34 Ω
Skew between pad rise/fall asymmetry +
skew caused by SSN
tSKD
clk = 533 MHz
0.1
ns
—
—
1
Note that the JEDEC JESD79_3C specification supersedes any specification in this document.
2
3
Vid(ac) specifies the input differential voltage |Vtr-Vcp| required for switching, where Vtr is the “true” input signal and Vcp is
the “complementary” input signal. The Minimum value is equal to Vih(ac) – Vil(ac).
The typical value of Vix(ac) is expected to be about 0.5 × OVDD. and Vix(ac) is expected to track variation of OVDD. Vix(ac)
indicates the voltage at which differential input signal must cross.
4.7.3
LVDS I/O AC Parameters
The differential output transition time waveform is shown in Figure 6.
padp
V
OH
0V
0V
0V (Differential)
padn
V
OL
80%
80%
0V
VDIFF
VDIFF = {padp} - {padn}
20%
20%
t
t
THL
TLH
Figure 6. Differential LVDS Driver Transition Time Waveform
Table 30 shows the AC parameters for LVDS I/O.
Table 30. I/O AC Parameters of LVDS Pad
Parameter
Differential pulse skew1
Symbol Test Condition
Min
Typ
Max
Unit
tSKD
—
—
—
—
—
—
—
0.25
0.5
Rload = 100 Ω,
Cload = 2 pF
Transition Low to High Time2
Transition High to Low Time2
Operating Frequency
tTLH
ns
tTHL
—
0.5
f
—
—
600
—
800
150
MHz
mV
Offset voltage imbalance
Vos
1
tSKD = | tPHLD – tPLHD |, is the magnitude difference in differential propagation delay time between the positive going edge and
the negative going edge of the same channel.
2
Measurement levels are 20–80% from output voltage.
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4.8
Output Buffer Impedance Parameters
This section defines the I/O impedance parameters of the i.MX 6Dual/6Quad processors for the following
I/O types:
•
•
•
General Purpose I/O (GPIO)
Double Data Rate I/O (DDR) for LPDDR2, and DDR3 modes
LVDS I/O
NOTE
GPIO and DDR I/O output driver impedance is measured with “long”
transmission line of impedance Ztl attached to I/O pad and incident wave
launched into transmission line. Rpu/Rpd and Ztl form a voltage divider that
defines specific voltage of incident wave relative to OVDD. Output driver
impedance is calculated from this voltage divider (see Figure 7).
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OVDD
PMOS (Rpu)
Ztl Ω, L = 20 inches
ipp_do
pad
predriver
Cload = 1p
NMOS (Rpd)
OVSS
U,(V)
VDD
Vin (do)
t,(ns)
0
U,(V)
Vout (pad)
OVDD
Vref2
Vref1
Vref
t,(ns)
0
Vovdd – Vref1
Vref1
Rpu =
Rpd =
× Ztl
× Ztl
Vref2
Vovdd – Vref2
Figure 7. Impedance Matching Load for Measurement
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4.8.1
GPIO Output Buffer Impedance
Table 31 shows the GPIO output buffer impedance (OVDD 1.8 V).
Table 31. GPIO Output Buffer Average Impedance (OVDD 1.8 V)
Parameter
Symbol
Drive Strength (DSE)
Typ Value
Unit
001
010
011
100
101
110
111
260
130
90
60
50
Output Driver
Impedance
Rdrv
Ω
40
33
Table 32 shows the GPIO output buffer impedance (OVDD 3.3 V).
Table 32. GPIO Output Buffer Average Impedance (OVDD 3.3 V)
Parameter
Symbol
Drive Strength (DSE)
Typ Value
Unit
001
010
011
100
101
110
111
150
75
50
37
30
25
20
Output Driver
Impedance
Rdrv
Ω
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4.8.2
DDR I/O Output Buffer Impedance
For details on supported DDR memory configurations, see Section 4.10.2, “MMDC Supported
DDR3/DDR3L/LPDDR2 Configurations.”
Table 33 shows DDR I/O output buffer impedance of i.MX 6Dual/6Quad processors.
Table 33. DDR I/O Output Buffer Impedance
Typical
NVCC_DRAM=1.5 V
(DDR3)
NVCC_DRAM=1.2 V
(LPDDR2)
Parameter
Symbol
Test Conditions
Unit
DDR_SEL=11
DDR_SEL=10
Drive Strength (DSE) =
000
001
010
011
100
101
110
111
Hi-Z
240
120
80
60
48
Hi-Z
240
120
80
60
48
Output Driver
Impedance
Rdrv
Ω
40
34
40
34
Note:
1. Output driver impedance is controlled across PVTs using ZQ calibration procedure.
2. Calibration is done against 240 W external reference resistor.
3. Output driver impedance deviation (calibration accuracy) is 5% (max/min impedance) across PVTs.
4.8.3
LVDS I/O Output Buffer Impedance
The LVDS interface complies with TIA/EIA 644-A standard. See, TIA/EIA STANDARD 644-A,
“Electrical Characteristics of Low Voltage Differential Signaling (LVDS) Interface Circuits” for details.
4.9
System Modules Timing
This section contains the timing and electrical parameters for the modules in each i.MX 6Dual/6Quad
processor.
4.9.1
Reset Timing Parameters
Figure 8 shows the reset timing and Table 34 lists the timing parameters.
SRC_POR_B
(Input)
CC1
Figure 8. Reset Timing Diagram
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Table 34. Reset Timing Parameters
ID
Parameter
Min
Max
Unit
CC1
Duration of SRC_POR_B to be qualified as valid
1
—
XTALOSC_RTC_ XTALI cycle
4.9.2
WDOG Reset Timing Parameters
Figure 9 shows the WDOG reset timing and Table 35 lists the timing parameters.
WDOG1_B
(Output)
CC3
Figure 9. WDOG1_B Timing Diagram
Table 35. WDOG1_B Timing Parameters
ID
Parameter
Min
Max
Unit
CC3 Duration of WDOG1_B Assertion
1
—
XTALOSC_RTC_ XTALI cycle
NOTE
XTALOSC_RTC_XTALI is approximately 32 kHz.
XTALOSC_RTC_XTALI cycle is one period or approximately 30 μs.
NOTE
WDOG1_B output signals (for each one of the Watchdog modules) do not
have dedicated pins, but are muxed out through the IOMUX. See the IOMUX
manual for detailed information.
4.9.3
External Interface Module (EIM)
The following subsections provide information on the EIM. Maximum operating frequency for EIM data
transfer is 104 MHz. Timing parameters in this section that are given as a function of register settings or
clock periods are valid for the entire range of allowed frequencies (0–104 MHz).
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4.9.3.1
EIM Interface Pads Allocation
EIM supports 32-bit, 16-bit and 8-bit devices operating in address/data separate or multiplexed modes.
Table 36 provides EIM interface pads allocation in different modes.
1
Table 36. EIM Internal Module Multiplexing
Multiplexed
Non Multiplexed Address/Data Mode
Address/Data mode
Setup
8 Bit
16 Bit
32 Bit
16 Bit
32 Bit
MUM = 0, MUM = 0, MUM = 0, MUM = 0, MUM = 0, MUM = 0, MUM = 0, MUM = 1, MUM = 1,
DSZ = 100 DSZ = 101 DSZ = 110 DSZ = 111 DSZ = 001 DSZ = 010 DSZ = 011 DSZ = 001 DSZ = 011
EIM_ADDR
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_AD
[15:00]
EIM_ADDR EIM_ADDR EIM_ADDR EIM_ADDR EIM_ADDR EIM_ADDR EIM_ADDR EIM_ADDR EIM_ADDR EIM_DATA
[25:16]
[25:16]
[25:16]
[25:16]
[25:16]
[25:16]
[25:16]
[25:16]
EIM_DATA EIM_AD
[07:00] [07:00]
[25:16]
[09:00]
EIM_DATA EIM_DATA
[07:00],
EIM_EB0_B
—
—
—
EIM_DATA
[07:00]
—
EIM_AD
[07:00]
[07:00]
—
EIM_DATA
[15:08],
EIM_EB1_B
EIM_DATA
[15:08]
—
—
—
EIM_DATA
[15:08]
—
EIM_DATA EIM_AD
EIM_AD
[15:08]
[15:08]
[15:08]
EIM_DATA
[23:16],
EIM_EB2_B
—
—
—
—
EIM_DATA
[23:16]
—
—
EIM_DATA EIM_DATA
[23:16] [23:16]
—
EIM_DATA
[07:00]
EIM_DATA
[31:24],
—
EIM_DATA
[31:24]
EIM_DATA EIM_DATA
[31:24] [31:24]
—
EIM_DATA
[15:08]
EIM_EB3_B
1
For more information on configuration ports mentioned in this table, see the i.MX 6Dual/6Quad reference manual
(IMX6DQRM).
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4.9.3.2
General EIM Timing-Synchronous Mode
Figure 10, Figure 11, and Table 37 specify the timings related to the EIM module. All EIM output control
signals may be asserted and deasserted by an internal clock synchronized to the EIM_BCLK rising edge
according to corresponding assertion/negation control fields.
WE2
EIM_BCLK
...
WE3
WE1
WE4
WE6
WE5
WE7
WE9
EIM_ADDRxx
EIM_CSx_B
WE8
WE10
WE12
EIM_WE_B
EIM_OE_B
EIM_EBx_B
WE11
WE13
WE15
WE17
WE14
WE16
EIM_LBA_B
Output Data
Figure 10. EIM Output Timing Diagram
EIM_BCLK
WE18
Input Data
WE19
WE20
EIM_WAIT_B
WE21
Figure 11. EIM Input Timing Diagram
4.9.3.3
Examples of EIM Synchronous Accesses
Table 37. EIM Bus Timing Parameters
ID
Parameter
Min1
Max1
Unit
WE1
WE2
WE3
EIM_BCLK cycle time2
t × (k+1)
—
—
—
ns
ns
ns
EIM_BCLK high level width
EIM_BCLK low level width
0.4 × t × (k+1)
0.4 × t × (k+1)
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Table 37. EIM Bus Timing Parameters (continued)
ID
Parameter
Clock rise to address valid
Min1
Max1
Unit
WE4
WE5
WE6
WE7
WE8
WE9
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
-0.5 × t × (k+1) - 1.25
0.5 × t × (k+1) - 1.25
2.3
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
-0.5 × t × (k+1) + 2.25
0.5 × t × (k+1) + 2.25
—
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Clock rise to address invalid
Clock rise to EIM_CSx_B valid
Clock rise to EIM_CSx_B invalid
Clock rise to EIM_WE_B valid
Clock rise to EIM_WE_B invalid
WE10 Clock rise to EIM_OE_B valid
WE11 Clock rise to EIM_OE_B invalid
WE12 Clock rise to EIM_EBx_B valid
WE13 Clock rise to EIM_EBx_B invalid
WE14 Clock rise to EIM_LBA_B valid
WE15 Clock rise to EIM_LBA_B invalid
WE16 Clock rise to output data valid
WE17 Clock rise to output data invalid
WE18 Input data setup time to clock rise
WE19 Input data hold time from clock rise
WE20 EIM_WAIT_B setup time to clock rise
WE21 EIM_WAIT_B hold time from clock rise
k represents register setting BCD value.
2
—
2
—
2
—
1
2
t is clock period (1/Freq). For 104 MHz, t = 9.165 ns.
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Figure 12 to Figure 15 provide few examples of basic EIM accesses to external memory devices with the
timing parameters mentioned previously for specific control parameters settings.
EIM_BCLK
EIM_ADDRxx
WE5
WE7
WE4
WE6
Address v1
Last Valid Address
WE6
EIM_CSx_B
EIM_WE_B
EIM_LBA_B
EIM_OE_B
WE14
WE15
WE10
WE12
WE11
WE13
EIM_EBx_B
WE18
WE19
D(v1)
EIM_DATAxx
Figure 12. Synchronous Memory Read Access, WSC=1
EIM_BCLK
WE4
WE6
WE5
WE7
WE9
EIM_ADDRxx
Last Valid Address
Address V1
EIM_CSx_B
EIM_WE_B
EIM_LBA_B
EIM_OE_B
WE8
WE14
WE15
WE13
WE17
WE12
WE16
EIM_EBx_B
EIM_DATAxx
D(V1)
Figure 13. Synchronous Memory, Write Access, WSC=1, WBEA=0 and WADVN=0
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EIM_BCLK
WE16
WE17
WE5
WE4
Last Valid Address
WE6
EIM_ADDRxx/
EIM_ADxx
Write Data
Address V1
WE7
WE9
EIM_CSx_B
EIM_WE_B
WE8
WE14
WE15
EIM_LBA_B
EIM_OE_B
WE10
WE11
EIM_EBx_B
Figure 14. Muxed Address/Data (A/D) Mode, Synchronous Write Access,
WSC=6,ADVA=0, ADVN=1, and ADH=1
NOTE
In 32-bit muxed address/data (A/D) mode the 16 MSBs are driven on the
data bus.
EIM_BCLK
WE4
WE5
Address V1
WE19
WE18
EIM_ADDRxx/
EIM_ADxx
Data
Last Valid
Address
WE6
EIM_CSx_B
EIM_WE_B
WE7
WE15
WE10
WE14
WE12
EIM_LBA_B
EIM_OE_B
WE11
WE13
EIM_EBx_B
Figure 15. 16-Bit Muxed A/D Mode, Synchronous Read Access,
WSC=7, RADVN=1, ADH=1, OEA=0
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4.9.3.4
General EIM Timing-Asynchronous Mode
Figure 16 through Figure 20 and Table 38 provide timing parameters relative to the chip select (CS) state
for asynchronous and DTACK EIM accesses with corresponding EIM bit fields and the timing
parameters mentioned above.
Asynchronous read and write access length in cycles may vary from what is shown in Figure 16 through
Figure 19 as RWSC, OEN & CSN is configured differently. See the i.MX 6Dual/6Quad reference manual
(IMX6DQRM) for the EIM programming model.
end of
access
start of
access
INT_CLK
MAXCSO
EIM_CSx_B
WE31
WE32
EIM_ADDRxx/
EIM_ADxx
Next Address
Last Valid Address
Address V1
EIM_WE_B
EIM_LBA_B
WE39
WE40
WE35
WE37
WE36
WE38
EIM_OE_B
EIM_EBx_B
WE44
MAXCO
EIM_DATA[07:00]
D(V1)
WE43
MAXDI
Figure 16. Asynchronous Memory Read Access (RWSC = 5)
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end of
access
start of
access
INT_CLK
MAXCSO
EIM_CSx_B
MAXDI
WE31
EIM_ADDRxx/
EIM_ADxx
D(V1)
Addr. V1
WE44
WE32A
WE40A
WE35A
EIM_WE_B
EIM_LBA_B
WE39
WE37
WE36
WE38
EIM_OE_B
EIM_EBx_B
MAXCO
Figure 17. Asynchronous A/D Muxed Read Access (RWSC = 5)
EIM_CSx_B
WE31
Last Valid Address
WE32
WE34
WE40
EIM_ADDRxx
Next Address
Address V1
WE33
EIM_WE_B
EIM_LBA_B
EIM_OE_B
WE39
WE45
WE41
WE46
EIM_EBx_B
WE42
EIM_DATAxx
D(V1)
Figure 18. Asynchronous Memory Write Access
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EIM_CSx_B
WE41A
WE31
EIM_ADDRxx/
EIM_DATAxx
D(V1)
Addr. V1
WE32A
WE42
WE33
WE39
WE34
EIM_WE_B
WE40A
EIM_LBA_B
EIM_OE_B
WE45
WE46
EIM_EBx_B
Figure 19. Asynchronous A/D Muxed Write Access
EIM_CSx_B
EIM_ADDRxx
WE31
WE32
Next Address
Last Valid Address
Address V1
EIM_WE_B
EIM_LBA_B
EIM_OE_B
EIM_EBx_B
WE39
WE35
WE37
WE40
WE36
WE38
WE44
D(V1)
EIM_DATAxx[07:00]
EIM_DTACK_B
WE43
WE48
WE47
Figure 20. DTACK Mode Read Access (DAP=0)
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EIM_CSx_B
WE31
WE32
WE34
WE40
EIM_ADDRxx
Next Address
Last Valid Address
Address V1
WE33
EIM_WE_B
EIM_LBA_B
EIM_OE_B
EIM_EBx_B
WE39
WE45
WE41
WE46
WE42
WE48
D(V1)
EIM_DATAxx
EIM_DTACK_B
WE47
Figure 21. DTACK Mode Write Access (DAP=0)
1 2
,
Table 38. EIM Asynchronous Timing Parameters Relative to Chip Select
DeterminationbySynchronous
Ref No.
Parameter
Min
Max
Unit
measured parameters
WE31 EIM_CSx_B valid to Address Valid
WE4-WE6-CSA×t
WE7-WE5-CSN× t
-3.5-CSA×t
-3.5-CSN×t
3.5-CSA×t
3.5-CSN×t
ns
ns
WE32 Address Invalid to EIM_CSx_B
Invalid
WE32A EIM_CSx_B valid to Address
(muxed Invalid
A/D)
t+WE4-WE7+
(ADVN+ADVA+1-CSA)×t
t - 3.5+(ADVN+A t + 3.5+(ADVN+ADVA+ ns
DVA+1-CSA)×t 1-CSA)×t
WE33 EIM_CSx_B Valid to EIM_WE_B
Valid
WE8-WE6+(WEA-WCSA)×t -3.5+(WEA-WCS 3.5+(WEA-WCSA)×t
A)×t
ns
ns
ns
WE34 EIM_WE_B Invalid to EIM_CSx_B WE7-WE9+(WEN-WCSN)×t -3.5+(WEN-WCS 3.5+(WEN-WCSN)×t
Invalid
N)×t
WE35 EIM_CSx_B Valid to EIM_OE_B
Valid
WE10- WE6+(OEA-RCSA)×t -3.5+(OEA-RCS 3.5+(OEA-RCSA)×t
A)×t
WE35A EIM_CSx_B Valid to EIM_OE_B WE10-WE6+(OEA+RADVN+R -3.5+(OEA+RAD 3.5+(OEA+RADVN+RA ns
(muxed Valid
A/D)
ADVA+ADH+1-RCSA)×t
VN+RADVA+ADH DVA+ADH+1-RCSA)×t
+1-RCSA)×t
WE36 EIM_OE_B Invalid to EIM_CSx_B WE7-WE11+(OEN-RCSN)×t -3.5+(OEN-RCS 3.5+(OEN-RCSN)×t
Invalid N)×t
ns
WE37 EIM_CSx_B Valid to EIM_EBx_B WE12-WE6+(RBEA-RCSA)× t -3.5+(RBEA- RC 3.5+(RBEA - RCSA)×t ns
Valid (Read access)
SA)×t
WE38 EIM_EBx_B Invalid to
WE7-WE13+(RBEN-RCSN)×t
-3.5+
(RBEN-RCSN)×t
3.5+(RBEN-RCSN)×t ns
EIM_CSx_B Invalid (Read access)
WE39 EIM_CSx_B Valid to EIM_LBA_B WE14-WE6+(ADVA-CSA)×t
-3.5+
(ADVA-CSA)×t
3.5+(ADVA-CSA)×t
ns
Valid
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1 2
,
Table 38. EIM Asynchronous Timing Parameters Relative to Chip Select
(continued)
DeterminationbySynchronous
Ref No.
Parameter
Min
Max
Unit
measured parameters
WE40 EIM_LBA_B Invalid to
EIM_CSx_B Invalid (ADVL is
asserted)
WE7-WE15-CSN×t
-3.5-CSN×t
3.5-CSN×t
ns
WE40A EIM_CSx_B Valid to EIM_LBA_B WE14-WE6+(ADVN+ADVA+1- -3.5+(ADVN+AD
3.5+(ADVN+ADVA
ns
ns
(muxed Invalid
A/D)
CSA)×t
VA+1-CSA)×t
+1-CSA)×t
WE41 EIM_CSx_B Valid to Output Data
Valid
WE16-WE6-WCSA×t
-3.5-WCSA×t
3.5-WCSA×t
WE41A EIM_CSx_B Valid to Output Data WE16-WE6+(WADVN+WADVA -3.5+(WADVN+ 3.5+(WADVN+WADVA ns
(muxed Valid
A/D)
+ADH+1-WCSA)×t
WADVA
+ADH+1-WCSA)
×t
+ADH+1-WCSA)×t
WE42 OutputData InvalidtoEIM_CSx_B
Invalid
WE17-WE7-CSN×t
-3.5-CSN×t
3.5-CSN×t
ns
ns
MAXCO Output maximum delay from
internal driving
10
—
10
EIM_ADDRxx/control flip-flops to
chip outputs.
MAXCSO Output maximum delay from
internal chip selects driving
10
5
—
—
10
5
ns
ns
flip-flops to EIM_CSx_B out.
MAXDI EIM_DATAxx MAXIMUM delay
from chip input data to its internal
flip-flop
WE43 Input Data Valid to EIM_CSx_B
Invalid
MAXCO-MAXCSO+MAXDI MAXCO-MAXCS
O+MAXDI
—
—
ns
ns
WE44 EIM_CSx_B Invalid to Input Data
Invalid
0
0
WE45 EIM_CSx_B Valid to EIM_EBx_B WE12-WE6+(WBEA-WCSA)×t -3.5+(WBEA-WC 3.5+(WBEA-WCSA)×t ns
Valid (Write access)
SA)×t
WE46 EIM_EBx_B Invalid to
WE7-WE13+(WBEN-WCSN)×t -3.5+(WBEN-WC 3.5+(WBEN-WCSN)×t ns
SN)×t
EIM_CSx_B Invalid (Write access)
MAXDTI Maximum delay from
EIM_DTACK_B input to its internal
10
—
10
ns
flip-flop + 2 cycles for
synchronization
WE47 EIM_DTACK_B Active to
EIM_CSx_B Invalid
MAXCO-MAXCSO+MAXDTI MAXCO-MAXCS
O+MAXDTI
—
—
ns
ns
WE48 EIM_CSx_B Invalid to
EIM_DTACK_B invalid
0
0
1
For more information on configuration parameters mentioned in this table, see the i.MX 6Dual/6Quad reference manual
(IMX6DQRM).
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2
In this table:
• t means clock period from axi_clk frequency.
• CSA means register setting for WCSA when in write operations or RCSA when in read operations.
• CSN means register setting for WCSN when in write operations or RCSN when in read operations.
• ADVN means register setting for WADVN when in write operations or RADVN when in read operations.
• ADVA means register setting for WADVA when in write operations or RADVA when in read operations.
4.10 Multi-Mode DDR Controller (MMDC)
The Multi-mode DDR Controller is a dedicated interface to DDR3/DDR3L/LPDDR2 SDRAM.
4.10.1 MMDC Compatibility with JEDEC-Compliant SDRAMs
The i.MX 6Dual/6Quad MMDC supports the following memory types:
•
•
LPDDR2 SDRAM compliant to JESD209-2B LPDDR2 JEDEC standard release June, 2009
DDR3/DDR3L SDRAM compliant to JESD79-3D DDR3 JEDEC standard release April, 2008
MMDC operation with the standards stated above is contingent upon the board DDR design adherence to
the DDR design and layout requirements stated in the Hardware Development Guide for i.MX 6Quad,
6Dual, 6DualLite, 6Solo Families of Applications Processors (IMX6DQ6SDLHDG).
4.10.2 MMDC Supported DDR3/DDR3L/LPDDR2 Configurations
The table below shows the supported DDR3/DDR3L/LPDDR2 configurations:
Table 39. i.MX 6Dual/6Quad Supported DDR3/DDR3L/LPDDR2 Configurations
Parameter
LPDDR2
DDR3
DDR3L
Clock frequency
Bus width
400 MHz
32-bit per channel
Dual
532 MHz
16/32/64-bit
Single
532 MHz
16/32/64-bit
Single
Channel
Chip selects
2 per channel
2
2
4.11 General-Purpose Media Interface (GPMI) Timing
The i.MX 6Dual/6Quad GPMI controller is a flexible interface NAND Flash controller with 8-bit data
width, up to 200 MB/s I/O speed and individual chip select. It supports Asynchronous timing mode, Source
Synchronous timing mode, and Samsung Toggle timing mode separately described in the following
subsections.
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4.11.1 Asynchronous Mode AC Timing (ONFI 1.0 Compatible)
Asynchronous mode AC timings are provided as multiplications of the clock cycle and fixed delay. The
Maximum I/O speed of GPMI in Asynchronous mode is about 50 MB/s. Figure 22 through Figure 25
depict the relative timing between GPMI signals at the module level for different operations under
Asynchronous mode. Table 40 describes the timing parameters (NF1–NF17) that are shown in the figures.
NF2
NF1
.!.$?#,%
NF3
NF4
.!.$?#%ꢀ?"
.!.$?7%?"
NF5
.!.$?!,%
NF6
NF8
Command
NF7
NF9
.!.$?$!4!XX
Figure 22. Command Latch Cycle Timing Diagram
NF1
.!.$?#,%
NF3
.!.$?#%ꢀ?"
.!.$?7%?"
NF10
NF5
NF11
NF7
.!.$?!,%
NF6
NF8
Address
NF9
NAND_DATAxx
Figure 23. Address Latch Cycle Timing Diagram
NF1
.!.$?#,%
.!.$?#%ꢀ?"
.!.$?7%?"
NF3
NF10
NF5
NF11
NF7
NF6
.!.$?!,%
NF8
Data to NF
NF9
.!.$?$!4!XX
Figure 24. Write Data Latch Cycle Timing Diagram
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Electrical Characteristics
.!.$?#,%
.!.$?#%ꢀ?"
.!.$?2%?"
NF14
NF13
NF15
.!.$?2%!$9?"
