SPC5675KFF0VMM2R [NXP]
MPC5675K Microcontroller;型号: | SPC5675KFF0VMM2R |
厂家: | NXP |
描述: | MPC5675K Microcontroller PC 微控制器 |
文件: | 总147页 (文件大小:1178K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
NXP Semiconductors
Data Sheet: Technical Data
Document Number: MPC5675K
Rev. 8.1, 04/2020
MPC5675K
MPC5675K Microcontroller
Data Sheet
1
Introduction
257 MAPBGA
473 MAPBGA
(19 x 19 mm)
(14 x 14 mm)
1
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.1 Document overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.2 Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.3 Device comparison. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
1.4 Block diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
1.5 Feature list . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
1.6 Feature details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Package pinouts and signal descriptions . . . . . . . . . . . . . . . . 17
2.1 Package pinouts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
2.2 Pin descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Electrical characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
3.1 Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
3.2 Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . 69
3.3 Recommended operating conditions . . . . . . . . . . . . . . 70
3.4 Thermal characteristics . . . . . . . . . . . . . . . . . . . . . . . . 72
3.5 Electromagnetic interference (EMI) characteristics . . . 73
3.6 Electrostatic discharge (ESD) characteristics. . . . . . . . 74
3.7 Static latch-up (LU). . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
1.1
Document overview
This document provides electrical specifications, pin
assignments, and package diagrams for the MPC5675K series
of microcontroller units (MCUs).
2
3
1.2
Description
The MPC5675K microcontroller, a SafeAssure solution, is a
32-bit embedded controller designed for advanced driver
assistance systems with RADAR, CMOS imaging, LIDAR
and ultrasonic sensors, and multiple 3-phase motor control
applications as in hybrid electric vehicles (HEV) in
automotive and high temperature industrial applications.
A member of NXP Semiconductor’s MPC5500/5600 family,
it contains the Book E compliant Power Architecture
technology core with Variable Length Encoding (VLE). This
core complies with the Power Architecture embedded
category, and is 100 percent user mode compatible with the
original Power PC™ user instruction set architecture (UISA).
It offers system performance up to four times that of its
MPC5561 predecessor, while bringing you the reliability and
familiarity of the proven Power Architecture technology.
3.8 Power
Management
Controller
(PMC)
electrical
characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
3.9 Supply current characteristics . . . . . . . . . . . . . . . . . . . 76
3.10 Temperature sensor electrical characteristics . . . . . . . 77
3.11 Main oscillator electrical characteristics . . . . . . . . . . . . 77
3.12 FMPLL electrical characteristics. . . . . . . . . . . . . . . . . . 78
3.13 16 MHz RC oscillator electrical characteristics . . . . . . 79
3.14 ADC electrical characteristics. . . . . . . . . . . . . . . . . . . . 80
3.15 Flash memory electrical characteristics . . . . . . . . . . . . 85
3.16 SRAM memory electrical characteristics . . . . . . . . . . . 87
3.17 GP pads specifications. . . . . . . . . . . . . . . . . . . . . . . . . 87
3.18 PDI pads specifications . . . . . . . . . . . . . . . . . . . . . . . . 90
3.19 DRAM pad specifications . . . . . . . . . . . . . . . . . . . . . . . 93
3.20 RESET characteristics . . . . . . . . . . . . . . . . . . . . . . . . 100
3.21 Reset sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
3.22 Peripheral timing characteristics. . . . . . . . . . . . . . . . . 107
Package characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . 131
4.1 Package mechanical data. . . . . . . . . . . . . . . . . . . . . . 131
Orderable parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
Reference documents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
Document revision historys . . . . . . . . . . . . . . . . . . . . . . . . . 137
A comprehensive suite of hardware and software
development tools is available to help simplify and speed
system design. Development support is available from
leading tools vendors providing compilers, debuggers and
simulation development environments.
4
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
1.3
Device comparison
Table 1. MPC5675K family device comparison
Features
MPC5673K MPC5674K
MPC5675K
CPU
Type
2 × e200z7d (SoR1) in lock-step or decoupled operation
Harvard
Architecture
Execution speed
0–150 MHz (+2% FM) 0–180 MHz (+2% FM) 0–180 MHz (+2% FM)
Nominal platform
frequency (in 1:1, 1:2,
and 1:3 modes)
0–75 MHz (+2% FM)
0–90 MHz (+2% FM)
0–90 MHz (+2% FM)
MMU
64 entries (SoR)
Yes
Instruction set PPC
Instruction set VLE
Instruction cache
Data cache
Yes
16 KB, 4-way with EDC (SoR)
16 KB, 4-way with Parity (SoR)
Yes (SoR)
MPU
Buses
Core bus
32-bit address, 64-bit data
32-bit address, 32-bit data
Yes (SoR)
Internal periphery bus
Master × slave ports
Static RAM (SRAM)
Code flash memory
Data flash memory
XBAR
Memory
256 KB (ECC)
1 MB2 (ECC)
384 KB (ECC)
512 KB (ECC)
2 MB2 (ECC)
1.5 MB2 (ECC)
64 KB2 (ECC)
Modules
Analog-to-Digital
Converter (ADC)
257 pin pkg: 4 × 12 bit (22 external channels)
473 pin pkg: 4 12 bit (up to 34 external channels)
×
CRC unit
2 (3 contexts each)
2 modules
Cross Triggering Unit
(CTU)
Deserial Serial
Peripheral Interface
(DSPI)
2 modules
(3 chip selects)3
3 modules4
Digital I/Os
≥ 16
DRAM Controller
(DRAMC)
No
Yes5
Enhanced Direct
Memory Access (eDMA)
2 modules, 32 channels each
3 modules, 6 channels each
eTimer
MPC5675K Microcontroller Data Sheet, Rev. 8.1
2
NXP Semiconductors
Introduction
Table 1. MPC5675K family device comparison (continued)
Features
MPC5673K
MPC5674K
MPC5675K
Modules
(cont.)
External Bus Interface
(EBI)
1 module5
16-bit Data + Address or 32-bit Data with Address bus muxed8
Fast Ethernet Controller
(FEC)
1 module
Fault Collection and
Control Unit (FCCU)
1 module
FlexCAN
FlexPWM
FlexRay
I2C
4 modules (32 message buffers each)
3 modules (each 4 × 3 channels)
Optional
2 modules6
3 modules7
3 modules
Interrupt Controller
(INTC)
Yes (SoR)
1 module8
LINFlex
4 modules
Parallel Data Interface
(PDI)
Periodic Interrupt Timer
(PIT)
1 module, 4 channels
Yes (SoR)
Software Watchdog
Timer (SWT)
System Timer Module
(STM)
Yes (SoR)
Temperature sensor
Wakeup Unit (WKPU)
Crossbar switch (XBAR)
1 module
Yes
3 modules, 2 are user-configurable
3 modules
Clocking
Clock monitor unit
(CMU)
Frequency-modulated
phase-locked loop
(FMPLL)
2 modules (system and auxiliary)
IRCOSC – 16 MHz
XOSC 4–40 MHz
1
1
Supply
Power management unit
(PMU)
Yes
1.2 V low-voltage
detector (LVD12)
1
1.2 V high-voltage
detector (HVD12)
1
2.7 V low-voltage
detector (LVD27)
4
Debug
Nexus
Class 3+ (for cores and SRAM ports)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
3
Introduction
Table 1. MPC5675K family device comparison (continued)
Features
MPC5673K
MPC5674K
MPC5675K
Packages
MAPBGA
257 pins
473 pins
Temperature Ambient
See the TA recommended operating condition in the device data sheet
1
Sphere of Replication.
2
3
4
5
6
7
8
Does not include Test or Shadow Flash memory space.
DSPI_0 and DSPI_1.
DSPI_0 has 8 chip selects; DSPI_1 and DSPI_2 have 4 chip selects each.
Available only on 473-pin package.
Any two of the three I2C can be chosen.
LinFlex_0, LinFlex_1, and LinFlex_2.
DDR available only on 473 package. Other modules available as follows:
EBI or DDR on 473 package
EBI + PDI on 473 package
DDR + PDI on 473 package
PDI only on 257 package
MPC5675K Microcontroller Data Sheet, Rev. 8.1
4
NXP Semiconductors
Introduction
1.4
Block diagram
Figure 1 shows a top-level block diagram of the MPC5675K device.
e200z7d
Core_1
e200z7d
Core_0
Debug
PMC
ECSM_1
STM
SWT_1
INTC
PMC
ECSM_0
STM
SWT_0
INTC
JTAG
Nexus
SPE2
VLE
SPE2
VLE
Redundancy
Checker[0]
MMU
MMU
I-CACHE
D-CACHE
I-CACHE
D-CACHE
l
SEMA4
SEMA4
Redundancy
Checker[5]
PDI
Ethernet
DMA_1
DMA_0
Crossbar switch (XBAR_2)
Redundancy
Checker[7]
Crossbar switch (XBAR_1)
Memory protection unit
Crossbar switch (XBAR_0)
Memory protection unit
Redundancy
Checker[6]
DDR Controller
External Bus
Interface
PFLASHC
PFLASHC
2MB Flash with ECC Logic
SRAM with ECC Logic
SRAM with ECC Logic
PBRIDGE
Redundancy
Checker[3]
Redundancy
Checker[4]
PBRIDGE
Redundancy
Checker[2]
ADC
BAM
CMU
CRC
– Analog-to-digital converter
– Boot assist module
– Clock monitoring unit
– Cyclic redundancy check unit
– Cross triggering unit
IRCOSC
JTAG
MC
– Internal RC oscillator
– Joint Test Action Group interface
– Mode entry, clock, reset, and power modules
– Mobile double data rate dynamic RAM
mDDR
CTU
PBRIDGE – Peripheral bridge
DSPI
EBI
ECC
– Deserial serial peripheral interface
– External bus interface
– Error correction code
– Error correction status module
– Enhanced direct memory access controller
– Fault collection and control unit
– Fast Ethernet controller
– Controller area network controller
– Pulse width modulator module
– Frequency-modulated phase-locked loop
– Inter-integrated circuit controller
– Interrupt controller
PDI
PIT
PMC
RC
RTC
SEMA4
SIUL
SSCM
STM
SWT
TSENS
XOSC
– Parallel data interface
– Periodic interrupt timer
– Power management controller
– Redundancy checker
– Real time clock
ECSM
eDMA
FCCU
FEC
FlexCAN
FlexPWM
FMPLL
I2C
– Semaphore unit
– System integration unit Lite
– System status and configuration module
– System timer module
– Software watchdog timer
– Temperature sensor
INTC
– Crystal oscillator
Figure 1. MPC5675K block diagram
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
5
Introduction
1.5
Feature list
High-performance e200z7d dual core
•
— 32-bit Power Architecture technology CPU
— Up to 180 MHz core frequency
— Dual-issue core
— Variable length encoding (VLE)
— Memory management unit (MMU) with 64 entries
— 16 KB instruction cache and 16 KB data cache
Memory available
•
•
— Up to 2 MB code flash memory with ECC
— 64 KB data flash memory with ECC
— Up to 512 KB on-chip SRAM with ECC
SIL3/ASILD innovative safety concept: LockStep mode and fail-safe protection
— Sphere of replication (SoR) for key components
— Redundancy checking units on outputs of the SoR connected to FCCU
— Fault collection and control unit (FCCU)
— Boot-time built-in self-test for memory (MBIST) and logic (LBIST) triggered by hardware
— Boot-time built-in self-test for ADC and flash memory
— Replicated safety-enhanced watchdog timer
— Silicon substrate (die) temperature sensor
— Non-maskable interrupt (NMI)
— 16-region memory protection unit (MPU)
— Clock monitoring units (CMU)
— Power management unit (PMU)
— Cyclic redundancy check (CRC) units
•
•
•
Decoupled Parallel mode for high-performance use of replicated cores
Nexus Class 3+ interface
Interrupts
— Replicated 16-priority interrupt controller
GPIOs individually programmable as input, output, or special function
3 general-purpose eTimer units (6 channels each)
3 FlexPWM units with four 16-bit channels per module
Communications interfaces
•
•
•
•
— 4 LINFlex modules
— 3 DSPI modules with automatic chip select generation
— 4 FlexCAN interfaces (2.0B Active) with 32 message objects
— FlexRay module (V2.1) with dual channel, up to 128 message objects and up to 10 Mbit/s
— Fast Ethernet Controller (FEC)
2
— 3 I C modules
•
Four 12-bit analog-to-digital converters (ADCs)
— 22 input channels
— Programmable cross triggering unit (CTU) to synchronize ADC conversion with timer and PWM
External bus interface
•
•
•
16-bit external DDR memory controller
Parallel digital interface (PDI)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
6
NXP Semiconductors
Introduction
•
•
On-chip CAN/UART bootstrap loader
Capable of operating on a single 3.3 V voltage supply
— 3.3 V-only modules: I/O, oscillators, flash memory
— 3.3 V or 5 V modules: ADCs, supply to internal VREG
— 1.8–3.3 V supply range: DRAM/PDI
•
Operating junction temperature range –40 to 150 °C
1.6
Feature details
1.6.1
High-performance e200z7d core processor
•
•
•
•
•
•
•
•
Dual 32-bit Power Architecture processor core
Loose or tight core coupling
NXP Variable Length Encoding (VLE) enhancements for code size footprint reduction
Thirty-two 64-bit general-purpose registers (GPRs)
Memory management unit (MMU) with 64-entry fully-associative translation look-aside buffer (TLB)
Branch processing unit
Fully pipelined load/store unit
16 KB Instruction and 16 KB Data caches per core with line locking
— Four way set associative
— Two 32-bit fetches per clock
— Eight-entry store buffer
— Way locking
— Supports tag and data cache parity
— Supports EDC for instruction cache
Vectored interrupt support
•
•
•
Signal processing engine 2 (SPE2) auxiliary processing unit (APU) operating on 64-bit general purpose registers
Floating point
— IEEE 754 compatible with software wrapper
— Single precision in hardware; double precision with software library
— Conversion instructions between single precision floating point and fixed point
Long cycle time instructions (except for guarded loads) do not increase interrupt latency in the MPC5675K
To reduce latency, long cycle time instructions are aborted upon interrupt requests
Extensive system development support through Nexus debug module
•
•
•
1.6.2
Crossbar Switch (XBAR)
•
•
32-bit address bus, 64-bit data bus
Simultaneous accesses from different masters to different slaves (there is no clock penalty when a parked master
accesses a slave)
1.6.3
Memory Protection Unit (MPU)
Each master (eDMA, FlexRay, CPU) can be assigned different access rights to each region.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
7
Introduction
•
•
16-region MPU with concurrent checks against each master access
32-byte granularity for protected address region
1.6.4
Enhanced Direct Memory Access (eDMA) controller
•
•
•
•
•
32 channels support independent 8-, 16-, 32-bit single value or block transfers
Supports variable-sized queues and circular queues
Source and destination address registers are independently configured to post-increment or remain constant
Each transfer is initiated by a peripheral, CPU, or eDMA channel request
Each eDMA channel can optionally send an interrupt request to the CPU on completion of a single value or block
transfer
1.6.5
Interrupt Controller (INTC)
•
•
•
•
•
208 peripheral interrupt requests
8 software settable sources
Unique 9-bit vector per interrupt source
16 priority levels with fixed hardware arbitration within priority levels for each interrupt source
Priority elevation for shared resources
1.6.6
Frequency-Modulated Phase-Locked Loop (FMPLL)
Two FMPLLs are available on each device.
Each FMPLL allows the user to generate high speed system clocks starting from a minimum reference of 4 MHz input clock.
Further, the FMPLL supports programmable frequency modulation of the system clock. The PLL multiplication factor and
output clock divider ratio are software configurable. The FMPLLs have the following major features:
•
•
•
Input frequency: 4–40 MHz continuous range (limited by the crystal oscillator)
Voltage controlled oscillator (VCO) range: 256–512 MHz
Frequency modulation via software control to reduce and control emission peaks
— Modulation depth ±2% if centered or 0% to –4% if downshifted via software control register
— Modulation frequency: triangular modulation with 25 kHz nominal rate
Option to switch modulation on and off via software interface
Reduced frequency divider (RFD) for reduced frequency operation without re-lock
2 modes of operation
•
•
•
— Normal PLL mode with crystal reference (default)
— Normal PLL mode with external reference
•
•
•
•
Lock monitor circuitry with lock status
Loss-of-lock detection for reference and feedback clocks
Self-clocked mode (SCM) operation
Auxiliary FMPLL
— Used for FlexRay due to precise symbol rate requirement by the protocol
— Used for motor control periphery and connected IP (A/D digital interface CTU) to allow independent frequencies
of operation for PWM and timers as well as jitter-free control
— Option to enable/disable modulation to avoid protocol violation on jitter and/or potential unadjusted error in
electric motor control loop
— Allows running motor control periphery at different (precisely lower, equal, or higher, as required) frequency than
the system to ensure higher resolution
MPC5675K Microcontroller Data Sheet, Rev. 8.1
8
NXP Semiconductors
Introduction
1.6.7
External Bus Interface (EBI)
•
•
Available on 473-pin devices
Data and address options:
— 16-bit data and address (non-muxed)
— 32-bit data and address (bus-muxed)
•
•
MPC5561 324 BGA compatibility mode: 16-bit data bus, 24-bit address bus is default ADDR[8:31], but configurable
to 26-bit address bus
Memory controller with support for various memory types
— Non-burst and burst mode SDR flash and SRAM
— Asynchronous/legacy flash and SRAM
Configurable bus speed modes
•
•
•
Support for 2 MB address space
Chip select and write/byte enable options as presented in the pin-muxing table in the “Signal Description” chapter of
the MPC5675K reference manual
•
•
Configurable wait states (via chip selects)
Optional automatic CLKOUT gating to save power and reduce EMI
1.6.8
On-chip flash memory
•
•
•
•
•
•
•
Up to 2 MB code flash memory with ECC
64 KB data flash memory with ECC
Censorship protection scheme to prevent flash content visibility
Multiple block sizes to support features such as boot block, operating system block, and EEPROM emulation
Read-while-write with multiple partitions
Parallel programming mode to support rapid end-of-line programming
Hardware programming state machine
1.6.9
Cache memory
•
•
•
Harvard architecture cache
16 KB instruction / 16 KB data
Four-way set-associative Harvard (instruction and data) 256-bit long cache
— Two 32-bit fetches per clock
— Eight-entry store buffer
— Way locking
— Supports tag and data cache parity
— Supports EDC for instruction cache
1.6.10 On-chip internal static RAM (SRAM)
•
•
Up to 512 KB general-purpose SRAM
ECC performs single-bit correction, double-bit error detection
— Address included in ECC checkbase
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
9
Introduction
1.6.11 DRAM controller
The DRAM controller (available only on 473-pin devices) is a multi-port controller that monitors incoming requests on the three
AHB slave ports and decides (at each rising clock edge) what command needs to be sent to the external DRAM.
The DRAM controller on this device supports the following types of memories:
•
•
•
•
Mobile DDR (mDDR)
DDR 1
DDR 2 (optional)
SDR
The controller has the following features:
•
•
•
•
•
•
Optimized timing for 32-byte bursts and single read accesses on the AHB interface
Optimized timing for 8-byte and 16-byte bursts on the DRAMC interface
Supports priority elevation on the slave ports for single accesses
16-bit wide DRAM interface
One chip select (CS)
mDDR memory controller
— 16-bit external interface
— Address range up to 8 MB
1.6.12 Boot Assist Module (BAM)
•
•
•
•
Enables booting via serial mode (FlexCAN, LINFlex)
Handles static mode in case of an erroneous boot procedure
Implemented in 8 KB ROM
Supports Lock Step Mode (LSM) and Decoupled Parallel Mode (DPM)
1.6.13 Parallel Data Interface (PDI)
•
•
•
•
•
•
Support for external ADC and CMOS image sensors
Parallel interface operation up to MCU system bus frequency
Selectable data capture from rising or falling edge
Receive FIFO with adjustable trigger thresholds
Data width for 8, 10, 12, 14, and 16 bits
Data Packing Unit to pack input data on 64-bit words — data packed on 8- or 16- bit boundary, depending on input
data width
•
•
Binary increasing channel select that allows as many as eight channels to be selected
Frame synchronization through Vsync, Hsync, PIXCLK
1.6.14 Deserial Serial Peripheral Interface (DSPI) modules
•
Three serial peripheral interfaces
— Full duplex communication ports with interrupt and eDMA request support
— Support for all functional modes from QSPI submodule of QSMCM (MPC5xx family)
— Support for queues in RAM
— Six chip selects, expandable to 64 with external demultiplexers
— Programmable frame size, baud rate, clock delay, and clock phase on a per-frame basis
MPC5675K Microcontroller Data Sheet, Rev. 8.1
10
NXP Semiconductors
Introduction
— Modified SPI mode for interfacing to peripherals with longer setup time requirements
Support for up to 60 Mbit/s in slave only Rx mode
•
1.6.15 Serial Communication Interface Module (LINFlex)
The LINFlex on this device features the following:
•
•
•
•
Supports LIN Master mode, LIN Slave mode, and UART mode
LIN state machine compliant to LIN1.3, 2.0, and 2.1 specifications
Manages LIN frame transmission and reception without CPU intervention
LIN features
— Autonomous LIN frame handling
— Message buffer to store as many as 8 data bytes
— Supports messages as long as 64 bytes
— Detection and flagging of LIN errors (Sync field, delimiter, ID parity, bit framing, checksum and timeout errors)
— Classic or extended checksum calculation
— Configurable break duration of up to 36-bit times
— Programmable baud rate prescalers (13-bit mantissa, 4-bit fractional)
— Diagnostic features (loop back, LIN bus stuck dominant detection)
— Interrupt-driven operation with 16 interrupt sources
LIN slave mode features
•
•
— Autonomous LIN header handling
— Autonomous LIN response handling
UART mode
— Full-duplex operation
— Standard non return-to-zero (NRZ) mark/space format
— Data buffers with 4-byte receive, 4-byte transmit
— Configurable word length (8-bit, 9-bit, or 16-bit words)
— Configurable parity scheme: none, odd, even, always 0
— Speed as fast as 2 Mbit/s
— Error detection and flagging (parity, noise, and framing errors)
— Interrupt-driven operation with four interrupt sources
— Separate transmitter and receiver CPU interrupt sources
— 16-bit programmable baud-rate modulus counter and 16-bit fractional
— Two receiver wake-up methods
•
Support for DMA-enabled transfers
1.6.16 FlexCAN
•
•
•
•
•
•
•
•
Thirty-two message buffers each
Full implementation of the CAN protocol specification, Version 2.0B
Programmable acceptance filters
Individual Rx filtering per message buffer
Short latency time for high priority transmit messages
Arbitration scheme according to message ID or message buffer number
Listen-only mode capabilities
Programmable clock source: system clock or oscillator clock
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
11
Introduction
•
•
•
Reception queue possible by setting more than one Rx message buffer with the same ID
Backwards compatible with previous FlexCAN modules
Safety CAN features on 1 CAN module as implemented on MPC5604P
1.6.17 Dual-channel FlexRay controller
•
•
•
•
•
•
•
Full implementation of FlexRay Protocol Specification 2.1
Sixty-four configurable message buffers can be handled
Message buffers configurable as Tx, Rx, or RxFIFO
Message buffer size configurable
Message filtering for all message buffers based on FrameID, cycle count, and message ID
Programmable acceptance filters for RxFIFO message buffers
Dual channel, each at up to 10 Mbit/s data rate
1.6.18 Periodic Interrupt Timer (PIT)
The PIT module implements the features below:
•
•
•
•
•
Four general-purpose interrupt timers
32-bit counter resolution
Clocked by system clock frequency
32-bit counter for real time interrupt, clocked from main external oscillator
Can be used for software tick or DMA trigger operation
1.6.19 System Timer Module (STM)
The STM implements the features below:
•
•
•
Replicated periphery to provide safety measures respective to high safety integrity levels (for example, SIL 3, ASIL D)
Up-counter with four output compare registers
OS task protection and hardware tick implementation as per current state-of-the-art AUTOSAR requirement
1.6.20 Motor control (MOTC) peripherals
The peripherals in this section can be used for general-purpose applications, but are specifically designed for motor control
(MOTC) applications.
1.6.20.1 FlexPWM
The pulse width modulator module (FlexPWM) contains three PWM channels, each of which is configured to control a single
half-bridge power stage. There may also be one or more fault channels.
This PWM is capable of controlling most motor types: AC induction motors (ACIM), permanent magnet AC motors (PMAC),
both brushless (BLDC) and brush DC motors (BDC), switched (SRM) and variable reluctance motors (VRM), and stepper
motors.
A FlexPWM module implements the following features:
•
•
•
•
16 bits of resolution for center, edge aligned, and asymmetrical PWMs
Maximum operating frequency lower than or equal to platform frequency
Clock source not modulated and independent from system clock (generated via auxiliary PLL)
Fine granularity control for enhanced resolution of the PWM period
MPC5675K Microcontroller Data Sheet, Rev. 8.1
12
NXP Semiconductors
Introduction
•
•
•
•
•
PWM outputs can operate as complementary pairs or independent channels
Ability to accept signed numbers for PWM generation
Independent control of both edges of each PWM output
Synchronization to external hardware or other PWM is supported
Double-buffered PWM registers
— Integral reload rates from 1 to 16
— Half-cycle reload capability
•
•
•
•
•
•
•
•
•
•
Multiple ADC trigger events can be generated per PWM cycle via hardware
Fault inputs can be assigned to control multiple PWM outputs
Programmable filters for fault inputs
Independently programmable PWM output polarity
Independent top and bottom deadtime insertion
Each complementary pair can operate with its own PWM frequency and deadtime values
Individual software control for each PWM output
All outputs can be forced to a value simultaneously
PWMX pin can optionally output a third signal from each channel
Channels not used for PWM generation can be used for:
— buffered output compare functions
— input capture functions
•
•
Enhanced dual-edge capture functionality
Option to supply the source for each complementary PWM signal pair from any of the following:
— External digital pin
— Internal timer channel
— External ADC input, taking into account values set in ADC high and low limit registers
Supports safety measures using DMA
•
1.6.20.2 Cross Triggering Unit (CTU)
The CTU provides automatic generation of ADC conversion requests on user-selected conditions without CPU load during the
PWM period and with minimized CPU load for dynamic configuration.
The CTU implements the following features:
•
•
•
•
•
•
•
•
•
•
Cross triggering between ADC, FlexPWM, eTimer, and external pins
Double-buffered trigger generation unit with as many as eight independent triggers generated from external triggers
Maximum operating frequency lower than or equal to platform
Trigger generation unit configurable in sequential mode or in triggered mode
Trigger delay unit to compensate the delay of external low-pass filter
Double-buffered global trigger unit allowing eTimer synchronization and/or ADC command generation
Double-buffered ADC command list pointers to minimize ADC trigger unit update
Double-buffered ADC conversion command list with as many as twenty-four ADC commands
Each trigger has the capability to generate consecutive commands
ADC conversion command allows controlling ADC channel from each ADC, single or synchronous sampling,
independent result queue selection
•
Supports safety measures using DMA
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
13
Introduction
1.6.20.3 Analog-To-Digital Converter (ADC)
•
•
•
•
•
•
Four independent ADCs with 12-bit A/D resolution
Common mode conversion range of 0–5 V or 0–3.3 V
Twenty-two single-ended input channels
Supports eight FIFO queues with fixed priority
Queue modes with priority-based preemption; initiated by software command, internal, or external triggers
DMA and interrupt request support
1.6.20.4 eTimer module
Three 16-bit general purpose up/down timer/counters per module are implemented with the following features:
•
•
Ability to operate up to platform frequency
Individual channel capability
— Input capture trigger
— Output compare
— Double buffer (to capture rising edge and falling edge)
— Separate prescaler for each counter
— Selectable clock source
— 0–100% pulse measurement
— Rotation direction flag (quad decoder mode)
Maximum count rate
•
— Equals peripheral clock/2 for external event counting
— Equals peripheral clock for internal clock counting
Cascadeable counters
•
•
•
•
•
•
•
•
Programmable count modulo
Quadrature decode capabilities
Counters can share available input pins
Count once or repeatedly
Preloadable counters
Pins available as GPIO when timer functionality is not in use
DMA support
1.6.21 Redundancy Control and Checker Unit (RCCU)
The RCCU checks all outputs of the sphere of replication (addresses, data, control signals). It has the following features:
•
•
Duplicated module to enable high diagnostic coverage (check of checker)
Replicated IP to be used as checkers on the PBRIDGE output, Flash Controller output, SRAM output, DMA Channel
Mux inputs
1.6.22 Software Watchdog Timer (SWT)
This module implements the features below:
•
•
•
•
Replicated periphery to provide safety measures respective to high safety integrity levels (for example, SIL 3, ASIL D)
Fault-tolerant output
Safe internal RC oscillator as reference clock
Windowed watchdog
MPC5675K Microcontroller Data Sheet, Rev. 8.1
14
NXP Semiconductors
Introduction
•
•
Program flow control monitor with 16-bit pseudorandom key generation
Provides measures to target high safety integrity levels (for example, SIL 3, ASIL D)
1.6.23 Fault Collection and Control Unit (FCCU)
The FCCU module has the following features:
•
•
•
•
Redundant collection of hardware checker results
Redundant collection of error information and latch of faults from critical modules on the device
Collection of test results
Configurable and graded fault control
— Internal reactions (no internal reaction, NMI, reset, or safe mode)
— External reaction (failure is reported to the outside world via configurable output pins)
1.6.24 System Integration Unit Lite (SIUL)
The SIUL controls MCU reset configuration, pad configuration, external interrupt, general purpose I/O (GPIO), internal
peripheral multiplexing, and the system reset operation. The reset configuration block contains the external pin boot
configuration logic. The pad configuration block controls the static electrical characteristics of I/O pins. The GPIO block
provides uniform and discrete input/output control of the I/O pins of the MCU.
The SIUL provides the following features:
•
Centralized pad control on a per-pin basis
— Pin function selection
— Configurable weak pullup/pulldown
— Configurable slew rate control (slow/medium/fast)
— Hysteresis on GPIO pins
— Configurable automatic safe mode pad control
Input filtering for external interrupts
•
1.6.25 Cyclic Redundancy Checker (CRC) unit
The CRC module is a configurable multiple data flow unit to compute CRC signatures on data written to an input register.
The CRC unit has the following features:
•
Three sets of registers to allow three concurrent contexts with possibly different CRC computations, each with a
selectable polynomial and seed
•
•
Computes 16- or 32-bit wide CRC on the fly (single-cycle computation) and stores the result in an internal register
Implements the following standard CRC polynomials:
16
12
5
— x + x + x + 1
[16-bit CRC-CCITT]
32
26
23
22
16
12
11
10
8
7
5
4
2
— x + x + x + x + x + x + x + x + x + x + x + x + x + x + 1
[32-bit CRC-ethernet(32)]
•
•
Key engine to be coupled with communication periphery where CRC application is added to support implementation
of safe communication protocol
Offloads the core from cycle-consuming CRC and helps in checking the configuration signature for safe start-up or
periodic procedures
•
•
Connected as a peripheral on the internal peripheral bus
Provides DMA support
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
15
Introduction
1.6.26 Non-Maskable Interrupt (NMI)
The non-maskable interrupt with de-glitching filter is available to support high priority core exceptions.
1.6.27 System Status and Configuration Module (SSCM)
The SSCM on the MPC5675K features the following:
•
•
•
System configuration and status
Debug port status and debug port enable
Multiple boot code starting locations out of reset through implementation of search for valid reset configuration
halfword
•
Sets up the MMU to allow user boot code to execute as either Classic Power Architecture Book E code (default) or as
NXP VLE code out of flash
•
•
•
Supports serial bootloading of either Classic Power Architecture Book E code (default) or NXP VLE code
Detection of user boot code
Automatic switch to serial boot mode if internal flash is blank or invalid
1.6.28 Nexus Development Interface (NDI)
•
•
•
•
•
•
•
•
Per IEEE-ISTO 5001-2008
Real-time development support for Power Architecture core through Nexus class 3 (some class 4 support)
Nexus support to snoop system SRAM traffic
Data trace of FlexRay accesses
Read and write access
Configured via the IEEE 1149.1 (JTAG) port
High bandwidth mode for fast message transmission
Reduced bandwidth mode for reduced pin usage
1.6.29 IEEE 1149.1 JTAG Controller (JTAGC)
•
•
IEEE 1149.1-2001 Test Access Port (TAP) interface
JCOMP input that provides the ability to share the TAP —selectable modes of operation include JTAGC/debug or
normal system operation
•
•
•
5-bit instruction register that supports IEEE 1149.1-2001 defined instructions
5-bit instruction register that supports additional public instructions
Three test data registers:
— Bypass register
— Boundary scan register
— Device identification register
•
TAP controller state machine that controls the operation of the data registers, instruction register, and associated
circuitry
MPC5675K Microcontroller Data Sheet, Rev. 8.1
16
NXP Semiconductors
Package pinouts and signal descriptions
2
Package pinouts and signal descriptions
2.1
Package pinouts
Figure 2 shows the MPC5675K in the 257 MAPBGA package. Figure 3, Figure 4, Figure 5, and Figure 6 show the MPC5675K
in the 473 MAPBGA package.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
flexray
CA_TR_
EN
fec
RX_
CLK
A
B
C
D
E
F
A
B
C
D
E
F
VSS_
VSS_
VDD_
nexus
nexus
nexus
flexray
VDD_
fec
fec
fec
fec
fec
VSS_
VSS_
HV_IO
HV_IO
HV_IO MDO[5] MDO[7] MDO[9] CB_TX
HV_IO
RXD[2]
RXD[0]
MDIO
TX_EN
TXD[3]
HV_IO
HV_IO
nexus
MDO
[14]
flexray
CB_TR_
EN
fec
TX_
CLK
VSS_
HV_IO
VSS_
HV_IO
mc_cgl
clk_out
can1
TXD
dspi2
CS1
flexray
CA_TX
VSS_
HV_IO
fec
fec
fec
fec
can0
TXD
VDD_
HV_IO
VSS_
HV_IO
RXD[3] RX_ER RXD[1] TX_ER
nexus
MDO
[15]
pdi
DATA
[5]
VDD_
HV_IO
VSS_
HV_IO
FCCU_
F[1]
flexray
CB_RX ETC[0]
etimer0 etimer0 etimer0 etimer0
fec
CRS
fec
TXD[0]
fec
COL
can0
RXD
VSS_
HV_PDI
pdi
CLOCK
JCOMP
ETC[1]
ETC[2]
ETC[3]
nexus
MDO
[2]
nexus
MDO
[3]
pdi
DATA
[0]
pdi
DATA
[1]
can1
RXD
dspi0 RESERV etimer0 etimer0
SOUT
VDD_
VSS_
fec
fec
fec
fec
MDC
VDD_
HV_PDI HV_IO
VSS_
ED
ETC[5]
ETC[4] HV_FLA HV_FLA TXD[2]
TXD[1] RX_DV
nexus
MDO
[0]
nexus
MDO
[1]
pdi
pdi
DATA
[3]
pdi
DATA
[4]
flexray
CA_RX
pdi
DATA
LINE_V
[2]
NMI
nexus
MDO
[11]
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
pdi
mc_cgl
DATA
pdi
DATA
[7]
pdi
DATA
[8]
nexus
MDO[6]
dspi1
SOUT
dspi1
SIN
clk_out
[6]
nexus
MDO
[4]
VDD_
LV_
VSS_
LV_
VSS_
LV_
VSS_
LV_
VSS_
LV_
VSS_
LV_
VDD_
LV_
pdi
DATA
[9]
pdi
DATA
[10]
pdi
pdi
G
H
J
G
H
J
VDD_
dspi0
SCK
dspi1
SCK
DATA FRAME_
HV_IO
COR
COR
COR
COR
COR
COR
COR
[11]
V
nexus
MDO
[10]
VDD_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VDD_
LV_
COR
pdi
DATA
[12]
pdi
DATA
[13]
VDD_
HV_
PDI
flexpwm
0
X[0]
VSS_
HV_IO
dspi0
CS0
dspi1
CS0
VDD_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VDD_
LV_
COR
pdi
DATA
[14]
pdi
DATA
[15]
VSS_
HV_
PDI
flexpwm
0
X[1]
nexus
MCKO MDO[8]
nexus
dspi2
CS0
dspi2
CS2
nexus
nexus
VDD_
LV_
VSS_
LV_
VSS_
LV_
VSS_
LV_
VSS_
LV_
VSS_
LV_
VDD_
LV_
flexpwm flexpwm flexpwm flexpwm
K
L
nexus
dspi0
SIN
K
L
MSEO_ MSEO_
0
0
0
0
RDY_B
B[0]
B[1]
COR
COR
COR
COR
COR
COR
COR
X[2]
X[3]
A[1]
B[0]
nexus
MDO
[13]
VDD_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VSS_
LV_
COR
VDD_
LV_
COR
VDD_HV
_DRAM_
VREF
flexpwm
0
nexus
EVTO_B EVTI_B
nexus
dspi2
SCK
TCK
TDI
TDO
B[1]
VDD_
VDD_
HV_
nexus
MDO
[12]
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
VDD_
LV_
COR
flexpwm
0
B[2]
flexpwm
1
A[1]
M
N
P
R
T
M
N
P
R
T
dspi1
CS2
TMS
HV_IO
OSC
flexpwm flexpwm flexpwm flexpwm
VSS_
XTALIN
dspi0
CS3
VSS_
LV_PLL
0
B[3]
0
A[2]
1
A[0]
1
B[0]
HV_IO
VSS_
adc0_
adc1
AN[14]
flexpwm flexpwm flexpwm
dspi0
CS2
VDD_
LV_PLL ETC[1]
etimer1 etimer1
adc0
AN[0]
etimer1
ETC[3]
VSS_
HV_IO
VDD_
HV_IO
etimer1 etimer1
ETC[4]
VDD_
HV_IO
HV_
RESET
0
0
1
ETC[2]
ETC[5]
OSC
A[3]
A[0]
B[1]
VDD_
HV_
adc2_
adc3
VDD_
HV_
adc0_
adc1
AN[13]
flexpwm flexpwm
XTAL
OUT
FCCU_ VSS_HV
F[0]
dspi1
CS3
adc2
adc2
AN[3]
adc0
AN[2]
adc1
AN[1]
VREG_C
TRL
lin0
TXD
VSS_
HV_IO
1
1
_IO
AN[0]
ADR_13 AN[14] ADR_02
A[2]
B[2]
VSS_
HV_
adc2_
adc3
VSS_
HV_
adc0_
adc1
AN[12]
VSS_
HV_IO
VDD_
HV_IO
dspi2
SOUT
adc3
AN[0]
adc3
AN[3]
adc2
AN[2]
adc0
AN[1]
adc1
AN[0]
adc1
AN[2]
lin0
RXD
etimer1
ETC[0]
VDD_
HV_IO
VSS_
HV_IO
ADR_13 AN[13] ADR_02
adc2_
adc3
AN[11]
adc2_
adc3
AN[12]
VDD_
HV_
ADV
VSS_
HV_
ADV
adc0_
adc1
AN[11]
VREG_
INT_EN
ABLE
VSS_
HV_
PMU
U
U
VSS_
HV_IO
VSS_
HV_IO
dspi2
SIN
adc3
AN[1]
adc3
AN[2]
adc2
AN[1]
RESET_ VDD_HV
VSS_
HV_IO
VSS_
HV_IO
SUP
_PMU
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
Figure 2. MPC5675K 257 MAPBGA pinout (top view)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
17
Package pinouts and signal descriptions
1
2
3
4
5
6
7
8
9
10
11
12
VSS_
HV_IO
VSS_
HV_IO
VDD_
HV_IO
nexus
MDO[5]
nexus
MDO[7]
nexus
MDO[9]
flexray
CB_TX
flexray
CA_TR_EN
fec
RX_DV
fec
MDIO
fec
TX_CLK
fec
TX_EN
A
B
C
D
E
F
VSS_
HV_IO
VSS_
HV_IO
mc_cgl
clk_out
can1
TXD
nexus
MDO[14]
dspi2
CS1
flexray
CB_TR_EN
flexray
CA_TX
fec
RXD[3]
fec
RX_ER
fec
TXD[0]
fec
RXD[0]
VDD_
HV_IO
nexus
MDO[15]
VSS_
HV_IO
FCCU_
F[1]
flexray
CB_RX
etimer0
ETC[4]
etimer0
ETC[1]
etimer0
ETC[2]
etimer0
ETC[3]
fec
TXD[2]
fec
TXD[1]
fec
CRS
nexus
MDO[1]
nexus
MDO[3]
can1
RXD
dspi0
SOUT
etimer0
ETC[5]
etimer0
ETC[0]
VDD_
HV_IO
VSS_
HV_IO
VSS_
HV_IO
VSS_
HV_FLA
RESERVED
JCOMP
nexus
MDO[0]
nexus
MDO[2]
flexray
CA_RX
NMI
nexus
nexus
nexus
nexus
VDD_
VDD_
VDD_
VDD_
VDD_
VDD_
VDD_
MDO[10]
MDO[11]
MDO[6]
MDO[4]
LV_COR
LV_COR
LV_COR
LV_COR
LV_COR
LV_COR
LV_COR
nexus
MCKO
VDD_
HV_IO
nexus
MDO[8]
nexus
MSEO_B[1]
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
G
H
J
nexus
EVTO_B
VSS_
HV_IO
nexus
MSEO_B[0]
nexus
EVTI_B
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
nexus
RDY_B
nexus
MDO[13]
nexus
MDO[12]
dspi1
SIN
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
dspi0
SCK
dspi1
CS0
dspi1
SCK
dspi1
SOUT
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
K
L
dspi0
CS0
dspi2
CS2
dspi2
CS0
VSS_
HV_IO
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
flexpwm0
X[0]
VDD_
HV_IO
dspi0
SIN
VDD_
HV_IO
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
M
Figure 3. MPC5675K 473 MAPBGA pinout (northwest, viewed from above)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
18
NXP Semiconductors
Package pinouts and signal descriptions
flexpwm0
A[0]
VSS_
HV_IO
flexpwm0
X[1]
flexpwm0
B[2]
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
N
P
flexpwm0
B[0]
flexpwm0
B[1]
flexpwm0
A[2]
flexpwm0
A[3]
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
flexpwm0
X[2]
flexpwm0
X[3]
flexpwm0
A[1]
VSS_
HV_IO
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
R
flexpwm0
B[3]
flexpwm1
A[0]
flexpwm1
A[1]
VDD_
HV_IO
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
T
flexpwm1
B[0]
flexpwm1
B[1]
flexpwm1
A[2]
dspi2
SCK
VDD_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
U
VDD_
HV_OSC
VDD_
HV_IO
flexpwm1
B[2]
dspi1
CS2
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
V
VSS_
HV_IO
dspi0
CS3
VSS_
LV_PLL
W
Y
XTALIN
VSS_
HV_OSC
dspi0
CS2
VDD_
LV_PLL
flexpwm1
X[0]
adc3
AN[0]
adc2_adc3 adc2_adc3
etimer1
ETC[1]
etimer1
ETC[2]
etimer1
ETC[3]
VSS_
HV_IO
RESET
AN[11]
AN[14]
FCCU_
F[0]
VSS_
HV_IO
dspi1
CS3
flexpwm1
X[1]
adc3
AN[1]
adc2_adc3
AN[12]
adc2
AN[0]
VDD_
HV_ADV
VSS_
HV_ADV
adc0
AN[2]
adc0
AN[5]
AA
AB
AC
XTALOUT
VSS_
HV_IO
VDD_
HV_IO
dspi2
SOUT
flexpwm1
X[2]
flexpwm1
X[3]
adc3
AN[2]
adc2_adc3
AN[13]
adc2
AN[1]
adc2
AN[2]
adc0
AN[0]
adc0
AN[4]
adc0
AN[6]
VSS_
HV_IO
VSS_
HV_IO
dspi2
SIN
flexpwm1
A[3]
flexpwm1
B[3]
adc3
AN[3]
VDD_HV_
ADR_23
VSS_HV_
ADR_23
adc2
AN[3]
adc0
AN[1]
adc0
AN[3]
VDD_
HV_ADR_0
1
2
3
4
5
6
7
8
9
10
11
12
Figure 4. MPC5675K 473 MAPBGA pinout (southwest, viewed from above)
13
14
15
16
17
18
19
20
21
22
23
fec
TXD[3]
VDD_
HV_IO
pdi
DATA[3]
pdi
DATA[1]
pdi
CLOCK
pdi
DATA[7]
pdi
DATA[10]
pdi
DATA[13]
pdi
DATA[15]
VSS_
HV_IO
VSS_
HV_IO
A
B
C
D
E
F
fec
TX_ER
VSS_
HV_IO
pdi
DATA[6]
pdi
DATA[4]
pdi
DATA[0]
pdi
LINE_V
pdi
DATA[9]
pdi
DATA[14]
can0
TXD
VDD_
HV_IO
VSS_
HV_IO
fec
RX_CLK
fec
RXD[1]
fec
COL
pdi
DATA[5]
pdi
DATA[2]
pdi
DATA[8]
pdi
DATA[12]
can0
RXD
VSS_
HV_PDI
siul
GPIO[197]
dramc
CAS
VDD_
HV_FLA
fec
RXD[2]
fec
MDC
VDD_
HV_PDI
VSS_
HV_PDI
pdi
DATA[11]
pdi
FRAME_V
VDD_
HV_PDI
dramc
BA[1]
siul
GPIO[195]
dramc
BA[0]
mc_cgl
clk_out
siul
GPIO[149]
dramc
CS0
dramc
BA[2]
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
dramc
RAS
siul
GPIO[194]
siul
GPIO[148]
dramc
D[5]
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
siul
GPIO[196]
dramc
DQS[0]
dramc
DM[0]
dramc
D[7]
G
H
J
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
D[2]
VDD_HV_
DRAM_VTT
VDD_HV_
DRAM
VSS_HV_
DRAM
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
D[0]
dramc
D[1]
dramc
D[3]
dramc
D[6]
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
VSS_
HV_IO
dramc
D[4]
dramc
D[8]
dramc
D[9]
K
L
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
VDD_
HV_IO
VDD_HV_
DRAM_VTT
VSS_HV_
DRAM
VDD_HV_
DRAM
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
ODT
dramc
WEB
dramc
D[11]
dramc
D[10]
M
Figure 5. MPC5675K 473 MAPBGA pinout (northeast, viewed from above)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
19
Package pinouts and signal descriptions
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
DQS[1]
dramc
DM[1]
dramc
D[13]
dramc
D[12]
N
P
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
D[14]
dramc
D[15]
VSS_HV_
DRAM
VDD_HV_
DRAM
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
VDD_HV_
DRAM_VREF
dramc
ADD[3]
dramc
CKE
dramc
CLKB
R
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
ADD[8]
dramc
ADD[9]
dramc
ADD[1]
dramc
CLK
T
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VSS_
LV_COR
VDD_
LV_COR
dramc
ADD[6]
dramc
ADD[12]
VDD_HV_
DRAM
dramc
ADD[0]
U
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
VDD_
LV_COR
lin0
TXD
dramc
ADD[13]
VSS_HV_
DRAM
dramc
ADD[2]
V
lin0
RXD
dramc
ADD[14]
dramc
ADD[7]
dramc
ADD[4]
W
Y
VDD_
HV_IO
adc0_adc1
AN[11]
etimer1
ETC[5]
etimer1
ETC[4]
adc1
AN[8]
adc1
AN[6]
dramc
ADD[15]
dramc
ADD[11]
dramc
ADD[5]
TCK
TDI
VDD_HV_IO
adc0
AN[8]
adc0_adc1
AN[12]
adc1
AN[0]
adc1
AN[2]
adc1
AN[5]
adc1
AN[7]
etimer1
ETC[0]
lin1
TXD
dramc
ADD[10]
AA
AB
AC
VSS_HV_IO
adc0
AN[7]
adc0_adc1
AN[13]
adc1
AN[1]
adc1
AN[3]
adc1
AN[4]
lin1
RXD
VDD_
HV_IO
VSS_
HV_IO
TDO
TMS
RESERVED
VSS_
HV_ADR_0
adc0_adc1
AN[14]
VDD_
HV_ADR_1
VSS_
HV_ADR_1
VDD_
HV_PMU
VSS_
HV_PMU
RESET_
SUP
VREG_INT_
ENABLE
VSS_
HV_IO
VSS_
HV_IO
VREG_CTRL
18
13
14
15
16
17
19
20
21
22
23
Figure 6. MPC5675K 473 MAPBGA pinout (southeast, viewed from above)
2.2
Pin descriptions
The following sections provide signal descriptions and related information about the functionality and configuration for this
device.
2.2.1
Pad types
Table 2 lists the pad types used on the MPC5675K.
Table 2. Pad types
Pad Type
Description
GP Slow
Slow buffer with CMOS Schmitt trigger and pullup/pulldown.
GP Slow/Fast
GP Slow/Medium
Programmable slow/fast buffer with CMOS Schmitt trigger, pullup/pulldown.
Programmable slow/medium buffer with CMOS Schmitt trigger, pullup/pulldown.
Programmable slow/medium buffer with CMOS Schmitt trigger, pullup/pulldown
and Injection proof analog switch.
GP Slow/Symmetric Programmable slow/symmetric buffer with CMOS Schmitt trigger,
pullup/pulldown.
PDI Medium
Medium slew-rate output with four selectable slew rates. Contains an input buffer
and weak pullup/pulldown.
PDI Fast
Fast slew-rate output with four selectable slew rates. Contains an input buffer and
weak pullup/pulldown.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
20
NXP Semiconductors
Package pinouts and signal descriptions
Table 2. Pad types (continued)
Pad Type
DRAM ACC
Description
Bidirectional DDR pad. Can be configured to support LPDDR half strength,
LPDDR full strength, DDR1, DDR2 half strength, DDR2 full strength, and SDR.
DRAM CLK
DRAM DQ
Differential clock driver.
Bidirectional DDR pad with integrated ODT. Can be configured to support
LPDDR half strength, LPDDR full strength, DDR1, DDR2 half strength, DDR2 full
strength, and SDR.
DRAM ODT CTL
Analog
Enable On Die Termination control.
CMOS Schmitt trigger cell with injection proof analog switch.
CMOS Schmitt trigger cell with two injection-proof analog switches.
Analog Shared
2.2.2
Power supply and reference voltage pins
Table 3 shows the supply pins for the MPC5675K in the 257 MAPBGA package. Table 5 shows the supply pins for the
MPC5675K in the 473 MAPBGA package.
Table 4 and Table 6 show the pins not populated on the MPC5675K 257 MAPBGA and 473 MAPBGA packages, respectively.
Table 3. 257 MAPBGA supply pins
Ball
number
Ball
number
Ball name
Pad type
Ball name
Pad type
VDD
A3
A9
VDD_HV_IO
VDD_HV_IO
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV_A
F9
F10
F11
F12
G6
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
B16
C1
VDD_HV_IO
VDD_HV_IO
G2
VDD_HV_IO
M2
VDD_HV_IO
G12
H6
P10
P14
T2
VDD_HV_IO
VDD_HV_IO
H12
J6
VDD_HV_IO
T16
L14
D8
VDD_HV_IO
J12
K6
VDD_HV_DRAM_VREF
VDD_HV_FLA
VDD_HV_OSC
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PMU
VDD_HV_ADR_13
K12
L6
M1
D14
H16
U14
R7
L12
M6
M7
M8
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
21
Package pinouts and signal descriptions
Table 3. 257 MAPBGA supply pins (continued)
Ball
number
Ball
number
Ball name
Pad type
Ball name
Pad type
R9
U9
F6
F7
F8
VDD_HV_ADR_02
VDD_HV_ADV
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_HV_A
VDD_HV_A
VDD_LV
M9
M10
M11
M12
P4
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_PLL
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VSS
A1
A2
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_FLA
VSS_HV_OSC
VSS_HV_PDI
VSS_HV_PDI
VSS_HV_ADR_02
VSS_HV_ADR_13
VSS_HV_ADV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV_A
VSS_HV_A
VSS_HV_A
G7
G8
G9
G10
G11
H7
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_PLL
VSS_HV_PMU
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
A16
A17
B1
B2
B9
H8
B17
C3
H9
H10
H11
J7
D15
H2
N2
J8
P9
J9
R3
J10
J11
K7
R15
T1
T17
U1
K8
K9
U2
K10
K11
L7
U16
U17
D9
L8
P1
L9
C15
J16
T9
L10
L11
N4
T7
U15
U10
MPC5675K Microcontroller Data Sheet, Rev. 8.1
22
NXP Semiconductors
Package pinouts and signal descriptions
Table 4. 257 MAPBGA pins not populated on package
E5
E13
J13
N6
E6
F5
K5
N7
E7
F13
K13
N8
E8
G5
L5
E9
E10
H5
E11
H13
M13
N12
E12
J5
G13
L13
N10
M5
N5
N9
N11
N13
Table 5. 473 MAPBGA supply pins
Ball
number
Ball
Pad type
Ball name
Ball name
Pad type
number
VDD
A3
A14
B22
C1
VDD_HV_IO
VDD_HV_IO
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV_A
VDD_HV_A
VDD_HV_A
VDD_HV_A
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
F15
F16
F17
F18
G6
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_HV_IO
VDD_HV_IO
D8
VDD_HV_IO
G2
VDD_HV_IO
G18
H6
L20
M2
VDD_HV_IO
VDD_HV_IO
H18
J6
M4
VDD_HV_IO
T4
VDD_HV_IO
J18
K6
V2
VDD_HV_IO
Y13
Y20
AB2
AB22
AC12
AC15
AC7
AA9
H22
L23
P23
U22
R20
H21
L21
VDD_HV_IO
K18
L6
VDD_HV_IO
VDD_HV_IO
L18
M6
VDD_HV_IO
VDD_HV_ADR_0
VDD_HV_ADR_1
VDD_HV_ADR_23
VDD_HV_ADV
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM_VREF
VDD_HV_DRAM_VTT
VDD_HV_DRAM_VTT
M18
N6
N18
P6
P18
R6
R18
T6
T18
U6
U18
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
23
Package pinouts and signal descriptions
Table 5. 473 MAPBGA supply pins (continued)
Ball
number
Ball
number
Ball name
Pad type
Ball name
Pad type
D13
V1
VDD_HV_FLA
VDD_HV_OSC
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PMU
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_HV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
V6
V7
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_COR
VDD_LV_PLL
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
VDD_LV
D16
D20
AC17
F6
V8
V9
V10
V11
V12
V13
V14
V15
V16
V17
V18
Y4
F7
F8
F9
F10
F11
F12
F13
F14
VSS
A2
A22
A23
B1
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
L7
L8
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
L9
L10
L11
L12
L13
L14
L15
L16
L17
M7
B2
B14
B23
C3
D9
D11
H2
K20
L4
M8
N2
M9
A1
M10
M11
M12
M13
M14
R4
W2
Y12
AA3
MPC5675K Microcontroller Data Sheet, Rev. 8.1
24
NXP Semiconductors
Package pinouts and signal descriptions
Table 5. 473 MAPBGA supply pins (continued)
Ball
number
Ball
number
Ball name
Pad type
Ball name
Pad type
AA21
AB1
AB23
AC1
AC2
AC22
AC23
AC13
AC16
AC8
AA10
H23
L22
VSS_HV_IO
VSS_HV_IO
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV_A
VSS_HV_A
VSS_HV_A
VSS_HV_A
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_HV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
M15
M16
M17
N7
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_HV_IO
VSS_HV_IO
VSS_HV_IO
N8
VSS_HV_IO
N9
VSS_HV_IO
N10
N11
N12
N13
N14
N15
N16
N17
P7
VSS_HV_ADR_0
VSS_HV_ADR_1
VSS_HV_ADR_23
VSS_HV_ADV
VSS_HV_DRAM
VSS_HV_DRAM
VSS_HV_DRAM
VSS_HV_DRAM
VSS_HV_FLA
VSS_HV_OSC
VSS_HV_PDI
VSS_HV_PDI
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
P22
V22
D12
Y1
P8
P9
C21
D17
G7
P10
P11
P12
P13
P14
P15
P16
P17
R7
G8
G9
G10
G11
G12
G13
G14
G15
G16
G17
H7
R8
R9
R10
R11
R12
R13
R14
R15
H8
H9
H10
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
25
Package pinouts and signal descriptions
Table 5. 473 MAPBGA supply pins (continued)
Ball
number
Ball
number
Ball name
Pad type
Ball name
Pad type
H11
H12
H13
H14
H15
H16
H17
J7
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
R16
R17
T7
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_COR
VSS_LV_PLL
VSS_HV_PMU
RESERVED
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_LV
VSS_HV
VSS_HV
T8
T9
T10
T11
T12
T13
T14
T15
T16
T17
U7
J8
J9
J10
J11
J12
J13
J14
J15
J16
J17
K7
U8
U9
U10
U11
U12
U13
U14
U15
U16
U17
W4
K8
K9
K10
K11
K12
K13
K14
K15
K16
K17
AC19
D5
AB20
RESERVED
MPC5675K Microcontroller Data Sheet, Rev. 8.1
26
NXP Semiconductors
Package pinouts and signal descriptions
Table 6. 473 MAPBGA pins not populated on package
E5
E13
F19
K19
P19
V19
W12
E6
E14
G5
E7
E15
G19
L19
R19
W6
E8
E16
H5
E9
E17
H19
M19
T19
W8
E10
E18
J5
E11
E19
J19
E12
F5
K5
L5
M5
N5
N19
U19
W10
W18
P5
R5
T5
U5
V5
W5
W13
W7
W15
W9
W17
W11
W19
W14
W16
2.2.3
System pins
Table 7 shows the system pins for the MPC5675K in the 257 MAPBGA package. Table 8 shows the system pins for the
MPC5675K in the 473 MAPBGA package.
Table 7. 257 MAPBGA system pins
Ball
number
Weak pull
during reset default condition
Safe mode
Ball name
FCCU_F[1]
Pad type
Power domain
C4
C10
E1
disabled
pulldown
—
not available
not available
not available
not available
not available
not available
not available
not available
not available
not available
—
GP Slow/Medium
GP Slow
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_REG
JCOMP
Nexus MDO[0]1
GP Slow/Fast
E4
NMI
pullup
pullup
pullup
—
GP Slow
L15
M16
N1
TCK2
GP Slow
TMS
GP Slow
XTALIN
Analog Feedthrough
Reset
P2
RESET
pulldown
—
R1
XTALOUT
FCCU_F[0]
VREG_CTRL
VREG_INT_ENABLE
RESET_SUP
Analog Feedthrough
GP Slow/Medium
Analog Feedthrough
Analog Feedthrough
Analog Feedthrough
R2
disabled
—
R13
U12
U13
—
—
VDD_HV_IO
VDD_HV_IO
pulldown
—
1
2
Do not connect pin directly to a power supply or ground.
If LBIST is enabled, an external pull between 1K and 100K ohm must be connected from TCK to either power or
ground to avoid LBIST failures.
Table 8. 473 MAPBGA system pins
Ball
number
Weak pull
during reset default condition
Safe mode
Ball name
FCCU_F[1]
Pad type
Power domain
C4
disabled not available
GP Slow/Medium
VDD_HV_IO
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
27
Package pinouts and signal descriptions
Table 8. 473 MAPBGA system pins (continued)
Ball
number
Weak pull
during reset default condition
Safe mode
Ball name
Pad type
Power domain
D10
E1
JCOMP
pulldown
—
not available
not available
not available
—
GP Slow
GP Slow/Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_REG
Nexus MDO[0]1
E4
NMI
pullup
—
GP Slow
R232 dramc CLKB
T232 dramc CLK
DRAM CLK
disabled
—
—
DRAM CLK
W1
Y2
XTALIN
RESET
TCK3
not available
not available
not available
not available
not available
not available
—
Analog Feedthrough
Reset
pulldown
pullup
—
Y19
GP Slow
AA1 XTALOUT
Analog Feedthrough
GP Slow/Medium
GP Slow
AA2 FCCU_F[0]
AB19 TMS
disabled
pullup
—
AC18 VREG_CTRL
AC20 RESET_SUP
AC21 VREG_INT_ENABLE
Analog Feedthrough
Analog Feedthrough
Analog Feedthrough
pulldown
—
—
VDD_HV_IO
VDD_HV_IO
—
1
2
Do not connect pin directly to a power supply or ground.
PCR234 can be used to control the slew rate of DRAM CLK and DRAM CLKB. See the “System Integration Unit
Lite” chapter of the MPC5675K reference manual.