NF12
NF16
NF17
Data from NF
.!.$?$!4!XX
Figure 25. Read Data Latch Cycle Timing Diagram (Non-EDO Mode)
.!.$?#,%
.!.$?#%ꢀ?"
NF14
NF13
NF15
.!.$?2%?"
.!.$?2%!$9?"
NF12
NF17
NF16
NAND_DATAxx
Data from NF
Figure 26. Read Data Latch Cycle Timing Diagram (EDO Mode)
1
Table 40. Asynchronous Mode Timing Parameters
Timing
T = GPMI Clock Cycle
ID
Parameter
Symbol
Unit
Min
(AS + DS) × T - 0.12 [see 2,3
Max
NF1
NF2
NF3
NF4
NF5
NF6
NF7
NF8
NF9
NAND_CLE setup time
NAND_CLE hold time
NAND_CEx_B setup time
NAND_CEx_B hold time
NAND_WE_B pulse width
NAND_ALE setup time
NAND_ALE hold time
Data setup time
tCLS
tCLH
tCS
]
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
DH × T - 0.72 [see 2]
(AS + DS + 1) × T [see 3,2
(DH+1) × T - 1 [see 2]
DS × T [see 2]
]
tCH
tWP
tALS
tALH
tDS
(AS + DS) × T - 0.49 [see 3,2
(DH × T - 0.42 [see 2]
DS × T - 0.26 [see 2]
DH × T - 1.37 [see 2]
(DS + DH) × T [see 2]
DH × T [see 2]
]
Data hold time
tDH
NF10 Write cycle time
tWC
tWH
tRR4
tRP
NF11 NAND_WE_B hold time
NF12 Ready to NAND_RE_B low
NF13 NAND_RE_B pulse width
NF14 READ cycle time
(AS + 2) × T [see 3,2
]
—
DS × T [see 2]
(DS + DH) × T [see 2]
DH × T [see 2]
tRC
NF15 NAND_RE_B high hold time
tREH
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1
Table 40. Asynchronous Mode Timing Parameters (continued)
Timing
T = GPMI Clock Cycle
ID
Parameter
Symbol
Unit
Min
Max
NF16 Data setup on read
NF17 Data hold on read
tDSR
tDHR
—
(DS × T -0.67)/18.38 [see 5,6
]
ns
ns
0.82/11.83 [see 5,6
]
—
1
The GPMI asynchronous mode output timing can be controlled by the module’s internal registers
HW_GPMI_TIMING0_ADDRESS_SETUP, HW_GPMI_TIMING0_DATA_SETUP, and HW_GPMI_TIMING0_DATA_HOLD.
This AC timing depends on these registers settings. In the table, AS/DS/DH represents each of these settings.
2
3
4
5
6
AS minimum value can be 0, while DS/DH minimum value is 1.
T = GPMI clock period -0.075ns (half of maximum p-p jitter).
NF12 is met automatically by the design.
Non-EDO mode.
EDO mode, GPMI clock ≈ 100 MHz
(AS=DS=DH=1, GPMI_CTL1 [RDN_DELAY] = 8, GPMI_CTL1 [HALF_PERIOD] = 0).
In EDO mode (Figure 26), NF16/NF17 are different from the definition in non-EDO mode (Figure 25).
They are called tREA/tRHOH (NAND_RE_B access time/NAND_RE_B HIGH to output hold). The
typical value for them are 16 ns (max for tREA)/15 ns (min for tRHOH) at 50 MB/s EDO mode. In EDO
mode, GPMI will sample NAND_DATAxx at rising edge of delayed NAND_RE_B provided by an
internal DPLL. The delay value can be controlled by GPMI_CTRL1.RDN_DELAY (see the GPMI chapter
of the i.MX 6Dual/6Quad reference manual (IMX6DQRM)). The typical value of this control register is
0x8 at 50 MT/s EDO mode. However, if the board delay is large enough and cannot be ignored, the delay
value should be made larger to compensate the board delay.
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Electrical Characteristics
4.11.2 Source Synchronous Mode AC Timing (ONFI 2.x Compatible)
Figure 27 shows the write and read timing of Source Synchronous mode.
NF19
NF18
.!.$?#%?"
NF23
NAND_CLE
NF26
NF25
NF24
NAND_ALE
NF25 NF26
NAND_WE/RE_B
NF22
NAND_CLK
NAND_DQS
NAND_DQS
Output enable
NF20
NF20
NF21
NF21
CMD
ADD
NAND_DATA[7:0]
NAND_DATA[7:0]
Output enable
Figure 27. Source Synchronous Mode Command and Address Timing Diagram
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Electrical Characteristics
NF19
NF18
.!.$?#%ꢀ?"
.!.$?#,%
NF23
NF23
NF24
NF24
NF25
NF25
NF26
NF26
.!.$?!,%
NAND_WE/RE_B
NF22
.!.$?#,+
.!.$?$13
NF27
NF27
.!.$?$13
Output enable
NF29
NF29
.!.$?$1;ꢁꢂꢀ=
NF28
NF28
.!.$?$1;ꢁꢂꢀ=
Output enable
Figure 28. Source Synchronous Mode Data Write Timing Diagram
NF18
NF19
.!.$?#%?"
.!.$?#,%
NF24
NF24
NF23
NF23
NF26
NF26
NF25
NF25
NAND_ALE
NF25
.!.$?7%ꢃ2%
NF25
NF22
NF26
.!.$?#,+
.!.$?$13
.!.$?$13
/UTPUT ENABLE
.!.$?$!4!;ꢁꢂꢀ=
.!.$?$!4!;ꢁꢂꢀ=
/UTPUT ENABLE
Figure 29. Source Synchronous Mode Data Read Timing Diagram
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Electrical Characteristics
.!.$?$13
NF30
.!.$?$!4!;ꢁꢂꢀ=
D0
D1
D2
D3
NF30
NF31
NF31
Figure 30. NAND_DQS/NAND_DQ Read Valid Window
1
Table 41. Source Synchronous Mode Timing Parameters
Timing
T = GPMI Clock Cycle
ID
Parameter
Symbol
Unit
Min
Max
2
NF18 NAND_CEx_B access time
tCE
tCH
CE_DELAY × T - 0.79 [see ]
0.5 × tCK - 0.63 [see 2]
0.5 × tCK - 0.05
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
—
—
—
—
NF19 NAND_CEx_B hold time
NF20 Command/address NAND_DATAxx setup time
NF21 Command/address NAND_DATAxx hold time
NF22 clock period
tCAS
tCAH
tCK
0.5 × tCK - 1.23
—
NF23 preamble delay
tPRE
tPOST
tCALS
tCALH
tDQSS
tDS
PRE_DELAY × T - 0.29 [see 2]
POST_DELAY × T - 0.78 [see 2]
0.5 × tCK - 0.86
NF24 postamble delay
NF25 NAND_CLE and NAND_ALE setup time
NF26 NAND_CLE and NAND_ALE hold time
NF27 NAND_CLK to first NAND_DQS latching transition
NF28 Data write setup
0.5 × tCK - 0.37
T - 0.41 [see 2]
0.25 × tCK - 0.35
NF29 Data write hold
tDH
0.25 × tCK - 0.85
NF30 NAND_DQS/NAND_DQ read setup skew
tDQSQ
tQHS
—
—
2.06
1.95
NF31 NAND_DQS/NAND_DQ read hold skew
1
2
The GPMI source synchronous mode output timing can be controlled by the module’s internal registers
GPMI_TIMING2_CE_DELAY,GPMI_TIMING_PREAMBLE_DELAY,GPMI_TIMING2_POST_DELAY.ThisACtimingdepends
on these registers settings. In the table, CE_DELAY/PRE_DELAY/POST_DELAY represents each of these settings.
T = tCK (GPMI clock period) -0.075ns (half of maximum p-p jitter).
Figure 30 shows the timing diagram of NAND_DQS/NAND_DATAxx read valid window. For Source
Synchronous mode, the typical value of tDQSQ is 0.85 ns (max) and 1 ns (max) for tQHS at 200MB/s.
GPMI will sample NAND_DATA[7:0] at both rising and falling edge of a delayed NAND_DQS signal,
which can be provided by an internal DPLL. The delay value can be controlled by GPMI register
GPMI_READ_DDR_DLL_CTRL.SLV_DLY_TARGET (see the GPMI chapter of the i.MX
6Dual/6Quad reference manual (IMX6DQRM)). Generally, the typical delay value of this register is equal
to 0x7 which means 1/4 clock cycle delay expected. However, if the board delay is large enough and cannot
be ignored, the delay value should be made larger to compensate the board delay.
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4.11.3 Samsung Toggle Mode AC Timing
4.11.3.1 Command and Address Timing
Samsung Toggle mode command and address timing is the same as ONFI 1.0 compatible Async mode AC
timing. See Section 4.11.1, “Asynchronous Mode AC Timing (ONFI 1.0 Compatible)” for details.
4.11.3.2 Read and Write Timing
DEV?CLK
ꢀ
.!.$?#%X?"
ꢀ
.!.$?#,%
ꢀ
.!.$?!,%
ꢄ
.!.$?7%?"
ꢄ
.!.$?2%?"
.&ꢇꢉ
.&ꢇꢈ
.!.$?$13
ꢀꢅꢆ T#+
ꢀꢅꢆ T#+
.!.$?$!4!;ꢁꢂꢀ=
Figure 31. Samsung Toggle Mode Data Write Timing
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Electrical Characteristics
DEV?CLK
.!.$?#%X?"
.& ꢄꢊ
.!.$?#,%
.!.$?!,%
ꢄ T #+
ꢄ
.&ꢇꢉ
.!.$?7%?"
.!.$?2%?"
ꢄ T #+
.& ꢇꢈ
ꢄ T #+
ꢄ T #+
ꢄ T #+
.!.$?$13
.!.$?$!4!;ꢁꢂꢀ=
Figure 32. Samsung Toggle Mode Data Read Timing
1
Table 42. Samsung Toggle Mode Timing Parameters
Timing
T = GPMI Clock Cycle
Min
ID
Parameter
Symbol
Unit
Max
NF1 NAND_CLE setup time
NF2 NAND_CLE hold time
NF3 NAND_CEx_B setup time
NF4 NAND_CEx_B hold time
NF5 NAND_WE_B pulse width
NF6 NAND_ALE setup time
NF7 NAND_ALE hold time
tCLS
tCLH
tCS
(AS + DS) × T - 0.12 [see 2,3
DH × T - 0.72 [see 2]
(AS + DS) × T - 0.58 [see 3,2
DH × T - 1 [see 2]
]
—
—
—
—
—
—
—
—
—
ns
ns
ns
ns
]
tCH
tWP
tALS
tALH
DS × T [see 2]
(AS + DS) × T - 0.49 [see 3,2
DH × T - 0.42 [see 2]
DS × T - 0.26 [see 2]
DH × T - 1.37 [see 2]
]
NF8 Command/address NAND_DATAxx setup time tCAS
NF9 Command/address NAND_DATAxx hold time
NF18 NAND_CEx_B access time
NF22 clock period
tCAH
tCE
CE_DELAY × T [see 4,2
]
—
—
—
—
tCK
—
NF23 preamble delay
tPRE
PRE_DELAY × T [see 5,2
]
NF24 postamble delay
tPOST POST_DELAY × T +0.43 [see 2]
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1
Table 42. Samsung Toggle Mode Timing Parameters (continued)
Timing
T = GPMI Clock Cycle
ID
Parameter
Symbol
Unit
Min
Max
NF28 Data write setup
NF29 Data write hold
tDS6
tDH6
tDQSQ7
tQHS7
0.25 × tCK - 0.32
—
—
ns
ns
—
—
0.25 × tCK - 0.79
NF30 NAND_DQS/NAND_DQ read setup skew
NF31 NAND_DQS/NAND_DQ read hold skew
—
—
3.18
3.27
1
The GPMI toggle mode output timing can be controlled by the module’s internal registers
HW_GPMI_TIMING0_ADDRESS_SETUP, HW_GPMI_TIMING0_DATA_SETUP, and HW_GPMI_TIMING0_DATA_HOLD.
This AC timing depends on these registers settings. In the table, AS/DS/DH represents each of these settings.
2
3
4
AS minimum value can be 0, while DS/DH minimum value is 1.
T = tCK (GPMI clock period) -0.075ns (half of maximum p-p jitter).
CE_DELAY represents HW_GPMI_TIMING2[CE_DELAY]. NF18 is met automatically by the design. Read/Write operation is
started with enough time of ALE/CLE assertion to low level.
5
6
7
PRE_DELAY+1) ≥ (AS+DS).
Shown in Figure 28.
Shown in Figure 29.
Figure 30 shows the timing diagram of NAND_DQS/NAND_DATAxx read valid window. For DDR
Toggle mode, the typical value of tDQSQ is 1.4 ns (max) and 1.4 ns (max) for tQHS at 133 MB/s. GPMI
will sample NAND_DATA[7:0] at both rising and falling edge of a delayed NAND_DQS signal, which is
provided by an internal DPLL. The delay value of this register can be controlled by GPMI register
GPMI_READ_DDR_DLL_CTRL.SLV_DLY_TARGET (see the GPMI chapter of the i.MX
6Dual/6Quad reference manual (IMX6DQRM)). Generally, the typical delay value is equal to 0x7 which
means 1/4 clock cycle delay expected. However, if the board delay is large enough and cannot be ignored,
the delay value should be made larger to compensate the board delay.
4.12 External Peripheral Interface Parameters
The following subsections provide information on external peripheral interfaces.
4.12.1 AUDMUX Timing Parameters
The AUDMUX provides a programmable interconnect logic for voice, audio, and data routing between
internal serial interfaces (SSIs) and external serial interfaces (audio and voice codecs). The AC timing of
AUDMUX external pins is governed by the SSI module. For more information, see the respective SSI
electrical specifications found within this document.
4.12.2 ECSPI Timing Parameters
This section describes the timing parameters of the ECSPI block. The ECSPI has separate timing
parameters for master and slave modes.
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4.12.2.1 ECSPI Master Mode Timing
Figure 33 depicts the timing of ECSPI in master mode and Table 43 lists the ECSPI master mode timing
characteristics.
ECSPIx_RDY_B
CS10
ECSPIx_SS_B
CS5
CS6
CS2
CS1
CS3
CS4
ECSPIx_SCLK
ECSPIx_MOSI
CS2
CS7
CS3
CS9
CS8
ECSPIx_MISO
Note: ECSPIx_MOSI is always driven (not tri-stated) between actual data transmissions. This limits the ECSPI to be
connected between a single master and a single slave.
Figure 33. ECSPI Master Mode Timing Diagram
Table 43. ECSPI Master Mode Timing Parameters
ID
Parameter
Symbol
Min
Max Unit
CS1
ECSPIx_SCLK Cycle Time–Read
• Slow group1
tclk
—
ns
55
40
15
• Fast group2
ECSPIx_SCLK Cycle Time–Write
CS2
ECSPIx_SCLK High or Low Time–Read
• Slow group1
tSW
—
ns
26
20
7
• Fast group2
ECSPIx_SCLK High or Low Time–Write
CS3
CS4
CS5
CS6
CS7
CS8
ECSPIx_SCLK Rise or Fall3
tRISE/FALL
tCSLH
—
—
—
—
—
1
ns
ns
ns
ns
ns
ns
ECSPIx_SSx pulse width
Half ECSPIx_SCLK period
Half ECSPIx_SCLK period - 4
Half ECSPIx_SCLK period - 2
-1
ECSPIx_SSx Lead Time (CS setup time)
ECSPIx_SSx Lag Time (CS hold time)
ECSPIx_MOSI Propagation Delay (CLOAD = 20 pF)
tSCS
tHCS
tPDmosi
tSmiso
ECSPIx_MISO Setup Time
• Slow group1
—
21.5
16
• Fast group2
CS9
ECSPIx_MISO Hold Time
tHmiso
tSDRY
0
5
—
—
ns
ns
CS10 ECSPIx_RDY to ECSPIx_SSx Time4
1
2
ECSPI slow includes:
ECSPI1/DISP0_DAT22, ECSPI1/KEY_COL1, ECSPI1/CSI0_DAT6,
ECSPI2/EIM_OE, ECSPI2/ ECSPI2/CSI0_DAT10, ECSPI3/DISP0_DAT2
ECSPI fast includes:
ECSPI1/EIM_D17, ECSPI4/EIM_D22, ECSPI5/SD2_DAT0, ECSPI5/SD1_DAT0
See specific I/O AC parameters Section 4.7, “I/O AC Parameters.”
3
4
ECSPI_RDY is sampled internally by ipg_clk and is asynchronous to all other CSPI signals.
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4.12.2.2 ECSPI Slave Mode Timing
Figure 34 depicts the timing of ECSPI in slave mode and Table 44 lists the ECSPI slave mode timing
characteristics.
ECSPIx_SS_B
CS5
CS6
CS2
CS1
CS4
ECSPIx_SCLK
ECSPIx_MISO
CS2
CS9
CS8
CS7
ECSPIx_MOSI
Note: ECSPIx_MISO is always driven (not tri-stated) between actual data transmissions. This limits the ECSPI to be con-
nected between a single master and a single slave.
Figure 34. ECSPI Slave Mode Timing Diagram
Table 44. ECSPI Slave Mode Timing Parameters
ID
Parameter
Symbol
Min
Max Unit
CS1
ECSPIx_SCLK Cycle Time–Read
• Slow group1
tclk
—
ns
55
40
15
• Fast group2
ECSPIx_SCLK Cycle Time–Write
CS2
ECSPIx_SCLK High or Low Time–Read
• Slow group1
tSW
—
ns
26
20
7
• Fast group2
ECSPIx_SCLK High or Low Time–Write
CS4
CS5
CS6
CS7
CS8
CS9
ECSPIx_SSx pulse width
tCSLH
tSCS
Half ECSPIx_SCLK period
—
—
—
—
—
ns
ns
ns
ns
ns
ns
ECSPIx_SSx Lead Time (CS setup time)
ECSPIx_SSx Lag Time (CS hold time)
ECSPIx_MOSI Setup Time
5
5
4
4
4
tHCS
tSmosi
tHmosi
tPDmiso
ECSPIx_MOSI Hold Time
ECSPIx_MISO Propagation Delay (CLOAD = 20 pF)
• Slow group1
• Fast group2
25
17
1
2
ECSPI slow includes:
ECSPI1/DISP0_DAT22, ECSPI1/KEY_COL1, ECSPI1/CSI0_DAT6,
ECSPI2/EIM_OE, ECSPI2/DISP0_DAT17, ECSPI2/CSI0_DAT10, ECSPI3/DISP0_DAT2
ECSPI fast includes:
ECSPI1/EIM_D17, ECSPI4/EIM_D22, ECSPI5/SD2_DAT0, ECSPI5/SD1_DAT0
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4.12.3 Enhanced Serial Audio Interface (ESAI) Timing Parameters
The ESAI consists of independent transmitter and receiver sections, each section with its own clock
generator. Table 45 shows the interface timing values. The number field in the table refers to timing
signals found in Figure 35 and Figure 36.
Table 45. Enhanced Serial Audio Interface (ESAI) Timing
ID
Parameter1,2
Symbol Expression2 Min
Max Condition3 Unit
62 Clock cycle4
tSSICC
4 × T
4 × T
30.0
30.0
—
—
i ck
i ck
ns
c
c
63 Clock high period:
• For internal clock
• For external clock
ns
—
—
2 × T − 9.0
6
15
—
—
—
—
c
2 × T
c
64 Clock low period:
• For internal clock
• For external clock
ns
—
—
2 × T − 9.0
6
15
—
—
—
—
c
2 × T
c
65 ESAI_RX_CLK rising edge to ESAI_RX_FS out (bl) high
—
—
—
—
—
—
19.0
7.0
x ck
i ck a
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
66 ESAI_RX_CLK rising edge to ESAI_RX_FS out (bl) low
—
—
—
—
—
—
19.0
7.0
x ck
i ck a
67 ESAI_RX_CLK rising edge to ESAI_RX_FS out (wr)
high5
—
—
—
—
—
—
19.0
9.0
x ck
i ck a
68 ESAI_RX_CLK rising edge to ESAI_RX_FS out (wr) low5
69 ESAI_RX_CLK rising edge to ESAI_RX_FS out (wl) high
70 ESAI_RX_CLK rising edge to ESAI_RX_FSout (wl) low
—
—
—
—
—
—
19.0
9.0
x ck
i ck a
—
—
—
—
—
—
19.0
6.0
x ck
i ck a
—
—
—
—
—
—
17.0
7.0
x ck
i ck a
71 Data in setup time before ESAI_RX_CLK (serial clock in
synchronous mode) falling edge
—
—
—
—
12.0
19.0
—
—
x ck
i ck
72 Data in hold time after ESAI_RX_CLK falling edge
—
—
—
—
3.5
9.0
—
—
x ck
i ck
73 ESAI_RX_FS input (bl, wr) high before ESAI_RX_CLK
falling edge5
—
—
—
—
2.0
19.0
—
—
x ck
i ck a
74 ESAI_RX_FS input (wl) high before ESAI_RX_CLK
falling edge
—
—
—
—
2.0
19.0
—
—
x ck
i ck a
75 ESAI_RX_FS input hold time after ESAI_RX_CLK falling
edge
—
—
—
—
2.5
8.5
—
—
x ck
i ck a
78 ESAI_TX_CLK rising edge to ESAI_TX_FS out (bl) high
—
—
—
—
—
—
19.0
8.0
x ck
i ck
79 ESAI_TX_CLK rising edge to ESAI_TX_FS out (bl) low
—
—
—
—
—
—
20.0
10.0
x ck
i ck
80 ESAI_TX_CLK rising edge to ESAI_TX_FS out (wr)
high5
—
—
—
—
—
—
20.0
10.0
x ck
i ck
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Table 45. Enhanced Serial Audio Interface (ESAI) Timing (continued)
Parameter1,2 Symbol Expression2 Min Max Condition3 Unit
ID
81 ESAI_TX_CLK rising edge to ESAI_TX_FS out (wr) low5
82 ESAI_TX_CLK rising edge to ESAI_TX_FS out (wl) high
83 ESAI_TX_CLK rising edge to ESAI_TX_FS out (wl) low
—
—
—
—
—
—
22.0
12.0
x ck
i ck
ns
ns
ns
ns
ns
ns
ns
ns
ns
—
—
—
—
—
—
19.0
9.0
x ck
i ck
—
—
—
—
—
—
20.0
10.0
x ck
i ck
84 ESAI_TX_CLK rising edge to data out enable from high
impedance
—
—
—
—
—
—
22.0
17.0
x ck
i ck
86 ESAI_TX_CLK rising edge to data out valid
—
—
—
—
—
—
19.0
13.0
x ck
i ck
87 ESAI_TX_CLK rising edge to data out high impedance 67
—
—
—
—
—
—
21.0
16.0
x ck
i ck
89 ESAI_TX_FS input (bl, wr) setup time before
ESAI_TX_CLK falling edge5
—
—
—
—
2.0
18.0
—
—
x ck
i ck
90 ESAI_TX_FS input (wl) setup time before ESAI_TX_CLK
falling edge
—
—
—
—
2.0
18.0
—
—
x ck
i ck
91 ESAI_TX_FS input hold time after ESAI_TX_CLK falling
edge
—
—
—
—
4.0
5.0
—
—
x ck
i ck
95 ESAI_RX_HF_CLK/ESAI_TX_HF_CLK clock cycle
—
—
2 x TC
—
15
—
—
—
—
ns
ns
96 ESAI_TX_HF_CLK input rising edge to ESAI_TX_CLK
output
18.0
97 ESAI_RX_HF_CLK input rising edge to ESAI_RX_CLK
output
—
—
—
18.0
—
ns
1
i ck = internal clock
x ck = external clock
i ck a = internal clock, asynchronous mode
(asynchronous implies that ESAI_TX_CLK and ESAI_RX_CLK are two different clocks)
i ck s = internal clock, synchronous mode
(synchronous implies that ESAI_TX_CLK and ESAI_RX_CLK are the same clock)
2
3
bl = bit length
wl = word length
wr = word length relative
ESAI_TX_CLK(ESAI_TX_CLK pin) = transmit clock
ESAI_RX_CLK(ESAI_RX_CLK pin) = receive clock
ESAI_TX_FS(ESAI_TX_FS pin) = transmit frame sync
ESAI_RX_FS(ESAI_RX_FS pin) = receive frame sync
ESAI_TX_HF_CLK(ESAI_TX_HF_CLK pin) = transmit high frequency clock
ESAI_RX_HF_CLK(ESAI_RX_HF_CLK pin) = receive high frequency clock
4
5
For the internal clock, the external clock cycle is defined by Icyc and the ESAI control register.
The word-relative frame sync signal waveform relative to the clock operates in the same manner as the bit-length frame sync
signal waveform, but it spreads from one serial clock before the first bit clock (like the bit length frame sync signal), until the
second-to-last bit clock of the first word in the frame.
6
Periodically sampled and not 100% tested.
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62
63
64
ESAI_TX_CLK
(Input/Output)
78
79
ESAI_TX_FS
(Bit)
Out
82
83
ESAI_TX_FS
(Word)
Out
86
84
86
87
First Bit
Last Bit
Data Out
89
91
ESAI_TX_FS
(Bit) In
91
90
ESAI_TX_FS
(Word) In
Figure 35. ESAI Transmitter Timing
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62
63
64
ESAI_RX_CLK
(Input/Output)
65
66
ESAI_RX_FS
(Bit) Out
69
70
ESAI_RX_FS
(Word) Out
72
71
Data In
Last Bit
First Bit
75
73
ESAI_RX_FS
(Bit) In
74
75
ESAI_RX_FS
(Word) In
Figure 36. ESAI Receiver Timing
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4.12.4 Ultra High Speed SD/SDIO/MMC Host Interface (uSDHC)
AC Timing
This section describes the electrical information of the uSDHC, which includes SD/eMMC4.3 (Single
Data Rate) timing and eMMC4.4/4.1 (Dual Date Rate) timing.
4.12.4.1 SD/eMMC4.3 (Single Data Rate) AC Timing
Figure 37 depicts the timing of SD/eMMC4.3, and Table 46 lists the SD/eMMC4.3 timing characteristics.
SD4
SD2
SD1
SD5
SDx_CLK
SD3
SD6
Output from uSDHC to card
SDx_DATA[7:0]
SD7
SD8
Input from card to uSDHC
SDx_DATA[7:0]
Figure 37. SD/eMMC4.3 Timing
Table 46. SD/eMMC4.3 Interface Timing Specification
ID
Parameter
Symbols
Min
Max
Unit
Card Input Clock
1
SD1
Clock Frequency (Low Speed)
fPP
0
0
400
25/50
20/52
400
—
kHz
MHz
MHz
kHz
ns
2
Clock Frequency (SD/SDIO Full Speed/High Speed)
Clock Frequency (MMC Full Speed/High Speed)
Clock Frequency (Identification Mode)
Clock Low Time
fPP
3
fPP
0
fOD
tWL
100
7
SD2
SD3
SD4
SD5
Clock High Time
tWH
tTLH
tTHL
7
—
ns
Clock Rise Time
—
—
3
ns
Clock Fall Time
3
ns
eSDHC Output/Card Inputs SD_CMD, SD_DATAx (Reference to SDx_CLK)
eSDHC Output Delay tOD –6.6
SD6
3.6
ns
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Table 46. SD/eMMC4.3 Interface Timing Specification (continued)
Parameter Symbols Min
eSDHC Input/Card Outputs SD_CMD, SD_DATAx (Reference to SDx_CLK)
ID
Max
Unit
SD7
SD8
eSDHC Input Setup Time
eSDHC Input Hold Time4
tISU
tIH
2.5
1.5
—
—
ns
ns
1
2
In low speed mode, card clock must be lower than 400 kHz, voltage ranges from 2.7 to 3.6 V.
In normal (full) speed mode for SD/SDIO card, clock frequency can be any value between 0–25 MHz. In high-speed mode,
clock frequency can be any value between 0–50 MHz.
3
In normal (full) speed mode for MMC card, clock frequency can be any value between 0–20 MHz. In high-speed mode, clock
frequency can be any value between 0–52 MHz.
4To satisfy hold timing, the delay difference between clock input and cmd/data input must not exceed 2 ns.
4.12.4.2 eMMC4.4/4.41 (Dual Data Rate) eSDHCv3 AC Timing
Figure 38 depicts the timing of eMMC4.4/4.41. Table 47 lists the eMMC4.4/4.41 timing characteristics.
Be aware that only SDx_DATAx is sampled on both edges of the clock (not applicable to SD_CMD).
SD1
SDx_CLK
SD2
SD2
Output from eSDHCv3 to card
SDx_DATA[7:0]
......
......
SD3
SD4
Input from card to eSDHCv3
SDx_DATA[7:0]
Figure 38. eMMC4.4/4.41 Timing
Table 47. eMMC4.4/4.41 Interface Timing Specification
ID
Parameter
Symbols
Card Input Clock1
fPP
fPP
Min
Max
Unit
SD1
SD1
Clock Frequency (EMMC4.4 DDR)
Clock Frequency (SD3.0 DDR)
0
0
52
50
MHz
MHz
uSDHC Output / Card Inputs SD_CMD, SD_DATAx (Reference to SD_CLK)
uSDHC Output Delay tOD 2.8 6.8
uSDHC Input / Card Outputs SD_CMD, SD_DATAx (Reference to SD_CLK)
SD2
ns
SD3
SD4
uSDHC Input Setup Time
uSDHC Input Hold Time
tISU
tIH
1.7
1.5
—
—
ns
ns
1
Clock duty cycle will be in the range of 47% to 53%.
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4.12.4.3 SDR50/SDR104 AC Timing
Figure 39 depicts the timing of SDR50/SDR104, and Table 48 lists the SDR50/SDR104 timing
characteristics.
SD1
SD2
SD3
SCK
SD5
SD4
Output from uSDHC to card
SD7
SD6
Input from card to uSDHC
SD8
Figure 39. SDR50/SDR104 Timing
Table 48. SDR50/SDR104 Interface Timing Specification
ID
Parameter
Symbols
Min
Max
Unit
Card Input Clock
SD1 Clock Frequency Period
SD2 Clock Low Time
tCLK
tCL
4.8
—
ns
ns
ns
0.46 × tCLK
0.46 × tCLK
0.54 × tCLK
0.54 × tCLK
SD3 Clock High Time
tCH
uSDHC Output/Card Inputs SD_CMD, SDx_DATAx in SDR50 (Reference to SDx_CLK)
SD4 uSDHC Output Delay tOD –3
uSDHC Output/Card Inputs SD_CMD, SDx_DATAx in SDR104 (Reference to SDx_CLK)
uSDHC Output Delay tOD –1.6 0.74
uSDHC Input/Card Outputs SD_CMD, SDx_DATAx in SDR50 (Reference to SDx_CLK)
1
ns
ns
SD5
uSDHC Input Setup Time
uSDHC Input Hold Time
tISU
tIH
2.5
1.5
—
—
ns
ns
SD6
SD7
uSDHC Input/Card Outputs SD_CMD, SDx_DATAx in SDR104 (Reference to SDx_CLK)1
Card Output Data Window tODW 0.5 × tCLK
—
ns
SD8
1Data window in SDR100 mode is variable.
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4.12.4.4 Bus Operation Condition for 3.3 V and 1.8 V Signaling
Signaling level of SD/eMMC4.3 and eMMC4.4/4.41 modes is 3.3 V. Signaling level of SDR104/SDR50
mode is 1.8 V. The DC parameters for the NVCC_SD1, NVCC_SD2, and NVCC_SD3 supplies are
identical to those shown in Table 21, “GPIO I/O DC Parameters,” on page 37.
4.12.5 Ethernet Controller (ENET) AC Electrical Specifications
4.12.5.1 ENET MII Mode Timing
This subsection describes MII receive, transmit, asynchronous inputs, and serial management signal
timings.
4.12.5.1.1 MII Receive Signal Timing (ENET_RX_DATA3,2,1,0, ENET_RX_EN,
ENET_RX_ER, and ENET_RX_CLK)
The receiver functions correctly up to an ENET_RX_CLK maximum frequency of 25 MHz + 1ꢀ. There
is no minimum frequency requirement. Additionally, the processor clock frequency must exceed twice the
ENET_RX_CLK frequency.
Figure 40 shows MII receive signal timings. Table 49 describes the timing parameters (M1–M4) shown in
the figure.
M3
ENET_RX_CLK (input)
M4
ENET_RX_DATA3,2,1,0
(inputs)
ENET_RX_EN
ENET_RX_ER
M1
M2
Figure 40. MII Receive Signal Timing Diagram
Table 49. MII Receive Signal Timing
ID
Characteristic1
Min
Max
Unit
M1
M2
ENET_RX_DATA3,2,1,0, ENET_RX_EN, ENET_RX_ER to
ENET_RX_CLK setup
5
—
ns
ENET_RX_CLK to ENET_RX_DATA3,2,1,0, ENET_RX_EN,
ENET_RX_ER hold
5
—
ns
M3
M4
ENET_RX_CLK pulse width high
ENET_RX_CLK pulse width low
35%
35%
65%
65%
ENET_RX_CLK period
ENET_RX_CLK period
1 ENET_RX_EN, ENET_RX_CLK, and ENET0_RXD0 have the same timing in 10 Mbps 7-wire interface mode.
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4.12.5.1.2 MII Transmit Signal Timing
(ENET_TX_DATA3,2,1,0, ENET_TX_EN, ENET_TX_ER, and ENET_TX_CLK)
The transmitter functions correctly up to an ENET_TX_CLK maximum frequency of 25 MHz + 1ꢀ.
There is no minimum frequency requirement. Additionally, the processor clock frequency must exceed
twice the ENET_TX_CLK frequency.
Figure 41 shows MII transmit signal timings. Table 50 describes the timing parameters (M5–M8) shown
in the figure.
M7
ENET_TX_CLK (input)
M5
M8
ENET_TX_DATA3,2,1,0
(outputs)
ENET_TX_EN
ENET_TX_ER
M6
Figure 41. MII Transmit Signal Timing Diagram
Table 50. MII Transmit Signal Timing
ID
Characteristic1
Min
Max
Unit
M5
M6
ENET_TX_CLK to ENET_TX_DATA3,2,1,0, ENET_TX_EN,
ENET_TX_ER invalid
5
—
ns
ENET_TX_CLK to ENET_TX_DATA3,2,1,0, ENET_TX_EN,
ENET_TX_ER valid
—
20
ns
M7
M8
ENET_TX_CLK pulse width high
ENET_TX_CLK pulse width low
35%
35%
65%
65%
ENET_TX_CLK period
ENET_TX_CLK period
1 ENET_TX_EN, ENET_TX_CLK, and ENET0_TXD0 have the same timing in 10-Mbps 7-wire interface mode.
4.12.5.1.3 MII Asynchronous Inputs Signal Timing (ENET_CRS and ENET_COL)
Figure 42 shows MII asynchronous input timings. Table 51 describes the timing parameter (M9) shown in
the figure.
ENET_CRS, ENET_COL
M9
Figure 42. MII Async Inputs Timing Diagram
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Table 51. MII Asynchronous Inputs Signal Timing
ID
M91
Characteristic
Min
Max
Unit
ENET_CRS to ENET_COL minimum pulse width
1.5
—
ENET_TX_CLK period
1 ENET_COL has the same timing in 10-Mbit 7-wire interface mode.
4.12.5.1.4 MII Serial Management Channel Timing (ENET_MDIO and ENET_MDC)
The MDC frequency is designed to be equal to or less than 2.5 MHz to be compatible with the IEEE 802.3
MII specification. However the ENET can function correctly with a maximum MDC frequency of
15 MHz.
Figure 43 shows MII asynchronous input timings. Table 52 describes the timing parameters (M10–M15)
shown in the figure.
M14
M15
ENET_MDC (output)
M10
ENET_MDIO (output)
M11
ENET_MDIO (input)
M12
M13
Figure 43. MII Serial Management Channel Timing Diagram
Table 52. MII Serial Management Channel Timing
ID
M10
Characteristic
Min
Max
Unit
ENET_MDC falling edge to ENET_MDIO output invalid
(minimum propagation delay)
0
—
ns
M11
ENET_MDC falling edge to ENET_MDIO output valid
(maximum propagation delay)
—
5
ns
M12
M13
M14
M15
ENET_MDIO (input) to ENET_MDC rising edge setup
ENET_MDIO (input) to ENET_MDC rising edge hold
ENET_MDC pulse width high
18
0
—
—
ns
ns
40%
40%
60%
60%
ENET_MDC period
ENET_MDC period
ENET_MDC pulse width low
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4.12.5.2 RMII Mode Timing
In RMII mode, ENET_CLK is used as the REF_CLK, which is a 50 MHz 50 ppm continuous reference
clock. ENET_RX_EN is used as the ENET_RX_EN in RMII. Other signals under RMII mode include
ENET_TX_EN, ENET0_TXD[1:0], ENET_RXD[1:0] and ENET_RX_ER.
Figure 44 shows RMII mode timings. Table 53 describes the timing parameters (M16–M21) shown in the
figure.
M16
M17
ENET_CLK (input)
M18
ENET0_TXD[1:0] (output)
ENET_TX_EN
M19
ENET_RX_EN (input)
ENET_RXD[1:0]
ENET_RX_ER
M20
M21
Figure 44. RMII Mode Signal Timing Diagram
Table 53. RMII Signal Timing
ID
M16
Characteristic
Min
Max
Unit
ENET_CLK pulse width high
ENET_CLK pulse width low
35%
35%
4
65%
65%
—
ENET_CLK period
M17
M18
M19
M20
ENET_CLK period
ENET_CLK to ENET0_TXD[1:0], ENET_TX_EN invalid
ENET_CLK to ENET0_TXD[1:0], ENET_TX_EN valid
ns
ns
ns
—
13.5
—
ENET_RXD[1:0], ENET_RX_EN(ENET_RX_EN), ENET_RX_ER to
ENET_CLK setup
4
M21
ENET_CLK to ENET_RXD[1:0], ENET_RX_EN, ENET_RX_ER hold
2
—
ns
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Electrical Characteristics
4.12.5.3 RGMII Signal Switching Specifications
The following timing specifications meet the requirements for RGMII interfaces for a range of transceiver
devices.
1
Table 54. RGMII Signal Switching Specifications
Symbol
Description
Min
Max
Unit
2
Tcyc
Clock cycle duration
7.2
-100
1
8.8
900
2.6
55
ns
ps
ns
%
3
TskewT
Data to clock output skew at transmitter
Data to clock input skew at receiver
3
TskewR
Duty_G4 Duty cycle for Gigabit
Duty_T4 Duty cycle for 10/100T
45
40
60
%
Tr/Tf
Rise/fall time (20–80%)
—
0.75
ns
1
The timings assume the following configuration:
DDR_SEL = (11)b
DSE (drive-strength) = (111)b
2
3
For 10 Mbps and 100 Mbps, Tcyc will scale to 400 ns 40 ns and 40 ns 4 ns respectively.
For all versions of RGMII prior to 2.0; This implies that PC board design will require clocks to be routed such that an additional
delay of greater than 1.2 ns and less than 1.7 ns will be added to the associated clock signal. For 10/100, the max value is
unspecified.
4
Duty cycle may be stretched/shrunk during speed changes or while transitioning to a received packet's clock domain as long
as minimum duty cycle is not violated and stretching occurs for no more than three Tcyc of the lowest speed transitioned
between.
Figure 45. RGMII Transmit Signal Timing Diagram Original
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Figure 46. RGMII Receive Signal Timing Diagram Original
Figure 47. RGMII Receive Signal Timing Diagram with Internal Delay
4.12.6 Flexible Controller Area Network (FlexCAN) AC Electrical
Specifications
The Flexible Controller Area Network (FlexCAN) module is a communication controller implementing
the CAN protocol according to the CAN 2.0B protocol specification.The processor has two CAN modules
available for systems design. Tx and Rx ports for both modules are multiplexed with other I/O pins. See
the IOMUXC chapter of the i.MX 6Dual/6Quad reference manual (IMX6DQRM) to see which pins
expose Tx and Rx pins; these ports are named FLEXCAN_TX and FLEXCAN_RX, respectively.
4.12.7 HDMI Module Timing Parameters
4.12.7.1 Latencies and Timing Information
Power-up time (time between TX_PWRON assertion and TX_READY assertion) for the HDMI 3D Tx
PHY while operating with the slowest input reference clock supported (13.5 MHz) is 3.35 ms.
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Power-up time for the HDMI 3D Tx PHY while operating with the fastest input reference clock supported
(340 MHz) is 133 μs.
4.12.7.2 Electrical Characteristics
The table below provides electrical characteristics for the HDMI 3D Tx PHY. The following three figures
illustrate various definitions and measurement conditions specified in the table below.
Figure 48. Driver Measuring Conditions
Figure 49. Driver Definitions
Figure 50. Source Termination
Table 55. Electrical Characteristics
Symbol
Parameter
Condition
Min
Typ
Max
Unit
Operating conditions for HDMI
avddtmds Termination supply voltage
—
3.15
3.3
3.45
V
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Table 55. Electrical Characteristics (continued)
Symbol
Parameter
Condition
—
Min
45
Typ
Max
Unit
RT
Termination resistance
50
55
Ω
TMDS drivers DC specifications
VOFF
Single-ended standby voltage
RT = 50 Ω
avddtmds 10 mV
mV
mV
For measurement conditions and
definitions, see the first two figures
above.
VSWING Single-ended output swing voltage
400
—
600
Compliance point TP1 as defined in
the HDMI specification, version 1.3a,
section 4.2.4.
VH
Single-ended output high voltage If attached sink supports TMDSCLK <
avddtmds 10 mV
mV
mV
mV
mV
Ω
For definition, see the second
figure above.
or = 165 MHz
If attached sink supports TMDSCLK > avddtmds
—
—
—
—
avddtmds
+ 10 mV
165 MHz – 200 mV
VL
Single-ended output low voltage
For definition, see the second
figure above.
If attached sink supports TMDSCLK < avddtmds
or = 165 MHz – 600 mV
avddtmds
– 400mV
If attached sink supports TMDSCLK > avddtmds
avddtmds
– 400 mV
165 MHz
– 700 mV
RTERM Differential source termination load
(inside HDMI 3D Tx PHY)
—
50
200
Although the HDMI 3D Tx PHY
includes differential source
termination, the user-defined value
is set for each single line (for
illustration, see the third figure
above).
Note: RTERM can also be
configured to be open and not
present on TMDS channels.
Hot plug detect specifications
HPDVH Hot plug detect high range
VHPD
—
—
—
—
2.0
0
—
—
—
—
5.3
0.8
—
V
V
Hot plug detect low range
VL
HPD
Hot plug detect input impedance
10
—
kΩ
µs
Z
HPD
Hot plug detect time delay
100
t
4.12.8 Switching Characteristics
Table 56 describes switching characteristics for the HDMI 3D Tx PHY. Figure 51 to Figure 55 illustrate
various parameters specified in table.
NOTE
All dynamic parameters related to the TMDS line drivers’ performance
imply the use of assembly guidelines.
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P
TMDSCLK
50%
t
t
CPL
CPH
Figure 51. TMDS Clock Signal Definitions
Figure 52. Eye Diagram Mask Definition for HDMI Driver Signal Specification at TP1
Figure 53. Intra-Pair Skew Definition
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Figure 54. Inter-Pair Skew Definition
Figure 55. TMDS Output Signals Rise and Fall Time Definition
Table 56. Switching Characteristics
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
TMDS Drivers Specifications
—
—
Maximum serial data rate
TMDSCLK frequency
TMDSCLK period
—
25
—
—
—
3.4
340
40
Gbps
MHz
ns
F
P
On TMDSCLKP/N outputs
TMDSCLK
TMDSCLK
RL = 50 Ω
See Figure 51.
2.94
t
t
= t
/ P
TMDSCLK duty cycle
40
50
60
%
CDC
CDC
CPH
TMDSCLK
RL = 50 Ω
See Figure 51.
t
TMDSCLK high time
TMDSCLK low time
RL = 50 Ω
4
4
5
5
6
6
UI
UI
CPH
See Figure 51.
t
RL = 50 Ω
See Figure 51.
CPL
—
TMDSCLK jitter1
RL = 50 Ω
—
—
—
—
0.25
0.15
UI
UI
t
Intra-pair (pulse) skew
RL = 50 Ω
See Figure 53.
SK(p)
t
Inter-pair skew
RL = 50 Ω
—
—
—
1
UI
ps
SK(pp)
See Figure 54.
tR
Differential output signal rise
time
20–80%
RL = 50 Ω
See Figure 55.
75
0.4 UI
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Table 56. Switching Characteristics (continued)
Parameter Conditions Min
Symbol
Typ
Max
Unit
tF
Differential output signal fall time 20–80%
75
—
0.4 UI
ps
RL = 50 Ω
See Figure 55.
—
—
Differential signal overshoot
Differential signal undershoot
Referred to 2x VSWING
Referred to 2x VSWING
—
—
—
—
15
25
%
%
Data and Control Interface Specifications
2
tPower-up
HDMI 3D Tx PHY power-up time From power-down to
—
—
3.35
ms
HSI_TX_READY assertion
Relative to ideal recovery clock, as specified in the HDMI specification, version 1.4a, section 4.2.3.
For information about latencies and associated timings, see Section 4.12.7.1, “Latencies and Timing Information.”
1
2
4.12.9 I2C Module Timing Parameters
2
2
This section describes the timing parameters of the I C module. Figure 56 depicts the timing of I C
2
module, and Table 57 lists the I C module timing characteristics.
I2Cx_SDA
I2Cx_SCL
IC11
IC9
IC10
IC7
IC4
IC2
IC3
IC8
IC10
IC6
IC11
STOP
START
START
START
IC5
IC1
2
Figure 56. I C Bus Timing
2
Table 57. I C Module Timing Parameters
Standard Mode
Fast Mode
ID
Parameter
Unit
Min
Max
Min
Max
IC1
IC2
IC3
IC4
IC5
IC6
IC7
IC8
I2Cx_SCL cycle time
10
4.0
4.0
01
—
—
2.5
0.6
0.6
01
—
—
—
µs
µs
µs
Hold time (repeated) START condition
Set-up time for STOP condition
Data hold time
—
3.452
—
0.92 µs
HIGH Period of I2Cx_SCL Clock
LOW Period of the I2Cx_SCL Clock
Set-up time for a repeated START condition
Data set-up time
4.0
4.7
4.7
250
0.6
1.3
0.6
1003
—
—
—
—
µs
µs
µs
ns
—
—
—
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2
Table 57. I C Module Timing Parameters (continued)
Standard Mode
Parameter
Fast Mode
ID
Unit
Min
Max
Min
Max
IC9
Bus free time between a STOP and START condition
4.7
—
—
—
—
1.3
—
µs
4
IC10
IC11
IC12
Rise time of both I2Cx_SDA and I2Cx_SCL signals
Fall time of both I2Cx_SDA and I2Cx_SCL signals
Capacitive load for each bus line (Cb)
1000
300
400
20 + 0.1Cb 300 ns
4
20 + 0.1Cb 300 ns
—
400 pF
1
A device must internally provide a hold time of at least 300 ns for I2Cx_SDA signal to bridge the undefined region of the falling
edge of I2Cx_SCL.
2
3
The maximum hold time has only to be met if the device does not stretch the LOW period (ID no IC5) of the I2Cx_SCL signal.
A Fast-mode I2C-bus device can be used in a Standard-mode I2C-bus system, but the requirement of Set-up time (ID No IC7)
of 250 ns must be met. This automatically is the case if the device does not stretch the LOW period of the I2Cx_SCL signal.
If such a device does stretch the LOW period of the I2Cx_SCL signal, it must output the next data bit to the I2Cx_SDA line
max_rise_time (IC9) + data_setup_time (IC7) = 1000 + 250 = 1250 ns (according to the Standard-mode I2C-bus specification)
before the I2Cx_SCL line is released.
4
Cb = total capacitance of one bus line in pF.
4.12.10 Image Processing Unit (IPU) Module Parameters
The purpose of the IPU is to provide comprehensive support for the flow of data from an image sensor
and/or to a display device. This support covers all aspects of these activities:
•
•
Connectivity to relevant devices—cameras, displays, graphics accelerators, and TV encoders.
Related image processing and manipulation: sensor image signal processing, display processing,
image conversions, and other related functions.
•
Synchronization and control capabilities, such as avoidance of tearing artifacts.
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4.12.10.1 IPU Sensor Interface Signal Mapping
The IPU supports a number of sensor input formats. Table 58 defines the mapping of the Sensor Interface
Pins used for various supported interface formats.
Table 58. Camera Input Signal Cross Reference, Format, and Bits Per Cycle
RGB565
8 bits
2 cycles
RGB5652
8 bits
3 cycles
RGB6663 RGB888
YCbCr4 RGB5655 YCbCr6
YCbCr7
16 bits
1 cycle
YCbCr8
20 bits
1 cycle
Signal
Name1
8 bits
8 bits
8 bits
16 bits
1 cycle
16 bits
1 cycle
3 cycles
3 cycles 2 cycles
IPUx_CSIx_
DATA00
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
0
C[0]
C[1]
C[2]
C[3]
C[4]
C[5]
C[6]
C[7]
C[8]
C[9]
Y[0]
Y[1]
Y[2]
Y[3]
Y[4]
Y[5]
Y[6]
Y[7]
Y[8]
Y[9]
IPUx_CSIx_
DATA01
—
—
0
IPUx_CSIx_
DATA02
—
—
—
—
C[0]
C[1]
C[2]
C[3]
C[4]
C[5]
C[6]
C[7]
0
IPUx_CSIx_
DATA03
—
—
—
—
IPUx_CSIx_
DATA04
—
—
B[0]
B[1]
B[2]
B[3]
B[4]
G[0]
G[1]
G[2]
G[3]
G[4]
G[5]
R[0]
R[1]
R[2]
R[3]
R[4]
C[0]
C[1]
C[2]
C[3]
C[4]
C[5]
C[6]
C[7]
Y[0]
Y[1]
Y[2]
Y[3]
Y[4]
Y[5]
Y[6]
Y[7]
IPU2_CSIx_
DATA_05
—
—
IPUx_CSIx_
DATA06
—
—
IPUx_CSIx_
DATA07
—
—
IPUx_CSIx_
DATA08
—
—
IPUx_CSIx_
DATA09
—
—
IPUx_CSIx_
DATA10
—
—
IPUx_CSIx_
DATA11
—
—
0
IPUx_CSIx_
DATA12
B[0], G[3] R[2],G[4],B[2] R/G/B[4]
B[1], G[4] R[3],G[5],B[3] R/G/B[5]
B[2], G[5] R[4],G[0],B[4] R/G/B[0]
B[3], R[0] R[0],G[1],B[0] R/G/B[1]
B[4], R[1] R[1],G[2],B[1] R/G/B[2]
G[0], R[2] R[2],G[3],B[2] R/G/B[3]
G[1], R[3] R[3],G[4],B[3] R/G/B[4]
G[2], R[4] R[4],G[5],B[4] R/G/B[5]
R/G/B[0]
R/G/B[1]
R/G/B[2]
R/G/B[3]
R/G/B[4]
R/G/B[5]
R/G/B[6]
R/G/B[7]
Y/C[0]
Y/C[1]
Y/C[2]
Y/C[3]
Y/C[4]
Y/C[5]
Y/C[6]
Y/C[7]
Y[0]
Y[1]
Y[2]
Y[3]
Y[4]
Y[5]
Y[6]
Y[7]
IPUx_CSIx_
DATA13
IPUx_CSIx_
DATA14
IPUx_CSIx_
DATA15
IPUx_CSIx_
DATA16
IPUx_CSIx_
DATA17
IPUx_CSIx_
DATA18
IPUx_CSIx_
DATA19
1
IPU2_CSIx stands for IPU2_CSI1 or IPU2_CSI2.