3
If LBIST is enabled, an external pull between 1K and 100K ohm must be connected from TCK to either power or
ground to avoid LBIST failures.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
28
NXP Semiconductors
2.2.4
Multiplexed pins
Table 9 shows the pin multiplexing for the MPC5675K in the 257 MAPBGA package. Table 10 shows the pin multiplexing for the MPC5675K in the
473 MAPBGA package.
Table 9. 257 MAPBGA pin multiplexing
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
A4
A5
GPIO nexus
A0: siul_GPIO[114]
A1: _
A2: npc_wrapper_MDO[5]
A3: _
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
MDO[5]1
GPIO nexus
MDO[7]1
A0: siul_GPIO[112]
A1: _
A2: npc_wrapper_MDO[7]
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
A6
GPIO nexus
MDO[9]1
A0: siul_GPIO[110]
A1: _
A2: npc_wrapper_MDO[9]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
A7
GPIO flexray
A0: siul_GPIO[51]
A1: flexray_CB_TX
A2: _
I: _
I: _
I: _
GP Slow/
Symmetric
CB_TX
A3: _
A8
GPIO flexray
A0: siul_GPIO[47]
I: ctu0_EXT_IN
I: flexpwm0_EXT_SYNC
I: _
GP Slow/
Symmetric
CA_TR_EN A1: flexray_CA_TR_EN
A2: _
A3: _
A10
A11
A12
GPIO fec
RXD[2]
A0: siul_GPIO[213]
A1: _
A2: _
I: fec_RXD[2]
I: _
I: siul_EIRQ[21]
GP Slow/
Medium
A3: dspi2_SOUT
GPIO fec
RX_CLK
A0: siul_GPIO[209]
A1: flexray_DBG2
A2: etimer2_ETC[2]
A3: dspi0_CS6
I: fec_RX_CLK
I: _
I: siul_EIRQ[25]
GP Slow/
Medium
GPIO fec
RXD[0]
A0: siul_GPIO[211]
A1: i2c1_clock
A2: _
I: fec_RXD[0]
I: _
I: siul_EIRQ[27]
GP Slow/
Medium
A3: _
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
A13
A14
A15
B3
GPIO fec
MDIO
A0: siul_GPIO[198]
A1: fec_MDIO
A2: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
I: siul_EIRQ[28]
A3: dspi2_CS0
GPIO fec
TX_EN
A0: siul_GPIO[200]
A1: fec_TX_EN
A2: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
A3: lin0_TXD
GPIO fec
A0: siul_GPIO[204]
A1: fec_TXD[3]
A2: _
I: flexpwm1_FAULT[2]
I: _
I: siul_EIRQ[29]
GP Slow/
Medium
TXD[3]
A3: dspi2_CS2
GPIO mc_cgl
clk_out
A0: siul_GPIO[22]
A1: mc_cgl_clk_out
A2: etimer2_ETC[5]
A3: _
I: _
I: _
GP Slow/
Fast
I: siul_EIRQ[18]
B4
GPIO can1
TXD
A0: siul_GPIO[14]
A1: can1_TXD
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[13]
A3: _
B5
GPIO nexus
A0: siul_GPIO[219]
A1: _
A2: npc_wrapper_MDO[14]
A3: can3_TXD
I: _
I: _
I: _
GP Slow/
Fast
MDO[14]1
B6
GPIO dspi2
CS1
A0: siul_GPIO[9]
A1: dspi2_CS1
A2: _
I: flexpwm0_FAULT[0]
I: lin3_RXD
I: can2_RXD
GP Slow/
Medium
A3: _
B7
GPIO flexray
A0: siul_GPIO[52]
I: _
I: _
I: _
GP Slow/
Symmetric
CB_TR_EN A1: flexray_CB_TR_EN
A2: _
A3: _
B8
GPIO flexray
CA_TX
A0: siul_GPIO[48]
A1: flexray_CA_TX
A2: _
I: ctu1_EXT_IN
I: _
I: _
GP Slow/
Symmetric
A3: _
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
B10
B11
B12
B13
B14
B15
C2
GPIO fec
A0: siul_GPIO[214]
A1: i2c1_data
A2: _
I: fec_RXD[3]
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
RXD[3]
A3: _
GPIO fec
RX_ER
A0: siul_GPIO[215]
A1: _
A2: _
I: fec_RX_ER
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
A3: dspi0_CS1
GPIO fec
RXD[1]
A0: siul_GPIO[212]
A1: dspi1_CS1
A2: etimer2_ETC[5]
A3: _
I: fec_RXD[1]
I: _
I: _
GP Slow/
Medium
GPIO fec
TX_ER
A0: siul_GPIO[205]
A1: fec_TX_ER
A2: dspi2_CS3
A3: _
I: flexpwm1_FAULT[3]
I: lin0_RXD
I: _
GP Slow/
Medium
GPIO fec
TX_CLK
A0: siul_GPIO[207]
A1: flexray_DBG0
A2: etimer2_ETC[4]
A3: dspi0_CS4
I: fec_TX_CLK
I: _
I: _
GP Slow/
Medium
GPIO can0
A0: siul_GPIO[16]
A1: can0_TXD
A2: _
I: _
I: _
GP Slow/
Medium
TXD
I: siul_EIRQ[15]
A3: sscm_DEBUG[0]
GPIO nexus
A0: siul_GPIO[220]
A1: _
A2: npc_wrapper_MDO[15]
A3: _
I: can3_RXD
I: can2_RXD
I: _
GP Slow/
Fast
MDO[15]1
C5
GPIO flexray
CB_RX
A0: siul_GPIO[50]
A1: _
A2: ctu1_EXT_TGR
A3: _
I: flexray_CB_RX
I: _
I: _
GP Slow/
Medium
C6
GPIO etimer0
ETC[0]
A0: siul_GPIO[0]
A1: etimer0_ETC[0]
A2: _
I: dspi2_SIN
I: _
I: siul_EIRQ[0]
GP Slow/
Medium
A3: _
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
C7
C8
GPIO etimer0
A0: siul_GPIO[1]
A1: etimer0_ETC[1]
A2: _
A3: _
I: _
I: _
—
disabled
disabled
pulldown
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
ETC[1]
I: siul_EIRQ[1]
GPIO etimer0
A0: siul_GPIO[2]
A1: etimer0_ETC[2]
A2: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
ETC[2]
I: siul_EIRQ[2]
A3: _
C9
GPIO etimer0
ETC[3]
A0: siul_GPIO[3]
A1: etimer0_ETC[3]
A2: _
I: _
GP Slow/
Medium
I: mc_rgm_ABS[2]
I: siul_EIRQ[3]
A3: _
C11
C12
C13
C14
C16
C17
GPIO fec
CRS
A0: siul_GPIO[208]
A1: flexray_DBG1
A2: etimer2_ETC[3]
A3: dspi0_CS5
I: fec_CRS
I: _
I: _
GP Slow/
Medium
GPIO fec
TXD[0]
A0: siul_GPIO[201]
A1: fec_TXD[0]
A2: etimer2_ETC[1]
A3: _
I: _
I: _
I: _
GP Slow/
Medium
GPIO fec
COL
A0: siul_GPIO[206]
A1: fec_COL
A2: _
I: _
I: _
I: _
GP Slow/
Medium
A3: lin1_TXD
GPIO can0
RXD
A0: siul_GPIO[17]
A1: _
A2: _
I: can0_RXD
I: can1_RXD
I: siul_EIRQ[16]
GP Slow/
Medium
A3: sscm_DEBUG[1]
GPIO pdi
DATA[5]
A0: siul_GPIO[136]
A1: flexpwm2_A[0]
A2: _
I: pdi_DATA[5]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[0]
GPIO pdi
CLOCK
A0: siul_GPIO[128]
A1: flexpwm2_B[1]
A2: _
I: pdi_CLOCK
I: _
I: _
PDI
Medium
A3: etimer1_ETC[3]
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
D1
D2
GPIO nexus
A0: siul_GPIO[85]
A1: _
A2: npc_wrapper_MDO[2]
A3: _
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
pulldown
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
MDO[2]1
GPIO nexus
MDO[3]1
A0: siul_GPIO[84]
A1: _
A2: npc_wrapper_MDO[3]
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
D3
GPIO can1
A0: siul_GPIO[15]
I: can1_RXD
I: can0_RXD
I: siul_EIRQ[14]
GP Slow/
Medium
RXD
A1: _
A2: _
A3: _
D4
GPIO dspi0
SOUT
A0: siul_GPIO[38]
A1: dspi0_SOUT
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[24]
A3: sscm_DEBUG[6]
D6
GPIO etimer0
ETC[5]
A0: siul_GPIO[44]
A1: etimer0_ETC[5]
A2: _
I: _
I: _
I: _
GP Slow/
Medium
A3: _
D7
GPIO etimer0
ETC[4]
A0: siul_GPIO[43]
A1: etimer0_ETC[4]
A2: _
I: _
GP Slow/
Medium
I: mc_rgm_ABS[0]
I: _
A3: _
D10
D11
D12
GPIO fec
TXD[2]
A0: siul_GPIO[203]
A1: fec_TXD[2]
A2: _
I: flexpwm1_FAULT[1]
I: _
I: _
GP Slow/
Medium
A3: _
GPIO fec
TXD[1]
A0: siul_GPIO[202]
A1: fec_TXD[1]
A2: _
I: flexpwm1_FAULT[0]
I: _
I: _
GP Slow/
Medium
A3: dspi2_SCK
GPIO fec
RX_DV
A0: siul_GPIO[210]
A1: flexray_DBG3
A2: etimer2_ETC[0]
A3: dspi0_CS7
I: fec_RX_DV
I: _
I: _
GP Slow/
Medium
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
D13
D16
D17
E2
GPIO fec
MDC
A0: siul_GPIO[199]
A1: fec_MDC
A2: _
I: _
I: lin1_RXD
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
A3: _
GPIO pdi
DATA[0]
A0: siul_GPIO[131]
A1: _
A2: lin3_TXD
A3: _
I: pdi_DATA[0]
I: _
I: flexpwm2_FAULT[2]
—
—
—
—
—
—
—
—
PDI
Medium
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_IO
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
GPIO pdi
A0: siul_GPIO[132]
A1: flexpwm2_B[3]
A2: _
I: pdi_DATA[1]
I: _
I: _
PDI
Medium
DATA[1]
A3: _
GPIO nexus
MDO[1]1
A0: siul_GPIO[86]
A1: _
A2: npc_wrapper_MDO[1]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
E3
GPIO flexray
CA_RX
A0: siul_GPIO[49]
A1: _
A2: ctu0_EXT_TGR
A3: _
I: flexray_CA_RX
I: _
I: _
GP Slow/
Medium
E14
E15
E16
E17
GPIO pdi
LINE_V
A0: siul_GPIO[129]
A1: _
A2: lin2_TXD
A3: _
I: pdi_LINE_V
I: _
I: flexpwm2_FAULT[0]
PDI
Medium
GPIO pdi
DATA[2]
A0: siul_GPIO[133]
A1: flexpwm2_A[1]
A2: _
I: pdi_DATA[2]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[2]
GPIO pdi
DATA[3]
A0: siul_GPIO[134]
A1: flexpwm2_X[1]
A2: _
I: pdi_DATA[3]
I: _
I: _
PDI
Medium
A3: _
GPIO pdi
DATA[4]
A0: siul_GPIO[135]
A1: flexpwm2_A[2]
A2: _
I: pdi_DATA[4]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[4]
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
F1
F2
GPIO nexus
A0: siul_GPIO[113]
A1: _
A2: npc_wrapper_MDO[6]
A3: _
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
MDO[6]1
GPIO nexus
MDO[11]1
A0: siul_GPIO[108]
A1: _
A2: npc_wrapper_MDO[11]
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_IO
F3
GPIO dspi1
A0: siul_GPIO[7]
A1: dspi1_SOUT
A2: _
I: _
I: _
GP Slow/
Medium
SOUT
I: siul_EIRQ[7]
A3: _
F4
GPIO dspi1
SIN
A0: siul_GPIO[8]
A1: _
A2: _
I: dspi1_SIN
I: _
I: siul_EIRQ[8]
GP Slow/
Medium
A3: _
F14
F15
F16
F17
G1
GPIO mc_cgl
clk_out
A0: siul_GPIO[233]
A1: mc_cgl_clk_out
A2: etimer2_ETC[5]
A3: _
I: _
I: _
I: _
PDI Fast
GPIO pdi
DATA[6]
A0: siul_GPIO[137]
A1: flexpwm2_B[0]
A2: _
I: pdi_DATA[6]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[1]
GPIO pdi
DATA[7]
A0: siul_GPIO[138]
A1: flexpwm2_B[2]
A2: _
I: pdi_DATA[7]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[5]
GPIO pdi
DATA[8]
A0: siul_GPIO[139]
A1: flexpwm2_A[3]
A2: _
I: pdi_DATA[8]
I: _
I: _
PDI
Medium
A3: _
GPIO nexus
MDO[4]1
A0: siul_GPIO[115]
A1: _
A2: npc_wrapper_MDO[4]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
G3
G4
GPIO dspi0
SCK
A0: siul_GPIO[37]
A1: dspi0_SCK
A2: _
I: flexpwm0_FAULT[3]
I: _
I: siul_EIRQ[23]
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
A3: sscm_DEBUG[5]
GPIO dspi1
SCK
A0: siul_GPIO[6]
A1: dspi1_SCK
A2: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
I: siul_EIRQ[6]
A3: _
G14
G15
G16
G17
H1
GPIO pdi
A0: siul_GPIO[140]
A1: flexpwm2_X[2]
A2: _
I: pdi_DATA[9]
I: _
I: _
PDI
Medium
DATA[9]
A3: _
GPIO pdi
DATA[10]
A0: siul_GPIO[141]
A1: flexpwm2_X[3]
A2: _
I: pdi_DATA[10]
I: _
I: _
PDI
Medium
A3: _
GPIO pdi
DATA[11]
A0: siul_GPIO[142]
A1: flexpwm2_X[0]
A2: _
I: pdi_DATA[11]
I: _
I: _
PDI
Medium
A3: _
GPIO pdi
A0: siul_GPIO[130]
I: pdi_FRAME_V
I: lin2_RXD
I: flexpwm2_FAULT[1]
PDI
Medium
FRAME_V A1: _
A2: _
A3: _
GPIO nexus
A0: siul_GPIO[109]
A1: _
A2: npc_wrapper_MDO[10]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
MDO[10]1
H3
GPIO dspi0
CS0
A0: siul_GPIO[36]
A1: dspi0_CS0
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[22]
A3: sscm_DEBUG[4]
H4
GPIO dspi1
CS0
A0: siul_GPIO[5]
A1: dspi1_CS0
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[5]
A3: dspi0_CS7
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
H14
H15
H17
J1
GPIO pdi
A0: siul_GPIO[143]
I: pdi_DATA[12]
I: lin3_RXD
I: flexpwm2_FAULT[3]
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
PDI
Medium
VDD_HV_PDI
DATA[12]
A1: _
A2: _
A3: _
GPIO pdi
A0: siul_GPIO[144]
A1: pdi_SENS_SEL[2]
A2: ctu1_EXT_TGR
A3: _
I: pdi_DATA[13]
I: _
I: _
—
—
—
—
—
—
—
—
PDI
Medium
VDD_HV_PDI
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
DATA[13]
GPIO flexpwm0
X[0]
A0: siul_GPIO[194]
A1: flexpwm0_X[0]
A2: ebi_AD28
A3: _
I: _
I: _
I: _
DRAM
ACC
GPIO nexus
MCKO
A0: siul_GPIO[87]
A1: _
A2: npc_wrapper_MCKO
A3: _
I: _
I: _
I: _
GP Slow/
Fast
J2
GPIO nexus
MDO[8]1
A0: siul_GPIO[111]
A1: _
A2: npc_wrapper_MDO[8]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
J3
GPIO dspi2
CS0
A0: siul_GPIO[10]
A1: dspi2_CS0
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[9]
A3: can3_TXD
J4
GPIO dspi2
CS2
A0: siul_GPIO[42]
A1: dspi2_CS2
A2: lin3_TXD
I: flexpwm0_FAULT[1]
I: _
I: _
GP Slow/
Medium
A3: can2_TXD
J14
J15
GPIO pdi
DATA[14]
A0: siul_GPIO[145]
A1: pdi_SENS_SEL[1]
A2: i2c2_clock
A3: _
I: pdi_DATA[14]
I: _
I: _
PDI
Medium
GPIO pdi
DATA[15]
A0: siul_GPIO[146]
A1: pdi_SENS_SEL[0]
A2: i2c2_data
I: pdi_DATA[15]
I: ctu1_EXT_IN
I: _
PDI
Medium
A3: _
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
J17
K1
GPIO flexpwm0
X[1]
A0: siul_GPIO[195]
A1: flexpwm0_X[1]
A2: ebi_AD29
A3: _
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
DRAM
ACC
VDD_HV_IO
GPIO nexus
A0: siul_GPIO[89]
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
MSEO_B[0]1 A1: _
A2: npc_wrapper_MSEO_B[0] I: _
A3: _
K2
GPIO nexus
A0: siul_GPIO[88]
I: _
I: _
GP Slow/
Fast
MSEO_B[1]1 A1: _
A2: npc_wrapper_MSEO_B[1] I: _
A3: _
K3
GPIO nexus
RDY_B
A0: siul_GPIO[216]
A1: _
A2: nexus_RDY_B
A3: _
I: _
I: _
I: _
GP Slow/
Fast
K4
GPIO dspi0
SIN
A0: siul_GPIO[39]
A1: _
A2: _
I: dspi0_SIN
I: _
I: _
GP Slow/
Medium
A3: sscm_DEBUG[7]
K14
K15
K16
K17
GPIO flexpwm0
X[2]
A0: siul_GPIO[196]
A1: flexpwm0_X[2]
A2: ebi_AD30
A3: _
I: _
I: _
I: _
DRAM
ACC
GPIO flexpwm0
X[3]
A0: siul_GPIO[197]
A1: flexpwm0_X[3]
A2: ebi_AD31
A3: _
I: _
I: _
I: _
DRAM
ACC
GPIO flexpwm0
A[1]
A0: siul_GPIO[149]
A1: _
A2: ebi_RD_WR
A3: flexpwm0_A[1]
I: _
I: _
I: _
DRAM
ACC
GPIO flexpwm0
B[0]
A0: siul_GPIO[148]
A1: _
A2: ebi_CLKOUT
A3: flexpwm0_B[0]
I: _
I: _
I: _
DRAM
ACC
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
L1
L2
GPIO nexus
A0: siul_GPIO[90]
A1: _
A2: npc_wrapper_EVTO_B
A3: _
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
EVTO_B
GPIO nexus
EVTI_B
A0: siul_GPIO[91]
A1: _
A2: leo_sor_proxy_EVTI_B
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
L3
GPIO dspi2
A0: siul_GPIO[11]
A1: dspi2_SCK
A2: _
I: can3_RXD
I: _
I: siul_EIRQ[10]
GP Slow/
Medium
SCK
A3: _
L4
GPIO nexus
A0: siul_GPIO[218]
A1: _
A2: npc_wrapper_MDO[13]
A3: _
I: can2_RXD
I: can3_RXD
I: _
GP Slow/
Fast
MDO[13]1
L16
L17
M3
M4
M14
GPIO flexpwm0
B[1]
A0: siul_GPIO[150]
A1: dramc_CS0
A2: ebi_TS
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm0_B[1]
GPIO TDO
A0: siul_GPIO[20]
A1: jtagc_TDO
A2: _
I: _
I: _
I: _
GP Slow/
Fast
A3: _
GPIO dspi1
CS2
A0: siul_GPIO[56]
A1: dspi1_CS2
A2: _
I: flexpwm0_FAULT[3]
I: lin2_RXD
I: _
GP Slow/
Medium
A3: dspi0_CS5
GPIO nexus
MDO[12]1
A0: siul_GPIO[217]
A1: _
A2: npc_wrapper_MDO[12]
A3: can2_TXD
I: _
I: _
I: _
GP Slow/
Fast
GPIO flexpwm0
B[2]
A0: siul_GPIO[152]
A1: dramc_CAS
A2: ebi_WE_BE_1
A3: flexpwm0_B[2]
I: _
I: _
I: _
DRAM
ACC
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
M15
M17
N3
GPIO TDI
A0: siul_GPIO[21]
I: jtagc_TDI
I: _
I: _
—
pullup
GP Slow/
Medium
VDD_HV_IO
A1: _
A2: _
A3: _
GPIO flexpwm1
A[1]
A0: siul_GPIO[157]
A1: dramc_ODT
A2: ebi_CS1
I: _
I: _
I: _
—
—
—
—
—
—
—
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
DRAM
ACC
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
A3: flexpwm1_A[1]
GPIO dspi0
CS3
A0: siul_GPIO[53]
A1: dspi0_CS3
A2: i2c2_clock
A3: _
I: flexpwm0_FAULT[2]
I: _
I: _
GP Slow/
Medium
N14
N15
N16
N17
P3
GPIO flexpwm0
B[3]
A0: siul_GPIO[154]
A1: dramc_BA[0]
A2: ebi_WE_BE_3
A3: flexpwm0_B[3]
I: _
I: _
I: _
DRAM
ACC
GPIO flexpwm0
A[2]
A0: siul_GPIO[151]
A1: dramc_RAS
A2: ebi_WE_BE_0
A3: flexpwm0_A[2]
I: _
I: _
I: _
DRAM
ACC
GPIO flexpwm1
A[0]
A0: siul_GPIO[155]
A1: dramc_BA[1]
A2: ebi_BDIP
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm1_A[0]
GPIO flexpwm1
B[0]
A0: siul_GPIO[156]
A1: dramc_BA[2]
A2: ebi_CS0
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm1_B[0]
GPIO dspi0
CS2
A0: siul_GPIO[54]
A1: dspi0_CS2
A2: i2c2_data
A3: _
I: flexpwm0_FAULT[1]
I: _
I: _
GP Slow/
Medium
P5
GPIO etimer1
ETC[1]
A0: siul_GPIO[45]
A1: etimer1_ETC[1]
A2: _
I: ctu0_EXT_IN
I: flexpwm0_EXT_SYNC
I: ctu1_EXT_IN
GP Slow/
Medium
A3: _
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
P6
GPIO etimer1
A0: siul_GPIO[46]
I: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
ETC[2]
A1: etimer1_ETC[2]
A2: ctu0_EXT_TGR
A3: _
P7
P8
ANA adc0
—
siul_GPI[23]
lin0_RXD
AN: adc0_AN[0]
—
Analog
VDD_HV_ADR02
VDD_HV_IO
AN[0]
GPIO etimer1
ETC[3]
A0: siul_GPIO[92]
A1: etimer1_ETC[3]
A2: _
I: ctu1_EXT_IN
I: mc_rgm_FAB
I: siul_EIRQ[30]
pulldown
GP Slow/
Medium
A3: _
P11
P12
ANA adc0_adc1
AN[14]
—
siul_GPI[28]
AN: adc0_adc1_AN[14]
—
Analog
Shared
VDD_HV_ADR02
VDD_HV_IO
GPIO etimer1
ETC[4]
A0: siul_GPIO[93]
A1: etimer1_ETC[4]
A2: ctu1_EXT_TGR
A3: _
I: _
I: _
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
I: siul_EIRQ[31]
P13
P15
P16
P17
GPIO etimer1
ETC[5]
A0: siul_GPIO[78]
A1: etimer1_ETC[5]
A2: _
I: _
I: _
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
I: siul_EIRQ[26]
A3: _
GPIO flexpwm0
A[3]
A0: siul_GPIO[153]
A1: dramc_WEB
A2: ebi_WE_BE_2
A3: flexpwm0_A[3]
I: _
I: _
I: _
DRAM
ACC
GPIO flexpwm0
A[0]
A0: siul_GPIO[147]
A1: dramc_CKE
A2: ebi_OE
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm0_A[0]
GPIO flexpwm1
B[1]
A0: siul_GPIO[163]
A1: dramc_ADD[5]
A2: ebi_ADD13
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm1_B[1]
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
R4
GPIO dspi1
CS3
A0: siul_GPIO[55]
I: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
A1: dspi1_CS3
A2: lin2_TXD
A3: dspi0_CS4
R5
R6
ANA adc2
AN[0]
—
siul_GPI[221]
siul_GPI[224]
siul_GPI[228]
siul_GPI[33]
siul_GPI[27]
AN: adc2_AN[0]
—
—
—
—
—
—
Analog
Analog
VDD_HV_ADR02
VDD_HV_ADR02
VDD_HV_ADR13
VDD_HV_ADR02
VDD_HV_ADR02
VDD_HV_ADR13
ANA adc2
AN[3]
—
—
—
—
—
AN: adc2_AN[3]
R8
ANA adc2_adc3
AN[14]
AN: adc2_adc3_AN[14]
AN: adc0_AN[2]
Analog
Shared
R10
R11
R12
ANA adc0
AN[2]
Analog
ANA adc0_adc1
AN[13]
AN: adc0_adc1_AN[13]
AN: adc1_AN[1]
Analog
Shared
ANA adc1
AN[1]
siul_GPI[30]
etimer0_ETC[4]
Analog
siul_EIRQ[19]
R14
R16
R17
GPIO lin0
TXD
A0: siul_GPIO[18]
A1: lin0_TXD
A2: i2c0_clock
I: _
I: _
—
—
—
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
I: siul_EIRQ[17]
A3: sscm_DEBUG[2]
GPIO flexpwm1
A[2]
A0: siul_GPIO[164]
A1: dramc_ADD[6]
A2: ebi_ADD14
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm1_A[2]
GPIO flexpwm1
B[2]
A0: siul_GPIO[165]
A1: dramc_ADD[7]
A2: ebi_ADD15
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm1_B[2]
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
T3
GPIO dspi2
A0: siul_GPIO[12]
A1: dspi2_SOUT
A2: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
SOUT
I: siul_EIRQ[11]
A3: _
T4
T5
ANA adc3
—
—
—
—
—
—
—
—
siul_GPI[229]
AN: adc3_AN[0]
—
—
—
—
—
—
—
—
Analog
Analog
Analog
VDD_HV_ADR13
VDD_HV_ADR13
VDD_HV_ADR02
VDD_HV_ADR02
VDD_HV_ADR02
VDD_HV_ADR02
VDD_HV_ADR13
VDD_HV_ADR13
AN[0]
ANA adc3
AN[3]
siul_GPI[232]
siul_GPI[223]
siul_GPI[227]
AN: adc3_AN[3]
T6
ANA adc2
AN[2]
AN: adc2_AN[2]
T8
ANA adc2_adc3
AN[13]
AN: adc2_adc3_AN[13]
AN: adc0_AN[1]
Analog
Shared
T10
T11
T12
T13
ANA adc0
AN[1]
siul_GPI[24]
etimer0_ETC[5]
Analog
ANA adc0_adc1
AN[12]
siul_GPI[26]
AN: adc0_adc1_AN[12]
AN: adc1_AN[0]
Analog
Shared
ANA adc1
AN[0]
siul_GPI[29]
Analog
Analog
lin1_RXD
ANA adc1
AN[2]
siul_GPI[31]
AN: adc1_AN[2]
siul_EIRQ[20]
T14
GPIO lin0
RXD
A0: siul_GPIO[19]
A1: _
A2: i2c0_data
A3: sscm_DEBUG[3]
I: lin0_RXD
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
Table 9. 257 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional inputs
Analog inputs
Pad type
Power domain
T15
U3
GPIO etimer1
A0: siul_GPIO[4]
A1: etimer1_ETC[0]
A2: _
A3: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
ETC[0]
I: siul_EIRQ[4]
GPIO dspi2
A0: siul_GPIO[13]
I: dspi2_SIN
I: flexpwm0_FAULT[0]
I: siul_EIRQ[12]
—
disabled
GP Slow/
Medium
VDD_HV_IO
SIN
A1: _
A2: _
A3: _
U4
U5
ANA adc3
AN[1]
—
—
—
—
—
—
siul_GPI[230]
siul_GPI[231]
siul_GPI[222]
siul_GPI[225]
siul_GPI[226]
siul_GPI[25]
AN: adc3_AN[1]
—
—
—
—
—
—
Analog
Analog
Analog
VDD_HV_ADR13
VDD_HV_ADR13
VDD_HV_ADR02
VDD_HV_ADR13
VDD_HV_ADR13
VDD_HV_ADR02
ANA adc3
AN[2]
AN: adc3_AN[2]
U6
ANA adc2
AN[1]
AN: adc2_AN[1]
U7
ANA adc2_adc3
AN[11]
AN: adc2_adc3_AN[11]
AN: adc2_adc3_AN[12]
AN: adc0_adc1_AN[11]
Analog
Shared
U8
ANA adc2_adc3
AN[12]
Analog
Shared
U11
ANA adc0_adc1
AN[11]
Analog
Shared
END OF 257 MAPBGA PIN MULTIPLEXING TABLE
Do not connect pin directly to a power supply or ground.