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2
The MSB bits are duplicated on LSB bits implementing color extension.
3
The two MSB bits are duplicated on LSB bits implementing color extension.
4
YCbCr, 8 bits—Supported within the BT.656 protocol (sync embedded within the data stream).
5
RGB, 16 bits—Supported in two ways: (1) As a “generic data” input—with no on-the-fly processing; (2) With on-the-fly
processing, but only under some restrictions on the control protocol.
6
YCbCr, 16 bits—Supported as a “generic-data” input—with no on-the-fly processing.
7
YCbCr, 16 bits—Supported as a sub-case of the YCbCr, 20 bits, under the same conditions (BT.1120 protocol).
8
YCbCr, 20 bits—Supported only within the BT.1120 protocol (syncs embedded within the data stream).
4.12.10.2 Sensor Interface Timings
There are three camera timing modes supported by the IPU.
4.12.10.2.1 BT.656 and BT.1120 Video Mode
Smart camera sensors, which include imaging processing, usually support video mode transfer. They use
an embedded timing syntax to replace the IPU2_CSIx_VSYNC and IPU2_CSIx_HSYNC signals. The
timing syntax is defined by the BT.656/BT.1120 standards.
This operation mode follows the recommendations of ITU BT.656/ ITU BT.1120 specifications. The only
control signal used is IPU2_CSIx_PIX_CLK. Start-of-frame and active-line signals are embedded in the
data stream. An active line starts with a SAV code and ends with a EAV code. In some cases, digital
blanking is inserted in between EAV and SAV code. The CSI decodes and filters out the timing-coding
from the data stream, thus recovering IPU2_CSIx_VSYNC and IPU2_CSIx_HSYNC signals for internal
use. On BT.656 one component per cycle is received over the IPU2_CSIx_DATA_EN bus. On BT.1120
two components per cycle are received over the IPU2_CSIx_DATA_EN bus.
4.12.10.2.2 Gated Clock Mode
The IPU2_CSIx_VSYNC, IPU2_CSIx_HSYNC, and IPU2_CSIx_PIX_CLK signals are used in this
mode. See Figure 57.
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Figure 57. Gated Clock Mode Timing Diagram
A frame starts with a rising edge on IPU2_CSIx_VSYNC (all the timings correspond to straight polarity
of the corresponding signals). Then IPU2_CSIx_HSYNC goes to high and hold for the entire line. Pixel
clock is valid as long as IPU2_CSIx_HSYNC is high. Data is latched at the rising edge of the valid pixel
clocks. IPU2_CSIx_HSYNC goes to low at the end of line. Pixel clocks then become invalid and the CSI
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stops receiving data from the stream. For the next line, the IPU2_CSIx_HSYNC timing repeats. For the
next frame, the IPU2_CSIx_VSYNC timing repeats.
4.12.10.2.3 Non-Gated Clock Mode
The timing is the same as the gated-clock mode (described in Section 4.12.10.2.2, “Gated Clock Mode,”)
except for the IPU2_CSIx_HSYNC signal, which is not used (see Figure 58). All incoming pixel clocks
are valid and cause data to be latched into the input FIFO. The IPU2_CSIx_PIX_CLK signal is inactive
(states low) until valid data is going to be transmitted over the bus.
Start of Frame
nth frame
n+1th frame
IPU2_CSIx_VSYNC
IPU2_CSIx_PIX_CLK
invalid
invalid
IPU2_CSIx_DATA_EN[19:0]
1st byte
1st byte
Figure 58. Non-Gated Clock Mode Timing Diagram
The timing described in Figure 58 is that of a typical sensor. Some other sensors may have a slightly
different timing. The CSI can be programmed to support rising/falling-edge triggered
IPU2_CSIx_VSYNC; active-high/low IPU2_CSIx_HSYNC; and rising/falling-edge triggered
IPU2_CSIx_PIX_CLK.
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4.12.10.3 Electrical Characteristics
Figure 59 depicts the sensor interface timing. IPU2_CSIx_PIX_CLK signal described here is not
generated by the IPU. Table 59 lists the sensor interface timing characteristics.
IPUx_CSIx_PIX_CLK
(Sensor Output)
1/IP1
IP2
IP3
IPUx_CSIx_DATA_EN,
IPUx_CSIx_VSYNC,
IPUx_CSIx_HSYNC
Figure 59. Sensor Interface Timing Diagram
Table 59. Sensor Interface Timing Characteristics
ID
Parameter
Symbol
Min
Max
Unit
IP1
IP2
IP3
—
Sensor output (pixel) clock frequency
Data and control setup time
Data and control holdup time
Vsync to Hsync
Fpck
Tsu
0.01
2
180
—
MHz
ns
Thd
1
—
ns
Tv-h
Tpulse
Tv-d
1/Fpck
1/Fpck
1/Fpck
—
ns
—
Vsync and Hsync pulse width
Vsync to first data
—
ns
—
—
ns
4.12.10.4 IPU Display Interface Signal Mapping
The IPU supports a number of display output video formats. Table 60 defines the mapping of the Display
Interface Pins used during various supported video interface formats.
Table 60. Video Signal Cross-Reference
i.MX 6Dual/6Quad
LCD
RGB/TV Signal Allocation (Example)
Comment1,2
RGB,
Signal
Name
Port Name
(x = 0, 1)
16-bit 18-bit 24 Bit
8-bit
16-bit 20-bit
RGB RGB RGB YCrCb3 YCrCb YCrCb
(General)
IPUx_DISPx_DAT00
IPUx_DISPx_DAT01
IPUx_DISPx_DAT02
IPUx_DISPx_DAT03
IPUx_DISPx_DAT04
DAT[0]
DAT[1]
DAT[2]
DAT[3]
DAT[4]
B[0]
B[1]
B[2]
B[3]
B[4]
B[0]
B[1]
B[2]
B[3]
B[4]
B[0]
B[1]
B[2]
B[3]
B[4]
Y/C[0]
Y/C[1]
Y/C[2]
Y/C[3]
Y/C[4]
C[0]
C[1]
C[2]
C[3]
C[4]
C[0]
C[1]
C[2]
C[3]
C[4]
—
—
—
—
—
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Table 60. Video Signal Cross-Reference (continued)
LCD
i.MX 6Dual/6Quad
RGB/TV Signal Allocation (Example)
RGB,
Comment1,2
Port Name
(x = 0, 1)
Signal
Name
(General)
16-bit 18-bit 24 Bit
8-bit
16-bit 20-bit
RGB RGB RGB YCrCb3 YCrCb YCrCb
IPUx_DISPx_DAT05
IPUx_DISPx_DAT06
IPUx_DISPx_DAT07
IPUx_DISPx_DAT08
IPUx_DISPx_DAT09
IPUx_DISPx_DAT10
IPUx_DISPx_DAT11
IPUx_DISPx_DAT12
IPUx_DISPx_DAT13
IPUx_DISPx_DAT14
IPUx_DISPx_DAT15
IPUx_DISPx_DAT16
IPUx_DISPx_DAT17
IPUx_DISPx_DAT18
IPUx_DISPx_DAT19
IPUx_DISPx_DAT20
IPUx_DISPx_DAT21
IPUx_DISPx_DAT22
IPUx_DISPx_DAT23
IPUx_DIx_DISP_CLK
DAT[5]
DAT[6]
G[0]
G[1]
G[2]
G[3]
G[4]
G[5]
R[0]
R[1]
R[2]
R[3]
R[4]
—
B[5]
G[0]
G[1]
G[2]
G[3]
G[4]
G[5]
R[0]
R[1]
R[2]
R[3]
R[4]
R[5]
—
B[5]
B[6]
Y/C[5]
Y/C[6]
Y/C[7]
—
C[5]
C[6]
C[7]
Y[0]
Y[1]
Y[2]
Y[3]
Y[4]
Y[5]
Y[6]
Y[7]
—
C[5]
C[6]
C[7]
C[8]
C[9]
Y[0]
Y[1]
Y[2]
Y[3]
Y[4]
Y[5]
Y[6]
Y[7]
Y[8]
Y[9]
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
DAT[7]
B[7]
DAT[8]
G[0]
G[1]
G[2]
G[3]
G[4]
G[5]
G[6]
G[7]
R[0]
R[1]
R[2]
R[3]
R[4]
R[5]
R[6]
R[7]
PixCLK
DAT[9]
—
DAT[10]
DAT[11]
DAT[12]
DAT[13]
DAT[14]
DAT[15]
DAT[16]
DAT[17]
DAT[18]
DAT[19]
DAT[20]
DAT[21]
DAT[22]
DAT[23]
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
IPUx_DIx_PIN01
IPUx_DIx_PIN02
IPUx_DIx_PIN03
—
May be required for anti-tearing
HSYNC
VSYNC
—
VSYNC out
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Table 60. Video Signal Cross-Reference (continued)
LCD
RGB/TV Signal Allocation (Example)
RGB,
Comment1,2
Port Name
(x = 0, 1)
Signal
Name
(General)
16-bit 18-bit 24 Bit
8-bit
16-bit 20-bit
RGB RGB RGB YCrCb3 YCrCb YCrCb
IPUx_DIx_PIN04
IPUx_DIx_PIN05
IPUx_DIx_PIN06
IPUx_DIx_PIN07
IPUx_DIx_PIN08
IPUx_DIx_D0_CS
IPUx_DIx_D1_CS
—
—
—
—
—
—
—
Additional frame/row synchronous
signals with programmable timing
—
Alternate mode of PWM output for
contrast or brightness control
IPUx_DIx_PIN11
IPUx_DIx_PIN12
IPUx_DIx_PIN13
IPUx_DIx_PIN14
IPUx_DIx_PIN15
IPUx_DIx_PIN16
IPUx_DIx_PIN17
—
—
—
—
—
Register select signal
Optional RS2
—
DRDY/DV
Data validation/blank, data enable
—
Q
Additional data synchronous
signals with programmable
features/timing
1
Signal mapping (both data and control/synchronization) is flexible. The table provides examples.
2
Restrictions for ports IPUx_DISPx_DAT00 through IPUx_DISPx_DAT23 are as follows:
• A maximum of three continuous groups of bits can be independently mapped to the external bus. Groups must not overlap.
• The bit order is expressed in each of the bit groups, for example, B[0] = least significant blue pixel bit.
This mode works in compliance with recommendation ITU-R BT.656. The timing reference signals (frame start, frame end, line
start, and line end) are embedded in the 8-bit data bus. Only video data is supported, transmission of non-video related data
during blanking intervals is not supported.
3
NOTE
Table 60 provides information for both the DISP0 and DISP1 ports.
However, DISP1 port has reduced pinout depending on IOMUXC
configuration and therefore may not support all configurations. See the
IOMUXC table for details.
4.12.10.5 IPU Display Interface Timing
The IPU Display Interface supports two kinds of display accesses: synchronous and asynchronous. There
are two groups of external interface pins to provide synchronous and asynchronous controls.
4.12.10.5.1 Synchronous Controls
The synchronous control changes its value as a function of a system or of an external clock. This control
has a permanent period and a permanent waveform.
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There are special physical outputs to provide synchronous controls:
•
The ipp_disp_clk is a dedicated base synchronous signal that is used to generate a base display
(component, pixel) clock for a display.
•
The ipp_pin_1– ipp_pin_7 are general purpose synchronous pins, that can be used to provide
HSYNC, VSYNC, DRDY or any else independent signal to a display.
The IPU has a system of internal binding counters for internal events (such as, HSYNC/VSYNC)
calculation. The internal event (local start point) is synchronized with internal DI_CLK. A suitable control
starts from the local start point with predefined UP and DOWN values to calculate control’s changing
points with half DI_CLK resolution. A full description of the counter system can be found in the IPU
chapter of the i.MX 6Dual/6Quad reference manual (IMX6DQRM).
4.12.10.5.2 Asynchronous Controls
The asynchronous control is a data-oriented signal that changes its value with an output data according to
additional internal flags coming with the data.
There are special physical outputs to provide asynchronous controls, as follows:
•
•
The ipp_d0_cs and ipp_d1_cs pins are dedicated to provide chip select signals to two displays.
The ipp_pin_11– ipp_pin_17 are general purpose asynchronous pins, that can be used to provide
WR. RD, RS or any other data-oriented signal to display.
NOTE
The IPU has independent signal generators for asynchronous signals
toggling. When a DI decides to put a new asynchronous data on the bus, a
new internal start (local start point) is generated. The signal generators
calculate predefined UP and DOWN values to change pins states with half
DI_CLK resolution.
4.12.10.6 Synchronous Interfaces to Standard Active Matrix TFT LCD Panels
4.12.10.6.1 IPU Display Operating Signals
The IPU uses four control signals and data to operate a standard synchronous interface:
•
•
•
•
IPP_DISP_CLK—Clock to display
HSYNC—Horizontal synchronization
VSYNC—Vertical synchronization
DRDY—Active data
All synchronous display controls are generated on the base of an internally generated “local start point”.
The synchronous display controls can be placed on time axis with DI’s offset, up and down parameters.
The display access can be whole number of DI clock (Tdiclk) only. The IPP_DATA can not be moved
relative to the local start point. The data bus of the synchronous interface is output direction only.
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4.12.10.6.2 LCD Interface Functional Description
Figure 60 depicts the LCD interface timing for a generic active matrix color TFT panel. In this figure,
signals are shown with negative polarity. The sequence of events for active matrix interface timing is:
•
•
DI_CLK internal DI clock is used for calculation of other controls.
IPP_DISP_CLK latches data into the panel on its negative edge (when positive polarity is selected).
In active mode, IPP_DISP_CLK runs continuously.
•
•
HSYNC causes the panel to start a new line. (Usually IPUx_DIx_PIN02 is used as HSYNC.)
VSYNC causes the panel to start a new frame. It always encompasses at least one HSYNC pulse.
(Usually IPUx_DIx_PIN03 is used as VSYNC.)
•
DRDY acts like an output enable signal to the CRT display. This output enables the data to be
shifted onto the display. When disabled, the data is invalid and the trace is off.
(DRDY can be used either synchronous or asynchronous generic purpose pin as well.)
VSYNC
HSYNC
LINE 1
LINE 2
LINE 3
LINE 4
LINE n-1 LINE n
HSYNC
DRDY
1
2
3
m–1
m
IPP_DISP_CLK
IPP_DATA
Figure 60. Interface Timing Diagram for TFT (Active Matrix) Panels
4.12.10.6.3 TFT Panel Sync Pulse Timing Diagrams
Figure 61 depicts the horizontal timing (timing of one line), including both the horizontal sync pulse and
the data. All the parameters shown in the figure are programmable. All controls are started by
corresponding internal events—local start points. The timing diagrams correspond to inverse polarity of
the IPP_DISP_CLK signal and active-low polarity of the HSYNC, VSYNC, and DRDY signals.
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IP13o
IP7
IP5
IP5o
IP8o
IP8
DI clock
IPP_DISP_CLK
VSYNC
HSYNC
DRDY
IPP_DATA
Dn
D0
D1
IP9o
IP10
IP9
IP6
Figure 61. TFT Panels Timing Diagram—Horizontal Sync Pulse
Figure 62 depicts the vertical timing (timing of one frame). All parameters shown in the figure are
programmable.
End of frame
Start of frame
IP13
VSYNC
HSYNC
DRDY
IP15
IP14
IP12
Figure 62. TFT Panels Timing Diagram—Vertical Sync Pulse
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Table 61 shows timing characteristics of signals presented in Figure 61 and Figure 62.
Table 61. Synchronous Display Interface Timing Characteristics (Pixel Level)
ID
Parameter
Symbol
Value
Description
Unit
IP5
IP6
Display interface clock period Tdicp
Display pixel clock period
(see1)
Display interface clock IPP_DISP_CLK
ns
ns
Tdpcp DISP_CLK_PER_PIXEL Time of translation of one pixel to display,
× Tdicp
DISP_CLK_PER_PIXEL—number of pixel
components in one pixel (1.n).
The DISP_CLK_PER_PIXEL is virtual
parameter to define display pixel clock
period.
TheDISP_CLK_PER_PIXELisreceivedby
DC/DI one access division to n
components.
IP7
Screen width time
Tsw
(SCREEN_WIDTH)
SCREEN_WIDTH—screen width in,
interface clocks. horizontal blanking
included.
ns
× Tdicp
The SCREEN_WIDTH should be built by
suitable DI’s counter2.
IP8
IP9
HSYNC width time
Thsw
Thbi1
(HSYNC_WIDTH)
HSYNC_WIDTH—Hsync width in DI_CLK
with 0.5 DI_CLK resolution. Defined by DI’s
counter.
ns
ns
Horizontal blank interval 1
BGXP × Tdicp
BGXP—width of a horizontal blanking
before a first active data in a line (in
interface clocks). The BGXP should be built
by suitable DI’s counter.
IP10 Horizontal blank interval 2
IP12 Screen height
Thbi2
Tsh
(SCREEN_WIDTH –
BGXP – FW) × Tdicp
Width a horizontal blanking after a last
active data in a line (in interface clocks)
FW—with of active line in interface clocks.
The FW should be built by suitable DI’s
counter.
ns
(SCREEN_HEIGHT)
SCREEN_HEIGHT—screen heightin lines ns
with blanking.
The SCREEN_HEIGHT is a distance
between 2 VSYNCs.
× Tsw
The SCREEN_HEIGHT should be built by
suitable DI’s counter.
IP13 VSYNC width
Tvsw
Tvbi1
Tvbi2
VSYNC_WIDTH
VSYNC_WIDTH—Vsync width in DI_CLK
with 0.5 DI_CLK resolution. Defined by DI’s
counter.
ns
ns
IP14 Vertical blank interval 1
IP15 Vertical blank interval 2
BGYP × Tsw
BGYP—width of first Vertical
blanking interval in line. The BGYP should
be built by suitable DI’s counter.
(SCREEN_HEIGHT –
BGYP – FH) × Tsw
Width of second vertical blanking interval in ns
line. The FH should be built by suitable DI’s
counter.
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Table 61. Synchronous Display Interface Timing Characteristics (Pixel Level) (continued)
ID
Parameter
Symbol
Value
Description
Unit
IP5o Offset of IPP_DISP_CLK
Todicp
DISP_CLK_OFFSET—offset of
IPP_DISP_CLK edges from local start
point, in DI_CLK×2
ns
DISP_×CLTKd_icOlkFFSET
(0.5 DI_CLK Resolution).
Defined by DISP_CLK counter.
IP13o Offset of VSYNC
Tovs
Tohs
VSYNC_OFFSET
VSYNC_OFFSET—offset of Vsync edges
from a local start point, when a Vsync
should be active, in DI_CLK×2
(0.5 DI_CLK Resolution). The
VSYNC_OFFSET should be built by
suitable DI’s counter.
ns
ns
ns
× Tdiclk
IP8o Offset of HSYNC
IP9o Offset of DRDY
HSYNC_OFFSET
HSYNC_OFFSET—offset of Hsync edges
from a local start point, when a Hsync
should be active, in DI_CLK×2
(0.5 DI_CLK Resolution). The
HSYNC_OFFSET should be built by
suitable DI’s counter.
× Tdiclk
Todrdy
DRDY_OFFSET
DRDY_OFFSET—offset of DRDY edges
from a suitable local start point, when a
corresponding data has been set on the
bus, in DI_CLK×2
× Tdiclk
(0.5 DI_CLK Resolution).
The DRDY_OFFSET should be built by
suitable DI’s counter.
1
Display interface clock period immediate value.
DISP_CLK_PERIOD
----------------------------------------------------
DISP_CLK_PERIOD
DI_CLK_PERIOD
T
×
,
for integer ----------------------------------------------------
diclk
DI_CLK_PERIOD
Tdicp =
DISP_CLK_PERIOD
----------------------------------------------------
+ 0.5 0.5 , for fractional ----------------------------------------------------
DISP_CLK_PERIOD
DI_CLK_PERIOD
T
floor
diclk
DI_CLK_PERIOD
DISP_CLK_PERIOD—number of DI_CLK per one Tdicp. Resolution 1/16 of DI_CLK.
DI_CLK_PERIOD—relation of between programing clock frequency and current system clock frequency
Display interface clock period average value.
DISP_CLK_PERIOD
----------------------------------------------------
Tdicp = T
×
DI_CLK_PERIOD
diclk
2
DI’s counter can define offset, period and UP/DOWN characteristic of output signal according to programed parameters of the
counter. Same of parameters in the table are not defined by DI’s registers directly (by name), but can be generated by
corresponding DI’s counter. The SCREEN_WIDTH is an input value for DI’s HSYNC generation counter. The distance between
HSYNCs is a SCREEN_WIDTH.
The maximum accuracy of UP/DOWN edge of controls is:
Accuracy = (0.5 × T
) 0.62ns
diclk
The maximum accuracy of UP/DOWN edge of IPP_DISP_DATA is:
Accuracy = T
diclk
0.62ns
The DISP_CLK_PERIOD, DI_CLK_PERIOD parameters are register-controlled.
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Figure 63 depicts the synchronous display interface timing for access level. The DISP_CLK_DOWN and
DISP_CLK_UP parameters are register-controlled. Table 62 lists the synchronous display interface timing
characteristics.
IP20o IP20
VSYNC
HSYNC
DRDY
other controls
IPP_DISP_CLK
Tdicd
Tdicu
IP18
IPP_DATA
IP16
IP17
IP19
local start point
Figure 63. Synchronous Display Interface Timing Diagram—Access Level
Table 62. Synchronous Display Interface Timing Characteristics (Access Level)
ID
Parameter
Symbol
Min
Typ1
Max
Unit
IP16
Display interface clock low Tckl
time
Tdicd-Tdicu-1.24
Tdicd2-Tdicu3
Tdicd-Tdicu+1.24
ns
IP17
Display interface clock
high time
Tckh
Tdicp-Tdicd+Tdicu-1.24 Tdicp-Tdicd+Tdicu Tdicp-Tdicd+Tdicu+1.2
ns
IP18
IP19
IP20o
Data setup time
Data holdup time
Tdsu
Tdhd
Tocsu
Tdicd-1.24
Tdicu
—
—
ns
ns
ns
Tdicp-Tdicd-1.24
Tocsu-1.24
Tdicp-Tdicu
Tocsu
Control signals offset
times (defined for each
pin)
Tocsu+1.24
IP20
Control signals setup time Tcsu
to display interface clock
(defined for each pin)
Tdicd-1.24-Tocsu%Tdicp Tdicu
—
ns
1The exact conditions have not been finalized, but will likely match the current customer requirement for their specific display.
These conditions may be chip specific.
2
Display interface clock down time
2 × DISP_CLK_DOWN
1
2
-----------------------------------------------------------
Tdicd = -- T
diclk
× ceil
DI_CLK_PERIOD
3
Display interface clock up time where CEIL(X) rounds the elements of X to the nearest integers towards infinity.
2 × DISP_CLK_UP
1
2
------------------------------------------------
Tdicu = -- T
diclk
× ceil
DI_CLK_PERIOD
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4.12.11 LVDS Display Bridge (LDB) Module Parameters
The LVDS interface complies with TIA/EIA 644-A standard. For more details, see TIA/EIA STANDARD
644-A, “Electrical Characteristics of Low Voltage Differential Signaling (LVDS) Interface Circuits.”
Table 63. LVDS Display Bridge (LDB) Electrical Specification
Parameter
Symbol
Test Condition
100 Ω Differential load
Min
Max
Units
Differential Voltage Output Voltage
Output Voltage High
VOD
Voh
250
450
1.6
mV
V
100 Ω differential load
(0 V Diff—Output High Voltage static)
1.25
Output Voltage Low
Offset Static Voltage
Vol
100 Ω differential load
0.9
1.25
V
V
(0 V Diff—Output Low Voltage static)
VOS
Two 49.9 Ω resistors in series between N-P
terminal, with output in either Zero or One state, the
voltage measured between the 2 resistors.
1.15
1.375
VOS Differential
VOSDIFF Difference in VOS between a One and a Zero state
ISA ISB With the output common shorted to GND
-50
-24
247
50
24
mV
mA
mV
Output short-circuited to GND
VT Full Load Test
VTLoad 100 Ω Differential load with a 3.74 kΩ load between
454
GND and I/O supply voltage
4.12.12 MIPI D-PHY Timing Parameters
This section describes MIPI D-PHY electrical specifications, compliant with MIPI CSI-2 version 1.0,
D-PHY specification Rev. 1.0 (for MIPI sensor port x4 lanes) and MIPI DSI Version 1.01, and D-PHY
specification Rev. 1.0 (and also DPI version 2.0, DBI version 2.0, DSC version 1.0a at protocol layer) (for
MIPI display port x2 lanes).
4.12.12.1 Electrical and Timing Information
Table 64. Electrical and Timing Information
Symbol
Parameters
Test Conditions
Min Typ
Max Unit
Input DC Specifications—Apply to DSI_CLK_P/_N and DSI_DATA_P/_N Inputs
VI
Input signal voltage range
Input leakage current
Transient voltage range is limited from -300
mV to 1600 mV
-50
-10
—
—
1350 mV
VLEAK
VGNDSH(min) = VI = VGNDSH(max) +
VOH(absmax)
10
mA
Lane module in LP Receive Mode
VGNDSH
Ground Shift
—
—
-50
—
—
—
50
mV
V
VOH(absmax)
Maximum transient output
voltage level
1.45
tvoh(absmax)
Maximum transient time
above VOH(absmax)
—
—
—
20
ns
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Symbol
Table 64. Electrical and Timing Information (continued)
Parameters
Test Conditions
Min Typ
Max Unit
HS Line Drivers DC Specifications
|VOD
|
HS Transmit Differential
output voltage magnitude
80 Ω<= RL< = 125 Ω
140
—
200
—
270
10
mV
mV
Δ|VOD
|
Change in Differential output
voltage magnitude between
logic states
80 Ω<= RL< = 125 Ω
VCMTX
Steady-state common-mode
output voltage.
80 Ω<= RL< = 125 Ω
80 Ω<= RL< = 125 Ω
150
—
200
—
250
5
mV
mV
ΔVCMTX(1,0)
Changes in steady-state
common-mode output voltage
between logic states
VOHHS
ZOS
HS output high voltage
80 Ω<= RL< = 125 Ω
—
—
360
mV
Single-ended output
impedance.
—
40
50
62.5
Ω
ΔZOS
Single-ended output
impedance mismatch.
—
—
—
10
%
LP Line Drivers DC Specifications
VOL
Output low-level SE voltage
—
—
—
-50
1.1
50
1.3
—
mV
V
VOH
ZOLP
Output high-level SE voltage
1.2
—
Single-ended output
impedance.
110
Ω
ΔZOLP(01-10)
Single-ended output
impedance mismatch driving
opposite level
—
—
—
—
—
—
20
5
%
%
ΔZOLP(0-11)
Single-ended output
impedance mismatch driving
same level
HS Line Receiver DC Specifications
VIDTH
VIDTL
VIHHS
VILHS
Differential input high voltage
threshold
—
—
—
—
—
-70
—
—
—
—
—
70
—
mV
mV
mV
mV
Differential input low voltage
threshold
Single ended input high
voltage
460
—
Single ended input low
voltage
-40
VCMRXDC
ZID
Input common mode voltage
Differential input impedance
—
—
70
80
—
—
330
125
mV
Ω
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Table 64. Electrical and Timing Information (continued)
Symbol
Parameters
Test Conditions
Min Typ
Max Unit
LP Line Receiver DC Specifications
VIL
VIH
Input low voltage
—
—
—
—
920
25
—
—
—
550
—
mV
mV
mV
Input high voltage
Input hysteresis
VHYST
—
Contention Line Receiver DC Specifications
VILF
Input low fault threshold
—
200
—
450
mV
4.12.12.2 D-PHY Signaling Levels
The signal levels are different for differential HS mode and single-ended LP mode. Figure 64 shows both
the HS and LP signal levels on the left and right sides, respectively. The HS signaling levels are below
the LP low-level input threshold such that LP receiver always detects low on HS signals.
VOH,MAX
LP
VOL
VOH,MIN
VIH
LP
VIH
LP Threshold
Region
VIL
VOHHS
Max VOD
VCMTX,MAX
LP VIL
HS Vout
Range
HS Vcm
Range
VGNDSH,MA
VCMTX,MIN
VOLHS
Min VOD
X
LP VOL
GND
VGNDSH,MIN
HS Differential Signaling
LP Single-ended Signaling
Figure 64. D-PHY Signaling Levels
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4.12.12.3 HS Line Driver Characteristics
Ideal Single-Ended High Speed Signals
VDN
VCMTX = (VDP + VDN)/2
VOD(0)
VOD(1)
VDP
Ideal Differential High Speed Signals
VOD(1)
0V
(Differential)
VOD(0)
VOD = VDP - VDN
Figure 65. Ideal Single-ended and Resulting Differential HS Signals
4.12.12.4 Possible ΔVCMTX and ΔVOD Distortions of the Single-ended HS Signals
VOD/2
Δ
V
OD (SE HS Signals)
Δ
VDN
VOD (1)
VCM TX
VOD(0)
VDP
V
Δ
OD /2
Static VCMTX (SE HS Signals)
Δ
VDN
VCMTX
VDP
VOD(0)
Dynamic VCMTX (SE HS Signals)
Δ
VDN
VCM TX
VDP
Figure 66. Possible ΔVCMTX and ΔVOD Distortions of the Single-ended HS Signals
4.12.12.5 D-PHY Switching Characteristics
Table 65. Electrical and Timing Information
Symbol
Parameters
Test Conditions
Min
Typ
Max
Unit
HS Line Drivers AC Specifications
—
Maximum serial data rate (forward
direction)
On DATAP/N outputs.
80 Ω <= RL <= 125 Ω
80
—
1000
Mbps
FDDRCLK
PDDRCLK
DDR CLK frequency
DDR CLK period
On DATAP/N outputs.
40
2
—
—
500
25
MHz
ns
80 Ω <= RL< = 125 Ω
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Table 65. Electrical and Timing Information (continued)
Symbol
tCDC
Parameters
DDR CLK duty cycle
Test Conditions
Min
Typ
Max
Unit
tCDC = tCPH / PDDRCLK
—
—
50
1
—
—
%
UI
tCPH
DDR CLK high time
—
tCPL
DDR CLK low time
—
—
1
—
UI
—
DDR CLK / DATA Jitter
Intra-Pair (Pulse) skew
Data to Clock Skew
—
—
75
0.075
—
—
ps pk-pk
UI
tSKEW[PN]
tSKEW[TX]
tr
—
—
—
—
0.350
150
150
—
0.650
0.3UI
0.3UI
15
UI
Differential output signal rise time
Differential output signal fall time
20% to 80%, RL = 50 Ω
20% to 80%, RL = 50 Ω
—
ps
tf
—
ps
ΔVCMTX(HF)
ΔVCMTX(LF)
Common level variation above 450 MHz 80 Ω<= RL< = 125 Ω
—
mVrms
mVp
Common level variation between 50
MHz and 450 MHz
80 Ω<= RL< = 125 Ω
—
—
25
LP Line Drivers AC Specifications
trlp, flp
t
Single ended output rise/fall time
15% to 85%, CL<70 pF
30% to 85%, CL<70 pF
15% to 85%, CL<70 pF
—
—
—
—
0
—
—
—
—
25
35
ns
ns
treo
—
δV/δtSR
CL
Signal slew rate
120
70
mV/ns
pF
Load capacitance
HS Line Receiver AC Specifications
tSETUP[RX]
tHOLD[RX]
Data to Clock Receiver Setup time
Clock to Data Receiver Hold time
—
—
—
0.15
0.15
—
—
—
—
—
—
UI
UI
ΔVCMRX(HF)
Common mode interference beyond
450 MHz
200
mVpp
ΔVCMRX(LF)
Common mode interference between
50 MHz and 450 MHz
—
—
-50
—
—
—
50
60
mVpp
pF
CCM
Common mode termination
LP Line Receiver AC Specifications
eSPIKE
TMIN
VINT
fINT
Input pulse rejection
—
—
—
50
—
—
—
—
300
—
Vps
ns
Minimum pulse response
Pk-to-Pk interference voltage
Interference frequency
—
—
—
400
—
mV
MHz
450
Model Parameters used for Driver Load switching performance evaluation
CPAD
Equivalent Single ended I/O PAD
capacitance.
—
—
—
—
—
—
1
2
pF
pF
CPIN
Equivalent Single ended Package +
PCB capacitance.
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Symbol
Table 65. Electrical and Timing Information (continued)
Parameters
Test Conditions
Min
Typ
Max
Unit
LS
RS
RL
Equivalent wire bond series inductance
Equivalent wire bond series resistance
Load Resistance
—
—
—
—
—
80
—
—
1.5
0.15
125
nH
Ω
100
Ω
4.12.12.6 High-Speed Clock Timing
CLKp
CLKn
1 Data Bit Time = 1UI
UIINST(1)
1 Data Bit Time = 1UI
UIINST(2)
1 DDR Clock Period = UIINST(1) + UIINST(2)
Figure 67. DDR Clock Definition
4.12.12.7 Forward High-Speed Data Transmission Timing
The timing relationship of the DDR Clock differential signal to the Data differential signal is shown in
Figure 68:
2EFERENCE 4IME
43%450
4(/,$
ꢋ
ꢀꢅꢆ5)).34
43+%7
#,+P
#,+N
ꢄ 5)).34
4#,+P
Figure 68. Data to Clock Timing Definitions
4.12.12.8 Reverse High-Speed Data Transmission Timing
TTD
NRZ Data
CLKn
CLKp
Clock to Data
Skew
2UI
2UI
Figure 69. Reverse High-Speed Data Transmission Timing at Slave Side
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4.12.12.9 Low-Power Receiver Timing
2*TLPX
2*TLPX
eSPIKE
VIH
VIL
Input
eSPIKE
TMIN-RX
TMIN-RX
Output
Figure 70. Input Glitch Rejection of Low-Power Receivers
4.12.13 HSI Host Controller Timing Parameters
This section describes the timing parameters of the HSI Host Controller which are compliant with
High-Speed Synchronous Serial Interface (HSI) Physical Layer specification version 1.01.
4.12.13.1 Synchronous Data Flow
Last bit of
frame
First bit of
frame
Last bit of
frame
First bit of
frame
tNomBit
DATA
FLAG
N-bits Frame
N-bits Frame
READY
Receiver has
detected the start
of the Frame
Receiver has captured
and stored a complete
Frame
Figure 71. Synchronized Data Flow READY Signal Timing (Frame and Stream Transmission)
4.12.13.2 Pipelined Data Flow
First bit of
frame
Last bit of
frame
Last bit of
frame
Last bit of
frame
First bit of
frame
tNomBit
DATA
FLAG
N-bits Frame
N-bits Frame
READY
E.
Ready
can
D. Ready shall
maintain zero of if
receiver does not
have free space
F. Ready
shall
maintain
its value
G. Ready
can change
C. Ready can change
A Ready can change
B Ready shall not
change to zero
change
Figure 72. Pipelined Data Flow READY Signal Timing (Frame Transmission Mode)
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4.12.13.3 Receiver Real-Time Data Flow
Last bit of
frame
First bit of
frame
Last bit of
frame
First bit of
frame
tNomBit
DATA
FLAG
N-bits Frame
N-bits Frame
READY
Receiver has
detected the start
of the Frame
Receiver has captured a
complete Frame
Figure 73. Receiver Real-Time Data Flow READY Signal Timing
4.12.13.4 Synchronized Data Flow Transmission with Wake
A
B
C
D
A
TX state
DATA
PHY Frame
PHY Frame
FLAG
3. First bit
received
6. Receiver
READY
4. Received
frame stored
2. Receiver in active
start state
can no longer
receive date
5. Transmitter
has no more
data to
transmit
WAKE
1. Transmitter has
data to transmit
A
B
C
A
D
RX state
A: Sleep state(non-operational)
B: Wake-up state
C: Active state (full operational)
D: Disable State(No communication ability)
Figure 74. Synchronized Data Flow Transmission with WAKE
4.12.13.5 Stream Transmission Mode Frame Transfer
Channel
Description
bits
its
Payload Data B
DATA
FLAG
Complete N-bits Frame
Complete N-bits Frame
READY
Figure 75. Stream Transmission Mode Frame Transfer (Synchronized Data Flow)
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4.12.13.6 Frame Transmission Mode (Synchronized Data Flow)
Frame
Channel
start bit
its
Payload Data B
Description
bits
DATA
FLAG
Complete N-bits Frame
Complete N-bits Frame
READY
Figure 76. Frame Transmission Mode Transfer of Two Frames (Synchronized Data Flow)
4.12.13.7 Frame Transmission Mode (Pipelined Data Flow)
Frame
Channel
start bit
Data Bits
Payload
Description
bits
DATA
FLAG
Complete N-bits Frame
Complete N-bits Frame
READY
Figure 77. Frame Transmission Mode Transfer of Two Frames (Pipelined Data Flow)
4.12.13.8 DATA and FLAG Signal Timing Requirement for a 15 pF Load
Table 66. DATA and FLAG Timing
Parameter
Description
1 Mbit/s 100 Mbit/s
tBit, nom
Nominal bit time
1000 ns
2 ns
10 ns
2 ns
tRise, min and tFall, min Minimum allowed rise and fall time
tTxToRxSkew, maxfq Maximum skew between transmitter and receiver package pins
50 ns
0.5 ns
4 ns
tEageSepTx, min
Minimum allowed separation of signal transitions at transmitter package pins,
including all timing defects, for example, jitter and skew, inside the transmitter.
400 ns
tEageSepRx, min
Minimum separation of signal transitions, measured at the receiver package pins, 350 ns
including all timing defects, for example, jitter and skew, inside the receiver.
3.5 ns
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4.12.13.9 DATA and FLAG Signal Timing
tEdgeSepTx
80%
50%
50%
DATA
(TX)
tRise
Note2
Note1
80%
80%
50%
FLAG
(TX)
20%
20%
20%
tBit
t Fall
tTxToRxSkew
tEdgeSepRx
80%
50%
50%
DATA
(RX)
Note1
Note2
50%
FLAG
(RX)
20%
Figure 78. DATA and FLAG Signal Timing
4.12.14 PCIe PHY Parameters
The PCIe interface complies with PCIe specification Gen2 x1 lane and supports the PCI Express 1.1/2.0
standard.
4.12.14.1 PCIE_REXT Reference Resistor Connection
The impedance calibration process requires connection of reference resistor 200 Ω. 1ꢀ precision resistor
on PCIE_REXT pads to ground. It is used for termination impedance calibration.
4.12.15 Pulse Width Modulator (PWM) Timing Parameters
This section describes the electrical information of the PWM. The PWM can be programmed to select one
of three clock signals as its source frequency. The selected clock signal is passed through a prescaler before
being input to the counter. The output is available at the pulse-width modulator output (PWMO) external
pin.
Figure 79 depicts the timing of the PWM, and Table 67 lists the PWM timing parameters.
PWMn_OUT
Figure 79. PWM Timing
Table 67. PWM Output Timing Parameters
ID
Parameter
Min
Max
Unit
—
P1
P2
PWM Module Clock Frequency
PWM output pulse width high
PWM output pulse width low
0
ipg_clk
—
MHz
ns
15
15
—
ns
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4.12.16 SATA PHY Parameters
This section describes SATA PHY electrical specifications.
4.12.16.1 Transmitter and Receiver Characteristics
The SATA PHY meets or exceeds the electrical compliance requirements defined in the SATA
specifications.
NOTE
The tables in the following sections indicate any exceptions to the SATA
specification or aspects of the SATA PHY that exceed the standard, as well
as provide information about parameters not defined in the standard.
The following subsections provide values obtained from a combination of simulations and silicon
characterization.
4.12.16.1.1 SATA PHY Transmitter Characteristics
Table 68 provides specifications for SATA PHY transmitter characteristics.
Table 68. SATA PHY Transmitter Characteristics
Parameters
Symbol
Min
Typ
Max
Unit
Transmit common mode voltage
VCTM
—
0.4
—
—
0.6
0.5
V
Transmitter pre-emphasis accuracy (measured
change in de-emphasized bit)
–0.5
dB
4.12.16.1.2 SATA PHY Receiver Characteristics
Table 69 provides specifications for SATA PHY receiver characteristics.
Table 69. SATA PHY Receiver Characteristics
Parameters
Symbol
Min
Typ
Max
Unit
Minimum Rx eye height (differential peak-to-peak)
Tolerance
VMIN_RX_EYE_HEIGHT
PPM
175
—
—
—
mV
–400
400
ppm
4.12.16.2 SATA_REXT Reference Resistor Connection
The impedance calibration process requires connection of reference resistor 191 Ω. 1ꢀ precision resistor
on SATA_REXT pad to ground.
Resistor calibration consists of learning which state of the internal Resistor Calibration register causes an
internal, digitally trimmed calibration resistor to best match the impedance applied to the SATA_REXT
pin. The calibration register value is then supplied to all Tx and Rx termination resistors.
During the calibration process (for a few tens of microseconds), up to 0.3 mW can be dissipated in the
external SATA_REXT resistor. At other times, no power is dissipated by the SATA_REXT resistor.
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4.12.17 SCAN JTAG Controller (SJC) Timing Parameters
Figure 80 depicts the SJC test clock input timing. Figure 81 depicts the SJC boundary scan timing.
Figure 82 depicts the SJC test access port. Figure 83 depicts the JTAG_TRST_B timing. Signal
parameters are listed in Table 70.
SJ1
SJ2
VM
SJ2
VM
JTAG_TCK
(Input)
VIH
VIL
SJ3
SJ3
Figure 80. Test Clock Input Timing Diagram
JTAG_TCK
(Input)
VIH
SJ5
Input Data Valid
VIL
SJ4
Data
Inputs
SJ6
Data
Outputs
Output Data Valid
SJ7
SJ6
Data
Outputs
Data
Outputs
Output Data Valid
Figure 81. Boundary Scan (JTAG) Timing Diagram
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JTAG_TCK
(Input)
VIH
SJ9
VIL
SJ8
Input Data Valid
JTAG_TDI
JTAG_TMS
(Input)
SJ10
SJ11
SJ10
JTAG_TDO
(Output)
Output Data Valid
JTAG_TDO
(Output)
JTAG_TDO
(Output)
Output Data Valid
Figure 82. Test Access Port Timing Diagram
JTAG_TCK
(Input)
SJ13
JTAG_TRST_B
(Input)
SJ12
Figure 83. JTAG_TRST_B Timing Diagram
Table 70. JTAG Timing
All Frequencies
ID
Parameter1,2
Unit
Min
Max
1
SJ0
SJ1
SJ2
SJ3
SJ4
SJ5
SJ6
SJ7
SJ8
JTAG_TCK frequency of operation 1/(3xTDC
)
0.001
45
22.5
—
22
—
—
3
MHz
ns
JTAG_TCK cycle time in crystal mode
2
JTAG_TCK clock pulse width measured at VM
JTAG_TCK rise and fall times
ns
ns
Boundary scan input data set-up time
Boundary scan input data hold time
JTAG_TCK low to output data valid
JTAG_TCK low to output high impedance
JTAG_TMS, JTAG_TDI data set-up time
5
—
—
40
40
—
ns
24
—
ns
ns
—
ns
5
ns
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Table 70. JTAG Timing (continued)
Parameter1,2
All Frequencies
ID
Unit
Min
Max
SJ9
JTAG_TMS, JTAG_TDI data hold time
25
—
—
44
44
—
—
ns
ns
ns
ns
ns
SJ10
SJ11
SJ12
SJ13
JTAG_TCK low to JTAG_TDO data valid
JTAG_TCK low to JTAG_TDO high impedance
JTAG_TRST_B assert time
—
100
40
JTAG_TRST_B set-up time to JTAG_TCK low
1
2
T
= target frequency of SJC
DC
VM = mid-point voltage
4.12.18 SPDIF Timing Parameters
The Sony/Philips Digital Interconnect Format (SPDIF) data is sent using the bi-phase marking code. When
encoding, the SPDIF data signal is modulated by a clock that is twice the bit rate of the data signal.
Table 71 and Figure 84 and Figure 85 show SPDIF timing parameters for the Sony/Philips Digital
Interconnect Format (SPDIF), including the timing of the modulating Rx clock (SPDIF_SR_CLK) for
SPDIF in Rx mode and the timing of the modulating Tx clock (SPDIF_ST_CLK) for SPDIF in Tx mode.
Table 71. SPDIF Timing Parameters
Timing Parameter Range
Parameter
Symbol
Unit
Min
Max
SPDIF_IN Skew: asynchronous inputs, no specs apply
—
—
0.7
ns
ns
SPDIF_OUT output (Load = 50pf)
• Skew
• Transition rising
• Transition falling
—
—
—
—
—
—
1.5
24.2
31.3
SPDIF_OUT output (Load = 30pf)
• Skew
• Transition rising
• Transition falling
—
—
—
—
—
—
1.5
13.6
18.0
ns
Modulating Rx clock (SPDIF_SR_CLK) period
SPDIF_SR_CLK high period
srckp
srckph
srckpl
stclkp
stclkph
stclkpl
40.0
16.0
16.0
40.0
16.0
16.0
—
—
—
—
—
—
ns
ns
ns
ns
ns
ns
SPDIF_SR_CLK low period
Modulating Tx clock (SPDIF_ST_CLK) period
SPDIF_ST_CLK high period
SPDIF_ST_CLK low period
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srckp
srckpl
VM
srckph
VM
SPDIF_SR_CLK
(Output)
Figure 84. SPDIF_SR_CLK Timing Diagram
stclkp
stclkpl
VM
stclkph
VM
SPDIF_ST_CLK
(Input)
Figure 85. SPDIF_ST_CLK Timing Diagram
4.12.19 SSI Timing Parameters
This section describes the timing parameters of the SSI module. The connectivity of the serial
synchronous interfaces are summarized in Table 72.
Table 72. AUDMUX Port Allocation
Port
Signal Nomenclature
Type and Access
AUDMUX port 1
AUDMUX port 2
AUDMUX port 3
AUDMUX port 4
AUDMUX port 5
AUDMUX port 6
AUDMUX port 7
SSI 1
SSI 2
AUD3
AUD4
AUD5
AUD6
SSI 3
Internal
Internal
External – AUD3 I/O
External – EIM or CSPI1 I/O through IOMUXC
External – EIM or SD1 I/O through IOMUXC
External – EIM or DISP2 through IOMUXC
Internal
NOTE
The terms WL and BL used in the timing diagrams and tables refer to Word
Length (WL) and Bit Length (BL).
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4.12.19.1 SSI Transmitter Timing with Internal Clock
Figure 86 depicts the SSI transmitter internal clock timing and Table 73 lists the timing parameters for
the SSI transmitter internal clock.
.
SS1
SS5
SS4
SS3
SS2
AUDx_TXC
(Output)
SS8
SS6
AUDx_TXFS (bl)
(Output)
SS10
SS12
SS14
SS17
AUDx_TXFS (wl)
(Output)
SS15
SS16
SS18
AUDx_TXD
(Output)
SS43
SS42
SS19
AUDx_RXD
(Input)
Note: AUDx_RXD input in synchronous mode only
Figure 86. SSI Transmitter Internal Clock Timing Diagram
Table 73. SSI Transmitter Timing with Internal Clock
ID
Parameter
Internal Clock Operation
Min
Max
Unit
SS1
SS2
AUDx_TXC/AUDx_RXC clock period
81.4
36.0
36.0
—
—
—
—
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
AUDx_TXC/AUDx_RXC clock high period
AUDx_TXC/AUDx_RXC clock low period
SS4
SS6
AUDx_TXC high to AUDx_TXFS (bl) high
AUDx_TXC high to AUDx_TXFS (bl) low
15.0
15.0
15.0
15.0
6.0
SS8
—
SS10
SS12
SS14
SS15
SS16
SS17
SS18
AUDx_TXC high to AUDx_TXFS (wl) high
AUDx_TXC high to AUDx_TXFS (wl) low
—
—
AUDx_TXC/AUDx_RXC Internal AUDx_TXFS rise time
AUDx_TXC/AUDx_RXC Internal AUDx_TXFS fall time
AUDx_TXC high to AUDx_TXD valid from high impedance
AUDx_TXC high to AUDx_TXD high/low
—
—
6.0
—
15.0
15.0
15.0
—
AUDx_TXC high to AUDx_TXD high impedance
—
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Table 73. SSI Transmitter Timing with Internal Clock (continued)
ID
Parameter
Min
Max
Unit
Synchronous Internal Clock Operation
SS42
SS43
AUDx_RXD setup before AUDx_TXC falling
AUDx_RXD hold after AUDx_TXC falling
10.0
0.0
—
—
ns
ns
NOTE
•
All the timings for the SSI are given for a non-inverted serial clock
polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync
(TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have
been inverted, all the timing remains valid by inverting the clock signal
AUDx_TXC/AUDx_RXC and/or the frame sync
AUDx_TXFS/AUDx_RXFS shown in the tables and in the figures.
•
All timings are on Audiomux Pads when SSI is being used for data
transfer.
•
•
The terms, WL and BL, refer to Word Length(WL) and Bit Length(BL).
For internal Frame Sync operation using external clock, the frame sync
timing is the same as that of transmit data (for example, during AC97
mode of operation).
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4.12.19.2 SSI Receiver Timing with Internal Clock
Figure 87 depicts the SSI receiver internal clock timing and Table 74 lists the timing parameters for the
receiver timing with the internal clock.
SS1
SS3
SS5
SS4
SS2
AUDx_TXC
(Output)
SS9
SS7
AUDx_TXFS (bl)
(Output)
SS11
SS13
AUDx_TXFS (wl)
(Output)
SS20
SS21
AUDx_RXD
(Input)
SS51
SS50
SS47
SS49
SS48
AUDx_RXC
(Output)
Figure 87. SSI Receiver Internal Clock Timing Diagram
Table 74. SSI Receiver Timing with Internal Clock
ID
Parameter
Min
Max
Unit
Internal Clock Operation
SS1
SS2
AUDx_TXC/AUDx_RXC clock period
81.4
36.0
—
—
—
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
AUDx_TXC/AUDx_RXC clock high period
AUDx_TXC/AUDx_RXC clock rise time
AUDx_TXC/AUDx_RXC clock low period
AUDx_TXC/AUDx_RXC clock fall time
AUDx_RXC high to AUDx_TXFS (bl) high
AUDx_RXC high to AUDx_TXFS (bl) low
AUDx_RXC high to AUDx_TXFS (wl) high
AUDx_RXC high to AUDx_TXFS (wl) low
AUDx_RXD setup time before AUDx_RXC low
AUDx_RXD hold time after AUDx_RXC low
SS3
6.0
—
SS4
36.0
—
SS5
6.0
15.0
15.0
15.0
15.0
—
SS7
—
SS9
—
SS11
SS13
SS20
SS21
—
—
10.0
0.0
—
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Table 74. SSI Receiver Timing with Internal Clock (continued)
ID
Parameter
Oversampling Clock Operation
Min
Max
Unit
SS47
SS48
SS49
SS50
SS51
Oversampling clock period
15.04
6.0
—
—
—
ns
ns
ns
ns
ns
Oversampling clock high period
Oversampling clock rise time
Oversampling clock low period
Oversampling clock fall time
3.0
—
6.0
—
3.0
NOTE
•
All the timings for the SSI are given for a non-inverted serial clock
polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync
(TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have
been inverted, all the timing remains valid by inverting the clock signal
AUDx_TXC/AUDx_RXC and/or the frame sync
AUDx_TXFS/AUDx_RXFS shown in the tables and in the figures.