1
Table 10. 473 MAPBGA pin multiplexing
Additional Inputs Analog Inputs
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Pad type Power domain
A4
A5
A6
A7
A8
A9
GPIO nexus
A0: siul_GPIO[114]
A1: _
A2: npc_wrapper_MDO[5]
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
MDO[5]1
GPIO nexus
MDO[7]1
A0: siul_GPIO[112]
A1: _
A2: npc_wrapper_MDO[7]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
GPIO nexus
MDO[9]1
A0: siul_GPIO[110]
A1: _
A2: npc_wrapper_MDO[9]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
GPIO flexray
A0: siul_GPIO[51]
A1: flexray_CB_TX
A2: _
I: _
I: _
I: _
GP Slow/
Symmetric
CB_TX
A3: _
GPIO flexray
A0: siul_GPIO[47]
I: ctu0_EXT_IN
I: flexpwm0_EXT_SYNC
I: _
GP Slow/
Symmetric
CA_TR_EN A1: flexray_CA_TR_EN
A2: _
A3: _
GPIO fec
RX_DV
A0: siul_GPIO[210]
A1: flexray_DBG3
A2: etimer2_ETC[0]
A3: dspi0_CS7
I: fec_RX_DV
I: _
I: _
GP Slow/
Medium
A10 GPIO fec
MDIO
A0: siul_GPIO[198]
A1: fec_MDIO
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[28]
A3: dspi2_CS0
A11 GPIO fec
TX_CLK
A0: siul_GPIO[207]
A1: flexray_DBG0
A2: etimer2_ETC[4]
A3: dspi0_CS4
I: fec_TX_CLK
I: _
I: _
GP Slow/
Medium
A12 GPIO fec
TX_EN
A0: siul_GPIO[200]
A1: fec_TX_EN
A2: _
I: _
I: _
I: _
GP Slow/
Medium
A3: lin0_TXD
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
A13 GPIO fec
TXD[3]
A0: siul_GPIO[204]
A1: fec_TXD[3]
A2: _
I: flexpwm1_FAULT[2]
I: _
I: siul_EIRQ[29]
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_IO
A3: dspi2_CS2
A15 GPIO pdi
DATA[3]
A0: siul_GPIO[134]
A1: flexpwm2_X[1]
A2: _
I: pdi_DATA[3]
I: _
I: _
—
—
—
—
—
—
—
—
PDI
Medium
A3: _
A16 GPIO pdi
DATA[1]
A0: siul_GPIO[132]
A1: flexpwm2_B[3]
A2: _
I: pdi_DATA[1]
I: _
I: _
PDI
Medium
A3: _
A17 GPIO pdi
CLOCK
A0: siul_GPIO[128]
A1: flexpwm2_B[1]
A2: _
I: pdi_CLOCK
I: _
I: _
PDI
Medium
A3: etimer1_ETC[3]
A18 GPIO pdi
DATA[7]
A0: siul_GPIO[138]
A1: flexpwm2_B[2]
A2: _
I: pdi_DATA[7]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[5]
A19 GPIO pdi
DATA[10]
A0: siul_GPIO[141]
A1: flexpwm2_X[3]
A2: _
I: pdi_DATA[10]
I: _
I: _
PDI
Medium
A3: _
A20 GPIO pdi
DATA[13]
A0: siul_GPIO[144]
A1: pdi_SENS_SEL[2]
A2: ctu1_EXT_TGR
A3: _
I: pdi_DATA[13]
I: _
I: _
PDI
Medium
A21 GPIO pdi
DATA[15]
A0: siul_GPIO[146]
A1: pdi_SENS_SEL[0]
A2: i2c2_data
I: pdi_DATA[15]
I: ctu1_EXT_IN
I: _
PDI
Medium
A3: _
B3
GPIO mc_cgl
clk_out
A0: siul_GPIO[22]
A1: mc_cgl_clk_out
A2: etimer2_ETC[5]
A3: _
I: _
I: _
GP Slow/
Fast
I: siul_EIRQ[18]
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[14]
A1: can1_TXD
A2: _
Additional Inputs
Analog Inputs
Pad type Power domain
B4
B5
B6
B7
B8
B9
GPIO can1
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
TXD
I: siul_EIRQ[13]
A3: _
GPIO nexus
A0: siul_GPIO[219]
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
MDO[14]1 A1: _
A2: npc_wrapper_MDO[14]
A3: can3_TXD
GPIO dspi2
CS1
A0: siul_GPIO[9]
A1: dspi2_CS1
A2: _
I: flexpwm0_FAULT[0]
I: lin3_RXD
I: can2_RXD
GP Slow/
Medium
A3: _
GPIO flexray
A0: siul_GPIO[52]
I: _
I: _
I: _
GP Slow/
Symmetric
CB_TR_EN A1: flexray_CB_TR_EN
A2: _
A3: _
GPIO flexray
CA_TX
A0: siul_GPIO[48]
A1: flexray_CA_TX
A2: _
I: ctu1_EXT_IN
GP Slow/
Symmetric
I: _
I: _
A3: _
GPIO fec
RXD[3]
A0: siul_GPIO[214]
A1: i2c1_data
A2: _
I: fec_RXD[3]
GP Slow/
Medium
I: _
I: _
A3: _
B10 GPIO fec
RX_ER
A0: siul_GPIO[215]
A1: _
A2: _
I: fec_RX_ER
GP Slow/
Medium
I: _
I: _
A3: dspi0_CS1
B11 GPIO fec
TXD[0]
A0: siul_GPIO[201]
A1: fec_TXD[0]
A2: etimer2_ETC[1]
A3: _
I: _
I: _
I: _
GP Slow/
Medium
B12 GPIO fec
RXD[0]
A0: siul_GPIO[211]
A1: i2c1_clock
A2: _
I: fec_RXD[0]
I: _
I: siul_EIRQ[27]
GP Slow/
Medium
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
B13 GPIO fec
TX_ER
A0: siul_GPIO[205]
A1: fec_TX_ER
A2: dspi2_CS3
A3: _
I: flexpwm1_FAULT[3]
I: lin0_RXD
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_IO
VDD_HV_IO
B15 GPIO pdi
DATA[6]
A0: siul_GPIO[137]
A1: flexpwm2_B[0]
A2: _
I: pdi_DATA[6]
I: _
I: _
—
—
—
—
—
—
—
—
PDI
Medium
A3: etimer1_ETC[1]
B16 GPIO pdi
DATA[4]
A0: siul_GPIO[135]
A1: flexpwm2_A[2]
A2: _
I: pdi_DATA[4]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[4]
B17 GPIO pdi
DATA[0]
A0: siul_GPIO[131]
A1: _
A2: lin3_TXD
A3: _
I: pdi_DATA[0]
I: _
I: flexpwm2_FAULT[2]
PDI
Medium
B18 GPIO pdi
LINE_V
A0: siul_GPIO[129]
A1: _
A2: lin2_TXD
A3: _
I: pdi_LINE_V
I: _
I: flexpwm2_FAULT[0]
PDI
Medium
B19 GPIO pdi
DATA[9]
A0: siul_GPIO[140]
A1: flexpwm2_X[2]
A2: _
I: pdi_DATA[9]
I: _
I: _
PDI
Medium
A3: _
B20 GPIO pdi
DATA[14]
A0: siul_GPIO[145]
A1: pdi_SENS_SEL[1]
A2: i2c2_clock
A3: _
I: pdi_DATA[14]
I: _
I: _
PDI
Medium
B21 GPIO can0
TXD
A0: siul_GPIO[16]
A1: can0_TXD
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[15]
A3: sscm_DEBUG[0]
C2
GPIO nexus
A0: siul_GPIO[220]
I: can3_RXD
I: can2_RXD
I: _
GP Slow/
Fast
MDO[15]1 A1: _
A2: npc_wrapper_MDO[15]
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[50]
A1: _
A2: ctu1_EXT_TGR
A3: _
Additional Inputs
Analog Inputs
Pad type Power domain
C5
C6
C7
C8
C9
GPIO flexray
I: flexray_CB_RX
—
disabled
pulldown
disabled
disabled
pulldown
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
CB_RX
I: _
I: _
GPIO etimer0
A0: siul_GPIO[43]
A1: etimer0_ETC[4]
A2: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
ETC[4]
I: mc_rgm_ABS[0]
I: _
A3: _
GPIO etimer0
ETC[1]
A0: siul_GPIO[1]
A1: etimer0_ETC[1]
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[1]
A3: _
GPIO etimer0
ETC[2]
A0: siul_GPIO[2]
A1: etimer0_ETC[2]
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[2]
A3: _
GPIO etimer0
ETC[3]
A0: siul_GPIO[3]
A1: etimer0_ETC[3]
A2: _
I: _
GP Slow/
Medium
I: mc_rgm_ABS[2]
I: siul_EIRQ[3]
A3: _
C10 GPIO fec
TXD[2]
A0: siul_GPIO[203]
A1: fec_TXD[2]
A2: _
I: flexpwm1_FAULT[1]
GP Slow/
Medium
I: _
I: _
A3: _
C11 GPIO fec
TXD[1]
A0: siul_GPIO[202]
A1: fec_TXD[1]
A2: _
I: flexpwm1_FAULT[0]
GP Slow/
Medium
I: _
I: _
A3: dspi2_SCK
C12 GPIO fec
CRS
A0: siul_GPIO[208]
A1: flexray_DBG1
A2: etimer2_ETC[3]
A3: dspi0_CS5
I: fec_CRS
I: _
GP Slow/
Medium
I: _
C13 GPIO fec
RX_CLK
A0: siul_GPIO[209]
A1: flexray_DBG2
A2: etimer2_ETC[2]
A3: dspi0_CS6
I: fec_RX_CLK
I: _
I: siul_EIRQ[25]
GP Slow/
Medium
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
I: fec_RXD[1]
I: _
I: _
Analog Inputs
Pad type Power domain
C14 GPIO fec
RXD[1]
A0: siul_GPIO[212]
A1: dspi1_CS1
A2: etimer2_ETC[5]
A3: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
C15 GPIO fec
COL
A0: siul_GPIO[206]
A1: fec_COL
A2: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
A3: lin1_TXD
C16 GPIO pdi
DATA[5]
A0: siul_GPIO[136]
A1: flexpwm2_A[0]
A2: _
I: pdi_DATA[5]
I: _
I: _
PDI
Medium
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_PDI
VDD_HV_IO
A3: etimer1_ETC[0]
C17 GPIO pdi
DATA[2]
A0: siul_GPIO[133]
A1: flexpwm2_A[1]
A2: _
I: pdi_DATA[2]
I: _
I: _
PDI
Medium
A3: etimer1_ETC[2]
C18 GPIO pdi
DATA[8]
A0: siul_GPIO[139]
A1: flexpwm2_A[3]
A2: _
I: pdi_DATA[8]
I: _
I: _
PDI
Medium
A3: _
C19 GPIO pdi
DATA[12]
A0: siul_GPIO[143]
I: pdi_DATA[12]
I: lin3_RXD
I: flexpwm2_FAULT[3]
PDI
Medium
A1: _
A2: _
A3: _
C20 GPIO can0
RXD
A0: siul_GPIO[17]
A1: _
I: can0_RXD
I: can1_RXD
I: siul_EIRQ[16]
GP Slow/
Medium
A2: _
A3: sscm_DEBUG[1]
C22 GPIO siul
A0: siul_GPIO[197]
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
GPIO[197] A1: flexpwm0_X[3]
A2: ebi_AD31
A3: _
C23 GPIO dramc
CAS
A0: siul_GPIO[152]
A1: dramc_CAS
A2: ebi_WE_BE_1
A3: flexpwm0_B[2]
I: _
I: _
I: _
DRAM
ACC
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[86]
Additional Inputs
Analog Inputs
Pad type Power domain
D1
D2
D3
D4
D6
D7
GPIO nexus
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_PDI
MDO[1]1
A1: _
A2: npc_wrapper_MDO[1]
A3: _
GPIO nexus
MDO[3]1
A0: siul_GPIO[84]
A1: _
A2: npc_wrapper_MDO[3]
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
GPIO can1
A0: siul_GPIO[15]
I: can1_RXD
I: can0_RXD
I: siul_EIRQ[14]
GP Slow/
Medium
RXD
A1: _
A2: _
A3: _
GPIO dspi0
SOUT
A0: siul_GPIO[38]
A1: dspi0_SOUT
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[24]
A3: sscm_DEBUG[6]
GPIO etimer0
ETC[5]
A0: siul_GPIO[44]
A1: etimer0_ETC[5]
A2: _
I: _
I: _
I: _
GP Slow/
Medium
A3: _
GPIO etimer0
ETC[0]
A0: siul_GPIO[0]
A1: etimer0_ETC[0]
A2: _
I: dspi2_SIN
I: _
I: siul_EIRQ[0]
GP Slow/
Medium
A3: _
D14 GPIO fec
RXD[2]
A0: siul_GPIO[213]
A1: _
A2: _
I: fec_RXD[2]
I: _
I: siul_EIRQ[21]
GP Slow/
Medium
A3: dspi2_SOUT
D15 GPIO fec
MDC
A0: siul_GPIO[199]
A1: fec_MDC
A2: _
I: _
GP Slow/
Medium
I: lin1_RXD
I: _
A3: _
D18 GPIO pdi
DATA[11]
A0: siul_GPIO[142]
A1: flexpwm2_X[0]
A2: _
I: pdi_DATA[11]
PDI
I: _
I: _
Medium
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
D19 GPIO pdi
A0: siul_GPIO[130]
I: pdi_FRAME_V
I: lin2_RXD
I: flexpwm2_FAULT[1]
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
PDI
Medium
VDD_HV_PDI
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
FRAME_V A1: _
A2: _
A3: _
D21 GPIO dramc
BA[1]
A0: siul_GPIO[155]
A1: dramc_BA[1]
A2: ebi_BDIP
I: _
I: _
I: _
—
—
—
—
—
—
—
—
DRAM
ACC
A3: flexpwm1_A[0]
D22 GPIO siul
A0: siul_GPIO[195]
I: _
I: _
I: _
DRAM
ACC
GPIO[195] A1: flexpwm0_X[1]
A2: ebi_AD29
A3: _
D23 GPIO dramc
A0: siul_GPIO[154]
A1: dramc_BA[0]
A2: ebi_WE_BE_3
A3: flexpwm0_B[3]
I: _
I: _
I: _
DRAM
ACC
BA[0]
E2
E3
GPIO nexus
A0: siul_GPIO[85]
A1: _
A2: npc_wrapper_MDO[2]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
MDO[2]1
GPIO flexray
CA_RX
A0: siul_GPIO[49]
A1: _
A2: ctu0_EXT_TGR
A3: _
I: flexray_CA_RX
I: _
I: _
GP Slow/
Medium
VDD_HV_IO
E20 GPIO mc_cgl
clk_out
A0: siul_GPIO[233]
A1: mc_cgl_clk_out
A2: etimer2_ETC[5]
A3: _
I: _
I: _
I: _
PDI Fast
VDD_HV_PDI
E21 GPIO siul
A0: siul_GPIO[149]
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
GPIO[149] A1: _
A2: ebi_RD_WR
A3: flexpwm0_A[1]
E22 GPIO dramc
CS0
A0: siul_GPIO[150]
A1: dramc_CS0
A2: ebi_TS
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm0_B[1]
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
E23 GPIO dramc
BA[2]
A0: siul_GPIO[156]
A1: dramc_BA[2]
A2: ebi_CS0
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
DRAM
ACC
VDD_HV_DRAM
A3: flexpwm1_B[0]
F1
F2
GPIO nexus
GPIO nexus
GPIO nexus
A0: siul_GPIO[109]
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
VDD_HV_IO
MDO[10]1 A1: _
A2: npc_wrapper_MDO[10]
A3: _
A0: siul_GPIO[108]
I: _
I: _
I: _
GP Slow/
Fast
VDD_HV_IO
MDO[11]1 A1: _
A2: npc_wrapper_MDO[11]
A3: _
F3
A0: siul_GPIO[113]
A1: _
A2: npc_wrapper_MDO[6]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
VDD_HV_IO
MDO[6]1
F4
GPIO nexus
MDO[4]1
A0: siul_GPIO[115]
A1: _
A2: npc_wrapper_MDO[4]
A3: _
I: _
I: _
I: _
GP Slow/
Fast
VDD_HV_IO
F20
F21
F22
F23
GPIO dramc
RAS
A0: siul_GPIO[151]
A1: dramc_RAS
A2: ebi_WE_BE_0
A3: flexpwm0_A[2]
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
GPIO siul
A0: siul_GPIO[194]
I: _
I: _
I: _
DRAM
ACC
GPIO[194] A1: flexpwm0_X[0]
A2: ebi_AD28
A3: _
GPIO siul
A0: siul_GPIO[148]
I: _
I: _
I: _
DRAM
ACC
GPIO[148] A1: _
A2: ebi_CLKOUT
A3: flexpwm0_B[0]
GPIO dramc
D[5]
A0: siul_GPIO[179]
A1: dramc_D[5]
A2: ebi_AD13
I: _
I: _
I: _
disabled DRAM DQ VDD_HV_DRAM
A3: ebi_ADD29
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[87]
Additional Inputs
Analog Inputs
Pad type Power domain
G1
GPIO nexus
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
MCKO
A1: _
A2: npc_wrapper_MCKO
A3: _
G3
GPIO nexus
MDO[8]1
A0: siul_GPIO[111]
A1: _
A2: npc_wrapper_MDO[8]
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Fast
VDD_HV_IO
G4
GPIO nexus
A0: siul_GPIO[88]
I: _
I: _
GP Slow/
Fast
VDD_HV_IO
MSEO_B[1]1 A1: _
A2: npc_wrapper_MSEO_B[1] I: _
A3: _
G20 GPIO siul
A0: siul_GPIO[196]
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
GPIO[196] A1: flexpwm0_X[2]
A2: ebi_AD30
A3: _
G21 GPIO dramc
A0: siul_GPIO[190]
A1: dramc_DQS[0]
A2: ebi_AD24
A3: _
I: _
I: _
I: _
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
DQS[0]
G22 GPIO dramc
DM[0]
A0: siul_GPIO[192]
A1: dramc_DM[0]
A2: ebi_AD26
A3: _
I: _
I: _
I: _
G23 GPIO dramc
D[7]
A0: siul_GPIO[181]
A1: dramc_D[7]
A2: ebi_AD15
I: _
I: _
I: _
A3: ebi_ADD31
H1
H3
GPIO nexus
EVTO_B
A0: siul_GPIO[90]
A1: _
A2: npc_wrapper_EVTO_B
A3: _
I: _
I: _
I: _
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
GPIO nexus
A0: siul_GPIO[89]
I: _
I: _
I: _
GP Slow/
Fast
MSEO_B[0]1 A1: _
A2: npc_wrapper_MSEO_B[0]
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[91]
Additional Inputs
Analog Inputs
Pad type Power domain
H4
GPIO nexus
I: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
EVTI_B
A1: _
A2: leo_sor_proxy_EVTI_B
A3: _
H20 GPIO dramc
D[2]
A0: siul_GPIO[176]
A1: dramc_D[2]
A2: ebi_AD10
I: _
I: _
I: _
—
—
—
—
—
—
—
—
disabled DRAM DQ VDD_HV_DRAM
A3: ebi_ADD26
J1
J2
GPIO nexus
RDY_B
A0: siul_GPIO[216]
A1: _
A2: nexus_RDY_B
A3: _
I: _
I: _
I: _
disabled
disabled
disabled
disabled
GP Slow/
Fast
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
GPIO nexus
A0: siul_GPIO[218]
I: can2_RXD
I: can3_RXD
I: _
GP Slow/
Fast
MDO[13]1 A1: _
A2: npc_wrapper_MDO[13]
A3: _
J3
GPIO nexus
A0: siul_GPIO[217]
I: _
I: _
I: _
GP Slow/
Fast
MDO[12]1 A1: _
A2: npc_wrapper_MDO[12]
A3: can2_TXD
J4
GPIO dspi1
SIN
A0: siul_GPIO[8]
A1: _
A2: _
I: dspi1_SIN
I: _
I: siul_EIRQ[8]
GP Slow/
Medium
A3: _
J20
J21
J22
GPIO dramc
D[0]
A0: siul_GPIO[174]
A1: dramc_D[0]
A2: ebi_AD8
I: _
I: _
I: _
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
A3: ebi_ADD24
GPIO dramc
D[1]
A0: siul_GPIO[175]
A1: dramc_D[1]
A2: ebi_AD9
I: _
I: _
I: _
A3: ebi_ADD25
GPIO dramc
D[3]
A0: siul_GPIO[177]
A1: dramc_D[3]
A2: ebi_AD11
I: _
I: _
I: _
A3: ebi_ADD27
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
J23
K1
K2
K3
K4
GPIO dramc
A0: siul_GPIO[180]
A1: dramc_D[6]
A2: ebi_AD14
I: _
I: _
I: _
—
disabled DRAM DQ VDD_HV_DRAM
D[6]
A3: ebi_ADD30
GPIO dspi0
A0: siul_GPIO[37]
A1: dspi0_SCK
A2: _
I: flexpwm0_FAULT[3]
I: _
I: siul_EIRQ[23]
—
—
—
—
—
—
—
—
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
SCK
A3: sscm_DEBUG[5]
GPIO dspi1
CS0
A0: siul_GPIO[5]
A1: dspi1_CS0
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[5]
A3: dspi0_CS7
GPIO dspi1
SCK
A0: siul_GPIO[6]
A1: dspi1_SCK
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[6]
A3: _
GPIO dspi1
SOUT
A0: siul_GPIO[7]
A1: dspi1_SOUT
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[7]
A3: _
K21 GPIO dramc
D[4]
A0: siul_GPIO[178]
A1: dramc_D[4]
A2: ebi_AD12
I: _
I: _
I: _
DRAM DQ VDD_HV_DRAM
A3: ebi_ADD28
K22 GPIO dramc
D[8]
A0: siul_GPIO[182]
A1: dramc_D[8]
A2: ebi_AD16
A3: _
I: _
I: _
I: _
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
K23 GPIO dramc
D[9]
A0: siul_GPIO[183]
A1: dramc_D[9]
A2: ebi_AD17
A3: _
I: _
I: _
I: _
L1
GPIO dspi0
CS0
A0: siul_GPIO[36]
A1: dspi0_CS0
A2: _
I: _
I: _
disabled
GP Slow/
Medium
VDD_HV_IO
I: siul_EIRQ[22]
A3: sscm_DEBUG[4]
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[42]
A1: dspi2_CS2
A2: lin3_TXD
A3: can2_TXD
Additional Inputs
Analog Inputs
Pad type Power domain
L2
L3
GPIO dspi2
I: flexpwm0_FAULT[1]
—
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
CS2
I: _
I: _
GPIO dspi2
A0: siul_GPIO[10]
A1: dspi2_CS0
A2: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
CS0
I: siul_EIRQ[9]
A3: can3_TXD
M1
M3
GPIO flexpwm0
X[0]
A0: siul_GPIO[57]
A1: flexpwm0_X[0]
A2: lin2_TXD
A3: _
I: _
I: _
I: _
GP Slow/
Medium
VDD_HV_IO
GPIO dspi0
SIN
A0: siul_GPIO[39]
A1: _
A2: _
I: dspi0_SIN
GP Slow/
Medium
VDD_HV_IO
I: _
I: _
A3: sscm_DEBUG[7]
M20 GPIO dramc
ODT
A0: siul_GPIO[157]
A1: dramc_ODT
A2: ebi_CS1
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
A3: flexpwm1_A[1]
M21 GPIO dramc
WEB
A0: siul_GPIO[153]
A1: dramc_WEB
A2: ebi_WE_BE_2
A3: flexpwm0_A[3]
I: _
I: _
I: _
DRAM
ACC
M22 GPIO dramc
D[11]
A0: siul_GPIO[185]
A1: dramc_D[11]
A2: ebi_AD19
A3: _
I: _
I: _
I: _
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
M23 GPIO dramc
D[10]
A0: siul_GPIO[184]
A1: dramc_D[10]
A2: ebi_AD18
A3: _
I: _
I: _
I: _
N1
GPIO flexpwm0
A[0]
A0: siul_GPIO[58]
A1: flexpwm0_A[0]
A2: _
I: _
disabled
GP Slow/
Medium
VDD_HV_IO
I: etimer0_ETC[0]
I: _
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[60]
A1: flexpwm0_X[1]
A2: _
A3: _
Additional Inputs
I: lin2_RXD
I: _
I: _
Analog Inputs
Pad type Power domain
N3
N4
GPIO flexpwm0
X[1]
—
disabled
GP Slow/
Medium
VDD_HV_IO
GPIO flexpwm0
B[2]
A0: siul_GPIO[100]
A1: flexpwm0_B[2]
A2: _
I: _
—
—
—
—
—
—
—
—
disabled
GP Slow/
Medium
VDD_HV_IO
I: etimer0_ETC[5]
I: _
A3: _
N20 GPIO dramc
DQS[1]
A0: siul_GPIO[191]
A1: dramc_DQS[1]
A2: ebi_AD25
A3: _
I: _
I: _
I: _
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
N21 GPIO dramc
DM[1]
A0: siul_GPIO[193]
A1: dramc_DM[1]
A2: ebi_AD27
A3: _
I: _
I: _
I: _
N22 GPIO dramc
D[13]
A0: siul_GPIO[187]
A1: dramc_D[13]
A2: ebi_AD21
A3: _
I: _
I: _
I: _
N23 GPIO dramc
D[12]
A0: siul_GPIO[186]
A1: dramc_D[12]
A2: ebi_AD20
A3: _
I: _
I: _
I: _
P1
P2
P3
GPIO flexpwm0
B[0]
A0: siul_GPIO[59]
A1: flexpwm0_B[0]
A2: _
I: _
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
I: etimer0_ETC[1]
I: _
A3: _
GPIO flexpwm0
B[1]
A0: siul_GPIO[62]
A1: flexpwm0_B[1]
A2: _
I: _
GP Slow/
Medium
I: etimer0_ETC[3]
I: _
A3: _
GPIO flexpwm0
A[2]
A0: siul_GPIO[99]
A1: flexpwm0_A[2]
A2: _
I: _
GP Slow/
Medium
I: etimer0_ETC[4]
I: _
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
P4
GPIO flexpwm0
A[3]
A0: siul_GPIO[102]
A1: flexpwm0_A[3]
A2: _
I: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
A3: _
P20 GPIO dramc
D[14]
A0: siul_GPIO[188]
A1: dramc_D[14]
A2: ebi_AD22
A3: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
disabled DRAM DQ VDD_HV_DRAM
disabled DRAM DQ VDD_HV_DRAM
P21 GPIO dramc
D[15]
A0: siul_GPIO[189]
A1: dramc_D[15]
A2: ebi_AD23
A3: _
I: _
I: _
I: _
R1
R2
R3
GPIO flexpwm0
X[2]
A0: siul_GPIO[98]
A1: flexpwm0_X[2]
A2: lin3_TXD
A3: _
I: _
I: _
I: _
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
GPIO flexpwm0
X[3]
A0: siul_GPIO[101]
A1: flexpwm0_X[3]
A2: _
I: lin3_RXD
I: _
I: _
GP Slow/
Medium
A3: _
GPIO flexpwm0
A[1]
A0: siul_GPIO[80]
A1: flexpwm0_A[1]
A2: _
I: _
GP Slow/
Medium
VDD_HV_IO
I: etimer0_ETC[2]
I: _
A3: _
R21 GPIO dramc
ADD[3]
A0: siul_GPIO[161]
A1: dramc_ADD[3]
A2: ebi_ADD11
A3: ebi_TEA
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
R22 GPIO dramc
CKE
A0: siul_GPIO[147]
A1: dramc_CKE
A2: ebi_OE
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm0_A[0]
T1
GPIO flexpwm0
B[3]
A0: siul_GPIO[103]
A1: flexpwm0_B[3]
A2: _
I: _
I: _
I: _
GP Slow/
Medium
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
T2
T3
GPIO flexpwm1
A[0]
A0: siul_GPIO[117]
A1: flexpwm1_A[0]
A2: _
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
A3: can2_TXD
GPIO flexpwm1
A[1]
A0: siul_GPIO[120]
A1: flexpwm1_A[1]
A2: _
I: _
I: _
I: _
—
—
—
—
—
—
—
—
GP Slow/
Medium
VDD_HV_IO
A3: can3_TXD
T20
T21
T22
U1
GPIO dramc
ADD[8]
A0: siul_GPIO[166]
A1: dramc_ADD[8]
A2: ebi_AD0
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
A3: ebi_ADD16
GPIO dramc
ADD[9]
A0: siul_GPIO[167]
A1: dramc_ADD[9]
A2: ebi_AD1
I: _
I: _
I: _
DRAM
ACC
A3: ebi_ADD17
GPIO dramc
ADD[1]
A0: siul_GPIO[159]
A1: dramc_ADD[1]
A2: ebi_ADD9
I: _
I: _
I: _
DRAM
ACC
A3: ebi_CS3
GPIO flexpwm1
B[0]
A0: siul_GPIO[118]
A1: flexpwm1_B[0]
A2: _
I: can2_RXD
I: can3_RXD
I: _
GP Slow/
Medium
A3: _
U2
GPIO flexpwm1
B[1]
A0: siul_GPIO[121]
A1: flexpwm1_B[1]
A2: _
I: can3_RXD
I: can2_RXD
I: _
GP Slow/
Medium
VDD_HV_IO
A3: _
U3
GPIO flexpwm1
A[2]
A0: siul_GPIO[123]
A1: flexpwm1_A[2]
A2: _
I: _
I: _
I: _
GP Slow/
Medium
VDD_HV_IO
A3: _
U4
GPIO dspi2
SCK
A0: siul_GPIO[11]
A1: dspi2_SCK
A2: _
I: can3_RXD
I: _
I: siul_EIRQ[10]
GP Slow/
Medium
VDD_HV_IO
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
U20 GPIO dramc
ADD[6]
A0: siul_GPIO[164]
A1: dramc_ADD[6]
A2: ebi_ADD14
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
disabled
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
A3: flexpwm1_A[2]
U21 GPIO dramc
ADD[12]
A0: siul_GPIO[170]
A1: dramc_ADD[12]
A2: ebi_AD4
I: _
I: _
I: _
—
—
—
—
—
—
—
—
DRAM
ACC
A3: ebi_ADD20
U23 GPIO dramc
ADD[0]
A0: siul_GPIO[158]
A1: dramc_ADD[0]
A2: ebi_ADD8
I: _
I: _
I: _
DRAM
ACC
A3: ebi_CS2
V3
V4
GPIO flexpwm1
B[2]
A0: siul_GPIO[124]
A1: flexpwm1_B[2]
A2: _
I: _
I: _
I: _
GP Slow/
Medium
A3: _
GPIO dspi1
CS2
A0: siul_GPIO[56]
A1: dspi1_CS2
A2: _
I: flexpwm0_FAULT[3]
I: lin2_RXD
I: _
GP Slow/
Medium
VDD_HV_IO
A3: dspi0_CS5
V20 GPIO lin0
TXD
A0: siul_GPIO[18]
A1: lin0_TXD
A2: i2c0_clock
I: _
I: _
GP Slow/
Medium
VDD_HV_IO
I: siul_EIRQ[17]
A3: sscm_DEBUG[2]
V21 GPIO dramc
A0: siul_GPIO[171]
A1: dramc_ADD[13]
A2: ebi_AD5
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
ADD[13]
A3: ebi_ADD21
V23 GPIO dramc
ADD[2]
A0: siul_GPIO[160]
A1: dramc_ADD[2]
A2: ebi_ADD10
A3: ebi_TA
I: _
I: _
I: _
DRAM
ACC
W3
GPIO dspi0
CS3
A0: siul_GPIO[53]
A1: dspi0_CS3
A2: i2c2_clock
A3: _
I: flexpwm0_FAULT[2]
I: _
I: _
GP Slow/
Medium
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[19]
A1: _
A2: i2c0_data
A3: sscm_DEBUG[3]
Additional Inputs
I: lin0_RXD
I: _
I: _
Analog Inputs
Pad type Power domain
W20 GPIO lin0
RXD
—
disabled
disabled
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
W21 GPIO dramc
ADD[14]
A0: siul_GPIO[172]
A1: dramc_ADD[14]
A2: ebi_AD6
I: _
I: _
I: _
—
—
—
—
—
DRAM
ACC
A3: ebi_ADD22
W22 GPIO dramc
ADD[7]
A0: siul_GPIO[165]
A1: dramc_ADD[7]
A2: ebi_ADD15
I: _
I: _
I: _
DRAM
ACC
A3: flexpwm1_B[2]
W23 GPIO dramc
ADD[4]
A0: siul_GPIO[162]
A1: dramc_ADD[4]
A2: ebi_ADD12
A3: ebi_ALE
I: _
I: _
I: _
DRAM
ACC
Y3
Y5
GPIO dspi0
CS2
A0: siul_GPIO[54]
A1: dspi0_CS2
A2: i2c2_data
A3: _
I: flexpwm0_FAULT[1]
I: _
I: _
GP Slow/
Medium
GPIO flexpwm1
X[0]
A0: siul_GPIO[116]
A1: flexpwm1_X[0]
A2: etimer2_ETC[0]
A3: dspi0_CS1
I: ctu0_EXT_IN
I: ctu1_EXT_IN
I: _
GP Slow/
Medium
VDD_HV_IO
Y6
Y7
Y8
ANA adc3
AN[0]
—
—
—
siul_GPI[229]
siul_GPI[225]
siul_GPI[228]
AN: adc3_AN[0]
—
—
—
Analog VDD_HV_ADR23
ANA adc2_adc3
AN[11]
AN: adc2_adc3_AN[11]
AN: adc2_adc3_AN[14]
Analog VDD_HV_ADR23
Shared
ANA adc2_adc3
AN[14]
Analog VDD_HV_ADR23
Shared
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
A0: siul_GPIO[45]
A1: etimer1_ETC[1]
A2: _
A3: _
Additional Inputs
Analog Inputs
Pad type Power domain
Y9
GPIO etimer1
I: ctu0_EXT_IN
I: flexpwm0_EXT_SYNC
I: ctu1_EXT_IN
—
disabled
disabled
pulldown
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
ETC[1]
Y10 GPIO etimer1
ETC[2]
A0: siul_GPIO[46]
A1: etimer1_ETC[2]
A2: ctu0_EXT_TGR
A3: _
I: _
I: _
I: _
—
—
GP Slow/
Medium
Y11 GPIO etimer1
ETC[3]
A0: siul_GPIO[92]
A1: etimer1_ETC[3]
A2: _
I: ctu1_EXT_IN
I: mc_rgm_FAB
I: siul_EIRQ[30]
GP Slow/
Medium
A3: _
Y14 ANA adc0_adc1
AN[11]
—
siul_GPI[25]
AN: adc0_adc1_AN[11]
—
—
Analog
Shared
VDD_HV_ADR0
VDD_HV_IO
Y15 GPIO etimer1
ETC[5]
A0: siul_GPIO[78]
A1: etimer1_ETC[5]
A2: _
I: _
I: _
disabled
GP Slow/
Medium
I: siul_EIRQ[26]
A3: _
Y16 GPIO etimer1
ETC[4]
A0: siul_GPIO[93]
A1: etimer1_ETC[4]
A2: ctu1_EXT_TGR
A3: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
I: siul_EIRQ[31]
Y17 ANA adc1
AN[8]
—
siul_GPI[74]