•
•
All timings are on Audiomux Pads when SSI is being used for data
transfer.
AUDx_TXC and AUDx_RXC refer to the Transmit and Receive
sections of the SSI.
•
•
The terms, WL and BL, refer to Word Length (WL) and Bit Length(BL).
For internal Frame Sync operation using external clock, the frame sync
timing is same as that of transmit data (for example, during AC97 mode
of operation).
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4.12.19.3 SSI Transmitter Timing with External Clock
Figure 88 depicts the SSI transmitter external clock timing and Table 75 lists the timing parameters for
the transmitter timing with the external clock.
SS22
SS25
SS26
SS23
SS24
AUDx_TXC
(Input)
SS27
SS29
AUDx_TXFS (bl)
(Input)
SS33
SS31
AUDx_TXFS (wl)
(Input)
SS39
SS38
SS37
AUDx_TXD
(Output)
SS45
SS44
AUDx_RXD
(Input)
Note: AUDx_RXD Input in Synchronous mode only
SS46
Figure 88. SSI Transmitter External Clock Timing Diagram
Table 75. SSI Transmitter Timing with External Clock
ID
Parameter
External Clock Operation
Min
Max
Unit
SS22
SS23
SS24
SS25
SS26
SS27
SS29
SS31
SS33
SS37
SS38
SS39
AUDx_TXC/AUDx_RXC clock period
81.4
36.0
—
—
—
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
AUDx_TXC/AUDx_RXC clock high period
AUDx_TXC/AUDx_RXC clock rise time
AUDx_TXC/AUDx_RXC clock low period
AUDx_TXC/AUDx_RXC clock fall time
6.0
—
36.0
—
6.0
15.0
—
AUDx_TXC high to AUDx_TXFS (bl) high
AUDx_TXC high to AUDx_TXFS (bl) low
AUDx_TXC high to AUDx_TXFS (wl) high
AUDx_TXC high to AUDx_TXFS (wl) low
AUDx_TXC high to AUDx_TXD valid from high impedance
AUDx_TXC high to AUDx_TXD high/low
AUDx_TXC high to AUDx_TXD high impedance
–10.0
10.0
–10.0
10.0
—
15.0
—
15.0
15.0
15.0
—
—
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Table 75. SSI Transmitter Timing with External Clock (continued)
ID
Parameter
Min
Max
Unit
Synchronous External Clock Operation
SS44
SS45
SS46
AUDx_RXD setup before AUDx_TXC falling
AUDx_RXD hold after AUDx_TXC falling
AUDx_RXD rise/fall time
10.0
2.0
—
—
—
ns
ns
ns
6.0
NOTE
All the timings for the SSI are given for a non-inverted serial clock
polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync
•
(TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have
been inverted, all the timing remains valid by inverting the clock signal
AUDx_TXC/AUDx_RXC and/or the frame sync
AUDx_TXFS/AUDx_RXFS shown in the tables and in the figures.
•
•
All timings are on Audiomux Pads when SSI is being used for data
transfer.
AUDx_TXC and AUDx_RXC refer to the Transmit and Receive
sections of the SSI.
•
•
The terms WL and BL refer to Word Length (WL) and Bit Length (BL).
For internal Frame Sync operation using external clock, the frame sync
timing is same as that of transmit data (for example, during AC97 mode
of operation).
4.12.19.4 SSI Receiver Timing with External Clock
Figure 89 depicts the SSI receiver external clock timing and Table 76 lists the timing parameters for the
receiver timing with the external clock.
SS22
SS24
SS26
SS25
SS23
SS28
AUDx_TXC
(Input)
SS30
AUDx_TXFS (bl)
(Input)
SS32
SS35
SS34
AUDx_TXFS (wl)
(Input)
SS41
SS36
SS40
AUDx_RXD
(Input)
Figure 89. SSI Receiver External Clock Timing Diagram
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Electrical Characteristics
Table 76. SSI Receiver Timing with External Clock
ID
Parameter
Min
Max
Unit
External Clock Operation
SS22
SS23
SS24
SS25
SS26
SS28
SS30
SS32
SS34
SS35
SS36
SS40
SS41
AUDx_TXC/AUDx_RXC clock period
81.4
36
—
—
—
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
AUDx_TXC/AUDx_RXC clock high period
AUDx_TXC/AUDx_RXC clock rise time
6.0
—
AUDx_TXC/AUDx_RXC clock low period
AUDx_TXC/AUDx_RXC clock fall time
36
—
6.0
15.0
—
AUDx_RXC high to AUDx_TXFS (bl) high
AUDx_RXC high to AUDx_TXFS (bl) low
AUDx_RXC high to AUDx_TXFS (wl) high
AUDx_RXC high to AUDx_TXFS (wl) low
AUDx_TXC/AUDx_RXC External AUDx_TXFS rise time
AUDx_TXC/AUDx_RXC External AUDx_TXFS fall time
AUDx_RXD setup time before AUDx_RXC low
AUDx_RXD hold time after AUDx_RXC low
–10
10
–10
10
—
15.0
—
6.0
6.0
—
—
10
2
—
NOTE
•
All the timings for the SSI are given for a non-inverted serial clock
polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync
(TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have
been inverted, all the timing remains valid by inverting the clock signal
AUDx_TXC/AUDx_RXC and/or the frame sync
AUDx_TXFS/AUDx_RXFS shown in the tables and in the figures.
•
•
All timings are on Audiomux Pads when SSI is being used for data
transfer.
AUDx_TXC and AUDx_RXC refer to the Transmit and Receive
sections of the SSI.
•
•
The terms, WL and BL, refer to Word Length (WL) and Bit Length(BL).
For internal Frame Sync operation using external clock, the frame sync
timing is same as that of transmit data (for example, during AC97 mode
of operation).
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4.12.20 UART I/O Configuration and Timing Parameters
4.12.20.1 UART RS-232 I/O Configuration in Different Modes
The i.MX 6Dual/6Quad UART interfaces can serve both as DTE or DCE device. This can be configured
by the DCEDTE control bit (default 0 – DCE mode). Table 77 shows the UART I/O configuration based
on the enabled mode.
Table 77. UART I/O Configuration vs. Mode
DTE Mode
Description
DCE Mode
Description
Port
Direction
Direction
UARTx_RTS_B
UARTx_CTS_B
UARTx_DTR_B
UARTx_DSR_B
UARTx_DCD_B
UARTx_RI_B
Output
Input
RTS from DTE to DCE
CTS from DCE to DTE
DTR from DTE to DCE
DSR from DCE to DTE
DCD from DCE to DTE
RING from DCE to DTE
Serial data from DCE to DTE
Serial data from DTE to DCE
Input
Output
Input
RTS from DTE to DCE
CTS from DCE to DTE
DTR from DTE to DCE
DSR from DCE to DTE
DCD from DCE to DTE
RING from DCE to DTE
Serial data from DCE to DTE
Serial data from DTE to DCE
Output
Input
Output
Output
Output
Output
Input
Input
Input
UARTx_TX_DATA
UARTx_RX_DATA
Input
Output
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4.12.20.2 UART RS-232 Serial Mode Timing
The following sections describe the electrical information of the UART module in the RS-232 mode.
4.12.20.2.1 UART Transmitter
Figure 90 depicts the transmit timing of UART in the RS-232 serial mode, with 8 data bit/1 stop bit
format. Table 78 lists the UART RS-232 serial mode transmit timing characteristics.
POSSIBLE
PARITY
UA1
UA1
Bit 3
BIT
NEXT
START
BIT
Start
Bit
UARTx_TX_DATA
(output)
STOP
BIT
Bit 7
Bit 0
Bit 1
Bit 2
Bit 4
Bit 5
Bit 6
Par Bit
UA1
UA1
Figure 90. UART RS-232 Serial Mode Transmit Timing Diagram
Table 78. RS-232 Serial Mode Transmit Timing Parameters
ID
Parameter
Transmit Bit Time
Symbol
Min
Max
1/Fbaud_rate + Tref_clk
Unit
2
UA1
tTbit
1/Fbaud_rate1 – Tref_clk
—
1
Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency)/16.
Tref_clk: The period of UART reference clock ref_clk (ipg_perclk after RFDIV divider).
2
4.12.20.2.2 UART Receiver
Figure 91 depicts the RS-232 serial mode receive timing with 8 data bit/1 stop bit format. Table 79 lists
serial mode receive timing characteristics.
POSSIBLE
PARITY
UA2
UA2
Bit 3
BIT
NEXT
START
BIT
Start
Bit
UARTx_RX_DATA
(input)
STOP
BIT
Bit 7
Bit 0
Bit 1
Bit 2
Bit 4
Bit 5
Bit 6
Par Bit
UA2
UA2
Figure 91. UART RS-232 Serial Mode Receive Timing Diagram
Table 79. RS-232 Serial Mode Receive Timing Parameters
ID
Parameter
Receive Bit Time1
Symbol
Min
Max
Unit
2
UA2
tRbit
1/Fbaud_rate
–
1/Fbaud_rate
+
—
1/(16 × Fbaud_rate
)
1/(16 × Fbaud_rate)
1
2
The UART receiver can tolerate 1/(16 × Fbaud_rate) tolerance in each bit. But accumulation tolerance in one frame must not
exceed 3/(16 × Fbaud_rate).
Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency)/16.
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4.12.20.2.3 UART IrDA Mode Timing
The following subsections give the UART transmit and receive timings in IrDA mode.
UART IrDA Mode Transmitter
Figure 92 depicts the UART IrDA mode transmit timing, with 8 data bit/1 stop bit format. Table 80 lists
the transmit timing characteristics.
UA3
UA3
UA4
UA3
UA3
UARTx_TX_DATA
(output)
Start
Bit
STOP
BIT
POSSIBLE
PARITY
BIT
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Figure 92. UART IrDA Mode Transmit Timing Diagram
Table 80. IrDA Mode Transmit Timing Parameters
ID
Parameter
Symbol
Min
Max
Unit
2
UA3 Transmit Bit Time in IrDA mode
UA4 Transmit IR Pulse Duration
tTIRbit
1/Fbaud_rate1 – Tref_clk
1/Fbaud_rate + Tref_clk
—
—
tTIRpulse (3/16) × (1/Fbaud_rate) – Tref_clk
(3/16) × (1/Fbaud_rate) + Tref_clk
1
2
Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency)/16.
Tref_clk: The period of UART reference clock ref_clk (ipg_perclk after RFDIV divider).
UART IrDA Mode Receiver
Figure 93 depicts the UART IrDA mode receive timing, with 8 data bit/1 stop bit format. Table 81 lists
the receive timing characteristics.
UA6
UA5
UA5
UA5
UA5
UARTx_RX_DATA
(input)
STOP
BIT
Start
Bit
POSSIBLE
PARITY
BIT
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Figure 93. UART IrDA Mode Receive Timing Diagram
Table 81. IrDA Mode Receive Timing Parameters
ID
Parameter
Symbol
Min
Max
1/Fbaud_rate
Unit
2
UA5 Receive Bit Time1 in IrDA mode
tRIRbit
1/Fbaud_rate
–
+
—
1/(16 × Fbaud_rate
)
1/(16 × Fbaud_rate
)
UA6 Receive IR Pulse Duration
tRIRpulse
1.41 μs
(5/16) × (1/Fbaud_rate
)
—
1
2
The UART receiver can tolerate 1/(16 × Fbaud_rate) tolerance in each bit. But accumulation tolerance in one frame must not
exceed 3/(16 × Fbaud_rate).
Fbaud_rate: Baud rate frequency. The maximum baud rate the UART can support is (ipg_perclk frequency)/16.
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4.12.21 USB HSIC Timings
This section describes the electrical information of the USB HSIC port.
NOTE
HSIC is a DDR signal. The following timing specification is for both rising
and falling edges.
4.12.21.1 Transmit Timing
Tstrobe
USB_H_STROBE
Todelay
Todelay
USB_H_DATA
Figure 94. USB HSIC Transmit Waveform
Table 82. USB HSIC Transmit Parameters
Name
Parameter
Min
Max
Unit
Comment
Tstrobe strobe period
4.166
550
4.167
1350
2
ns
ps
—
Todelay data output delay time
Measured at 50% point
Averaged from 30% – 70% points
Tslew
strobe/data rising/falling time
0.7
V/ns
4.12.21.2 Receive Timing
Tstrobe
USB_H_STROBE
USB_H_DATA
Thold
Tsetup
Figure 95. USB HSIC Receive Waveform
1
Table 83. USB HSIC Receive Parameters
Name
Parameter
Min
Max
Unit
Comment
Tstrobe strobe period
4.166
300
365
0.7
4.167
—
ns
ps
—
Thold
Tsetup
Tslew
data hold time
Measured at 50% point
data setup time
—
ps
Measured at 50% point
strobe/data rising/falling time
2
V/ns
Averaged from 30% – 70% points
1
The timings in the table are guaranteed when:
—AC I/O voltage is between 0.9x to 1x of the I/O supply
—DDR_SEL configuration bits of the I/O are set to (10)b
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Electrical Characteristics
4.12.22 USB PHY Parameters
This section describes the USB-OTG PHY and the USB Host port PHY parameters.
The USB PHY meets the electrical compliance requirements defined in the Universal Serial Bus Revision
2.0 OTG, USB Host with the amendments below (On-The-Go and Embedded Host Supplement to the USB
Revision 2.0 Specification is not applicable to Host port).
•
USB ENGINEERING CHANGE NOTICE
— Title: 5V Short Circuit Withstand Requirement Change
— Applies to: Universal Serial Bus Specification, Revision 2.0
Errata for USB Revision 2.0 April 27, 2000 as of 12/7/2000
USB ENGINEERING CHANGE NOTICE
•
•
— Title: Pull-up/Pull-down resistors
— Applies to: Universal Serial Bus Specification, Revision 2.0
USB ENGINEERING CHANGE NOTICE
•
•
— Title: Suspend Current Limit Changes
— Applies to: Universal Serial Bus Specification, Revision 2.0
USB ENGINEERING CHANGE NOTICE
— Title: USB 2.0 Phase Locked SOFs
— Applies to: Universal Serial Bus Specification, Revision 2.0
On-The-Go and Embedded Host Supplement to the USB Revision 2.0 Specification
— Revision 2.0 plus errata and ecn June 4, 2010
Battery Charging Specification (available from USB-IF)
— Revision 1.2, December 7, 2010
•
•
— Portable device only
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Boot Mode Configuration
5 Boot Mode Configuration
This section provides information on boot mode configuration pins allocation and boot devices interfaces
allocation.
5.1
Boot Mode Configuration Pins
Table 84 provides boot options, functionality, fuse values, and associated pins. Several input pins are also
sampled at reset and can be used to override fuse values, depending on the value of BT_FUSE_SEL fuse.
The boot option pins are in effect when BT_FUSE_SEL fuse is ‘0’ (cleared, which is the case for an
unblown fuse). For detailed boot mode options configured by the boot mode pins, see the i.MX
6Dual/6Quad Fuse Map document and the System Boot chapter of the i.MX 6Dual/6Quad reference
manual (IMX6DQRM).
Table 84. Fuses and Associated Pins Used for Boot
Pin
Direction at Reset
eFuse Name
Boot Mode Selection
BOOT_MODE1
BOOT_MODE0
Input
Input
Boot Mode Selection
Boot Mode Selection
Boot Options1
EIM_DA0
EIM_DA1
EIM_DA2
EIM_DA3
EIM_DA4
EIM_DA5
EIM_DA6
EIM_DA7
EIM_DA8
EIM_DA9
EIM_DA10
EIM_DA11
EIM_DA12
EIM_DA13
EIM_DA14
EIM_DA15
EIM_A16
EIM_A17
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
BOOT_CFG1[0]
BOOT_CFG1[1]
BOOT_CFG1[2]
BOOT_CFG1[3]
BOOT_CFG1[4]
BOOT_CFG1[5]
BOOT_CFG1[6]
BOOT_CFG1[7]
BOOT_CFG2[0]
BOOT_CFG2[1]
BOOT_CFG2[2]
BOOT_CFG2[3]
BOOT_CFG2[4]
BOOT_CFG2[5]
BOOT_CFG2[6]
BOOT_CFG2[7]
BOOT_CFG3[0]
BOOT_CFG3[1]
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Boot Mode Configuration
Table 84. Fuses and Associated Pins Used for Boot (continued)
Pin
Direction at Reset
eFuse Name
EIM_A18
EIM_A19
EIM_A20
EIM_A21
EIM_A22
EIM_A23
EIM_A24
EIM_WAIT
EIM_LBA
EIM_EB0
EIM_EB1
EIM_RW
EIM_EB2
EIM_EB3
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
BOOT_CFG3[2]
BOOT_CFG3[3]
BOOT_CFG3[4]
BOOT_CFG3[5]
BOOT_CFG3[6]
BOOT_CFG3[7]
BOOT_CFG4[0]
BOOT_CFG4[1]
BOOT_CFG4[2]
BOOT_CFG4[3]
BOOT_CFG4[4]
BOOT_CFG4[5]
BOOT_CFG4[6]
BOOT_CFG4[7]
1
Pin value overrides fuse settings for BT_FUSE_SEL = ‘0’. Signal Configuration as Fuse Override Input at Power
Up. These are special I/O lines that control the boot up configuration during product development. In production,
the boot configuration can be controlled by fuses.
5.2
Boot Devices Interfaces Allocation
Table 85 lists the interfaces that can be used by the boot process in accordance with the specific boot
mode configuration. The table also describes the interface’s specific modes and IOMUXC allocation,
which are configured during boot when appropriate.
Table 85. Interfaces Allocation During Boot
Interface
IP Instance
Allocated Pads During Boot
Comment
SPI
ECSPI-1
EIM_D17, EIM_D18, EIM_D16, EIM_EB2, EIM_D19,
EIM_D24, EIM_D25
—
SPI
SPI
SPI
SPI
EIM
ECSPI-2
ECSPI-3
ECSPI-4
ECSPI-5
EIM
CSI0_DAT10, CSI0_DAT9, CSI0_DAT8, CSI0_DAT11,
EIM_LBA, EIM_D24, EIM_D25
—
—
—
—
DISP0_DAT2, DISP0_DAT1, DISP0_DAT0,
DISP0_DAT3,DISP0_DAT4,DISP0_DAT5,DISP0_DAT6
EIM_D22, EIM_D28, EIM_D21, EIM_D20, EIM_A25,
EIM_D24, EIM_D25
SD1_DAT0, SD1_CMD, SD1_CLK, SD1_DAT1,
SD1_DAT2, SD1_DAT3, SD2_DAT3
EIM_DA[15:0], EIM_D[31:16], CSI0_DAT[19:4],
CSI0_DATA_EN, CSI0_VSYNC
Used for NOR, OneNAND boot
Only CS0 is supported
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Boot Mode Configuration
Table 85. Interfaces Allocation During Boot (continued)
Allocated Pads During Boot
Interface
IP Instance
Comment
NAND Flash
GPMI
NANDF_CLE, NANDF_ALE, NANDF_WP_B,
SD4_CMD, SD4_CLK, NANDF_RB0, SD4_DAT0,
NANDF_CS0, NANDF_CS1, NANDF_CS2,
NANDF_CS3, NANDF_D[7:0]
8 bit
Only CS0 is supported
SD/MMC
SD/MMC
SD/MMC
SD/MMC
USDHC-1
USDHC-2
USDHC-3
USDHC-4
SD1_CLK, SD1_CMD,SD1_DAT0, SD1_DAT1,
SD1_DAT2, SD1_DAT3, NANDF_D0, NANDF_D1,
NANDF_D2, NANDF_D3, KEY_COL1
1, 4, or 8 bit
SD2_CLK, SD2_CMD, SD2_DAT0, SD2_DAT1,
SD2_DAT2, SD2_DAT3, NANDF_D4, NANDF_D5,
NANDF_D6, NANDF_D7, KEY_ROW1
1, 4, or 8 bit
SD3_CLK, SD3_CMD, SD3_DAT0, SD3_DAT1,
SD3_DAT2, SD3_DAT3, SD3_DAT4, SD3_DAT5,
SD3_DAT6, SD3_DAT7, GPIO_18
1, 4, or 8 bit
SD4_CLK, SD4_CMD, SD4_DAT0, SD4_DAT1,
SD4_DAT2, SD4_DAT3, SD4_DAT4, SD4_DAT5,
SD4_DAT6, SD4_DAT7, NANDF_CS1
1, 4, or 8 bit
I2C
I2C
I2C-1
I2C-2
I2C-3
EIM_D28, EIM_D21
EIM_D16, EIM_EB2
EIM_D18, EIM_D17
—
—
—
—
I2C
SATA
SATA_PHY SATA_TXM, SATA_TXP, SATA_RXP, SATA_RXM,
SATA_REXT
USB
USB-OTG
PHY
USB_OTG_DP
USB_OTG_DN
USB_OTG_VBUS
—
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Package Information and Contact Assignments
6 Package Information and Contact Assignments
This section includes the contact assignment information and mechanical package drawing.
6.1
Signal Naming Convention
The signal names of the i.MX6 series of products are standardized to align the signal names within the
family and across the documentation. Benefits of this standardization are as follows:
•
•
•
•
Signal names are unique within the scope of an SoC and within the series of products
Searches will return all occurrences of the named signal
Signal names are consistent between i.MX 6 series products implementing the same modules
The module instance is incorporated into the signal name
This standardization applies only to signal names. The ball names are preserved to prevent the need to
change schematics, BSDL models, IBIS models, and so on.
Throughout this document, the signal names are used except where referenced as a ball name (such as the
Functional Contact Assignments table, Ball Map table, and so on). A master list of signal names is in the
document, IMX 6 Series Standardized Signal Name Map (EB792). This list can be used to map the signal
names used in older documentation to the standardized naming conventions.
6.2
21 x 21 mm Package Information
6.2.1
Case FCPBGA, 21 x 21 mm, 0.8 mm Pitch, 25 x 25 Ball Matrix
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Package Information and Contact Assignments
6.2.1.1
21 x 21 mm Lidded Package
Figure 96 and Figure 97 show the top, bottom, and side views of the 21 × 21 mm lidded package.
Figure 96. 21 x 21 mm Lidded Package Top, Bottom, and Side Views (Sheet 1 of 2)
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Package Information and Contact Assignments
Figure 97. 21 x 21 mm Lidded Package Top, Bottom, and Side Views (Sheet 2 of 2)
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Package Information and Contact Assignments
6.2.2
21 x 21 mm Ground, Power, Sense, and Reference Contact
Assignments
Table 86 shows the device connection list for ground, power, sense, and reference contact signals.
Table 86. 21 x 21 mm Supplies Contact Assignment
Supply Rail Name
Ball(s) Position(s)
Remark
CSI_REXT
DRAM_VREF
DSI_REXT
FA_ANA
D4
AC2
G4
—
—
—
—
—
A5
GND
A13, A25, A4, A8, AA10, AA13, AA16, AA19, AA22, AD4, D3,
F8, J15, L10, M15, P15, T15, U8, W17, AA7, AD7, D6, G10,
J18, L12, M18, P18, T17, V19, W18, AB24, AE1, D8, G19, J2,
L15, M8, P8, T19, V8, W19, AB3, AE25, E5, G3, J8, L18, N10,
R12, T8, W10, W3, AD10, B4, E6, H12, K10, L2, N15, R15,
U11, W11, W7, AD13, C1, E7, H15, K12, L5, N18, R17, U12,
W12, W8, AD16, C10, F5, H18, K15, L8, N8, R8, U15, W13,
W9, AD19, C4, F6, H8, K18, M10, P10, T11, U17, W15, Y24,
AD22, C6, F7, J12, K8, M12, P12, T12, U19, W16, Y5
GPANAIO
C8
Analog output for NXP use only. This
output must remain unconnected
HDMI_DDCCEC
K2
Analog ground reference for the Hot
Plug detect signal
HDMI_REF
HDMI_VP
J1
L7
—
—
—
HDMI_VPH
NVCC_CSI
NVCC_DRAM
M7
N7
Supply of the camera sensor interface
Supply of the DDR interface
R18, T18, U18, V10, V11, V12, V13,
V14, V15, V16, V17, V18, V9
NVCC_EIM0
NVCC_EIM1
NVCC_EIM2
NVCC_ENET
NVCC_GPIO
NVCC_JTAG
K19
L19
M19
R19
P7
Supply of the EIM interface
Supply of the EIM interface
Supply of the EIM interface
Supply of the ENET interface
Supply of the GPIO interface
J7
Supply of the JTAG tap controller
interface
NVCC_LCD
P19
V7
Supply of the LCD interface
NVCC_LVDS2P5
Supply of the LVDS display interface
and DDR pre-drivers. Even if the LVDS
interface is not used, this supply must
remain powered.