siul_GPI[76]
AN: adc1_AN[8]
AN: adc1_AN[6]
—
—
—
Analog
Analog
VDD_HV_ADR1
VDD_HV_ADR1
VDD_HV_DRAM
Y18 ANA adc1
AN[6]
—
Y21 GPIO dramc
ADD[15]
A0: siul_GPIO[173]
A1: dramc_ADD[15]
A2: ebi_AD7
I: _
I: _
I: _
disabled
DRAM
ACC
A3: ebi_ADD23
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
Y22 GPIO dramc
ADD[11]
A0: siul_GPIO[169]
A1: dramc_ADD[11]
A2: ebi_AD3
I: _
I: _
I: _
—
disabled
disabled
disabled
disabled
DRAM
ACC
VDD_HV_DRAM
VDD_HV_DRAM
VDD_HV_IO
A3: ebi_ADD19
Y23 GPIO dramc
ADD[5]
A0: siul_GPIO[163]
A1: dramc_ADD[5]
A2: ebi_ADD13
I: _
I: _
I: _
—
—
—
DRAM
ACC
A3: flexpwm1_B[1]
AA4 GPIO dspi1
CS3
A0: siul_GPIO[55]
A1: dspi1_CS3
A2: lin2_TXD
I: _
I: _
I: _
GP Slow/
Medium
A3: dspi0_CS4
AA5 GPIO flexpwm1
X[1]
A0: siul_GPIO[119]
A1: flexpwm1_X[1]
A2: etimer2_ETC[1]
A3: dspi0_CS4
I: _
I: _
I: _
GP Slow/
Medium
VDD_HV_IO
AA6 ANA adc3
AN[1]
—
—
—
—
—
—
siul_GPI[230]
siul_GPI[226]
siul_GPI[221]
siul_GPI[33]
siul_GPI[66]
siul_GPI[69]
AN: adc3_AN[1]
AN: adc2_adc3_AN[12]
AN: adc2_AN[0]
AN: adc0_AN[2]
AN: adc0_AN[5]
AN: adc0_AN[8]
—
—
—
—
—
—
Analog VDD_HV_ADR23
AA7 ANA adc2_adc3
AN[12]
Analog VDD_HV_ADR23
Shared
AA8 ANA adc2
AN[0]
Analog VDD_HV_ADR23
AA11 ANA adc0
AN[2]
Analog
Analog
Analog
VDD_HV_ADR0
VDD_HV_ADR0
VDD_HV_ADR0
AA12 ANA adc0
AN[5]
AA13 ANA adc0
AN[8]
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
siul_GPI[26]
Analog Inputs
Pad type Power domain
AA14 ANA adc0_adc1
AN[12]
—
AN: adc0_adc1_AN[12]
—
—
—
Analog
Shared
VDD_HV_ADR0
VDD_HV_ADR1
VDD_HV_ADR1
AA15 ANA adc1
AN[0]
—
—
siul_GPI[29]
AN: adc1_AN[0]
AN: adc1_AN[2]
Analog
Analog
lin1_RXD
AA16 ANA adc1
AN[2]
siul_GPI[31]
siul_EIRQ[20]
siul_GPI[64]
AA17 ANA adc1
AN[5]
—
—
AN: adc1_AN[5]
AN: adc1_AN[7]
—
—
—
Analog
Analog
VDD_HV_ADR1
VDD_HV_ADR1
VDD_HV_IO
AA18 ANA adc1
AN[7]
siul_GPI[73]
AA19 GPIO TDI
A0: siul_GPIO[21]
I: jtagc_TDI
I: _
I: _
pullup
GP Slow/
Medium
A1: _
A2: _
A3: _
AA20 GPIO etimer1
ETC[0]
A0: siul_GPIO[4]
A1: etimer1_ETC[0]
A2: _
I: _
I: _
—
—
—
—
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
I: siul_EIRQ[4]
A3: _
AA22 GPIO lin1
TXD
A0: siul_GPIO[94]
A1: lin1_TXD
A2: i2c1_clock
A3: _
I: _
I: _
I: _
GP Slow/
Medium
AA23 GPIO dramc
ADD[10]
A0: siul_GPIO[168]
A1: dramc_ADD[10]
A2: ebi_AD2
I: _
I: _
I: _
DRAM
ACC
VDD_HV_DRAM
VDD_HV_IO
A3: ebi_ADD18
AB3 GPIO dspi2
SOUT
A0: siul_GPIO[12]
A1: dspi2_SOUT
A2: _
I: _
I: _
GP Slow/
Medium
I: siul_EIRQ[11]
A3: _
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
Analog Inputs
Pad type Power domain
AB4 GPIO flexpwm1
X[2]
A0: siul_GPIO[122]
A1: flexpwm1_X[2]
A2: etimer2_ETC[2]
A3: dspi0_CS5
I: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
AB5 GPIO flexpwm1
X[3]
A0: siul_GPIO[125]
A1: flexpwm1_X[3]
A2: etimer2_ETC[3]
A3: dspi0_CS6
I: _
I: _
I: _
—
disabled
GP Slow/
Medium
VDD_HV_IO
AB6 ANA adc3
AN[2]
—
—
—
—
—
—
—
—
—
siul_GPI[231]
siul_GPI[227]
siul_GPI[222]
siul_GPI[223]
siul_GPI[23]
AN: adc3_AN[2]
—
—
—
—
—
—
—
—
—
Analog VDD_HV_ADR23
AB7 ANA adc2_adc3
AN[13]
AN: adc2_adc3_AN[13]
AN: adc2_AN[1]
Analog VDD_HV_ADR23
Shared
AB8 ANA adc2
AN[1]
Analog VDD_HV_ADR23
Analog VDD_HV_ADR23
AB9 ANA adc2
AN[2]
AN: adc2_AN[2]
AB10 ANA adc0
AN[0]
AN: adc0_AN[0]
Analog
Analog
Analog
Analog
VDD_HV_ADR0
VDD_HV_ADR0
VDD_HV_ADR0
VDD_HV_ADR0
VDD_HV_ADR0
lin0_RXD
AB11 ANA adc0
AN[4]
siul_GPI[70]
AN: adc0_AN[4]
AB12 ANA adc0
AN[6]
siul_GPI[71]
siul_GPI[68]
siul_GPI[27]
AN: adc0_AN[6]
AB13 ANA adc0
AN[7]
AN: adc0_AN[7]
AB14 ANA adc0_adc1
AN[13]
AN: adc0_adc1_AN[13]
Analog
Shared
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
siul_GPI[30]
Analog Inputs
Pad type Power domain
AB15 ANA adc1
AN[1]
—
AN: adc1_AN[1]
—
Analog
VDD_HV_ADR1
etimer0_ETC[4]
siul_EIRQ[19]
siul_GPI[32]
AB16 ANA adc1
AN[3]
—
—
AN: adc1_AN[3]
AN: adc1_AN[4]
—
—
—
Analog
Analog
VDD_HV_ADR1
VDD_HV_ADR1
VDD_HV_IO
AB17 ANA adc1
AN[4]
siul_GPI[75]
AB18 GPIO TDO
A0: siul_GPIO[20]
A1: jtagc_TDO
A2: _
I: _
I: _
I: _
disabled
GP Slow/
Fast
A3: _
AB21 GPIO lin1
RXD
A0: siul_GPIO[95]
A1: _
A2: i2c1_data
A3: _
I: lin1_RXD
I: _
I: _
—
—
—
—
disabled
disabled
disabled
disabled
GP Slow/
Medium
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
VDD_HV_IO
AC3 GPIO dspi2
SIN
A0: siul_GPIO[13]
I: dspi2_SIN
I: flexpwm0_FAULT[0]
I: siul_EIRQ[12]
GP Slow/
Medium
A1: _
A2: _
A3: _
AC4 GPIO flexpwm1
A[3]
A0: siul_GPIO[126]
A1: flexpwm1_A[3]
A2: etimer2_ETC[4]
A3: dspi0_CS7
I: _
I: _
I: _
GP Slow/
Medium
AC5 GPIO flexpwm1
B[3]
A0: siul_GPIO[127]
A1: flexpwm1_B[3]
A2: etimer2_ETC[5]
A3: _
I: _
I: _
I: _
GP Slow/
Medium
AC6 ANA adc3
AN[3]
—
siul_GPI[232]
siul_GPI[224]
AN: adc3_AN[3]
AN: adc2_AN[3]
—
—
GP Slow/ VDD_HV_ADR23
Medium
AC9 ANA adc2
AN[3]
—
Analog VDD_HV_ADR23
Table 10. 473 MAPBGA pin multiplexing (continued)
Ball
number type
Ball
Weak pull
during reset
Ball name
Alternate I/O
Additional Inputs
siul_GPI[24]
Analog Inputs
Pad type Power domain
AC10 ANA adc0
AN[1]
—
AN: adc0_AN[1]
—
—
—
Analog
VDD_HV_ADR0
VDD_HV_ADR0
VDD_HV_ADR0
etimer0_ETC[5]
AC11 ANA adc0
AN[3]
—
—
siul_GPI[34]
AN: adc0_AN[3]
Analog
AC14 ANA adc0_adc1
AN[14]
siul_GPI[28]
AN: adc0_adc1_AN[14]
Analog
Shared
END OF 473 MAPBGA PIN MULTIPLEXING TABLE
Do not connect pin directly to a power supply or ground.
1
Electrical characteristics
3
Electrical characteristics
3.1
Introduction
This section contains detailed information on power considerations, DC/AC electrical characteristics, and AC timing
specifications for this device.
The “Symbol” column of the electrical parameter and timings tables may contain an additional column containing “SR”, “CC”,
“P”, “C”, “T”, or “D”.
•
“SR” identifies system requirements—conditions that must be provided to ensure normal device operation. An
example is the input voltage of a voltage regulator.
•
“CC” identifies specifications that define normal device operation. Where available, the letters “P”, “C”, “T”, or “D”
replace the letter “CC” and apply to these controller characteristics. They specify how each characteristic is
guaranteed.
— P: parameter is guaranteed by production testing of each individual device.
— C: parameter is guaranteed by design characterization. Measurements are taken from a statistically relevant
sample size across process variations.
— T: parameter is guaranteed by design characterization on a small sample size from typical devices under typical
conditions unless otherwise noted. All values are shown in the typical (“typ”) column are within this category.
— D: parameters are derived mainly from simulations.
3.2
Absolute maximum ratings
1
Table 11. Absolute maximum ratings
No.
Symbol
Parameter
Conditions
Min
Max
Unit
1
2
VDD_HV_PMU SR Voltage regulator supply voltage
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
–0.3
–0.1
–0.3
–0.1
–0.3
–0.1
–0.3
–0.1
–0.3
–0.1
–0.3
–0.1
–0.3
–0.1
–0.3
–0.1
–0.3
5.52
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
VSS_HV_PMU
VDD_HV_IO
VSS_HV_IO
SR Voltage regulator supply ground
SR Input/output supply voltage
SR Input/output supply ground
SR Flash supply voltage
0.1
3
3.633,4
0.1
4
5
VDD_HV_FLA
VSS_HV_FLA
3.63,4
6
SR Flash supply ground
0.1
7
VDD_HV_OSC SR Crystal oscillator amplifier supply voltage
3.63,4
0.1
8
VSS_HV_OSC
VDD_HV_PDI
VSS_HV_PDI
SR Crystal oscillator amplifier supply ground
SR PDI interface supply voltage
9
3.63,4
10
SR PDI interface supply ground
0.1
11 VDD_HV_DRAM SR DRAM interface supply voltage
3.63,4
0.1
5
12 VSS_HV_DRAM SR DRAM interface supply ground
6
13 VDD_HV_ADRx
SR ADCx high reference voltage
6.0
14
15
16
17
VSS_HV_ADRx SR ADCx low reference voltage
0.1
VDD_HV_ADV
VSS_HV_ADV
VDD_LV_COR
SR ADC supply voltage
3.633,4
SR ADC supply ground
0.1
SR Core supply voltage digital logic
1.327
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
69
Electrical characteristics
1
Table 11. Absolute maximum ratings (continued)
No.
Symbol
Parameter
Conditions
Min
Max
Unit
18
19
20
21
VSS_LV_COR
VDD_LV_PLL
VSS_LV_PLL
TVDD
SR Core supply voltage ground digital logic
SR PLL supply voltage
—
—
—
—
–0.1
–0.3
–0.1
—
0.1
1.32
0.1
V
V
SR PLL reference voltage
V
SR Slope characteristics on all VDD during power
up
25
mV/µs
22
23
24
25
VIN
SR Voltage on any pin with respect to its supply rail Relative to
–0.3
–10
–3
VDD_HV_xxx
+ 0.38
V
VDD_HV_xxx
VDD_HV_xxx
IINJPAD
IINJPADA
IINJSUM
SR Injected input current on any pin during
overload condition
—
10
mA
mA
mA
SR Injected input current on any analog pin during
overload condition
—
—
3
SR Absolute sum of all injected input currents
during overload condition
–50
–559
50
150
26
27
TSTG
TSDR
SR Storage temperature
—
—
°C
°C
SR Maximum Solder Temperature10
Pb-free package
—
—
260
245
SnPb package
28
MSL
SR Moisture Sensitivity Level11
—
—
3
—
1
Functional operating conditions are given in the DC electrical characteristics. Absolute maximum ratings are stress
ratings only, and functional operation at the maxima is not guaranteed. Stress beyond the listed maxima may affect
device reliability or cause permanent damage to the device.
2
3
4
5
6.5 V for 10 hours cumulative time, 5.0 V + 10% for time remaining.
5.3 V for 10 hours cumulative over lifetime of device, 3.63 V for time remaining.
Voltage overshoots during a high-to-low or low-to-high transition must not exceed 10 seconds per instance.
As the VDD_HV_DRAM_VREF supply should always be constrained by the VDD_HV_DRAM supply for example through a
voltage divider network per the JEDEC specification, the maximum ratings for the VDD_HV_DRAM supply should be used
for the VDD_HV_DRAM_VREF reference as well.
6
7
8
9
All VDD_HV_ADRx rails must be operated at the same supply voltage.
2.0 V for 10 hours cumulative time, 1.2 V + 10% for time remaining.
Only when VDD_HV_xxx < 5.2 V.
If the ambient temperature is at or above the minimum storage temperature and below the recommended minimum
operating temperature, power may be applied to the device safely. However, functionality is not guaranteed and a power
cycle must be administered if in internal regulation mode or an assertion of RESET_SUP_B must be administered if in
external regulation mode once device enters into the recommended operating temperature range.
10 Solder profile per CDF-AEC-Q100.
11 Moisture sensitivity per JEDEC test method A112.
3.3
Recommended operating conditions
Table 12. Recommended operating conditions
No.
Symbol
Parameter
Conditions
Min
Max
Unit
1
VDD_HV_PMU SR Voltage regulator supply voltage
—
3.0
5.5
V
MPC5675K Microcontroller Data Sheet, Rev. 8.1
70
NXP Semiconductors
Electrical characteristics
Table 12. Recommended operating conditions (continued)
No.
Symbol
Parameter
Conditions
Min
Max
Unit
2
3
VSS_HV_PMU
VDD_HV_IO
SR Voltage regulator supply ground
SR Input/output supply voltage
SR Input/output supply ground
SR Flash supply voltage
—
—
—
—
—
—
—
—
—
—
—
—
0
3.0
0
0
3.63
0
V
V
V
V
V
V
V
V
V
V
V
V
4
VSS_HV_IO
5
VDD_HV_FLA
VSS_HV_FLA
VDD_HV_OSC
VSS_HV_OSC
VDD_HV_PDI
VSS_HV_PDI
3.0
0
3.63
0
6
SR Flash supply ground
7
SR Crystal oscillator amplifier supply voltage
SR Crystal oscillator amplifier supply ground
SR PDI interface supply voltage
SR PDI interface supply ground
3.0
0
3.63
0
8
9
1.62
0
3.63
0
10
11 VDD_HV_DRAM SR DRAM interface supply voltage
1.62
0
3.63
0
12
13
VSS_HV_DRAM SR DRAM interface supply ground
VDD_HV_ADRx SR ADCx high reference voltage1
3.0
4.5
3.63
5.5
Alternate input
voltage
14
15
16
17
VSS_HV_ADRx SR ADCx low reference voltage
—
—
—
0
3.0
0
0
V
V
V
V
VDD_HV_ADV
VSS_HV_ADV
VDD_LV_COR
SR ADC supply voltage
3.63
0
SR ADC supply ground
SR Core supply voltage digital logic2
ExternalVREG
mode
1.14
1.32
17a
CC
Internal VREG
Mode
1.14
1.32
V
18
19
VSS_LV_COR
VDD_LV_PLL
SR Core supply voltage ground digital logic
SR PLL supply voltage2
—
0
0
V
V
ExternalVREG
mode
1.14
1.32
19a
CC
Internal VREG
Mode
1.14
1.32
V
20
21
VSS_LV_PLL
TA
SR PLL reference voltage
—
0
0
V
SR Ambient temperature under bias3,4
257 MAPBGA
473 MAPBGA
257 MAPBGA
473 MAPBGA
–40
–40
–40
–40
125
125
150
150
°C
°C
°C
22
TJ
SR Junction temperature under bias4
1
2
If this supply is not above its absolute minimum recommended operating level, LBIST operations can fail.
The jitter specifications for both PLLs holds true only up to 50 mV noise (peak to peak) on VDD_LV_COR and
VDD_LV_PLL
.
3
4
See Table 1 for available frequency and package options.
When determining if the operating temperature specifications are met, either the ambient temperature or junction
temperature specification can be used. It is not necessary that both specifications be met at all times. However, it
is critical that the junction temperature specification is not exceeded under any condition.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
71
Electrical characteristics
3.4
Thermal characteristics
Table 13. Thermal characteristics for package options
Value
No.
Symbol
Parameter
Conditions
Unit
BGA BGA
257
473
1
2
3
4
RθJA CC Thermal resistance junction-to-ambient Single layer board – 1s
natural convection1
≤ 40 ≤ 34 °C/W
≤ 22 ≤ 20 °C/W
≤ 32 ≤ 26 °C/W
≤ 18 ≤ 17 °C/W
≤ 10 ≤ 10 °C/W
RθJA CC Thermal resistance junction-to-ambient Four layer board – 2s2p
natural convection1
RθJMA CC Thermal resistance
junction-to-moving-air ambient1
@ 200 ft./min.,
single layer board – 1s
RθJMA CC Thermal resistance
junction-to-moving-air ambient1
@ 200 ft./min.,
four layer board – 2s2p
5
6
7
RθJB CC Thermal resistance junction-to-board2
RθJC CC Thermal resistance junction-to-case3
—
—
—
≤ 6
≤ 2
≤ 6 °C/W
≤ 2 °C/W
ΨJT
CC Junction-to-package-top natural
convection4
1
2
3
4
Junction-to-Ambient thermal resistance determined per JEDEC JESD51-3 and JESD51-6. Thermal test board
meets JEDEC specification for this package.
Junction-to-Board thermal resistance determined per JEDEC JESD51-8. Thermal test board meets JEDEC
specification for the specified package.
Junction-to-Case at the top of the package determined using MIL-STD 883 Method 1012.1. The cold plate
temperature is used for the case temperature. Reported value includes the thermal resistance of the interface layer.
Thermal characterization parameter indicating the temperature difference between the package top and the
junction temperature per JEDEC JESD51-2. When Greek letters are not available, the thermal characterization
parameter is written as Psi-JT.
3.4.1
General notes for specifications at maximum junction temperature
An estimation of the chip junction temperature, T , can be obtained from Equation 1:
J
T = T + (R
× P )
Eqn. 1
J
A
θJA
D
where:
o
T
= ambient temperature for the package ( C)
A
o
R
= junction to ambient thermal resistance ( C/W)
= power dissipation in the package (W)
θJA
P
D
The junction to ambient thermal resistance is an industry standard value that provides a quick and easy estimation of thermal
performance. Unfortunately, there are two values in common usage: the value determined on a single layer board and the value
obtained on a board with two planes. For packages such as the PBGA, these values can be different by a factor of two. Which
value is closer to the application depends on the power dissipated by other components on the board. The value obtained on a
single layer board is appropriate for the tightly packed printed circuit board. The value obtained on the board with the internal
planes is usually appropriate if the board has low power dissipation and the components are well separated.
When a heat sink is used, the thermal resistance is expressed in Equation 2 as the sum of a junction to case thermal resistance
and a case to ambient thermal resistance:
MPC5675K Microcontroller Data Sheet, Rev. 8.1
72
NXP Semiconductors
Electrical characteristics
R
= R
+ R
θCA
Eqn. 2
θJA
θJC
where:
R
R
R
= junction to ambient thermal resistance (°C/W)
= junction to case thermal resistance (°C/W)
= case to ambient thermal resistance (°C/W)
θJA
θJC
θCA
R
is device related and cannot be influenced by the user. The user controls the thermal environment to change the case to
θJC
ambient thermal resistance, R
. For instance, the user can change the size of the heat sink, the air flow around the device, the
θCA
interface material, the mounting arrangement on printed circuit board, or change the thermal dissipation on the printed circuit
board surrounding the device.
To determine the junction temperature of the device in the application when heat sinks are not used, the Thermal
Characterization Parameter (Ψ ) can be used to determine the junction temperature with a measurement of the temperature at
JT
the top center of the package case using Equation 3:
T = T + (Ψ × P )
Eqn. 3
J
T
JT
D
where:
T
= thermocouple temperature on top of the package (°C)
= thermal characterization parameter (°C/W)
= power dissipation in the package (W)
T
Ψ
JT
P
D
The thermal characterization parameter is measured per JESD51-2 specification using a 40 gauge type T thermocouple epoxied
to the top center of the package case. The thermocouple should be positioned so that the thermocouple junction rests on the
package. A small amount of epoxy is placed over the thermocouple junction and over about 1 mm of wire extending from the
junction. The thermocouple wire is placed flat against the package case to avoid measurement errors caused by cooling effects
of the thermocouple wire.
See [6] to [10] in Section 6, Reference documents, for more information.
3.5
Electromagnetic interference (EMI) characteristics
Test Setup
3.5.1
Electromagnetic emission tests are performed by TEM cell [2] and via direct coupling [3] (150 Ω) measurements.
Electromagnetic immunity is measured by DPI [4].
See Section 6, Reference documents, for more information.
3.5.2
Test parameters
The following test parameters shall be used:
Table 14. EMC test parameters
Receiver
Method
Frequency Range
BW
Step Size
150 Ω
1 MHz to 1000 MHz
1 MHz
500 kHz
TEM
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
73
Electrical characteristics
In case of only narrow band disturbances the maximum of the results will not change. In case of broadband signals the emission
has to be below the limits.
3.6
Electrostatic discharge (ESD) characteristics
Electrostatic discharges (a positive then a negative pulse separated by 1 second) are applied to the pins of each sample according
to each pin combination. The sample size depends on the number of supply pins in the device (3 parts × (n + 1) supply pin).
This test conforms to the AEC-Q100-002/-003/-011 standard.
1, 2
Table 15. ESD ratings
No.
Symbol
Parameter
Conditions
Class Max value3
Unit
1
VESD(HBM)
SR Electrostatic discharge TA = 25 °C
H1C
2000
V
(Human Body Model)
conforming to AEC-Q100-002
2
3
VESD(MM)
SR Electrostatic discharge TA = 25 °C
M2
200
V
V
(Machine Model)
conforming to AEC-Q100-003
VESD(CDM)
SR Electrostatic discharge TA = 25 °C
C3A 750 (corners)
500
(Charged Device Model) conforming to AEC-Q100-011
1
2
All ESD testing is in conformity with CDF-AEC-Q100 Stress Test Qualification for Automotive Grade Integrated
Circuits.
A device will be defined as a failure if after exposure to ESD pulses the device no longer meets the device
specification requirements. Complete DC parametric and functional testing shall be performed per applicable
device specification at room temperature followed by hot temperature, unless specified otherwise in the device
specification.
3
Data based on characterization results, not tested in production.
3.7
Static latch-up (LU)
Two complementary static tests are required on six parts to assess the latch-up performance:
•
•
A supply over voltage is applied to each power supply pin.
A current injection is applied to each input, output and configurable I/O pin.
These tests are compliant with the EIA/JESD 78 IC latch-up standard.
Table 16. Latch-up results
No.
Symbol
LU
Parameter
CC Static latch-up class
Conditions
Class
1
TA = 125 °C conforming to JESD 78
II level A
3.8
Power Management Controller (PMC) electrical characteristics
PMC electrical specifications
3.8.1
This section contains electrical characteristics for the PMC.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
74
NXP Semiconductors
Electrical characteristics
Table 17. PMC electrical specifications
No.
Symbol
Parameter
Min
Typ
Max
Unit
1
VDD_LV_COR CC Nominal VRC regulated 1.2 V output
VDD_LV_COR
—
1.24
—
V
Vrc after reset 1.2V output with DC load
1.178
1.240
1.302
2
3
PorC
LvdC
CC POR rising VDD 1.2 V
• POR VDD variation
—
PorC – 30%
—
0.7
PorC
75
—
PorC + 30%
—
V
V
mV
• POR 1.2 V hysteresis
CC Nominal LVD 1.2 V
—
1.125
1.17
1.110
1.155
1.16
1.16
1.215
1.145
1.2
—
V
V
V
V
V
• LVD rising supply 1.2V after reset
• LVD rising supply 1.2V at reset
• LVD falling supply 1.2V after reset
• LVD falling supply 1.2V at reset
1.195
1.26
1.18
1.245
4
HvdC
CC Nominal HVD 1.2 V
—
1.36
1.36
1.44
1.33
1.41
—
1.4
1.5
1.37
1.47
• HVD rising supply 1.2V after reset
• HVD rising supply 1.2V at reset
• HVD falling supply 1.2V after reset
• HVD falling supply 1.2V at reset
1.32
1.38
1.29
1.35
V
V
V
V
5
6
PorReg
LvdReg
CC POR rising on VDDREG
• POR VDDREG variation
• POR VDDREG hysteresis
—
2.00
—
V
V
mV
PorReg – 30% PorReg PorReg + 30%
—
250
—
CC Nominal rising LVD 3.3 V on VDDREG
VDDIO, VDDFLASH, and VDDADC
• LVD 3.3 V rising supply after reset
• LVD 3.3 V rising supply at reset
• LVD 3.3 V falling supply after reset
• LVD 3.3 V falling supply at reset
• Minimum slew rate
,
—
2.78
2.765
2.75
2.735
—
2.865
2.865
2.865
2.835
2.835
50
—
2.95
2.965
2.92
2.935
—
V
V
V
V
V
mV/ms
mV/µs
• Maximum slew rate
—
25
—
7
8
LvdStepReg CC Trimming step LVD 3.3 V
Vadctol
CC Voltage tolerance of PMC channels1
—
30
—
—
mV
mV
-20
+20
1
This tolerance can only be achieved when adhering to the PMC internal channel sample time requirements listed
in the ADC specifications section.
3.8.2
PMC board schematic and components
Figure 7 shows a sample application for the PMC.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
75
Electrical characteristics
VDD_HV_PMU
VSS_HV_PMU
Ca
Cb
Cd
R
Q
VREG_CTRL
VDD_LV_COR
L
Cl
Ce
D
VSS_LV_COR
Figure 7. PMU mandatory external components
Table 18. VRC SMPS recommended external devices
Reference
designator
Part description
Part type
Nominal
Description
Ca
Cb
Cd
—
—
—
capacitor 20 µF, 20 V Filter capacitor
capacitor 0.1 µF, 20 V Filter capacitor
capacitor 20 µF, 20 V Supply decoupling cap, ESR < 50 mΩ,
as close to PMOS source as possible
Ce
Cl
—
—
capacitor 0.1 µF, 16 V Ceramic
capacitor 20 µF, 16 V Buck capacitor, total ESR < 100 mΩ,
as close to the coil as possible
D
L
SS8P3L
—
Schottky
—
Vishay low Vf Schottky diode
inductor 4 µH, 1.5 A Buck shielded coil low ESR
Q
FDC642P or
SQ2301ES or
SI3443DV
pMOS 2 A, 10 V
Low threshold PMOS Vth < 1.5 V,
Rdson@4.5 V < 120 mΩ, Qg < 16 nC
R
—
resistor 50–100 kΩ Pullup for power PMOS gate
3.9
Supply current characteristics
1
Table 19. Current consumption characteristics
No.
Symbol
Parameter
Conditions
DD_LV = 1.36 V, fCore = 180 MHz, 1:2
Min Typ Max Unit
1
IDD_LV
CC Maximum run IDD
V
—
600 900 mA
(incl. digital core logic mode, DPM, both cores executing EMC test
and analog block of code, internal VREG mode, all caches
the LV rail)
enabled, code execution of core 0 from
code flash 0, code execution of core 1 from
code flash 1, FMPLL_1 active at 120 MHz.
2
IDD_LV_PLL CC Maximum run IDD for VDD_LV_PLL = 1.36 V, fVCO running at
each PLL2
maximum frequency.
—
1.5
2
mA
MPC5675K Microcontroller Data Sheet, Rev. 8.1
76
NXP Semiconductors
Electrical characteristics
Min Typ Max Unit
1
Table 19. Current consumption characteristics (continued)
No.
Symbol
Parameter
Conditions
3
3
IDD_HV_FLA
CC Maximum run IDD
VDD_HV_FLA = 3.6 V, DPM, both cores
executing EMC test code, code execution of
core 0 from code flash 0, code execution of
core 1 from code flash 1.
—
20
30 mA
Flash
4
5
6
IDD_HV_OSC CC Maximum run IDD
fOSC 4 MHz to 40 MHz,
VDD_HV_OSC 3.6 V
—
—
1
2
3
4
2
mA
mA
mA
OSC
IDD_HV_ADV CC Maximum run IDD for VDD_HV_ADV = 3.6 V
each ADC4
IDD_HV_ADR02 CC Maximum reference ADC0 powered on7
—
—
—
—
—
—
—
—
—
—
5
6
IDD
ADC2 powered on
1.2 mA
1.2 mA
1.2 mA
5
7
IDD_HV_ADR13 CC Maximum reference ADC1 powered on
6
IDD
ADC3 powered on
8
8
9
IDD_HV_ADR0 CC Maximum reference ADC0 powered on7
2
mA
IDD
8
IDD_HV_ADR1 CC Maximum reference ADC1 powered on
—
—
1.2 mA
IDD
8
10 IDD_HV_ADR23 CC Maximum reference ADC2 powered on
—
—
—
—
1.2 mA
1.2 mA
6
IDD
ADC3 powered on
1
2
3
4
5
6
7
8
Applies to TJ = –40 °C to 150 °C.
Total current on IDD_LV_PLL needs to be multiplied with the number of active PLLs.
The current specified for Idd_HV_FLA includes current consumed during programming and erase operations.
Total current on IDD_HV_ADV needs to be multiplied with the number of active ADCs.
257 MAPBGA only.
Total current on IDD_HV_ADRxx is the sum of both references if both ADCs are powered on.
ADC0 includes 0.7 mA dissipation for the temperature sensor (TSENS).
473 MAPBGA only.
3.10 Temperature sensor electrical characteristics
Table 20. Temperature sensor electrical characteristics
Symbol
Parameter
Conditions
Min
Max
Unit
1
2
—
P Accuracy
D Minimum sampling period
TJ = –40 °C to TA = 125 °C
—
–10
4
10
—
°C
µs
TS
3.11 Main oscillator electrical characteristics
The MPC5675K provides an oscillator/resonator driver.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
77
Electrical characteristics
×
Table 21. Main oscillator electrical characteristics
Value
Typ
No.
Symbol
Parameter
Conditions1
Unit
Min
Max
1
FXOSCHS SR Oscillator frequency
—
4.0
—
6
40.0
MHz
ms
2a TXOSCHSSU CC Oscillator start-up time fOSC < 16 MHz
—
—
10
4
2b
3
fOSC = 16 MHz to 40 MHz
2
VIH
VIL
SR Input high level CMOS Oscillator bypass mode
Schmitt Trigger
0.65 × VDD
—
VDD + 0.4
V
V
4
SR Input low level CMOS Oscillator bypass mode
Schmitt Trigger
–0.4
—
0.35 × VDD
1
VDD = 3.0 V to 3.6 V, TJ = –40 to 150 °C, unless otherwise specified.
3.12 FMPLL electrical characteristics
Table 22. FMPLL electrical characteristics
No.
Symbol
Parameter
Conditions
Crystal reference
Min
Typ
Max
Unit
1
fREF_CRYSTAL D FMPLL reference frequency
4
—
—
—
120
MHz
MHz
MHz
fREF_EXT
range1, 2
2
3
fPLL_IN D Phase detector input frequency
range (after pre-divider)
—
4
16
fFMPLLOUT D Clock frequency range in
normal mode
See the FMPLL chapter in the
chip reference manual for more
details on PLL configuration.
16
256
4
fFREE
P Free running frequency
Measured using clock division
19
—
60
MHz
(typically ÷16)
5
6
fsys
D On-chip FMPLL frequency2
D System clock period
—
—
—
—
—
—
—
—
—
180
1 / fsys
3.7
MHz
ns
tCYC
—
Lower limit
Upper limit
—
7a
7b
8
fLORL
fLORH
D Loss of reference frequency
window3
1.6
24
20
—
MHz
56
fSCM
D Self-clocked mode frequency4,5
P Lock time
150
MHz
µs
9
tLOCK
Stable oscillator (fPLLIN = 4 MHz),
stable VDD
200
10
11
tlpll
tdc
D FMPLL lock time 6, 7
—
—
—
20
—
—
—
—
200
80
μs
%
D Duty cycle of reference
12a CJITTER T CLKOUT period jitter8,9,10,11
Peak-to-peak (clock edge to
clock edge), fFMPLLOUT
maximum12
160
ps
12b
Long-term jitter (avg. over 2 ms
interval), fFMPLLOUT maximum
—
—
—
—
6
ns
ps
13 ΔtPKJIT T Single period jitter (peak to
PHI @ 16 MHz,
Input clock @ 4 MHz
500
peak)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
78
NXP Semiconductors
Electrical characteristics
Table 22. FMPLL electrical characteristics (continued)
No.
Symbol
Parameter
Conditions
PHI @ 16 MHz,
Min
Typ
Max
Unit
14 ΔtLTJIT T Long term jitter
—
—
6
ns
Input clock @ 4 MHz
15
16
fLCK
fUL
D Frequency LOCK range
D Frequency un-LOCK range
D Modulation Depth
—
–4
—
—
+4
%
fFMPLLOUT
—
–16
+16
%
fFMPLLOUT
17a
17b
18
fCS
fDS
Center spread
Down Spread
0.25
–0.5
—
—
—
—
4
%
fFMPLLOUT
–8
fMOD
D Modulation frequency13
31 < LDF14 < 63
LDF > 63
(2240/LD
kHz
F)
35
1
2
Considering operation with FMPLL not bypassed.
PFD clock range is 4– 16 MHz. An appropriate PLL Input division factor (IDF) should be chosen to divide the reference
frequency to this range.
3
4
“Loss of Reference Frequency” window is the reference frequency range outside of which the FMPLL is in self clocked mode.
Self clocked mode frequency is the frequency that the FMPLL operates at when the reference frequency falls outside the fLOR
window.
5
fVCO is the frequency at the output of the VCO; its range is 256–512 MHz.
fSCM is the self-clocked mode frequency (free running frequency); its range is 20–150 MHz.
fsys = fVCO÷ODF
This value is determined by the crystal manufacturer and board design. For 4 MHz to 20 MHz crystals specified for this
FMPLL, load capacitors should not exceed these limits.
6
7
This specification applies to the period required for the FMPLL to relock after changing the MFD frequency control bits in the
synthesizer control register (SYNCR).
8
9
This value is determined by the crystal manufacturer and board design.
Jitter is the average deviation from the programmed frequency measured over the specified interval at maximum fFMPLLOUT
.
Measurements are made with the device powered by filtered supplies and clocked by a stable external clock signal. Noise
injected into the FMPLL circuitry via VDDPLL and VSSPLL and variation in crystal oscillator frequency increase the CJITTER
percentage for a given interval.
10 Proper PC board layout procedures must be followed to achieve specifications.
11 Values are with frequency modulation disabled. If frequency modulation is enabled, jitter is the sum of CJITTER and either fCS
or fDS (depending on whether center spread or down spread modulation is enabled).
12 Core operating at 180 MHz.
13 Modulation depth is attenuated from depth setting when operating at modulation frequencies above 50 kHz.
14 PLL Loop Division Factor (LDF).
3.13 16 MHz RC oscillator electrical characteristics
Table 23. RC oscillator electrical characteristics
No.
Symbol
Parameter
Conditions
Min Typ Max Unit
1
2
fRC
CC RC oscillator frequency
25 °C, 1.2 V trimmed
—
—
—
16
—
—
5
MHz
%
ΔRCMVAR CC Frequency spread: The variation in
output frequency from PTF1 across
temperature and supply voltage range
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
79
Electrical characteristics
Table 23. RC oscillator electrical characteristics (continued)
No.
Symbol
Parameter
Conditions
Min Typ Max Unit
1.6
3
ΔIRCTRIM CC Internal RC oscillator trimming step
TA = 25 °C
—
—
%
1
PTF = Post Trimming Frequency: The frequency of the output clock after trimming at typical supply voltage and
temperature.
3.14 ADC electrical characteristics
The MPC5675K provides a 12-bit Successive Approximation Register (SAR) Analog-to-Digital Converter.
Offset Error OSE Gain Error GE
4095
4094
4093
4092
4091
4090
(2)
1 LSB ideal =(VrefH-VrefL)/ 4096 =
3.3 V/ 4096 = 0.806 mV
Total Unadjusted Error
TUE = ±6 LSB = ±4.84 mV
code out
7
(1)
6
5
(1) Example of an actual transfer curve
(2) The ideal transfer curve
(3) Differential non-linearity error (DNL)
(4) Integral non-linearity error (INL)
(5) Center of a step of the actual transfer
curve
(5)
4
3
(4)
(3)
2
1
1 LSB (ideal)
0
1
2
3
4
5
6
7
4089 40904091 40924093 40944095
Vin(A) (LSBideal
)
Offset Error OSE
Figure 8. ADC characteristics and error definitions
3.14.1 Input impedance and ADC accuracy
To preserve the accuracy of the A/D converter, it is necessary that analog input pins have low AC impedance. Placing a capacitor
with good high frequency characteristics at the input pin of the device can be effective: the capacitor should be as large as
possible, ideally infinite. This capacitor contributes to attenuating the noise present on the input pin; further, it sources charge
during the sampling phase, when the analog signal source is a high-impedance source.
A real filter can typically be obtained by using a series resistance with a capacitor on the input pin (simple RC filter). The RC
filtering may be limited according to the value of source impedance of the transducer or circuit supplying the analog signal to
be measured. The filter at the input pins must be designed taking into account the dynamic characteristics of the input signal
(bandwidth) and the equivalent input impedance of the ADC itself.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
80
NXP Semiconductors
Electrical characteristics
In fact a current sink contributor is represented by the charge sharing effects with the sampling capacitance: C and C being
S
P2
substantially a switched capacitance, with a frequency equal to the conversion rate of the ADC, it can be seen as a resistive path
to ground. For instance, assuming a conversion rate of 1 MHz, with C equal to 3 pF, a resistance of 330 kΩ is obtained
S
(R = 1 / (f × C ), where f represents the conversion rate at the considered channel). To minimize the error induced by the
EQ
C
S
C
voltage partitioning between this resistance (sampled voltage on C ) and the sum of R + R , the external circuit must be
S
S
F
designed to respect Equation 4:
R + R
S
F
1
2
--------------------
V •
< -- LSB
Eqn. 4
A
R
EQ
Equation 4 generates a constraint for external network design, in particular on resistive path. Internal switch resistances (R
SW
and R ) can be neglected with respect to external resistances.
AD
EXTERNAL CIRCUIT
INTERNAL CIRCUIT SCHEME
V
DD
Channel
Sampling
Selection
Source
Filter
Current Limiter
R
R
R
R
R
AD
S
F
L
SW1
C
V
C
C
P1
C
S
A
F
P2
R
Source Impedance
Filter Resistance
Filter Capacitance
Current Limiter Resistance
Channel Selection Switch Impedance
Sampling Switch Impedance
S
F
F
L
R
C
R
R
R
C
C
SW1
AD
P
Pin Capacitance (two contributions, C and C
Sampling Capacitance
)
P1
P2
S
Figure 9. Input equivalent circuit
A second aspect involving the capacitance network shall be considered. Assuming the three capacitances C , C , and C are
F
P1
P2
initially charged at the source voltage V (please see the equivalent circuit in Figure 9): A charge sharing phenomenon is
A
installed when the sampling phase is started (A/D switch is closed).
Voltage Transient on CS
V
CS
V
A
ΔV < 0.5 LSB
V
A2
1
2
τ1 < (RSW + RAD) CS << TS
V
A1
τ2 = RL (CS + CP1 + CP2)
T
t
S
Figure 10. Transient behavior during sampling phase
In particular two different transient periods can be distinguished:
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
81
Electrical characteristics
• A first and quick charge transfer from the internal capacitance C and C to the sampling capacitance C occurs (C
S
P1
P2
S
is supposed initially completely discharged): considering a worst case (since the time constant in reality would be
faster) in which C is reported in parallel to C (call C = C + C ), the two capacitances C and C are in series,
P2
P1
P
P1
P2
P
S
and the time constant is:
C • C
P
S
--------------------
τ
= (R
+ R
) •
Eqn. 5
1
SW
AD
C + C
P
S
Equation 5 can again be simplified considering only C as an additional worst condition. In reality, the transient is
S
faster, but the A/D converter circuitry has been designed to be robust also in the very worst case: the sampling time T
is always much longer than the internal time constant:
S
τ
< (R
+ R
) • C « T
S
Eqn. 6
1
SW
AD
S
The charge of C and C is redistributed also on C , determining a new value of the voltage V on the capacitance
P1
P2
S
A1
according to Equation 7:
V
• (C + C + C ) = V • (C + C )
P2
Eqn. 7
A1
S
P1
P2
A
P1
•
A second charge transfer involves also C (that is typically bigger than the on-chip capacitance) through the resistance
F
R : again considering the worst case in which C and C were in parallel to C (since the time constant in reality
L
P2
S
P1
would be faster), the time constant is:
τ
< R • (C + C + C )
P1 P2
Eqn. 8
2
L
S
In this case, the time constant depends on the external circuit: in particular imposing that the transient is completed
well before the end of sampling time T , a constraints on R sizing is obtained:
S
L
10 • τ = 10 • R • (C + C + C ) < T
P1 P2 S
Eqn. 9
2
L
S
Of course, R shall be sized also according to the current limitation constraints, in combination with R (source
L
S
impedance) and R (filter resistance). Being C definitively bigger than C , C and C , then the final voltage V
F
F
P1 P2
S
A2
(at the end of the charge transfer transient) will be much higher than V . Equation 10 must be respected (charge
A1
balance assuming now C already charged at V ):
S
A1
V
• (C + C + C + C ) = V • C + V • (C + C + C )
P1 P2 A1 P1 P2
Eqn. 10
A2
S
F
A
F
S
The two transients above are not influenced by the voltage source that, due to the presence of the R C filter, is not able to
F
F
provide the extra charge to compensate the voltage drop on C with respect to the ideal source V ; the time constant R C of
S
A
F F
the filter is very high with respect to the sampling time (T ). The filter is typically designed to act as anti-aliasing.
S
MPC5675K Microcontroller Data Sheet, Rev. 8.1
82
NXP Semiconductors
Electrical characteristics
Analog Source Bandwidth (V )
A
T
f
≤ 2 R C (Conversion Rate vs. Filter Pole)
F F
C
Noise
= f (Anti-aliasing Filtering Condition)
F
0
2 f ≤ f (Nyquist)
0
C
f
0
f
Anti-Aliasing Filter (f = RC Filter pole)
Sampled Signal Spectrum (f = conversion Rate)
C
F
f
f
f
C
F
0
f
f
Figure 11. Spectral representation of input signal
Calling f the bandwidth of the source signal (and as a consequence the cut-off frequency of the anti-aliasing filter, f ),
0
F
according to the Nyquist theorem the conversion rate f must be at least 2f ; it means that the constant time of the filter is greater
C
0
than or at least equal to twice the conversion period (T ). Again the conversion period T is longer than the sampling time T ,
C
C
S
which is just a portion of it, even when fixed channel continuous conversion mode is selected (fastest conversion rate at a
specific channel): in conclusion it is evident that the time constant of the filter R C is definitively much higher than the
F
F
sampling time T , so the charge level on C cannot be modified by the analog signal source during the time in which the
S
S
sampling switch is closed.
The considerations above lead to impose new constraints on the external circuit, to reduce the accuracy error due to the voltage
drop on C ; from the two charge balance equations above, it is simple to derive Equation 11 between the ideal and real sampled
S
voltage on C :
S
Eqn. 11
V
C
+ C + C
P2
---------- = -------------------------------------------------------
A2
P1
F
V
C
+ C + C + C
A
P1
P2 S
F
From this formula, in the worst case (when V is maximum, that is for instance 5 V), assuming to accept a maximum error of
A
half a count, a constraint is evident on C value:
F
C
> 8192 • C
Eqn. 12
F
S
Table 24. ADC conversion characteristics
Parameter
Conditions1
No. Symbol
Min Typ Max Unit
1
fCK SR ADC clock frequency (depends on ADC
configuration)
—
3
—
60 MHz
(The duty cycle depends on AD_CK2 frequency)
2
3
4
fs
SR Sampling frequency
—
—
—
—
—
—
959 kHz
tADC_S D Sample time3
60 MHz
60 MHz
383
717
—
—
ns
ns
tADC_S C Sample time of internal PMC channels.
_PMC
5
tADC_E P Evaluation time4
600
—
—
ns
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
83
Electrical characteristics
Table 24. ADC conversion characteristics (continued)
No. Symbol
Parameter
Conditions1
Min Typ Max Unit
5
6
7
CS
D ADC input sampling capacitance
D ADC input pin capacitance 1
D ADC input pin capacitance 2
—
—
—
—
—
—
—
—
—
—
—
—
—
—
7.32 pF
2.5 pF
0.8 pF
1.0 kΩ
1.2 kΩ
5
5
CP1
CP2
—
8
—
5
9
RSW1 D Channel selection switch resistance
VREF range = 4.5 to 5.5 V
10
V
REF range = 3.0 to 3.6 V
5
11 RAD
12
D Sample switching resistance
T Current injection
—
825
3
Ω
IINJ
Currentinjectionon oneADC –3
input channel, different from
the converted one. Other
parameters stay within
mA
specified limits as long as the
ADC supply stays within its
specified limits due to the
current injection.
13
INL
P Integral non linearity
—
—
—
—
—
—
—
—
—
—
–3
–1.0
–4
—
—
—
—
—
—
—
—
—
—
3
2
LSB
LSB
LSB
LSB
LSB
LSB
dB
14 DNL P Differential non linearity6
15 OFS T Offset error
4
16 GNE T Gain error
–4
4
17 TUE7 P Total unadjusted error
18 TUE7 T Total unadjusted error with current injection
19 SNR T Signal-to-noise ratio
20 THD T Total harmonic distortion
21 SINAD T Signal-to-noise and distortion
22 ENOB T Effective number of bits
–6
6
–6
6
69
—
—
—
—
–72
65
dB
dB
10.5
bits
1
2
3
VDD = 3.3 V, TJ = –40 to +150 °C, unless otherwise specified and analog input voltage from VAGND to VAREF
.
AD_CK clock is always half of the ADC module input clock defined via the auxiliary clock divider for the ADC.
During the sample time the input capacitance CS can be charged/discharged by the external source. The internal
resistance of the analog source must allow the capacitance to reach its final voltage level within tADC_S. After the end of
the sample time tADC_S, changes of the analog input voltage have no effect on the conversion result. Values for the
sample clock tADC_S depend on programming.
4
This parameter does not include the sample time tADC_S, but only the time for determining the digital result and the time
to load the result register with the conversion result.
5
6
7
See Figure 9.
No missing codes.
When operating the MPC5675K in a switched mode power supply configuration, the specifications for the ADCs under
worst case conditions can be upheld only through the use of averaging back-to-back samples. In the 257 package, 10
samples must be averaged when using ADC 0, 2, or 3. In the 473 package, 5 samples must be averaged. For ADC 1,
due to its close proximity to the PMC, the TUE spec must be increased to +/-10 counts, 10 samples of averaging must
be used in both packages, and the VDD_HV_PMU supply must be below 3.6 V. Better performance can be obtained
with lower VDD_HV_PMU supplies and higher VDD_HV_ADRx supplies. The ADC1 self test limit for the S2 algorithm
needs to be modified by the user to accommodate for the increased TUE limit of +/-10 counts when operating the device
in internal regulation mode. This can be accomplished by reading the current value from the test flash and subtracting
4 counts before storing the value to the ADC1 Self Test Analog Watchdog Register 2 (STAW2R).
MPC5675K Microcontroller Data Sheet, Rev. 8.1
84
NXP Semiconductors
Electrical characteristics
3.15 Flash memory electrical characteristics
3.15.1 Program/erase characteristics
Table 25 shows the code flash memory program and erase characteristics.
Table 25. Code flash memory program and erase electrical specifications
Initial Lifetime
No.
Symbol
Parameter
Min Typ1
Unit
max2
max3
1
2
3
4
5
TDWPROGRAM CC Doubleword (64 bits) program time4
—
—
—
—
—
18
50
500
µs
ms
ms
ms
ms
T16KPPERASE
T32KPPERASE
T64KPPERASE
CC 16 KB block pre-program and erase time
CC 32 KB block pre-program and erase time
CC 64 KB block pre-program and erase time
200
300
400
500
600
900
5000
5000
5000
7500
T128KPPERASE CC 128 KB block pre-program and erase time
600 1300
1
2
Typical program and erase times assume nominal supply values and operation at 25 °C.
Initial Max program and erase times provide guidance for time-out limits used in the factory and apply for < 100
program/erase cycles, nominal supply values and operation at TJ = 25 °C. These values are verified at production
test.
3
4
Lifetime Max program and erase times apply across the voltage, temperature, and cycling range of product life.
These values are characterized, but not tested.
Actual hardware programming times. This does not include software overhead.
Table 26 shows the data flash memory program and erase characteristics.
Table 26. Data flash memory program and erase electrical specifications
Initial Lifetime
No.
Symbol
Parameter
Min Typ1
Unit
max2
max3
1
2
TDWPROGRAM CC Singleword (32 bits) program time4
T16KPPERASE CC 16 KB block pre-program and erase time
—
—
30
70
300
µs
700
800
1500
ms
1
2
Typical program and erase times assume nominal supply values and operation at 25 °C.
Initial Max program and erase times provide guidance for time-out limits used in the factory and apply for < 100
program/erase cycles, nominal supply values and operation at TJ = 25 °C. These values are verified at production
test.
3
4
Lifetime Max program and erase times apply across the voltage, temperature, and cycling range of product life.
These values are characterized, but not tested.
Actual hardware programming times. This does not include software overhead.
Table 27. Flash memory module life
Value
No.
Symbol
Parameter
Condition
Unit
Min
Typ1
Max
1a
1b
1c
P/E
CC Number of program/erase
cycles per block for over the
operating temperature range
(TJ)
16 KB blocks
100,000
—
—
—
—
cycles
cycles
cycles
32 KB and 64 KB blocks
128 KB blocks
10,000 100,000
1,000 100,000
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
85
Electrical characteristics
Table 27. Flash memory module life (continued)
Value
No.
Symbol
Parameter
Condition
Unit
Min
Typ1
Max
2
Retention CC Minimum data retention at
85 °C average ambient
Blocks with 0–1,000
P/E cycles
20
—
—
years
years
years
temperature2
Blocks with 1,001–10,000
P/E cycles
10
5
—
—
—
—
Blocks with 10,001–100,000
P/E cycles
1
2
Typical endurance is evaluated at 25 oC. Product qualification is performed to the minimum specification. For
additional information on the NXP definition of Typical Endurance, please refer to Engineering Bulletin EB619,
Typical Endurance for Nonvolatile Memory.
Ambient temperature averaged over duration of application, not to exceed product operating temperature range.
3.15.2 Read access timing
Table 28. Code flash read access timing
Value
Max
No.
Symbol
Parameter
Condition
Unit
1
2
fREAD
CC Maximum frequency for Flash reading
(system clock frequency SYS_CLK)
4 wait states
3 wait states
90
60
MHz
MHz
Table 29. Data flash read access timing
Value
Max
No.
Symbol
Parameter
Condition
Unit
1
2
fREAD
CC Maximum frequency for Flash reading
(system clock frequency SYS_CLK)
12 wait states
8 wait states
90
60
MHz
MHz
3.15.3 Write access timing
Table 30. Code flash write access timing
Value
No.
Symbol
Parameter
Condition
Unit
Max
1
fWRITE
CC Maximum frequency for Flash writing
(system clock frequency SYS_CLK)
—
90
MHz
MPC5675K Microcontroller Data Sheet, Rev. 8.1
86
NXP Semiconductors
Electrical characteristics
Table 31. Data flash write access timing
Value
Unit
No.
Symbol
Parameter
Condition
Max
1
fWRITE
CC Maximum frequency for Flash writing
(system clock frequency SYS_CLK)
—
90
MHz
3.16 SRAM memory electrical characteristics
Table 32. System SRAM memory read/write access timing
Value
No.
Symbol
Parameter
Condition
Unit
Max
1
sREAD/WRITE CC Maximum frequency for system SRAM
reading/writing (system clock frequency
SYS_CLK)
1 wait state
90
MHz
3.17 GP pads specifications
This section specifies the electrical characteristics of the GP pads. Please refer to the tables in Section 2.2, Pin descriptions, for
a cross reference between package pins and pad types.
3.17.1 GP pads DC specifications
Table 33 gives the DC electrical characteristics at 3.3 V (3.0 V < V
< 3.6 V).
DD_HV_IO
1
Table 33. GP pads DC electrical characteristics
No.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
1
2
3
4
5
6
VIL
VIH
SR Low level input voltage
SR High level input voltage
CC Schmitt trigger hysteresis
—
–0.12
0.65 VDD_HV_IO
0.1 VDD_HV_IO
—
—
—
—
—
—
—
0.35 VDD_HV_IO
V
V
V
V
V
V
—
—
VDD_HV_IO + 0.12
VHYS
—
0.5
—
VOL_S CC Slow, low level output voltage
IOL = 1.5 mA
VOH_S CC Slow, high level output voltage IOH = –1.5 mA VDD_HV_IO – 0.8
VOL_M CC Medium, low level output
voltage
IOL = 2 mA
IOH = –2 mA VDD_HV_IO – 0.8
IOL = 11 mA
—
0.5
7
VOH_M CC Medium, high level output
voltage
—
—
V
8
9
VOL_F CC Fast, high level output voltage
—
—
—
—
0.5
—
V
V
V
VOH_F CC Fast, high level output voltage IOH = –11 mA VDD_HV_IO – 0.8
10 VOL_SYM CC Symmetric, high level output
voltage
IOL = 5 mA
—
0.5
11 VOH_SYM CC Symmetric, high level output
voltage
IOH = –5 mA VDD_HV_IO – 0.8
—
—
V
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
87
Electrical characteristics
1
Table 33. GP pads DC electrical characteristics (continued)
No.
Symbol
Parameter
Conditions
Min
Typ
Max
Unit
12
IPU
IPD
IIL
CC Equivalent pullup current
VIN = VIL
VIN = VIH
VIN = VIL
VIN = VIH
–130
—
—
—
—
—
—
—
–10
—
µA
13
14
CC Equivalent pulldown current
10
µA
—
130
1
P
P
P
Input leakage current
(all bidirectional ports)
TA = –40 to
150 °C
-1
µA
µA
µA
Input leakage current
TA = –40 to
150 °C
-0.25
-0.3
—
—
0.25
0.3
(All single ADC channels)3
Input leakage current
TA = –40 to
150 °C
(All shared ADC channels)
16
17
VILR
VIHR
SR RESET, low level input voltage
SR RESET, high level input voltage
—
—
—
–0.42
—
—
—
0.35 VDD_HV_IO
VDD_HV_IO+0.42
—
V
V
V
0.65 VDD_HV_IO
0.1 VDD_HV_IO
18 VHYSR CC RESET, Schmitt trigger
hysteresis
19
20
VOLR
IPD
CC RESET, low level output voltage IOL = 2 mA
—
10
—
—
—
—
—
0.5
—
V
CC RESET, equivalent pulldown
current
VIN = VIL
µA
VIN = VIH
—
130
3
21
CIN
D
Input pad capacitance
—
—
pF
V
22 VILRSB SR Reset Sup B, Low level input
voltage
—
-0.12
0.30
VDD_HV_IO
23 VIHRSB SR Reset Sup B, High level input
voltage
—
0.65 VDD_HV_IO
—
VDD_HV_IO + 0.12
V
1
2
The values provided in this table are not applicable for PDI and EBI/DRAM interface.
“SR” parameter values must not exceed the absolute maximum ratings shown in Table 11.
3
Specified values are applicable to all modes of the pad, i.e., IBE = 0/1 and/or APC = 0/1.
3.17.2 GP pads AC specifications
1
Table 34. GP pads AC electrical characteristics
Tswitchon1
(ns)
Rise/Fall2
(ns)
Frequency
(MHz)
Current slew3
(mA/ns)
Load drive
(pF)
No.
Pad
Min Typ Max Min Typ Max Min Typ Max Min Typ Max
1
Slow
3
3
3
3
—
—
—
—
40
40
40
40
4
6
—
—
—
—
40
50
—
—
—
—
—
—
—
—
4
2
2
2
0.01
0.01
0.01
0.01
—
—
—
—
2
2
2
2
25
50
10
14
75
100
200
100
MPC5675K Microcontroller Data Sheet, Rev. 8.1
88
NXP Semiconductors
Electrical characteristics
1
Table 34. GP pads AC electrical characteristics (continued)
Tswitchon1
(ns)
Rise/Fall2
(ns)
Frequency
(MHz)
Current slew3
(mA/ns)
Load drive
(pF)
No.
Pad
Min Typ Max Min Typ Max Min Typ Max Min Typ Max
2
Medium
1
1
—
—
—
—
—
—
—
—
—
—
15
15
15
15
6
2
4
—
—
—
—
—
—
—
—
—
—
12
25
40
70
4
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
40
20
13
7
2.5
2.5
2.5
2.5
3
—
—
—
—
—
—
—
—
—
—
7
7
25
50
1
8
7
100
200
25
1
14
1
7
3
Fast
1
72
55
40
25
50
—
40
40
40
40
25
—
1
6
1.5
3
7
7
50
1
6
12
18
5
7
100
200
25
1
6
5
7
4
5
Symmetric
1
8
1
3
Pullup/down
(3.6 V max)
—
—
—
7500
—
50
1
2
3
The values provided in this table are not applicable for PDI and EBI/DRAM interface.
Slope at rising/falling edge.