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Package Information and Contact Assignments
Table 86. 21 x 21 mm Supplies Contact Assignment (continued)
Supply Rail Name
Ball(s) Position(s)
Remark
NVCC_MIPI
K7
Supply of the MIPI interface
NVCC_NANDF
G15
Supply of the RAW NAND Flash
Memories interface
NVCC_PLL_OUT
NVCC_RGMII
NVCC_SD1
E8
G18
G16
G17
G14
H7
—
Supply of the ENET interface
Supply of the SD card interface
NVCC_SD2
Supply of the SD card interface
NVCC_SD3
Supply of the SD card interface
PCIE_VP
—
PCIE_REXT
PCIE_VPH
A2
—
G7
PCI PHY supply
PCIE_VPTX
SATA_REXT
SATA_VP
G8
PCI PHY supply
C14
G13
G12
D10
E9
—
—
—
—
—
SATA_VPH
USB_H1_VBUS
USB_OTG_VBUS
VDD_CACHE_CAP
N12
Cache supply input. This input should
be connected to (driven by)
VDD_SOC_CAP. The external
capacitor used for VDD_SOC_CAP is
sufficient for this supply.
VDD_FA
B5
G9
—
VDD_SNVS_CAP
Secondary supply for the SNVS
(internal regulator output—requires
capacitor if internal regulator is used)
VDD_SNVS_IN
VDDARM_CAP
G11
Primary supply for the SNVS regulator
H13, J13, K13, L13, M13, N13, P13, R13
Secondary supply for the ARM0 and
ARM1 cores (internal regulator
output—requires capacitor if internal
regulator is used)
VDDARM_IN
H14, J14, K14, L14, M14, N14, P14, R14
H11, J11, K11, L11, M11, N11, P11, R11
Primary supply for the ARM0 and
ARM1 core regulator
VDDARM23_CAP
Secondary supply for the ARM2 and
ARM3 cores (internal regulator
output—requires capacitor if internal
regulator is used)
VDDARM23_IN
K9, L9, M9, N9, P9, R9, T9, U9
Primary supply for the ARM2 and
ARM3 core regulator
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
137
Package Information and Contact Assignments
Table 86. 21 x 21 mm Supplies Contact Assignment (continued)
Supply Rail Name
Ball(s) Position(s)
Remark
VDDHIGH_CAP
H10, J10
Secondary supply for the 2.5 V domain
(internal regulator output—requires
capacitor if internal regulator is used)
VDDHIGH_IN
VDDPU_CAP
H9, J9
Primary supply for the 2.5 V regulator
H17, J17, K17, L17, M17, N17, P17
Secondary supply for the VPU and
GPU (internal regulator output—
requires capacitor if internal regulator
is used)
VDDSOC_CAP
R10, T10, T13, T14, U10, U13, U14
Secondary supply for the SoC and PU
(internal regulator output—requires
capacitor if internal regulator is used)
VDDSOC_IN
H16, J16, K16, L16, M16, N16, P16, R16, T16, U16
F9
Primary supply for the SoC and PU
regulators
VDDUSB_CAP
Secondary supply for the 3 V domain
(internal regulator output—requires
capacitor if internal regulator is used)
ZQPAD
AE17
Connect ZQPAD to an external 240Ω
1% resistor to GND. This is a reference
used during DRAM output buffer driver
calibration.
6.2.3
21 x 21 mm Functional Contact Assignments
Table 87 displays an alpha-sorted list of the signal assignments including power rails. The table also
includes out of reset pad state.
Table 87. 21 x 21 mm Functional Contact Assignments
Out of Reset Condition1
Default
Ball Name
Ball
Power Group Ball Type
Mode
(Reset
Mode)
Default Function
(Signal Name)
Input/Output
Value2
BOOT_MODE0
BOOT_MODE1
CLK1_N
C12
F12
VDD_SNVS_IN
VDD_SNVS_IN
GPIO
GPIO
—
ALT0
ALT0
—
SRC_BOOT_MODE0
SRC_BOOT_MODE1
CLK1_N
Input
Input
—
PD (100K)
PD (100K)
C7 VDD_HIGH_CAP
D7 VDD_HIGH_CAP
C5 VDD_HIGH_CAP
D5 VDD_HIGH_CAP
—
—
—
—
—
—
—
—
—
CLK1_P
—
—
CLK1_P
—
CLK2_N
—
—
CLK2_N
—
CLK2_P
—
—
CLK2_P
—
CSI_CLK0M
CSI_CLK0P
CSI_D0M
F4
F3
E4
E3
D1
NVCC_MIPI
NVCC_MIPI
NVCC_MIPI
NVCC_MIPI
NVCC_MIPI
—
—
CSI_CLK_N
CSI_CLK_P
CSI_DATA0_N
CSI_DATA0_P
CSI_DATA1_N
—
—
—
—
—
—
—
CSI_D0P
—
—
—
CSI_D1M
—
—
—
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
138
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
CSI_D1P
CSI_D2M
D2
E1
NVCC_MIPI
NVCC_MIPI
NVCC_MIPI
NVCC_MIPI
NVCC_MIPI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_CSI
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
—
—
CSI_DATA1_P
CSI_DATA2_N
CSI_DATA2_P
CSI_DATA3_N
CSI_DATA3_P
GPIO5_IO28
GPIO5_IO29
GPIO5_IO30
GPIO5_IO31
GPIO6_IO00
GPIO6_IO01
GPIO6_IO02
GPIO6_IO03
GPIO6_IO04
GPIO6_IO05
GPIO5_IO22
GPIO5_IO23
GPIO5_IO24
GPIO5_IO25
GPIO5_IO26
GPIO5_IO27
GPIO5_IO20
GPIO5_IO19
GPIO5_IO18
GPIO5_IO21
GPIO4_IO16
GPIO4_IO17
GPIO4_IO18
GPIO4_IO19
GPIO4_IO20
GPIO4_IO21
GPIO4_IO22
GPIO4_IO31
GPIO5_IO05
GPIO5_IO06
GPIO5_IO07
—
—
—
—
—
—
CSI_D2P
E2
—
—
—
—
CSI_D3M
F2
—
—
—
—
CSI_D3P
F1
—
—
—
—
CSI0_DAT10
CSI0_DAT11
CSI0_DAT12
CSI0_DAT13
CSI0_DAT14
CSI0_DAT15
CSI0_DAT16
CSI0_DAT17
CSI0_DAT18
CSI0_DAT19
CSI0_DAT4
CSI0_DAT5
CSI0_DAT6
CSI0_DAT7
CSI0_DAT8
CSI0_DAT9
CSI0_DATA_EN
CSI0_MCLK
CSI0_PIXCLK
CSI0_VSYNC
DI0_DISP_CLK
DI0_PIN15
M1
M3
M2
L1
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
M4
M5
L4
L3
M6
L6
N1
P2
N4
N3
N6
N5
P3
P4
P1
N2
N19
N21
N25
N20
P25
P24
P22
R21
T23
T24
R20
DI0_PIN2
DI0_PIN3
DI0_PIN4
DISP0_DAT0
DISP0_DAT1
DISP0_DAT10
DISP0_DAT11
DISP0_DAT12
DISP0_DAT13
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
139
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
DISP0_DAT14
DISP0_DAT15
DISP0_DAT16
DISP0_DAT17
DISP0_DAT18
DISP0_DAT19
DISP0_DAT2
DISP0_DAT20
DISP0_DAT21
DISP0_DAT22
DISP0_DAT23
DISP0_DAT3
DISP0_DAT4
DISP0_DAT5
DISP0_DAT6
DISP0_DAT7
DISP0_DAT8
DISP0_DAT9
DRAM_A0
U25
T22
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_LCD
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
GPIO5_IO08
GPIO5_IO09
Input
Input
PU (100K)
PU (100K)
T21
GPIO5_IO10
Input
PU (100K)
U24
GPIO5_IO11
Input
PU (100K)
V25
GPIO5_IO12
Input
PU (100K)
U23
GPIO5_IO13
Input
PU (100K)
P23
GPIO4_IO23
Input
PU (100K)
U22
GPIO5_IO14
Input
PU (100K)
T20
GPIO5_IO15
Input
PU (100K)
V24
GPIO5_IO16
Input
PU (100K)
W24
P21
GPIO5_IO17
Input
PU (100K)
GPIO4_IO24
Input
PU (100K)
P20
GPIO4_IO25
Input
PU (100K)
R25
GPIO4_IO26
Input
PU (100K)
R23
GPIO4_IO27
Input
PU (100K)
R24
GPIO4_IO28
Input
PU (100K)
R22
GPIO4_IO29
Input
PU (100K)
T25
GPIO4_IO30
Input
PU (100K)
AC14
AB14
AA15
AC12
AD12
AC17
AA12
Y12
DRAM_ADDR00
DRAM_ADDR01
DRAM_ADDR10
DRAM_ADDR11
DRAM_ADDR12
DRAM_ADDR13
DRAM_ADDR14
DRAM_ADDR15
DRAM_ADDR02
DRAM_ADDR03
DRAM_ADDR04
DRAM_ADDR05
DRAM_ADDR06
DRAM_ADDR07
DRAM_ADDR08
DRAM_ADDR09
DRAM_CAS_B
DRAM_CS0_B
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
DRAM_A1
DRAM_A10
DRAM_A11
DRAM_A12
DRAM_A13
DRAM_A14
DRAM_A15
DRAM_A2
AA14
Y14
DRAM_A3
DRAM_A4
W14
AE13
AC13
Y13
DRAM_A5
DRAM_A6
DRAM_A7
DRAM_A8
AB13
AE12
AE16
Y16
DRAM_A9
DRAM_CAS
DRAM_CS0
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
140
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
DRAM_CS1
DRAM_D0
AD17
AD2
AE2
AA6
AE7
AB5
AC5
AB6
AC7
AB7
AA8
AB9
Y9
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
DRAM_CS1_B
DRAM_DATA00
DRAM_DATA01
DRAM_DATA10
DRAM_DATA11
DRAM_DATA12
DRAM_DATA13
DRAM_DATA14
DRAM_DATA15
DRAM_DATA16
DRAM_DATA17
DRAM_DATA18
DRAM_DATA19
DRAM_DATA02
DRAM_DATA20
DRAM_DATA21
DRAM_DATA22
DRAM_DATA23
DRAM_DATA24
DRAM_DATA25
DRAM_DATA26
DRAM_DATA27
DRAM_DATA28
DRAM_DATA29
DRAM_DATA03
DRAM_DATA30
DRAM_DATA31
DRAM_DATA32
DRAM_DATA33
DRAM_DATA34
DRAM_DATA35
DRAM_DATA36
DRAM_DATA37
DRAM_DATA38
DRAM_DATA39
DRAM_DATA04
Output
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
0
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
DRAM_D1
DRAM_D10
DRAM_D11
DRAM_D12
DRAM_D13
DRAM_D14
DRAM_D15
DRAM_D16
DRAM_D17
DRAM_D18
DRAM_D19
DRAM_D2
AC4
Y7
DRAM_D20
DRAM_D21
DRAM_D22
DRAM_D23
DRAM_D24
DRAM_D25
DRAM_D26
DRAM_D27
DRAM_D28
DRAM_D29
DRAM_D3
Y8
AC8
AA9
AE9
Y10
AE11
AB11
AC9
AD9
AA5
AD11
AC11
AA17
AA18
AC18
AE19
Y17
DRAM_D30
DRAM_D31
DRAM_D32
DRAM_D33
DRAM_D34
DRAM_D35
DRAM_D36
DRAM_D37
DRAM_D38
DRAM_D39
DRAM_D4
Y18
AB19
AC19
AC1
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
141
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
DRAM_D40
DRAM_D41
DRAM_D42
DRAM_D43
DRAM_D44
DRAM_D45
DRAM_D46
DRAM_D47
DRAM_D48
DRAM_D49
DRAM_D5
Y19
AB20
AB21
AD21
Y20
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
DRAM_DATA40
DRAM_DATA41
DRAM_DATA42
DRAM_DATA43
DRAM_DATA44
DRAM_DATA45
DRAM_DATA46
DRAM_DATA47
DRAM_DATA48
DRAM_DATA49
DRAM_DATA05
DRAM_DATA50
DRAM_DATA51
DRAM_DATA52
DRAM_DATA53
DRAM_DATA54
DRAM_DATA55
DRAM_DATA56
DRAM_DATA57
DRAM_DATA58
DRAM_DATA59
DRAM_DATA06
DRAM_DATA60
DRAM_DATA61
DRAM_DATA62
DRAM_DATA63
DRAM_DATA07
DRAM_DATA08
DRAM_DATA09
DRAM_DQM0
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Output
Output
Output
Output
Output
Output
Output
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
0
AA20
AE21
AC21
AC22
AE22
AD1
DRAM_D50
DRAM_D51
DRAM_D52
DRAM_D53
DRAM_D54
DRAM_D55
DRAM_D56
DRAM_D57
DRAM_D58
DRAM_D59
DRAM_D6
AE24
AC24
AB22
AC23
AD25
AC25
AB25
AA21
Y25
Y22
AB4
DRAM_D60
DRAM_D61
DRAM_D62
DRAM_D63
DRAM_D7
AB23
AA23
Y23
W25
AE4
DRAM_D8
AD5
DRAM_D9
AE5
DRAM_DQM0
DRAM_DQM1
DRAM_DQM2
DRAM_DQM3
DRAM_DQM4
DRAM_DQM5
DRAM_DQM6
AC3
AC6
DRAM_DQM1
0
AB8
DRAM_DQM2
0
AE10
AB18
AC20
AD24
DRAM_DQM3
0
DRAM_DQM4
0
DRAM_DQM5
0
DRAM_DQM6
0
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
142
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
DRAM_DQM7
DRAM_RAS
Y21
AB15
Y6
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_DRAM
NVCC_MIPI
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
DRAM_DQM7
DRAM_RAS_B
Output
Output
Output
Output
Output
Output
Output
Output
Output
—
0
0
DRAM_RESET
DRAM_SDBA0
DRAM_SDBA1
DRAM_SDBA2
DRAM_SDCKE0
DRAM_SDCKE1
DRAM_RESET
0
AC15
Y15
DRAM_SDBA0
0
DRAM_SDBA1
0
AB12
Y11
DRAM_SDBA2
0
DRAM_SDCKE0
DRAM_SDCKE1
DRAM_SDCLK0_P
DRAM_SDCLK0_N
DRAM_SDCLK1_P
DRAM_SDCLK1_N
DRAM_ODT0
0
AA11
0
DRAM_SDCLK_0 AD15
DRAM_SDCLK_0_B AE15
DRAM_SDCLK_1 AD14
DRAM_SDCLK_1_B AE14
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
0
—
—
0
Output
—
DDRCLK
DDR
—
—
0
DRAM_SDODT0
DRAM_SDODT1
DRAM_SDQS0
DRAM_SDQS0_B
DRAM_SDQS1
DRAM_SDQS1_B
DRAM_SDQS2
DRAM_SDQS2_B
DRAM_SDQS3
AC16
AB17
AE3
ALT0
ALT0
Output
Output
Input
—
DDR
DRAM_ODT1
0
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DDRCLK
DDRCLK ALT0
DRAM_SDQS0_P
DRAM_SDQS0_N
DRAM_SDQS1_P
DRAM_SDQS1_N
DRAM_SDQS2_P
DRAM_SDQS2_N
DRAM_SDQS3_P
DRAM_SDQS3_N
DRAM_SDQS4_P
DRAM_SDQS4_N
DRAM_SDQS5_P
DRAM_SDQS5_N
DRAM_SDQS6_P
DRAM_SDQS6_N
DRAM_SDQS7_P
DRAM_SDQS7_N
DRAM_SDWE_B
DSI_CLK_N
Hi-Z
—
Hi-Z
—
Hi-Z
—
Hi-Z
—
Hi-Z
—
Hi-Z
—
Hi-Z
—
Hi-Z
—
0
AD3
AD6
AE6
—
Input
—
—
AD8
AE8
Input
—
—
AC10
Input
—
DRAM_SDQS3_B AB10
DRAM_SDQS4 AD18
DRAM_SDQS4_B AE18
DRAM_SDQS5 AD20
DRAM_SDQS5_B AE20
DRAM_SDQS6 AD23
DRAM_SDQS6_B AE23
DRAM_SDQS7 AA25
DRAM_SDQS7_B AA24
—
Input
—
—
Input
—
—
Input
—
—
Input
—
DDRCLK
—
ALT0
—
DRAM_SDWE
DSI_CLK0M
DSI_CLK0P
DSI_D0M
AB16
H3
DDR
—
Output
—
—
—
—
—
—
H4
NVCC_MIPI
—
—
DSI_CLK_P
—
G2
NVCC_MIPI
—
—
DSI_DATA0_N
—
DSI_D0P
G1
NVCC_MIPI
—
—
DSI_DATA0_P
—
DSI_D1M
H2
NVCC_MIPI
—
—
DSI_DATA1_N
—
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
143
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
DSI_D1P
EIM_A16
EIM_A17
EIM_A18
EIM_A19
EIM_A20
EIM_A21
EIM_A22
EIM_A23
EIM_A24
EIM_A25
EIM_BCLK
EIM_CS0
EIM_CS1
EIM_D16
EIM_D17
EIM_D18
EIM_D19
EIM_D20
EIM_D21
EIM_D22
EIM_D23
EIM_D24
EIM_D25
EIM_D26
EIM_D27
EIM_D28
EIM_D29
EIM_D30
EIM_D31
EIM_DA0
EIM_DA1
EIM_DA2
EIM_DA3
EIM_DA4
EIM_DA5
H1
NVCC_MIPI
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM0
NVCC_EIM2
NVCC_EIM1
NVCC_EIM1
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM0
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
—
—
DSI_DATA1_P
EIM_ADDR16
EIM_ADDR17
EIM_ADDR18
EIM_ADDR19
EIM_ADDR20
EIM_ADDR21
EIM_ADDR22
EIM_ADDR23
EIM_ADDR24
EIM_ADDR25
EIM_BCLK
—
—
H25
G24
J22
G25
H22
H23
F24
J21
F25
H19
N22
H24
J23
C25
F21
D24
G21
G20
H20
E23
D25
F22
G22
E24
E25
G23
J19
J20
H21
L20
J25
L21
K24
L22
L23
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Output
Input
0
0
0
0
0
0
0
0
0
0
0
EIM_CS0_B
EIM_CS1_B
GPIO3_IO16
GPIO3_IO17
GPIO3_IO18
GPIO3_IO19
GPIO3_IO20
GPIO3_IO21
GPIO3_IO22
GPIO3_IO23
GPIO3_IO24
GPIO3_IO25
GPIO3_IO26
GPIO3_IO27
GPIO3_IO28
GPIO3_IO29
GPIO3_IO30
GPIO3_IO31
EIM_AD00
1
1
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
EIM_AD01
Input
EIM_AD02
Input
EIM_AD03
Input
EIM_AD04
Input
EIM_AD05
Input
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
144
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
EIM_DA6
EIM_DA7
K25
L25
L24
M21
M22
M20
M24
M23
N23
N24
K21
K23
E22
F23
K22
J24
K20
M25
U21
V20
V23
V22
W23
W21
W22
V21
U20
W20
T5
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM2
NVCC_EIM0
NVCC_EIM0
NVCC_EIM1
NVCC_EIM1
NVCC_EIM1
NVCC_EIM2
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_ENET
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT5
ALT5
ALT0
ALT0
ALT0
ALT0
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
EIM_AD06
EIM_AD07
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Output
Output
Input
Input
Output
Output
Output
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
1
EIM_DA8
EIM_AD08
EIM_DA9
EIM_AD09
EIM_DA10
EIM_DA11
EIM_DA12
EIM_DA13
EIM_DA14
EIM_DA15
EIM_EB0
EIM_AD10
EIM_AD11
EIM_AD12
EIM_AD13
EIM_AD14
EIM_AD15
EIM_EB0_B
EIM_EB1_B
GPIO2_IO30
GPIO2_IO31
EIM_LBA_B
EIM_OE
EIM_EB1
1
EIM_EB2
PU (100K)
PU (100K)
1
EIM_EB3
EIM_LBA
EIM_OE
1
EIM_RW
EIM_RW
1
EIM_WAIT
ENET_CRS_DV
ENET_MDC
ENET_MDIO
ENET_REF_CLK3
ENET_RX_ER
ENET_RXD0
ENET_RXD1
ENET_TX_EN
ENET_TXD0
ENET_TXD1
GPIO_0
EIM_WAIT
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
GPIO1_IO25
GPIO1_IO31
GPIO1_IO22
GPIO1_IO23
GPIO1_IO24
GPIO1_IO27
GPIO1_IO26
GPIO1_IO28
GPIO1_IO30
GPIO1_IO29
GPIO1_IO00
GPIO1_IO01
GPIO7_IO11
GPIO7_IO12
GPIO7_IO13
GPIO4_IO05
GPIO1_IO02
GPIO1_IO03
GPIO_1
T4
GPIO_16
R2
GPIO_17
R1
GPIO_18
P6
GPIO_19
P5
GPIO_2
T1
GPIO_3
R7
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
145
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
GPIO_4
GPIO_5
R6
R4
T3
R3
R5
T2
J5
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
HDMI_VPH
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
—
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
—
GPIO1_IO04
GPIO1_IO05
Input
Input
Input
Input
Input
Input
—
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
—
GPIO_6
GPIO1_IO06
GPIO_7
GPIO1_IO07
GPIO_8
GPIO1_IO08
GPIO_9
GPIO1_IO09
HDMI_CLKM
HDMI_CLKP
HDMI_D0M
HDMI_D0P
HDMI_D1M
HDMI_D1P
HDMI_D2M
HDMI_D2P
HDMI_HPD
JTAG_MOD
JTAG_TCK
JTAG_TDI
HDMI_TX_CLK_N
HDMI_TX_CLK_P
HDMI_TX_DATA0_N
HDMI_TX_DATA0_P
HDMI_TX_DATA1_N
HDMI_TX_DATA1_P
HDMI_TX_DATA2_N
HDMI_TX_DATA2_P
HDMI_TX_HPD
JTAG_MODE
JTAG_TCK
J6
HDMI_VPH
—
—
—
—
K5
K6
J3
HDMI_VPH
—
—
—
—
HDMI_VPH
—
—
—
—
HDMI_VPH
—
—
—
—
J4
HDMI_VPH
—
—
—
—
K3
K4
K1
H6
H5
G5
G6
C3
C2
W5
U7
W6
U5
T6
V6
U6
W4
T7
V5
HDMI_VPH
—
—
—
—
HDMI_VPH
—
—
—
—
HDMI_VPH
—
—
—
—
NVCC_JTAG
NVCC_JTAG
NVCC_JTAG
NVCC_JTAG
NVCC_JTAG
NVCC_JTAG
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
NVCC_GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
ALT0
ALT0
ALT0
ALT0
ALT0
ALT0
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
—
Input
Input
Input
Output
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
—
PU (100K)
PU (47K)
PU (47K)
Keeper
PU (47K)
PU (47K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
—
JTAG_TDI
JTAG_TDO
JTAG_TMS
JTAG_TRSTB
KEY_COL0
KEY_COL1
KEY_COL2
KEY_COL3
KEY_COL4
KEY_ROW0
KEY_ROW1
KEY_ROW2
KEY_ROW3
KEY_ROW4
LVDS0_CLK_N
LVDS0_CLK_P
LVDS0_TX0_N
LVDS0_TX0_P
LVDS0_TX1_N
JTAG_TDO
JTAG_TMS
JTAG_TRST_B
GPIO4_IO06
GPIO4_IO08
GPIO4_IO10
GPIO4_IO12
GPIO4_IO14
GPIO4_IO07
GPIO4_IO09
GPIO4_IO11
GPIO4_IO13
GPIO4_IO15
V4 NVCC_LVDS_2P5 LVDS
V3 NVCC_LVDS_2P5 LVDS
U2 NVCC_LVDS_2P5 LVDS
U1 NVCC_LVDS_2P5 LVDS
U4 NVCC_LVDS_2P5 LVDS
LVDS0_CLK_N
LVDS0_CLK_P
LVDS0_TX0_N
LVDS0_TX0_P
LVDS0_TX1_N
ALT0
—
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
146
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
LVDS0_TX1_P
LVDS0_TX2_N
LVDS0_TX2_P
LVDS0_TX3_N
LVDS0_TX3_P
LVDS1_CLK_N
LVDS1_CLK_P
LVDS1_TX0_N
LVDS1_TX0_P
LVDS1_TX1_N
LVDS1_TX1_P
LVDS1_TX2_N
LVDS1_TX2_P
LVDS1_TX3_N
LVDS1_TX3_P
NANDF_ALE
NANDF_CLE
NANDF_CS0
NANDF_CS1
NANDF_CS2
NANDF_CS3
NANDF_D0
U3 NVCC_LVDS_2P5 LVDS
V2 NVCC_LVDS_2P5 LVDS
V1 NVCC_LVDS_2P5 LVDS
W2 NVCC_LVDS_2P5 LVDS
W1 NVCC_LVDS_2P5 LVDS
Y3 NVCC_LVDS_2P5 LVDS
Y4 NVCC_LVDS_2P5 LVDS
Y1 NVCC_LVDS_2P5 LVDS
Y2 NVCC_LVDS_2P5 LVDS
AA2 NVCC_LVDS_2P5 LVDS
AA1 NVCC_LVDS_2P5 LVDS
AB1 NVCC_LVDS_2P5 LVDS
AB2 NVCC_LVDS_2P5 LVDS
AA3 NVCC_LVDS_2P5 LVDS
AA4 NVCC_LVDS_2P5 LVDS
ALT0
—
LVDS0_TX1_P
LVDS0_TX2_N
LVDS0_TX2_P
LVDS0_TX3_N
LVDS0_TX3_P
LVDS1_CLK_N
LVDS1_CLK_P
LVDS1_TX0_N
LVDS1_TX0_P
LVDS1_TX1_N
LVDS1_TX1_P
LVDS1_TX2_N
LVDS1_TX2_P
LVDS1_TX3_N
LVDS1_TX3_P
GPIO6_IO08
GPIO6_IO07
GPIO6_IO11
GPIO6_IO14
GPIO6_IO15
GPIO6_IO16
GPIO2_IO00
GPIO2_IO01
GPIO2_IO02
GPIO2_IO03
GPIO2_IO04
GPIO2_IO05
GPIO2_IO06
GPIO2_IO07
GPIO6_IO10
GPIO6_IO09
SRC_ONOFF
PCIE_RX_N
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
ALT0
—
Input
—
Keeper
—
ALT0
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
—
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
—
Keeper
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
—
A16
C15
F15
C16
A17
D16
A18
C17
F16
D17
A19
B18
E17
C18
B16
E15
D12
B1
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
VDD_SNVS_IN
PCIE_VPH
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
—
NANDF_D1
NANDF_D2
NANDF_D3
NANDF_D4
NANDF_D5
NANDF_D6
NANDF_D7
NANDF_RB0
NANDF_WP_B
ONOFF
PCIE_RXM
—
PCIE_RXP
B2
PCIE_VPH
—
—
PCIE_RX_P
—
—
PCIE_TXM
A3
PCIE_VPH
—
—
PCIE_TX_N
—
—
PCIE_TXP
B3
PCIE_VPH
—
—
PCIE_TX_P
—
—
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
NXP Semiconductors
147
Package Information and Contact Assignments
Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
PMIC_ON_REQ
D11
VDD_SNVS_IN
GPIO
ALT0
SNVS_PMIC_ON_REQ
Output
Open
Drain with
PU (100K)
PMIC_STBY_REQ F11
VDD_SNVS_IN
VDD_SNVS_IN
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
NVCC_RGMII
GPIO
GPIO
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
DDR
—
ALT0
ALT0
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
—
CCM_PMIC_STBY_REQ
SRC_POR_B
GPIO6_IO25
GPIO6_IO27
GPIO6_IO28
GPIO6_IO29
GPIO6_IO24
GPIO6_IO30
GPIO6_IO20
GPIO6_IO21
GPIO6_IO22
GPIO6_IO23
GPIO6_IO26
GPIO6_IO19
RTC_XTALI
Output
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
—
0
POR_B
RGMII_RD0
RGMII_RD1
RGMII_RD2
RGMII_RD3
RGMII_RX_CTL
RGMII_RXC
RGMII_TD0
RGMII_TD1
RGMII_TD2
RGMII_TD3
RGMII_TX_CTL
RGMII_TXC
RTC_XTALI
RTC_XTALO
SATA_RXM
SATA_RXP
SATA_TXM
SATA_TXP
SD1_CLK
C11
C24
B23
B24
D23
D22
B25
C22
F20
E21
A24
C23
D21
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
PD (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
PD (100K)
—
D9 VDD_SNVS_CAP
C9 VDD_SNVS_CAP
—
—
RTC_XTALO
SATA_PHY_RX_N
SATA_PHY_RX_P
SATA_PHY_TX_N
SATA_PHY_TX_P
GPIO1_IO20
GPIO1_IO18
GPIO1_IO16
GPIO1_IO17
GPIO1_IO19
GPIO1_IO21
GPIO1_IO10
GPIO1_IO11
GPIO1_IO15
GPIO1_IO14
GPIO1_IO13
GPIO1_IO12
GPIO7_IO03
GPIO7_IO02
—
—
A14
B14
B12
A12
D20
B21
A21
C20
E19
F18
C21
F19
A22
E20
A23
B22
D14
B13
SATA_VPH
SATA_VPH
SATA_VPH
SATA_VPH
NVCC_SD1
NVCC_SD1
NVCC_SD1
NVCC_SD1
NVCC_SD1
NVCC_SD1
NVCC_SD2
NVCC_SD2
NVCC_SD2
NVCC_SD2
NVCC_SD2
NVCC_SD2
NVCC_SD3
NVCC_SD3
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
SD1_CMD
SD1_DAT0
SD1_DAT1
SD1_DAT2
SD1_DAT3
SD2_CLK
SD2_CMD
SD2_DAT0
SD2_DAT1
SD2_DAT2
SD2_DAT3
SD3_CLK
SD3_CMD
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Table 87. 21 x 21 mm Functional Contact Assignments (continued)
Out of Reset Condition1
Default
Mode
(Reset
Mode)
Ball Name
Ball
Power Group Ball Type
Default Function
(Signal Name)
Input/Output
Value2
SD3_DAT0
SD3_DAT1
SD3_DAT2
SD3_DAT3
SD3_DAT4
SD3_DAT5
SD3_DAT6
SD3_DAT7
SD3_RST
E14
F14
A15
B15
D13
C13
E13
F13
D15
E16
B17
D18
B19
F17
A20
E18
C19
B20
D19
E11
E12
NVCC_SD3
NVCC_SD3
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
—
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT5
ALT0
—
GPIO7_IO04
GPIO7_IO05
GPIO7_IO06
GPIO7_IO07
GPIO7_IO01
GPIO7_IO00
GPIO6_IO18
GPIO6_IO17
GPIO7_IO08
GPIO7_IO10
GPIO7_IO09
GPIO2_IO08
GPIO2_IO09
GPIO2_IO10
GPIO2_IO11
GPIO2_IO12
GPIO2_IO13
GPIO2_IO14
GPIO2_IO15
SNVS_TAMPER
TCU_TEST_MODE
USB_H1_DN
USB_H1_DP
USB_OTG_CHD_B
USB_OTG_DN
USB_OTG_DP
XTALI
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
—
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PU (100K)
PD (100K)
PD (100K)
—
NVCC_SD3
NVCC_SD3
NVCC_SD3
NVCC_SD3
NVCC_SD3
NVCC_SD3
NVCC_SD3
SD4_CLK
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
NVCC_NANDF
VDD_SNVS_IN
VDD_SNVS_IN
SD4_CMD
SD4_DAT0
SD4_DAT1
SD4_DAT2
SD4_DAT3
SD4_DAT4
SD4_DAT5
SD4_DAT6
SD4_DAT7
TAMPER
TEST_MODE
USB_H1_DN
USB_H1_DP
USB_OTG_CHD_B
USB_OTG_DN
USB_OTG_DP
XTALI
F10 VDD_USB_CAP
E10 VDD_USB_CAP
—
—
—
—
—
—
B8
B6
A6
A7
B7
VDD_USB_CAP
VDD_USB_CAP
VDD_USB_CAP
NVCC_PLL
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
XTALO
NVCC_PLL
—
—
XTALO
—
—
1
2
The state immediately after reset and before ROM firmware or software has executed.