Data based on characterization results, not tested in production.
3.17.3 I/O pad current specifications
The power consumption of an I/O segment is dependent on the usage of the pins on a particular segment. The power
consumption is the sum of all output pin currents for a particular segment. The output pin current can be calculated based on
the voltage, frequency, and load on the pin.
Table 35. I/O pad current specifications
Load
(pF)
Frequency
(MHz)
VDD_HV_IO
(V)
Current
(mA)
Pad Type
GP Slow/Medium
GP Slow/Symmetric
GP Slow/Fast
20
20
20
20
4
3.6
3.6
3.6
3.6
0.30
0.76
3.40
0.04
10
45
0.5
GP Slow
3.17.4 Power Sequence Pin States for GPIO Pads
Table 36. Power sequence pin states for GPIO pads
VDD_LV_COR
VDD_HV_IO
Pad Function
Low
Low
High
Low
High
Low
Outputs Disabled
Outputs Disabled
Outputs Disabled
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
89
Electrical characteristics
Table 36. Power sequence pin states for GPIO pads
VDD_LV_COR
VDD_HV_IO
Pad Function
High
High
Normal Operation
3.18 PDI pads specifications
This section specifies the electrical characteristics of the PDI pads. Please refer to the tables in Section 2.2, Pin descriptions, for
a cross reference between package pins and pad types.
PDI pads feature list:
•
Direction
— Input
— Output
— Bidirectional
•
Driver
— Push/Pull/Open Drain
— Configurable Four Drive Strengths on Fast driver pads
— Configurable No Slew-Rate, Slow Slew-Rate, and Fast Slew-Rate on Slow, Medium, and SLR driver pads
— VDD_HV_PDI NOTE: All pads are NOT 5 V TOLERANT. Pads are not capable of driving to or from voltages
above their respective VDD_HV_PDI. In other words, you cannot connect a 3.3V external device to a pad
supplied with 2.5 V. If a pad must be connected to a 3.3V device, its local VDD_HV_PDI must be 3.3 V. Injection
current is then handled by the intrinsic diodes from the pad transistors and by the ESD diodes.
— VDD_HV_PDI range 1.8 V to 3.3 V, as specified in the following tables
•
Receiver
— Selectable hysteresis input buffer
— CMOS Input Buffer
The electrical data provided in this section applies:
•
•
To the pads listed in Table 37
Over the voltage range 1.62–3.6 V
Table 37. PDI I/O pads
No.
Name
Voltage
Used for
Notes
1
PDI Fast
1.62–3.6 V
I/O
Enhanced operating voltage range fast slew-rate output with four selectable
slew-rates. Contains an input buffer and weak pullup/pulldown.
2
PDI
Medium
Enhanced operating voltage range medium slew-rate output with four
selectable slew-rates. Contains an input buffer and weak pullup/pulldown.
1
Table 38. PDI pads DC electrical characteristics
No.
Symbol
Parameter
Min
Max
Unit
1
2
VDD_HV_PDI SR I/O supply voltage
1.62
3.6
V
V
VIH_C
CC CMOS input buffer high voltage
(hysteresis enabled)
0.65 × VDD_HV_PDI VDD_HV_PDI + 0.3
3
VIH_C
CC CMOS input buffer high voltage
(hysteresis disabled)
0.58 × VDD_HV_PDI VDD_HV_PDI + 0.3
V
MPC5675K Microcontroller Data Sheet, Rev. 8.1
90
NXP Semiconductors
Electrical characteristics
1
Table 38. PDI pads DC electrical characteristics (continued)
No.
Symbol
Parameter
Min
Max
Unit
4
VIL_C
CC CMOS input buffer low voltage
(hysteresis enabled)
VSS – 0.3
0.35 × VDD_HV_PDI
V
5
VIL_C
CC CMOS input buffer low voltage
(hysteresis disabled)
VSS – 0.3
0.42 × VDD_HV_PDI
V
6
7
8
9
VHYS_C CC CMOS input buffer hysteresis
0.1 × VDD_HV_PDI
—
V
µA
V
IACT_S
VOH
CC Selectable weak pullup/pulldown current
CC Output high voltage
25
0.8 × VDD_HV_PDI
—
150
—
VOL
CC Output low voltage
0.2 × VDD_HV_PDI
V
1
Over- and undershoots occurring due to impedance mismatch of the external driver and the transmission line at
PDI pads in input mode can be allowed up to 0.7 V repeatedly throughout the product expected lifetime and will not
cause any long term reliability issue.
Table 39. Drive current
Pad
Drive Mode
Minimum IOH (mA)1
Minimum IOL (mA)2
PDI Fast
All
All
26.2
19.2
84.8
52.1
PDI Medium
1
2
IOH is defined as the current sourced by the pad to drive the output to VOH
.
IOL is defined as the current sunk by the pad to drive the output to VOL
.
Table 40. PDI pads AC electrical characteristics
Prop. Delay (ns)
Rise/Fall Edge
(ns)
Drive/Slew
Rate Select
L → H/H → L1
Drive Load
(pF)
No.
Name
Min
Max
Min
Max
MSB, LSB
1
PDI Medium
0.8/0.7
--------
1.1/1.08
5.5/4.5
12/8.3
49/22
1.02/1
3.5/2.3
9.1/6
—
50
200
50
11
10
01
00
60/31
14/9.2
18/12
200
50
102/44
119/53
722/302
772/325
24/16
200
50
126/85
136/90
200
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
91
Electrical characteristics
Table 40. PDI pads AC electrical characteristics (continued)
Prop. Delay (ns)
Rise/Fall Edge
(ns)
Drive/Slew
Rate Select
L → H/H → L1
Drive Load
(pF)
No.
Name
Min
Max
Min
Max
MSB, LSB
2
PDI Fast
0.8/0.7
--------
1.1/1.08
10/10
15/15
15/15
22/22
24/24
33/33
66/66
84/84
1.1/1.1
2.6/2.6
2.4/2.4
5/5
—
50
200
50
11
10
01
00
200
50
5/5
8/8
200
50
16/16
21/21
200
1
L → H signifies low-to-high propagation delay and H → L signifies high-to-low propagation delay.
3.18.1 PDI pad current specifications
The power consumption of an I/O segment is dependent on the usage of the pins on a particular segment. The power
consumption is the sum of all output pin currents for a particular segment. The output pin current can be calculated based on
the voltage, frequency, and load on the pin.
Table 41. PDI pad current specifications
Frequency
(MHz)
Load
(pF)
Voltage
(V)
Drive/Slew Rate
Select
Current
(mA)
Pad Type
PDI Medium
66
33
20
3
50
50
3.6
3.6
3.6
3.6
3.6
3.6
3.6
3.6
3.6
3.6
11
10
01
00
00
11
10
01
00
00
8.7
3.8
2.3
0.38
1.5
12
50
50
3
200
50
PDI Fast
66
50
33
20
20
50
6.2
4.0
2.4
8.9
50
50
200
3.18.2 Power Sequence Pin States for PDI Pads
Table 42. Power sequence pin states for PDI pads
VDD_LV_COR
VDD_HV_IO
VDD_HV_PDI
Pad Function
Low
Low
High
Outputs drive high
MPC5675K Microcontroller Data Sheet, Rev. 8.1
92
NXP Semiconductors
Electrical characteristics
Table 42. Power sequence pin states for PDI pads
VDD_LV_COR
VDD_HV_IO
VDD_HV_PDI
Pad Function
Low
High
High
High
High
High
Low
Low
High
High
x
Outputs Disabled
Outputs Disabled
Outputs drive high
Normal Operation1
Normal Operation
Low
High
Low
High
1
Normal operation except no drive current and input buffer output is unknown. The pad
pre-drive circuitry will function normally but since VDD_HV_PDI is unpowered the outputs
will not drive high even though the output PMOS can be enabled.
3.19 DRAM pad specifications
This section specifies the electrical characteristics of the DRAM pads. Please refer to the tables in Section 2.2, Pin descriptions,
for a cross reference between package pins and pad types.
DRAM pads feature list:
•
Driver
— Configurable to support LPDDR half strength, LPDDR full strength, DDR1, DDR2 half strength, DDR2 full
strength, and SDR modes.
— VDD_HV_DRAM range of
–
–
–
1.8 V nominal
2.5 V nominal
3.3 V nominal
•
Receiver
— Differential or pseudo-differential input buffer in all DRAM pads
— All inputs are tolerant up to their VDD_HV_DRAM absolute maximum rating
— Data and strobe pads can be configured to support four signal termination options
–
–
–
–
Infinite/no termination
50 Ω
75 Ω
150 Ω
The electrical data provided in Section 3.19, DRAM pad specifications, applies to the pads listed in Table 43.
Table 43. DRAM pads
Name
Voltage
Used For
Notes1
DRAM ACC
DRAM CLK
DRAM DQ
1.62 V–3.6 V
1.62 V–3.6 V
1.62 V–3.6 V
I/O
O
Bidirectional DDR pad
Output only differential clock driver pad
Bidirectional DDR pad with integrated ODT
I/O
1
All pads can be configured to support LPDDR half strength, LPDDR full strength, DDR1, DDR2 half
strength, DDR2 full strength, and SDR.
All three pad types can be configured to support SDR, DDR, DDR2 half and full strength, and LPDDR half and full strength
modes, according to Table 44.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
93
Electrical characteristics
Table 44. Mode configuration for DRAM pads
Configuration1
Mode
000
001
010
011
100
101
110
111
1.8 V LPDDR Half Strength
1.8 V LPDDR Full Strength
1.8 V DDR2 Half Strength
2.5 V DDR
Not supported
Not supported
1.8 V DDR2 Full Strength
SDR
1
Configuration is selected in the corresponding PCR registers of the SIUL.
NOTE
0.7 V overshoot/undershoot can be allowed to occur repeatedly throughout the product
expected lifetime and will not cause any long term reliability issue.
3.19.1 DRAM pads electrical specifications (V
= 3.3 V)
= 3.3 V)
Max
DD_HV_DRAM
Table 45. DRAM pads DC electrical specifications (V
DD_HV_DRAM
No.
Symbol
Parameter
Condition
Min
Unit
1
2
VDD_HV_DRAM SR I/O supply voltage
—
—
3.0
1.3
3.6
1.7
V
V
VDD_HV_DRAM_VREF CC Input reference
voltage
3
4
5
6
7
VDD_HV_DRAM_VTT CC Termination voltage1
—
—
—
—
—
VDD_HV_DRAM_VREF
– 0.05
VDD_HV_DRAM_VREF
+ 0.05
V
V
V
V
V
VIH
VIL
CC Input high voltage
CC Input low voltage
CC Output high voltage
CC Output low voltage
VDD_HV_DRAM_VREF
0.20
+
—
VDD_HV_DRAM_VREF
– 0.2
VOH
VOL
VDD_HV_DRAM_VTT
+ 0.8
—
—
VDD_HV_DRAM_VTT
– 0.8
1
BGA473: Termination voltage can be supplied via package pins. BGA257 termination voltage internally tied as the
BGA257 does not provide DRAM interface. Disable ODT.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
94
NXP Semiconductors
Electrical characteristics
Table 46. Output drive current @ V
= 3.3 V ( 10%)
DDE
1
2
No.
Pad Name
Drive Mode
Minimum I (mA)
Minimum I (mA)
OH
OL
1
2
3
DRAM ACC
DRAM DQ
DRAM CLK
111
–16
16
1
2
IOH is defined as the current sourced by the pad to drive the output to VOH
IOL is defined as the current sunk by the pad to drive the output to VOL
.
.
Table 47. DRAM pads AC electrical specifications (V
= 3.3 V)
DD_HV_DRAM
Prop. Delay (ns)
Output Slew rate
Rise/Fall (V/ns)
Drive/Slew
Rate Select
L → H/H → L1
Drive Load
No.
1
Pad Name
DRAM ACC
DRAM DQ
DRAM CLK
(pF)
Min
Max
Min
Max
MSB, LSB
1.4/1.4
1.7/1.7
1.4/1.4
1.7/1.7
1.4/1.4
1.6/1.6
2.4/2.4
2.7/2.7
2.4/2.4
2.7/2.7
2.4/2.4
2.6/2.6
3.1/2.5
0.9/1.1
3.1/2.5
0.9/1.1
3.1/2.5
1.1/1.3
5.6/5.4
1.7/2.0
5.6/5.4
1.7/2.0
5.7/5.7
2.3/2.3
5
20
5
111
111
111
111
111
111
2
20
5
3
20
1
L → H signifies low-to-high propagation delay and H → L signifies high-to-low propagation delay.
3.19.2 DRAM pads electrical specification (V
= 2.5 V)
DD_HV_DRAM
Table 48. DRAM pads DC electrical specifications (V
= 2.5 V)
DD_HV_DRAM
Symbol
Parameter
Condition
Min
2.3
Max
Unit
No.
1
2
3
VDD_HV_DRAM
SR I/O supply voltage
—
—
—
2.7
V
V
V
VDD_HV_DRAM_VREF CC Input reference voltage
VDD_HV_DRAM_VTT CC Termination voltage1
0.49 × VDD_HV_DRAM 0.51 × VDD_HV_DRAM
VDD_HV_DRAM_VREF VDD_HV_DRAM_VREF
– 0.04
+ 0.04
4
5
6
7
VIH
VIL
CC Input high voltage
CC Input low voltage
CC Output high voltage
CC Output low voltage
—
—
—
—
VDD_HV_DRAM_VREF
+ 0.15
—
V
V
V
V
—
VDD_HV_DRAM_VREF
– 0.15
VOH
VOL
VDD_HV_DRAM_VTT
+ 0.81
—
—
VDD_HV_DRAM_VTT
– 0.81
1
473 MAPBGA: Termination voltage can be supplied via package pins. 257 MAPBGA Termination voltage internally
tied as the 257 MAPBGA does not provide DRAM interface. Disable ODT.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
95
Electrical characteristics
Table 49. Output drive current @ V
= 2.5 V ( 200 mV)
DDE
Pad Name
Drive Mode
Minimum IOH (mA)1
Minimum IOL (mA)2
DRAM ACC
DRAM DQ
DRAM CLK
011
011
011
–16.2
16.2
1
2
IOH is defined as the current sourced by the pad to drive the output to VOH
.
IOL is defined as the current sunk by the pad to drive the output to VOL
.
Table 50. DRAM pads AC electrical specifications (V
Prop. Delay (ns)
= 2.5 V)
DD_HV_DRAM
Drive/Slew
Rate Select
Rise/Fall Edge (ns)
Drive
Load
(pF)
L → H/H → L1
No.
1
Pad Name
DRAM ACC
DRAM DQ
DRAM CLK
Min
Max
Min
Max
MSB, LSB
1.4/1.5
1.7/1.7
1.4/1.5
1.7/1.7
1.4/1.4
1.6/1.6
2.5/2.4
2.8/2.7
2.5/2.4
2.8/2.7
2.4/2.4
2.7/2.7
2.1/2.1
0.6/0.7
2.1/2.1
0.6/0.7
2.1/2.1
0.6/0.7
4.3/4.1
1.1/1.3
4.3/4.1
1.1/1.3
4.4/4.1
1.6/1.8
5
20
5
011
2
011
011
20
5
3
20
1
L → H signifies low-to-high propagation delay and H → L signifies high-to-low propagation delay.
3.19.3 DRAM pads electrical specification (V
= 1.8 V)
DD_HV_DRAM
Table 51. DRAM pads DC electrical specifications (V
= 1.8 V)
DD_HV_DRAM
No.
Symbol
Parameter
Condition
Min
Max
Unit
1
2
3
VDD_HV_DRAM
SR I/O supply voltage
—
—
—
1.62
1.9
V
VDD_HV_DRAM_VREF CC Input reference voltage
VDD_HV_DRAM_VTT CC Termination voltage1
0.49 × VDD_HV_DRAM 0.51 × VDD_HV_DRAM
VDD_HV_DRAM_VREF VDD_HV_DRAM_VREF
V
V
V
V
– 0.04
+ 0.04
4
5
VIH
VIL
CC Input high voltage
CC Input low voltage
—
—
VDD_HV_DRAM_VREF
+ 0.125
—
—
VDD_HV_DRAM_VREF
– 0.125
6
7
VOH
VOL
CC Output high voltage
CC Output low voltage
—
—
1.42
—
—
V
V
0.28
1
BGA473: Termination voltage can be supplied via package pins. BGA257 Termination voltage internally tied as the
BGA257 does not provide DRAM interface. Disable ODT.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
96
NXP Semiconductors
Electrical characteristics
Table 52. Output drive current @ V
= 1.8 V ( 100 mV)
DDE
No.
Pad Name
Drive Mode
Minimum IOH (mA)1
Minimum IOL (mA)2
1
DRAM ACC
000
001
010
110
000
001
010
110
000
001
010
110
–3.57
–7.84
–5.36
–13.4
–3.57
–7.84
–5.36
–13.4
–3.57
–7.84
–5.36
–13.4
3.57
7.84
5.36
13.4
3.57
7.84
5.36
13.4
3.57
7.84
5.36
13.4
2
3
DRAM DQ
DRAM CLK
1
2
IOH is defined as the current sourced by the pad to drive the output to VOH
.
IOL is defined as the current sunk by the pad to drive the output to VOL
.
Table 53. DRAM pads AC electrical specifications (V
= 1.8 V)
DD_HV_DRAM
Prop. Delay (ns)
Rise/Fall Edge
(ns)
Drive/Slew
Rate Select
L → H/H → L1
Drive Load
(pF)
No.
Pad Name
Min
Max
Min
Max
MSB, LSB
1
DRAM ACC
1.4/1.4
1.7/1.7
1.4/1.5
1.7/1.7
1.4/1.5
1.7/1.7
1.4/1.5
1.7/1.8
1.4/1.4
1.7/1.7
1.4/1.5
1.7/1.7
1.4/1.5
1.7/1.7
1.4/1.5
1.7/1.8
2.4/2.4
2.8/2.7
2.4/2.5
2.8/2.8
2.4/2.4
2.8/2.7
2.5/2.5
2.8/2.8
2.4/2.4
2.8/2.7
2.4/2.5
2.8/2.8
2.4/2.4
2.8/2.7
2.5/2.5
2.8/2.8
0.6/1.0
0.2/0.4
1.1/1.1
0.4/0.4
1.0/1.1
0.3/0.4
1.5/1.1
0.4/0.4
0.6/1.0
0.2/0.4
1.1/1.1
0.4/0.4
1.0/1.1
0.3/0.4
1.5/1.1
0.4/0.4
2.7/2.6
0.5/0.6
3.0/2.7
0.7/0.7
2.9/2.7
0.6/0.7
3.1/2.6
0.7/0.6
2.7/2.6
0.5/0.6
3.0/2.7
0.7/0.7
2.9/2.7
0.6/0.7
3.1/2.6
0.7/0.6
5
20
5
000
001
010
110
000
001
010
110
20
5
20
5
20
5
2
DRAM DQ
20
5
20
5
20
5
20
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
97
Electrical characteristics
Table 53. DRAM pads AC electrical specifications (V
(continued) = 1.8 V)
DD_HV_DRAM
Prop. Delay (ns)
Rise/Fall Edge
(ns)
Drive/Slew
Rate Select
L → H/H → L1
Drive Load
(pF)
No.
Pad Name
Min
Max
Min
Max
MSB, LSB
3
DRAM CLK
1.4/1.4
1.6/1.6
1.4/1.4
1.7/1.7
1.4/1.4
1.6/1.6
1.4/1.4
1.7/1.7
2.4/2.4
2.7/2.7
2.4/2.4
2.7/2.7
2.4/2.4
2.7/2.7
2.5/2.5
2.7/2.7
0.4/0.6
0.7/0.9
1.1/1.1
0.3/0.4
0.9/1.1
0.3/0.4
1.5/1.2
0.4/0.4
2.7/2.7
1.8/3.4
3.0/2.8
1.0/1.1
3.0/2.8
0.9/1.0
3.2/2.6
1.1/1.2
5
20
5
000
001
010
110
20
5
20
5
20
1
L → H signifies low-to-high propagation delay and H → L signifies high-to-low propagation delay.
3.19.4 DRAM Pad Current Specifications
The power consumption of an I/O segment is dependent on the usage of the pins on a particular segment. The power
consumption is the sum of all output pin currents for a particular segment. The output pin current can be calculated based on
the voltage, frequency, and load on the pin.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
98
NXP Semiconductors
Electrical characteristics
Table 54. DRAM pad current specifications
Frequency
(MHz)
Load
(pF)
Voltage
(V)
Drive/Slew Rate
Select
Current
(mA)
Pad Type
DRAM DQ /
DRAM ACC
45
45
45
45
45
45
45
45
45
45
45
45
90
90
90
90
90
90
90
90
90
90
90
90
5
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
1.8
LPDDR_HS (010)1
LPDDR_FS (110)1
DDR2_HS (010)1
DDR2_FS (110)1
LPDDR_HS (010)1
LPDDR_FS (110)1
DDR2_HS (010)1
DDR2_FS (110)1
LPDDR_HS (010)1
LPDDR_FS (110)1
DDR2_HS (010)1
DDR2_FS (110)1
LPDDR_HS (010)1
LPDDR_FS (110)1
DDR2_HS (010)1
DDR2_FS (110)1
LPDDR_HS (010)1
LPDDR_FS (110)1
DDR2_HS (010)1
DDR2_FS (110)1
LPDDR_HS (010)1
LPDDR_FS (110)1
DDR2_HS (010)1
DDR2_FS (110)1
0.74
0.9
5
5
0.81
1.26
1.14
1.28
1.21
1.59
1.97
2.08
2.02
2.33
1.41
1.73
1.56
2.42
2.19
2.45
2.32
3.05
3.77
3.98
3.87
4.46
5
10
10
10
10
20
20
20
20
5
5
5
5
10
10
10
10
20
20
20
20
1
LPDDR_HS = LPDDR half strength, LPDDR_FS = LPDDR full strength, DDR2_HS = DDR2 half strength, DDR2_FS
= DDR2 half strength.
3.19.5 Power Sequence Pin States for DRAM Pads
Table 55. Power sequence pin states for DRAM pads
VDD_LV_COR
VDD_HV_IO
VDD_HV_PDI
Pad Function
Low
Low
High
High
Low
High
Low
Low
High
x
Outputs Disabled
Outputs Disabled
Outputs Disabled
Outputs Disabled
Low
High
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
99
Electrical characteristics
Table 55. Power sequence pin states for DRAM pads
VDD_LV_COR
VDD_HV_IO
VDD_HV_PDI
Pad Function
High
High
High
High
Low
Normal Operation1
Normal Operation
High
1
Normal operation except no drive current and input buffer output is unknown. The pad
pre-drive circuitry will function normally but since VDD_HV_DRAM is unpowered, the
outputs will not drive high even though the output PMOS can be enabled. DDR pad is only
guaranteed to operate and be in compliance with Jedec standards, when all three power
supplies, VDD_LV_COR, VDD_HV_IO and VDD_HV_DRAM are fully powered up.
3.20 RESET characteristics
3.20.1 RESET pin characteristics
Table 56. RESET pin characteristics
No.
Symbol
WFRST
WNFRST
Parameter
Conditions
Min Max Unit
1
2
SR RESET pulse is sure to be filtered
SR RESET pulse is sure not to be filtered
—
—
—
70
—
ns
ns
400
3.20.2 RESET_SUP_B pin characteristics
Table 57. RESET_SUP_B pin characteristics
No.
Symbol
WFRST
Parameter
Conditions
Min Max Unit
1
SR RESET_SUP_B pulse is sure to be filtered (there
is no internal filter on this pin)
—
—
0
ns
2
TRSTSUP SR RESET_SUP_B release by an external
delay/monitor circuit after all supplies are stable
—
0
—
ns
3.21 Reset sequence
This section shows the duration for different reset sequences. It describes the different reset sequences and it specifies the start
conditions and the end indication for the reset sequences depending on internal or external VREG mode.
3.21.1 Reset sequence duration
Table 58 specifies the minimum and the maximum reset sequence duration for the five different reset sequences described in
Section 3.21.2, Reset sequence description.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
100
NXP Semiconductors
Electrical characteristics
Table 58. RESET sequences
Parameter
TReset
No.
Symbol
Unit
Min
Typ
Max1
1
2
3
4
5
TDRB
TDR
CC
CC
Destructive Reset Sequence, BIST enabled
Destructive Reset Sequence, BIST disabled
External Reset Sequence Long, BIST enabled
Functional Reset Sequence Long
50
40
50
40
1
60
400
60
70
1000
70
ms
µs
TERLB CC
ms
µs
TFRL
TFRS
CC
CC
300
3
600
10
Functional Reset Sequence Short
µs
1
The maximum value is applicable only if the reset sequence duration is not prolonged by an extended assertion of
RESET by an external reset generator.
3.21.2 Reset sequence description
The figures in this section show the internal states of the MPC5675K during the five different reset sequences. The doted lines
in the figures indicate the starting point and the end point for which the duration is specified in Table 58. The start point and
end point conditions as well as the reset trigger mapping to the different reset sequences is specified in Section 3.21.3, Reset
sequence trigger mapping.
With the beginning of DRUN mode, the first instruction is fetched and executed. At this point, application execution starts and
the internal reset sequence is finished.
The following figures show the internal states of the MPC5675K during the execution of the reset sequence and the possible
states of the RESET signal pin.
NOTE
RESET is a bidirectional pin. The voltage level on this pin can either be driven low by an
external reset generator or by the MPC5675K internal reset circuitry. A high level on this
pin can only be generated by an external pullup resistor which is strong enough to overdrive
the weak internal pulldown resistor. The rising edge on RESET in the following figures
indicates the time when the device stops driving it low. The reset sequence durations given
in Table 58 are applicable only if the internal reset sequence is not prolonged by an external
reset generator keeping RESET asserted low beyond the last PHASE3.
Reset Sequence Trigger
Reset Sequence Start Condition
RESET
PHASE0
PHASE1,2
PHASE3
BIST
PHASE1,2
PHASE3
DRUN
Establish
IRC and
PWR
Flash
Init
Flash
Init
Device
Config
Self
Test
Setup
Device
Config
Application
Execution
MBIST
LBIST
TDRB, min < TRESET < TDRB, max
Figure 12. Destructive reset sequence, BIST enabled
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
101
Electrical characteristics
Reset Sequence Trigger
Reset Sequence Start Condition
RESET
PHASE0
PHASE1,2
PHASE3
DRUN
Establish
IRC and
PWR
Flash
Init
Device
Config
Application
Execution
TDR, min < TRESET < TDR, max
Figure 13. Destructive reset sequence, BIST disabled
Reset Sequence Trigger
Reset Sequence Start Condition
RESET
PHASE1,2
PHASE3
BIST
PHASE1,2
PHASE3
DRUN
Flash
Init
Flash
Init
Device
Config
Self
Test
Setup
Device
Config
Application
Execution
MBIST
LBIST
TERLB, min < TRESET < TERLB, max
Figure 14. External reset sequence long, BIST enabled
Reset Sequence Trigger
Reset Sequence Start Condition
RESET
PHASE1,2
PHASE3
DRUN
Flash
Init
Device
Config
Application
Execution
TFRL, min < TRESET < TFRL, max
Figure 15. Functional reset sequence long
MPC5675K Microcontroller Data Sheet, Rev. 8.1
102
NXP Semiconductors
Electrical characteristics
Reset Sequence Trigger
Reset Sequence Start Condition
RESET
PHASE3
DRUN
Application
Execution
TFRS, min < TRESET < TFRS, max
Figure 16. Functional reset sequence short
The reset sequences shown in Figure 15 and Figure 16 are triggered by functional reset events. RESET is driven low during
these two reset sequences only if the corresponding functional reset source (which triggered the reset sequence) was enabled to
drive RESET low for the duration of the internal reset sequence. See the RGM_FBRE register in the MPC5675K Reference
Manual for more information.
3.21.3 Reset sequence trigger mapping
The following table shows the possible trigger events for the different reset sequences, depending on the VREG mode (external
or internal). It specifies the reset sequence start conditions as well as the reset sequence end indications that are the basis for the
timing data provided in Table 58.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
103
Electrical characteristics
Table 59. Reset sequence trigger—reset sequence
Reset Sequence
Reset
Sequence Sequence
Start End
Condition Indication
Reset
Destructive
Reset
Destructive
Reset
External
Reset
Sequence
Long,
Functional
Reset
Sequence
Long
Functional
Reset
Sequence
Short
Reset
Sequence
Trigger
Sequence,
BIST
Sequence,
BIST
2
2
enabled
disabled
BIST
enabled
All active
internal
destructive
reset sources
(LVDs or
I
Section 3.
21.4.1,
Internal
VREG
Release of
RESET
triggers
cannot
trigger
cannot
trigger
cannot
trigger
3
mode
internal HVD
during
power-up and
during
E
Section 3.
21.4.2,
External
VREG
cannot
trigger
cannot
trigger
cannot
trigger
operation)
mode
Assertion of
RESET_SUP4
Assertion of
RESET5
I/E
I/E
I/E
Section 3.
21.4.3,
External
reset via
RESET
cannot trigger
cannot trigger
cannot trigger
triggers6
triggers7
triggers
triggers8
All internal
functional
reset sources
configured for
long reset
Sequence
starts with
internal
reset
Release of
RESET
cannot
trigger
cannot
trigger
9
trigger
All internal
functional
cannot
trigger
cannot
trigger
triggers
reset sources
configured for
short reset
1
2
3
VREG Mode: I = Internal VREG Mode, E = External VREG Mode.
Whether BIST is executed or not depends on device configuration data stored in the shadow sector of the NVM.
End of the internal reset sequence (as specified in Table 58) can only be observed by release of RESET if it is not held low
externally beyond the end of the internal sequence which would prolong the internal reset PHASE3 until RESET is released
externally.
4
5
In external VREG mode only.
The assertion of RESET can only trigger a reset sequence if the device was running (RESET released) before.
RESET does not gate a Destructive Reset Sequence, BIST enabled or a Destructive Reset Sequence, BIST
disabled. However, it can prolong these sequences if RESET is held low externally beyond the end of the internal
sequence (beyond PHASE3).
6
7
If RESET is configured for long reset (default) and if BIST is enabled via device configuration data stored in the
shadow sector of the NVM.
If RESET is configured for long reset (default) and if BIST is disabled via device configuration data stored in the
shadow sector of the NVM.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
104
NXP Semiconductors
Electrical characteristics
8
9
If RESET is configured for short reset.
Internal reset sequence can only be observed by state of RESET if bidirectional RESET functionality is enabled for the functional
reset source which triggered the reset sequence.
3.21.4 Reset sequence—start condition
The impact of the voltage thresholds on the starting point of the internal reset sequence are becoming important if the voltage
rails / signals ramp up with a very slow slew rate compared to the overall reset sequence duration.