Variance of the pull-up and pull-down strengths are shown in the tables as follows:
• Table 21, “GPIO I/O DC Parameters,” on page 37.
• Table 23, “LPDDR2 I/O DC Electrical Parameters,” on page 39.
• Table 24, “DDR3/DDR3L I/O DC Electrical Parameters,” on page 40.
3
ENET_REF_CLK is used as a clock source for MII and RGMII modes only. RMII mode uses either GPIO_16 or RGMII_TX_CTL
as a clock source. For more information on these clocks, see your specific device reference manual and the Hardware
Development Guide for i.MX 6Quad, 6Dual, 6DualLite, 6Solo Families of Applications Processors (IMX6DQ6SDLHDG).
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6.2.4
Signals with Different Reset States
For most of the signals, the state during reset is same as the state after reset, given in Out of Reset Condition
column of Table 87, “21 x 21 mm Functional Contact Assignments”. However, there are few signals for
which the state during reset is different from the state after reset. These signals along with their state during
reset are given in Table 88.
Table 88. Signals with Differing Before Reset and After Reset States
Before Reset State
Ball Name
Input/Output
Value
EIM_A16
EIM_A17
EIM_A18
EIM_A19
EIM_A20
EIM_A21
EIM_A22
EIM_A23
EIM_A24
EIM_A25
EIM_DA0
EIM_DA1
EIM_DA2
EIM_DA3
EIM_DA4
EIM_DA5
EIM_DA6
EIM_DA7
EIM_DA8
EIM_DA9
EIM_DA10
EIM_DA11
EIM_DA12
EIM_DA13
EIM_DA14
EIM_DA15
EIM_EB0
EIM_EB1
EIM_EB2
EIM_EB3
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
Input
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
PD (100K)
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Package Information and Contact Assignments
Table 88. Signals with Differing Before Reset and After Reset States (continued)
Before Reset State
Ball Name
Input/Output
Value
EIM_LBA
EIM_RW
Input
Input
PD (100K)
PD (100K)
EIM_WAIT
GPIO_17
GPIO_19
KEY_COL0
Input
PD (100K)
Output
Output
Output
Drive state unknown (x)
Drive state unknown (x)
Drive state unknown (x)
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6.2.5
21 x 21 mm, 0.8 mm Pitch Ball Map
Table 89 shows the FCPBGA 21 x 21 mm, 0.8 mm pitch ball map.
Table 89. 21 x 21 mm, 0.8 mm Pitch Ball Map
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Table 89. 21 x 21 mm, 0.8 mm Pitch Ball Map (continued)
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Table 89. 21 x 21 mm, 0.8 mm Pitch Ball Map (continued)
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Table 89. 21 x 21 mm, 0.8 mm Pitch Ball Map (continued)
1
MLB is only supported in automotive and consumer graded parts. These balls are not connected in industrial graded parts.
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Revision History
7 Revision History
Table 90 provides a revision history for the i.MX 6Dual/6Quad data sheet.
Table 90. i.MX 6Dual/6Quad Data Sheet Document Revision History
Rev.
Number
Date
Substantive Change(s)
6
10/2018 Revision 6 changes:
• Table 20, “XTALI and RTC_XTALI DC Parameters,” on page 37,
– Row: XTALI input leakage current at startup, IXTALI_STARTUP: Changed from “... driven 32 KHz RTC
clock @ 1.1V” to “...driven 24 MHz clock at 1.1V.”
• Table 47, “eMMC4.4/4.41 Interface Timing Specification,” on page 77,
– Row: SD2, uSDHC Output Delay: Changed tOD from 2.5 ns minimum to 2.8 ns and 7.1 ns maximum
to 6.8 ns.
(Revision History table continues on next page.)
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Revision History
Table 90. i.MX 6Dual/6Quad Data Sheet Document Revision History (continued)
Rev.
Number
Date
Substantive Change(s)
5
09/2017 Rev. 5 changes include the following:
• Changed throughout:
– Changed terminology from “floating” to “not connected”.
– Removed VADC feature from 19mm x 19mm package. Contact NXP sales and marketing with
enablement options.
• Section 1, “Introduction” on page 1: Corrected A9 core speed from 1 GHz to 800 MHz.
• Section 1.2, “Features” on page 4: Changed Internal/external peripheral item from “LVDS serial ports—
One port up to 165 MPixels/sec…” to: “…—One port up to 170 MPixels/sec…”.
• Table 1, “Example Orderable Part Numbers”: Added part numbers for silicon revision 1.4 with suffix “E”.
• Section 1.3, “Signal Naming Convention” on page 7” and Section 6.1, “Signal Naming Convention”:
changed wording from updated or changed signal naming, to standard signal naming.
• Table 2, “i.MX 6Dual/6Quad Modules List,” on page 9:
– Added bullet to uSDHC row: “Conforms to the SD Host Controller Standard Specification v3.0”
• Section 4, “Electrical Characteristics” on page 18: Changed several references from JESD and JEDEC
standards to cross references to the Section 4.10, “Multi-Mode DDR Controller (MMDC).
• Table 4, “Absolute Maximum Ratings,” on page 19: Multiple changes:
– Core supply voltages: Separated rows by LDO enabled and LDO bypass. For LDO enabled, changed
maximum value from 1.5 to 1.6V.
– Renamed Internal supply voltages to Core supply output voltage (LDO enabled) and changed
maximum value from 1.3 to 1.4V. Added symbol NVCC_PLL_OUT.
– Reordered VDD_HIGH_IN row and changed maximum value from 3.6 to 3.7V.
– DDR I/O supply voltage row changes:
— Changed Symbols from “Supplies denoted as I/O supply” to: “NVCC_DRAM”
— Added footnote.
– GPIO I/O supply voltage: Added symbols. Changed maximum value from 3.6 to 3.7V.
– Resequenced: HDMI, PCIe, and SATA PHY high (VPH) supply voltage to precede low (VP)
– Added row: RGMII I/O supply voltage
– Added row, Vin/Vout input/output voltage range (non-DDR pins) distinguishing between DDR pins.
– Changed maximum value for Vin/Vout input/output voltage range DDR pins to OVDD+0.4.
– Added footnotes to both maximum values of Vin/Vout input/output voltage range.
– Added row: USB_OTG_CHD_B
• Section 4.1.2, “Thermal Resistance” on page 20: Added NOTE: “Per JEDEC JESD51-2, the intent of
thermal resistance measurements…”.
• Section 4.1.5, “Maximum Measured Supply Currents” on page 24: Clarified language throughout this
section regarding the use case to estimate the maximum supply current.
• Section 4.2.1, “Power-Up Sequence” on page 31:
– Removed content about calculating the proper current limiting resistor for a coin cell.
– Removed inference to internal POR.
• Section 4.5.2, “OSC32K” on page 35: Removed content about calculating the proper current limiting
resistor for a coin cell.
• Section 4.6.1, “XTALI and RTC_XTALI (Clock Inputs) DC Parameters” on page 37:
– Added “NOTE: The Vil and Vih specifications only apply when an external clock source is used…”.
(Revision History table continues on next page.)
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Revision History
Table 90. i.MX 6Dual/6Quad Data Sheet Document Revision History (continued)
Date Substantive Change(s)
Rev.
Number
5
09/2017 • Table 20, “XTALI and RTC_XTALI DC Parameters,” on page 37:
– Added footnote to RTC_XTALI high level DC input voltage row: “This voltage specification must not be
exceeded and …”.
(Cont.)
Section 4.6.4, “RGMII I/O 2.5V I/O DC Electrical Parameters” on page 38: Added section and table.
• Section 4.10, “Multi-Mode DDR Controller (MMDC)” on page 60: Replaced section with new content.
Was: 4.9.4 “DDR SDRAM Specific Parameters (DDR3/DDR3L/LPDDR2)” with timing diagrams and
parameter tables for DDR3/DDR3L/LPDDR2.
• Table 47, “eMMC4.4/4.41 Interface Timing Specification,” on page 77,
– Corrected SD3, uSDHC Input Setup Time, minimum value from 2.6ns to 1.7ns.
– Added footnote to Card Input Clock regarding duty cycle range.
• Table 48, “SDR50/SDR104 Interface Timing Specification,” on page 78: Changes to Min/Max values:
– SD2 min from: 0.3 x tCLK; to: 0.46 x tCLK
– SD2 max from: 0.7 x tCLK to: 0.54 x tCLK
– SD3 min from: 0.3 x tCLK; to: 0.46 x tCLK. Also corrected ID from duplicate SD2 to SD3.
– SD3 max from: 0.7 x tCLK; to: 0.54 x tCLK
– SD5 max from: 1 ns; to: 0.74 ns
• Table 58, “Camera Input Signal Cross Reference, Format, and Bits Per Cycle,” on page 91: Changed
RGB565, 16 bits column heading from 2 cycles to 1 cycle.
• Table 59, “Sensor Interface Timing Characteristics,” on page 94, Sensor Interface Timing characteristics:
Added rows to include Vsync values.
• Table 86, “21 x 21 mm Supplies Contact Assignment,” on page 136: Added description to ZQPAD.
• Table 87, “21 x 21 mm Functional Contact Assignments,” on page 138:
– Changed rows DRAM_SDCLK_0 and DRAM_SDCLK_1, Out of Reset Conditions from “Input–Hi-Z” to
“Output–0”.
– Added description to GPANAIO row: “…output for NXP use only…”
(Revision History table continues on next page.)
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Table 90. i.MX 6Dual/6Quad Data Sheet Document Revision History (continued)
Date Substantive Change(s)
Rev.
Number
4
07/2015 • Added footnote to Table 1, “Example Orderable Part Numbers,” on page 3: If a 24 MHz input clock is
used (required for USB), the maximum SoC speed is limited to 996 MHz.
• Section 1.2, “Features” changed Five UARTs, from up to 4.0 Mbps, to up to 5.0 Mbps.
• Table 6, “Operating Ranges,” on page 21, Row: run mode: LDO bypassed, removed LDO bypassed for
operation up to 852 MHz.
• Table 6, “Operating Ranges,” on page 21: Row: VDD_HIGH internal regulator, changed minimum
parameter value from 2.8 to 2.7V.
• Table 6, “Operating Ranges,” on page 21: Removed footnote: VDDSOC and VDDPU output voltages
must be set according to this rule: VDDARM-VDDSOC/PU<50mV. This was a duplicate footnote,
renumbered footnotes accordingly.
• Table 6, “OperatingRanges,”onpage21:Changedvalue: Standby/DSMMode, VDD_SOC_IN, minimum
voltage, from 0.9V to 1.05V.
• Table 8, “Maximum Supply Currents,” on page 25, Differentiated VDD_ARM_IN, VDD_ARM23_IN, and
VDD_SOC_IN by frequency and by Power Virus/CoreMark maximum current.
• Table 20, “XTALI and RTC_XTALI DC Parameters,” on page 37, Added rows: Input capacitance; Startup
current; and DC input current and their values.
• Table 37, “EIM Bus Timing Parameters,” on page 51, Changed WE4–WE17 minimum and maximum
parameter values from, 0.5 t (k+1)/2-1.25, to 0.5 x t x (k+1)-1.25.
• Table 38, “EIM Asynchronous Timing Parameters Relative to Chip Select,,” on page 58 Added to end of
formulas in the minimum, typical, and maximum parameter values for WE31–WE42 and WE45–WE46,
× t. For example from 3-CSN, to 3-CSN× t. Also added maximum value to MAXDTI of 10.
• Table 58, “DDR3/DDR3L Write Cycle,” on page 90, Changed minimum parameter value of DDR17 from
240 to 125; and of DDR18 from 240 to 150.
• Figure 29, “LPDDR2 Command and Address Timing Diagram,” on page 91, LP2 signal cycle reduced.
• Table 62, “LPDDR2 Write Cycle,” on page 93, Changed LP21 minimum and maximum parameter value
from -0.25/+0.25 to 0.8/1.2.
• Figure 33, "ECSPI Master Mode Timing Diagram," on page 70, Added footnote: Note: ECSPIx_MOSI is
always driven (not tri-stated) between actual data transmissions. This limits the ECSPI to be connected
between a single master and a single slave.
• Figure 34, "ECSPI Slave Mode Timing Diagram," on page 71, Added footnote: Note: ECSPIx_MISO is
always driven (not tri-stated) between actual data transmissions. This limits the ECSPI to be connected
between a single master and a single slave.
• Figure 57, "Gated Clock Mode Timing Diagram," on page 92, Corrected IPU2_CSIx_HSYNC trace
drawing.
• Section 4.12.22, “USB PHY Parameters” Specified Battery Charging Specification applies to portable
devices only.
(Revision History table continues on next page.)
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Revision History
Table 90. i.MX 6Dual/6Quad Data Sheet Document Revision History (continued)
Date Substantive Change(s)
Rev.
Number
Rev. 3 02/2014 • Updates throughout for Silicon revision D, include:
- Figure 1 Part number nomenclature diagram.
- Example Orderable Part Number tables, Table 1
• Feature description for Miscellaneous IPs and interfaces; SSI and ESAI.
• Table 6, UART 1–5 description change: programmable baud rate up to 5 MHz.
• Table 6, uSDHC 1–4 description change: including SDXC cards up to 2 TB.
• Table 6, operating range for Run mode: LDO bypassed, minimum value corrected to 1.150 V.
• Table 6, table footnotes, added LDO enabled mode footnote for internal LDO output set points.
• Table 61, added table footnote to the Comment heading in the Comment column.
• Removed table “On-Chip LDOs and their On-Chip Loads.”
• Section 4.1.4, External Clock Sources; added Note, “The internal RTC oscillator does not …”.
• Section 4.1.5, reworded second paragraph about the power management IC to explain that a robust
thermal design is required for the increased system power dissipation.
• Table 8, Maximum Supply Currents: NVCC_RGMII Condition value changed to N=6.
• Table 8, Maximum Supply currents: Added row; NVCC_LVDS2P5
• Section 4.2.1 Power-Up Sequence: reworded third bulleted item regarding POR control.
• Section 4.2.1 Power-Up Sequence: removed Note.
• Section 4.5.2 OSC32K, second paragraph reworded to describe OSC32K automatic switching.
• Section 4.5.2 OSC32K, added Note following second paragraph to caution use of internal oscillator use.
• Table 20 XTALI and RTC_XTALI DC parameters; changed RTC_XTALI Vih minimum value to 0.8.
• Table 20 XTALI and RTC_XTALI DC parameters; changed RTC_XTALI Vih maximum value to 1.1.
• Table 34 Reset Timing Parameters; removed footnote.
• Section 4.9.3 External Interface Module; enhanced wording to first paragraph to describe operating
frequency for data transfers, and to explain register settings are valid for entire range of frequencies.
• Table 37. EIM Bus Timing Parameters; reworded footnotes for clarity.
• Table 38. EIM Asynchronous Timing Parameters; removed comment from the Max heading cell.
• Table 38. EIM Asynchronous Timing Parameters; reworded footnote 2 for clarity.
• Table 53. RMII Signal Timing; parameter M19 Max value relaxed to 13.5 ns.
• Table 95. Corrected the ALT5 Default Function names.
• Figure 96 and Figure 97 21 x 21 mm Lidded Package; updated drawing (Rev D).
Rev. 2.3 07/26
/2013
• Table 95, 21 x 21Functional Contact Assignments:
Restored NANDF_WP_B row and description.
• System Timing Parameters Table 34, Reset timing parameter, CC1 description clarified, change from:
“Duration of SRC_POR_B to be qualified as valid (input slope <= 5 ns)” to:
“Duration of SRC_POR_B to be qualified as valid”
and added a footnote to the parameter with the following text:
“SRC_POR_B rise and fall times must be 5 ns or less.”
This change was made for clarity and does not represent a specification change.
Rev. 2.2 07/2013 • Editor corrections to revision history links. No technical content changes.
Rev. 2.1 07/2013 • Figure 1, Changed temperature references from Consumer to Commercial.
• Table 95, 21 x 21Functional Contact Assignments:
—Removed rows: DRAM_VREF, HDMI_DDCCEC, and HDMI_REF.
—Due to a typographical error in revision 2.0, the ball names for rows EIM_DA2 through EIM_DA15 were
ordered incorrectly. This has been corrected in revision 2.1. The ball map is correct in both revision 2.0
and 2.1.
(Revision History table continues on next page.)
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Table 90. i.MX 6Dual/6Quad Data Sheet Document Revision History (continued)
Date Substantive Change(s)
Rev.
Number
Rev. 2 04/2013 Substantive changes throughout this document are as follows:
• Incorporated standardized signal names. This change is extensive throughout.
Added reference to EB792, i.MX Signal Name Mapping.
• Figures updated to align to standardized signal names.
• Aligned references to FCBGA to read FCPBGA throughout document.
• Updated references to eMMC standard to include 4.41.
• Table 1 “Example Industrial Grade Orderable Part Numbers”: Part Numbers MCIMX6Q4AVT10AC,
MCIMX6Q4AVT08AC, MCIMX6D4AVT10AC, and MCIMX6D4AVT08AC were updated to show GPU
instead of VPU as an option.
• Table 2, “i.MX 6Dual/6Quad Modules List,” Changed reference to Global Power Controller to read
General Power Controller.
• Table 4, “Absolute Maximum Ratings,” Added VDD_ARM23_IN to Core supply voltages.
• Table 6 “Operating Ranges”: Run Mode - LDO Enabled, VDD_ARM_IN/VDD_ARM23_IN, 792 MHz,
input voltage minimum changed to 1.275V and VDD_ARM CAP minimum changed to 1.150V.
NVCC_NAND, changed to NVCC_NANDF.
• Table 6 “Operating Ranges”: Added reference for information on product lifetime: i.MX 6Dual/6Quad
Product Usage Lifetime Estimates Application Note, AN4724.
• Table 9. “Maximum Supply Currents”: Added current for i.MX6Dual
• Table 10 “Stop Mode Current and Power Consumption”: Added SNVS Only mode.
• Table 22 “GPIO I/O DC Parameters”: Removed parameters Iskod and Isspp.
• Table 48, “ECSPI Master Mode Timing Parameters,” Updated parameter CS6 ECSPIx_SSx Lag Time
(CS hold time) Min from Half SCLK period to Half SCLK period-2.
• Table 77 “SD/eMMC4.3 Interface Timing Specification,” eMMC parameter SD8 value Min updated from
5.6 ns to 1.5 ns.
• Table 89 RGMII Signal Switching Specifications RGMII parameter TskewR units corrected.
• Table 134 “21 x 21 mm Functional Contact Assignments,” Updated GPIO_1 Ball Name value to PU
(100K).
• Table 134 “21 x 21 mm Functional Contact Assignments,” Clarification of ENET_REF_CLK naming.
• Removed section, EIM Signal Cross Reference. Signal names are now aligned with reference manual.
• Section 1.2, “Features added bulleted item regarding the SOC-level memory system.
• Section 4.2.1, “Power-Up Sequence” updated wording.
• Section 4.3.2, “Regulators for Analog Modules”: Added NVCC_PLL_OUT to section heading.
• Section 4.6.1, “XTALI and RTC_XTALI (Clock Inputs) DC Parameters”: Added section.
• Section 4.10, “General-Purpose Media Interface (GPMI) Timing” figures replaced, tables revised.
i.MX 6Dual/6Quad Applications Processors for Industrial Products, Rev. 6, 11/2018
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Document Number: IMX6DQIEC
Rev. 6
11/2018
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