3.21.4.1 Internal VREG mode
Figure 17 shows the voltage threshold that determines the start of the Destructive Reset Sequence, BIST enabled and the start
for the Destructive Reset Sequence, BIST disabled. The last voltage rail crossing the levels shown in Figure 17 determines the
start of the reset times specified in Table 58.
Supply rail
V
V
max
V
min
T
starts here
Reset, max
t
T
starts here
Reset, min
Figure 17. Reset sequence start in internal VREG mode
Table 60. Voltage thresholds
Variable name
Value
Vmin
Vmax
LvdReg – 3.5%
LvdReg + 3.5%
Supply Rail
VDD_HV_PMU
VDD_HV_IO
VDD_HV_FLASH
VDD_HV_ADV
3.21.4.2 External VREG mode
Figure 18 and Figure 19 show the voltage thresholds that determine the start of the Destructive Reset Sequence, BIST enabled
and the start for the Destructive Reset Sequence, BIST disabled.
NOTE
RESET_SUP must not be released unless V
RESET_SUP input circuitry needs a valid V
RESET_SUP.
is within its valid range of operation.
rail in order to detect a high level on
DD_LV_xxx
DD_HV_IO
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
105
Electrical characteristics
Min VDD_HV_XXX
Min VDD_LV_XXX
VDD_HV_PMU
VDD_HV_IO
V
VDD_HV_FLASH
VDD_HV_ADV
VDD_LV_CORE
VDD_LV_PLL
t
V
RESET_SUP
0.8 × VDD_HV_IO
0.2 × VDD_HV_IO
T
starts here
Reset, max
t
T
RSTSUP
T
starts here
Reset, min
Figure 18. External VREG mode, RESET_SUP rises after V
are stable
DD_HV_xxx
VDD_HV_PMU
VDD_HV_IO
V
VDD_HV_FLASH
VDD_HV_ADV
LvdReg + 3.5%
LvdReg – 3.5%
t
V
RESET_SUP
T
starts here
Reset, max
t
T
starts here
Reset, min
Figure 19. External VREG mode, RESET_SUP rises with V
DD_HV_xxx
NOTE
In case RESET_SUP has reached a valid high level before V
is stable, the reset
DD_HV_IO
sequence will start as documented in Figure 19 as the RESET_SUP input circuitry needs a
valid V
rail in order to detect a high level on RESET_SUP.
DD_HV_IO
MPC5675K Microcontroller Data Sheet, Rev. 8.1
106
NXP Semiconductors
Electrical characteristics
3.21.4.3 External reset via RESET
Figure 20 shows the voltage thresholds that determine the start of the reset sequences initiated by the assertion of RESET as
specified in Table 59.
V
RESET_SUP
0.65 × VDD_HV_IO
0.352 × VDD_HV_IO
T
starts here
t
Reset, max
T
starts here
Reset, min
Figure 20. Reset sequence start via RESET assertion
3.21.5 External watchdog window
If the application design requires the use of an external watchdog the data provided in Section 3.21, Reset sequence can be used
to determine the correct positioning of the trigger window for the external watchdog. Figure 21 shows the relationships between
the minimum and the maximum duration of a given reset sequence and the position of an external watchdog trigger window.
Watchdog needs to be triggered within this window
T
WDStart, min
External watchdog window closed
T
WDStart, max
External watchdog window closed
Watchdog trigger
Basic application init
T
Reset, min
Application running
Basic application init
T
Reset, max
Application running
Latest
application
start
Earliest
application
start
Application time required
to prepare watchdog trigger
Internal reset sequence
Start condition (signal or voltage rail)
Figure 21. Reset sequence—external watchdog trigger window position
3.22 Peripheral timing characteristics
3.22.1 SDRAM (DDR)
The MPC5675K memory controller supports three types of DDR devices:
•
•
•
DDR-1 (SSTL_2 class II interface)
DDR-2 (SSTL_18 interface)
LPDDR/Mobile-DDR (1.8V I/O supply voltage)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
107
Electrical characteristics
JEDEC standards define the minimum set of requirements for compliant memory devices:
•
•
•
JEDEC STANDARD, DDR2 SDRAM SPECIFICATION, JESD79-2C, MAY 2006
JEDEC STANDARD, Double Data Rate (DDR) SDRAM Specification, JESD79E, May 2005
JEDEC STANDARD, Low Power Double Data Rate (LPDDR) SDRAM Specification, JESD79-4, May 2006
The MPC5675K supports the configuration of two output drive strengths for DDR2 and LPDDR:
•
•
Full drive strength
Half drive strength (intended for lighter loads or point-to-point environments)
The MPC5675K memory controller supports dynamic on-die termination in the host device and in the DDR2 memory device.
This section includes AC specifications for all DDR SDRAM pins. The DC parameters are specified in the Section 3.19, DRAM
pad specifications.
3.22.1.1 DDR and DDR2 SDRAM AC timing specifications
Table 61. DDR and DDR2 (DDR2-400) SDRAM timing specifications
At recommended operating conditions with VDD_MEM_IO of 5%
No.
Symbol
Parameter
CC Clock cycle time, CL = x
Min
Max
Unit
1
2
tCK
—
90
MHz
V
VIX-AC
CC MCK AC differential crosspoint voltage1
VDD_MEM_IO
× 0.5 – 0.1
VDD_MEM_IO
× 0.5 + 0.1
3
4
5
6
tCH
tCL
tDQSS
tOS(base)
CC CK HIGH pulse width1, 2
0.47
0.47
0.53
0.53
0.25
tCK
tCK
tCK
ps
CC CK LOW pulse width1, 2
CC Skew between MCK and DQS transitions2, 3
−0.25
CC Address and control output setup time relative to
MCK rising edge2, 3
(tCK/2 – 750)
7
tOH(base)
CC Address and control output hold time relative to
MCK rising edge2, 3
(tCK/2 – 750)
—
ps
8
9
tDS1(base)
tDH1(base)
tDQSQ
CC DQ and DM output setup time relative to DQS2, 3
CC DQ and DM output hold time relative to DQS2, 3
(tCK/4 – 500)
(tCK/4 – 500)
—
—
ps
ps
10
CC DQS-DQ skew for DQS and associated DQ inputs2 –(tCK/4 – 600) (tCK/4 – 600) ps
1
2
3
Measured with clock pin loaded with differential 100 Ω termination resistor.
All transitions measured at mid-supply (VDD_MEM_IO/2).
Measured with all outputs except the clock loaded with 50 Ω termination resistor to VDD_MEM_IO/2.
Figure 22 shows the DDR SDRAM write timing.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
108
NXP Semiconductors
Electrical characteristics
tCL
tCH
MCK
DQS
tCK
tDQSS
DQ, DM (out)
tDS
tDH
Figure 22. DDR write timing
Figure 23 and Figure 24 show the DDR SDRAM read timing.
DQS (in)
Any DQ (in)
tDQSQ
tDQSQ
Figure 23. DDR read timing, DQ vs. DQS
MCK
Command
Address
Read
tOS
tOH
DQS (in)
tDQSEN (min)
tDQSEN
Figure 24. DDR read timing, DQSEN
Figure 25 provides the AC test load for the DDR bus.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
109
Electrical characteristics
VDD_MEM_IO/2
Output
Z0 = 50 Ω
RL = 50 Ω
Figure 25. DDR AC test load
3.22.2 IEEE 1149.1 (JTAG) interface timing
3.22.2.1 Standard interface timing
Table 62. JTAG pin AC electrical characteristics
No.
Symbol
Parameter Conditions
Min Max Unit
1
2
tJCYC
tJDC
D
D
D
D
D
D
D
D
D
D
TCK cycle time 1
—
—
—
—
—
—
—
—
—
—
60
—
ns
%
TCK clock pulse width (measured at VDDE/2)
TCK rise and fall times (40%–70%)
TMS, TDI data setup time
40 60
3
tTCKRISE
—
12
6
3
ns
ns
ns
ns
ns
ns
ns
ns
4
tTMSS, TDIS
TMSH, tTDIH
tTDOV
tTDOI
tTDOHZ
tBSDV
t
—
—
18
—
18
14
15
5
t
TMS, TDI data hold time
6
TCK low to TDO data valid
—
6
7
TCK low to TDO data invalid
8
TCK low to TDO high impedance
TCK falling edge to output valid (BSR)
—
—
—
9
10
tBSDVZ
TCK falling edge to output valid out of high impedance
(BSR)
11
12
13
tBSDHZ
tBSDST
tBSDHT
D
D
D
TCK falling edge to output high impedance (BSR)
Boundary scan input valid to TCK rising edge
TCK rising edge to boundary scan input invalid
—
—
—
—
15
2
10
—
—
ns
ns
ns
1
fTCK = 1/tTCK. fTCK must not exceed 1/4 the frequency of the system clock (SYS_CLK).
3.22.2.2 Interface timing for Full Cycle mode
Table 63. JTAG pin Full Cycle mode AC electrical characteristics
No.
Symbol
Parameter
Conditions
Min Max Unit
1
2
3
4
5
6
7
tJCYC
tJDC
D
D
D
D
D
D
D
TCK cycle time 1
—
—
—
—
—
—
—
40
—
ns
%
TCK clock pulse width (measured at VDDE/2)
TCK rise and fall times (40%–70%)
TMS, TDI data setup time
40 60
tTCKRISE
—
12
6
3
ns
ns
ns
ns
ns
tTMSS, TDIS
tTMSH, TDIH
tTDOV
tTDOI
t
—
—
18
—
t
TMS, TDI data hold time
TCK low to TDO data valid
—
6
TCK low to TDO data invalid
MPC5675K Microcontroller Data Sheet, Rev. 8.1
110
NXP Semiconductors
Electrical characteristics
fTCK = 1/tTCK. fTCK needs to be smaller than the system clock (SYS_CLK). This frequency is valid only in special
1
modes where TDO is sampled at the next falling edge for Core0/1 Nexus TAPs and hence full cycle is given to TDO
for settling before it is sampled.
TCK
2
3
2
1
3
Figure 26. JTAG test clock input timing
TCK
4
5
TMS, TDI
6
8
7
TDO
Figure 27. JTAG test access port timing
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
111
Electrical characteristics
TCK
11
13
Output
Signals
12
Output
Signals
14
15
Input
Signals
Figure 28. JTAG boundary scan timing
3.22.3 Nexus timing
1
Table 64. Nexus debug port timing Div mode = 2
No.
Symbol
Parameter
Conditions
Min
Max
Unit
1
2
3
4
5
tMCKO
tMDC
CC MCKO cycle time
—
—
—
—
—
16.67
50
—
50
ns
%
CC MCKO duty cycle2
tMDOV
tEVTIPW
tPW
CC MCKO Low to MDO, MSEO, EVTO data valid3
CC EVTI pulse width. Captured on JTAG TCK.
CC MDO, MSEO,EVTO pulse width in SDR mode
–1.67
4.0
3.34
—
ns
tJCYC
tMCKO
1
—
1
All Nexus timing relative to MCKO is measured from 50% of MCKO and 50% of the respective signal. Rise/Fall time
for Nexus signals can be derived from Fast GPIO pad specification section.
2
3
Jitter/tolerance for MCKO clock is derived from PLL. Please see PLL section for jitter specification.
MDO, MSEO, and EVTO data is held valid until next MCKO low cycle in SDR mode. For DDR mode, this timing is
same for both MCKO edges.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
112
NXP Semiconductors
Electrical characteristics
1
2
MCKO
3
MDO
MSEO
EVTO
Output Data Valid
5
4
EVTI
Figure 29. Nexus SDR (Even divisor) timing
1
Table 65. Nexus debug port timing Divide by 3 SDR mode
No.
Symbol
tMCKO
tMDC
Parameter
Conditions
Min
Max
Unit
1
2
3
4
5
CC MCKO cycle time
—
—
—
—
—
16.67
33
—
66
ns
%
CC MCKO duty cycle2
tMDOV
tEVTIPW
tPW
CC MCKO Low to MDO, MSEO, EVTO data valid
CC EVTI pulse width. Captured on JTAG TCK.
CC MDO, MSEO,EVTO pulse width in SDR mode
–1.67
4.0
3.34
—
ns
tJCYC
tMCKO
1
—
1
2
MDO, MSEO, and EVTO data is held valid until next MCKO low cycle in SDR mode. Rise/Fall time for Nexus signals
can be derived from Fast GPIO pad specification section.
Jitter/tolerance for MCKO clock is derived from PLL. Please see PLL section for jitter specification.
1
2
MCKO
3
MDO
MSEO
EVTO
Output Data Valid
5
4
EVTI
Figure 30. Nexus SDR output timing for DIV=3
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
113
Electrical characteristics
1
Table 66. Nexus debug port timing DIVIDE by 4 DDR mode
No.
Symbol
Parameter
Conditions
Min
Max
Unit
1
2
3
4
5
tMCKO
tMDC
CC MCKO cycle time
—
—
—
—
—
22.22
50
—
50
ns
%
CC MCKO duty cycle2
tMDOV
tEVTIPW
tPW
CC MCKO Low to MDO, MSEO, EVTO data valid3
–2.23
4.0
4.45
—
ns
CC EVTI pulse width
tJCYC
tMCKO
CC MDO, MSEO,EVTO pulse width in DDR mode
0.5
—
1
All Nexus timing relative to MCKO is measured from 50% of MCKO and 50% of the respective signal.Rise/Fall time
for Nexus signals can be derived from Fast GPIO pad specification section.
2
3
Jitter/tolerance for MCKO clock is derived from PLL. Please see PLL section for jitter specification.
MDO, MSEO, and EVTO data is held valid for half of time period. Using this time period, Data valid window for these
signals is between 0.2 tMCKO to 0.4 tMCKO starting from each MCKO edge.
1
2
MCKO
3
MDO
MSEO
Output Data Valid
5
Figure 31. Nexus DDR mode timing
3.22.4 External interrupt timing (IRQ pins)
Table 67. External interrupt timing (NMI IRQ)
No.
Symbol
Parameter Conditions
Min Max Unit
1
2
3
tIPWL SR IRQ pulse width low
tIPWH SR IRQ pulse width high
tICYC SR IRQ edge to edge time1
—
—
—
3
3
6
—
—
—
tCYC
tCYC
tCYC
1
Applies when IRQ pins are configured for rising edge or falling edge events, but not both.
Table 68. External interrupt timing (GPIO IRQ)
No.
Symbol
Parameter
Conditions
Min Max Unit
1
2
tIPWL SR IRQ pulse width low
tIPWH SR IRQ pulse width high
—
—
3
3
—
—
tCYC
tCYC
MPC5675K Microcontroller Data Sheet, Rev. 8.1
114
NXP Semiconductors
Electrical characteristics
Min Max Unit
Table 68. External interrupt timing (GPIO IRQ) (continued)
No.
Symbol
Parameter
Conditions
3
tICYC SR IRQ edge to edge time1
—
6
—
tCYC
1
Applies when IRQ pins are configured for rising edge or falling edge events, but not both.
CLKOUT
IRQ
1
2
3
Figure 32. External interrupt timing
3.22.5 FlexCAN timing
Table 69. FlexCAN timing
Parameter
No.
Symbol
Conditions Min
Max
Unit
1
2
fCAN_TX CC FlexCAN design target transmit data rate
fCAN_RX CC FlexCAN design target receive data rate
—
—
10
10
—
—
MBit/s
MBit/s
3.22.6 DSPI timing
Table 70. DSPI timing
Conditions
No. Symbol
Parameter
Min
Max
Unit
1
tSCK CC DSPI cycle time
Master (MTFE = 0)
62
62
16
16
16
—
—
—
—
—
ns
Slave (MTFE = 0)
Slave receive only mode1
2
3
4
tCSC CC PCS to SCK delay
tASC CC After SCK delay
tSDC CC SCK duty cycle
—
—
—
ns
ns
0.4 × tSCK 0.6 × tSCK ns
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
115
Electrical characteristics
No. Symbol
Table 70. DSPI timing (continued)
Parameter
Conditions
Min
Max
Unit
5
6
7
8
9
tA
CC Slave access time
SS active to SOUT valid
SS inactive to SOUT High-Z or invalid
—
—
—
13
13
20
2
40
10
—
—
—
—
—
—
—
—
—
—
4
ns
ns
ns
ns
ns
tDIS CC Slave SOUT disable time
tPCSC CC PCSx to PCSS time
tPASC CC PCSS to PCSx time
tSUI CC Data setup time for inputs
—
Master (MTFE = 0)
Slave
Master (MTFE = 1, CPHA = 0)
Master (MTFE = 1, CPHA = 1)
Master (MTFE = 0)
Slave
5
20
–5
4
10
tHI
CC Data hold time for inputs
ns
ns
ns
ns
Master (MTFE = 1, CPHA = 0)
Master (MTFE = 1, CPHA = 1)
Master (MTFE = 0)
Slave
11
–5
—
—
—
—
–2
6
11 tSUO CC Data valid (after SCK edge)
12 tHO CC Data hold time for outputs
13 tDT CC Delay after Transfer
23
11
5
Master (MTFE = 1, CPHA = 0)
Master (MTFE = 1, CPHA = 1)
Master (MTFE = 0)
Slave
—
—
—
—
Master (MTFE = 1, CPHA = 0)
Master (MTFE = 1, CPHA = 1)
Continuous mode
6
–2
62
134
—
—
(minimum CS negation time) Non-continuos mode2
1
2
Slave Receive Only Mode can operate at a maximum frequency of 60 MHz. Note that in this mode, the DSPI can
receive data on SIN, but no valid data is transmitted on SOUT.
In non-continuous mode, this value is always tSCK × DSPI_CTARn[DT] × DSPI_CTARn[PDT]. The minimum
permissible value of DT is 2 and the minimum permissible value of PDT is 1. See the DSPI chapter of the
MPC5675K Reference Manual for more information.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
116
NXP Semiconductors
Electrical characteristics
2
3
PCSx
1
4
SCK Output
(CPOL=0)
4
SCK Output
(CPOL=1)
10
9
Last Data
SIN
First Data
First Data
Data
Data
12
11
Last Data
SOUT
Figure 33. DSPI classic SPI timing—master, CPHA = 0
PCSx
SCK Output
(CPOL=0)
10
SCK Output
(CPOL=1)
9
Data
Data
First Data
Last Data
SIN
12
11
SOUT
Last Data
First Data
Figure 34. DSPI classic SPI timing—master, CPHA = 1
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
117
Electrical characteristics
3
2
SS
1
4
SCK Input
(CPOL=0)
4
SCK Input
(CPOL=1)
5
11
12
Data
6
First Data
Last Data
SOUT
SIN
9
10
Data
Last Data
First Data
Figure 35. DSPI classic SPI timing—slave, CPHA = 0
SS
SCK Input
(CPOL=0)
SCK Input
(CPOL=1)
11
5
6
12
Last Data
Data
Data
SOUT
SIN
First Data
10
9
Last Data
First Data
Figure 36. DSPI classic SPI timing—slave, CPHA = 1
MPC5675K Microcontroller Data Sheet, Rev. 8.1
118
NXP Semiconductors
Electrical characteristics
3
PCSx
4
1
2
SCK Output
(CPOL=0)
4
SCK Output
(CPOL=1)
9
10
SIN
First Data
12
Last Data
Last Data
Data
11
SOUT
First Data
Data
Figure 37. DSPI modified transfer format timing—master, CPHA = 0
PCSx
SCK Output
(CPOL=0)
SCK Output
(CPOL=1)
10
9
SIN
Last Data
First Data
Data
12
Data
11
First Data
Last Data
SOUT
Figure 38. DSPI modified transfer format timing—master, CPHA = 1
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
119
Electrical characteristics
3
2
SS
1
SCK Input
(CPOL=0)
4
4
SCK Input
(CPOL=1)
12
11
6
5
First Data
9
Data
Data
Last Data
10
SOUT
SIN
Last Data
First Data
Figure 39. DSPI modified transfer format timing—slave, CPHA = 0
SS
SCK Input
(CPOL=0)
SCK Input
(CPOL=1)
11
5
6
12
Last Data
First Data
Data
Data
SOUT
9
10
SIN
First Data
Last Data
Figure 40. DSPI modified transfer format timing—slave, CPHA = 1
MPC5675K Microcontroller Data Sheet, Rev. 8.1
120
NXP Semiconductors
Electrical characteristics
(CPOL = 0)
(CPOL = 1)
SCK
SCK
Master SOUT
Master SIN
PCSx
3
2
2
13
Figure 41. Example of non-continuous format (CPHA = 1, CONT = 0)
SCK (CPOL = 0)
SCK (CPOL = 1)
Master SOUT
Master SIN
PCS
2
3
2
Figure 42. Example of continuous transfer (CPHA = 1, CONT = 1)
8
7
PCSS
PCSx
Figure 43. DSPI PCS strobe (PCSS) timing
Table 71. PDI electrical characteristics
3.22.7 PDI timing
No.
Symbol
Parameter
Conditions
Min
Max
Unit
1
tPDI_CLOCK SR PDI clock period
—
15
—
ns
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
121
Electrical characteristics
Table 71. PDI electrical characteristics (continued)
No.
Symbol
Parameter
Conditions
Min
Max
Unit
2
3
tPDI_IS
tPDI_IH
SR Input setup time1
SR Input hold time1
—
—
3
3
—
—
ns
ns
1
Data can be captured at both launching and capturing edge of PDI_CLK.
PDI_CLOCK
1
2
3
PDI_DATA[15:0]
PDI_LINE_V
Input Data Valid
PDI_FRAME_V
Figure 44. PDI timing
3.22.8 Fast Ethernet interface
MII signals use CMOS signal levels compatible with devices operating at either 5.0 V or 3.3 V. Signals are not TTL compatible.
They follow the CMOS electrical characteristics.
3.22.8.1 MII receive signal timing (RXD[3:0], RX_DV, RX_ER, and RX_CLK)
The receiver functions correctly up to a RX_CLK maximum frequency of 25 MHz +1%. There is no minimum frequency
requirement. In addition, the system clock frequency must exceed two times the RX_CLK frequency.
Table 72. MII receive signal timing
No.
Parameter
Min
Max
Unit
1
2
3
4
RXD[3:0], RX_DV, RX_ER to RX_CLK setup
RX_CLK to RXD[3:0], RX_DV, RX_ER hold
RX_CLK pulse width high
5
—
—
ns
5
ns
40%
40%
60%
60%
RX_CLK period
RX_CLK period
RX_CLK pulse width low
MPC5675K Microcontroller Data Sheet, Rev. 8.1
122
NXP Semiconductors
Electrical characteristics
3
RX_CLK (input)
4
RXD[3:0] (inputs)
RX_DV
RX_ER
1
2
Figure 45. MII receive signal timing diagram
3.22.8.2 MII transmit signal timing (TXD[3:0], TX_EN, TX_ER, TX_CLK)
The transmitter functions correctly up to a TX_CLK maximum frequency of 25 MHz +1%. There is no minimum frequency
requirement. In addition, the system clock frequency must exceed two times the TX_CLK frequency.
The transmit outputs (TXD[3:0], TX_EN, TX_ER) can be programmed to transition from either the rising or falling edge of
TX_CLK, and the timing is the same in either case. This options allows the use of non-compliant MII PHYs.
Refer to the Ethernet chapter for details of this option and how to enable it.
1
Table 73. MII transmit signal timing
No.
Parameter
Min
Max
Unit
5
6
7
8
TX_CLK to TXD[3:0], TX_EN, TX_ER invalid
TX_CLK to TXD[3:0], TX_EN, TX_ER valid
TX_CLK pulse width high
5
—
25
ns
—
ns
40%
40%
60%
60%
TX_CLK period
TX_CLK period
TX_CLK pulse width low
1
Output pads configured with SRC = 0b11.
7
TX_CLK (input)
5
8
TXD[3:0] (outputs)
TX_EN
TX_ER
6
Figure 46. MII transmit signal timing diagram
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
123
Electrical characteristics
3.22.8.3 MII async inputs signal timing (CRS and COL)
1
Table 74. MII async inputs signal timing
No.
Parameter
CRS, COL minimum pulse width
Min
Max
Unit
9
1.5
—
TX_CLK period
1
Output pads configured with SRC = 0b11.
CRS, COL
9
Figure 47. MII async inputs timing diagram
3.22.8.4 MII serial management channel timing (MDIO and MDC)
The FEC functions correctly with a maximum MDC frequency of 5 MHz.
1
Table 75. MII serial management channel timing
No.
Parameter
Min
Max
Unit
10 MDC falling edge to MDIO output invalid (minimum propagation delay)
11 MDC falling edge to MDIO output valid (max prop delay)
12 MDIO (input) to MDC rising edge setup
13 MDIO (input) to MDC rising edge hold
14 MDC pulse width high
0
—
—
25
ns
ns
ns
10
—
0
—
ns
40%
40%
60%
60%
MDC period
MDC period
15 MDC pulse width low
1
Output pads configured with SRC = 0b11.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
124
NXP Semiconductors
Electrical characteristics
14
15
MDC (output)
MDIO (output)
10
11
MDIO (input)
12
Figure 48. MII serial management channel timing diagram
13
3.22.9 External Bus Interface (EBI) timing
Table 76. EBI timing
45 MHz (Ext. Bus Freq)1
No.
Symbol
Parameter
Unit
Notes
Min
Max
1
tC
CC D_CLKOUT period
22.2
—
ns Signals are measured
at 50% VDDE
.
2
3
4
5
tCDC CC D_CLKOUT duty cycle
45%
—
55%
—
tC
ns
ns
ns
—
—
—
—
tCRT
tCFT
CC D_CLKOUT rise time
CC D_CLKOUT fall time
—
—
tCOH CC D_CLKOUT posedge to output
signal invalid or high Z (hold time)
1.0
—
D_ADD[9:30]
D_BDIP
D_CS[0:3]
D_DAT[0:15]
D_OE
D_RD_WR
D_TA
D_TS
D_WE[0:3]/D_BE[0:3]
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
125
Electrical characteristics
Table 76. EBI timing (continued)
45 MHz (Ext. Bus Freq)1
No.
Symbol
Parameter
Unit
Notes
Min
Max
6
tCOV CC D_CLKOUT posedge to output
signal valid (output delay)
—
10
ns
—
D_ADD[9:30]
D_BDIP
D_CS[0:3]
D_DAT[0:15]
D_OE
D_RD_WR
D_TA
D_TS
D_WE[0:3]/D_BE[0:3]
7
tCIS
CC Input signal valid to D_CLKOUT
posedge (setup time)
7.5
—
ns
—
D_ADD[9:30]
D_DAT[0:15]
D_RD_WR
D_TA
D_TS
8
tCIH
CC D_CLKOUT posedge to input signal
invalid (hold time)
1.0
—
ns
—
D_ADD[9:30]
D_DAT[0:15]
D_RD_WR
D_TA
D_TS
9
tAPW CC D_ALE pulse width
6.5
1.5
—
—
ns The timing is for
asynchronous
external memory
system.
10
tAAI
CC D_ALE negated to address invalid
ns
• The timing is for
asynchronous
external memory
system.
• ALE is measured at
50% of VDDE.
1
Speed is the nominal maximum frequency. Maximum core speed allowed is 180 MHz plus frequency modulation
(FM).
MPC5675K Microcontroller Data Sheet, Rev. 8.1
126
NXP Semiconductors
Electrical characteristics
VOH_F
VDDE / 2
VOL_F
D_CLKOUT
2
3
2
4
1
Figure 49. D_CLKOUT timing
VDDE / 2
D_CLKOUT
6
5
5
Output
Bus
VDDE / 2
6
5
5
Output
Signal
VDDE / 2
6
Output
Signal
VDDE / 2
Figure 50. Synchronous output timing
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
127
Electrical characteristics
D_CLKOUT
VDDE / 2
7
8
Input
Bus
VDDE / 2
7
8
Input
Signal
VDDE / 2
Figure 51. Synchronous input timing
ipg_clk
D_CLKOUT
D_ALE
D_TS
D_ADD/D_DAT
DATA
ADDR
9
10
Figure 52. ALE signal timing
MPC5675K Microcontroller Data Sheet, Rev. 8.1
128
NXP Semiconductors
Electrical characteristics
3.22.10 I2C timing
2
Table 77. I C SCL and SDA input timing specifications
Value
Min Max
No.
Symbol
Parameter
Unit
1
2
3
4
5
6
7
—
—
—
—
—
—
—
D Start condition hold time
D Clock low time
2
8
—
—
—
—
—
—
—
IP bus cycle1
IP bus cycle1
ns
D Data hold time
0.0
4
D Clock high time
IP bus cycle1
D Data setup time
0.0
2
ns
D Start condition setup time (for repeated start condition only)
D Stop condition setup time
IP bus cycle1
IP bus cycle1
2
1
Inter Peripheral Clock is the clock at which the I2C peripheral is working in the device.
2
Table 78. I C SCL and SDA output timing specifications
Value
No.
Symbol
Parameter
Unit
Min Max
11
21
33
41
51
61
71
81
91
—
—
—
—
—
—
—
—
—
D Start condition hold time
D Clock low time
6
—
—
IP bus cycle2
IP bus cycle1
ns
10
—
7
D SCL/SDA rise time
D Data hold time
99.6
—
IP bus cycle1
D SCL/SDA fall time
D Clock high time
—
10
2
99.5
—
ns
IP bus cycle1
IP bus cycle1
IP bus cycle1
IP bus cycle1
D Data setup time
—
D Start condition setup time (for repeated start condition only)
D Stop condition setup time
20
10
—
—
1
Programming IBFD (I2C bus Frequency Divider) with the maximum frequency results in the minimum output timings
listed. The I2C interface is designed to scale the data transition time, moving it to the middle of the SCL low period.
The actual position is affected by the prescale and division values programmed in IFDR.
2
3
Inter Peripheral Clock is the clock at which the I2C peripheral is working in the device.
Because SCL and SDA are open-drain-type outputs, which the processor can only actively drive low, the time SCL
or SDA takes to reach a high level depends on external signal capacitance and pullup resistor values.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
129
Electrical characteristics
2
6
5
SCL
3
1
8
4
7
9
SDA
2
Figure 53. I C input/output timing
3.22.11 LINFlex timing
The maximum bit rate is 1.875 MBit/s.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
130
NXP Semiconductors
Package characteristics
4
Package characteristics
Package mechanical data
257 MAPBGA
4.1
4.1.1
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
131
Package characteristics
Figure 54. 257 MAPBGA mechanical data (1 of 2)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
132
NXP Semiconductors
Package characteristics
Figure 55. 257 MAPBGA mechanical data (2 of 2)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
133
Package characteristics
4.1.2
473 MAPBGA
Figure 56. 473 MAPBGA package mechanical data (1 of 3)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
134
NXP Semiconductors
Package characteristics
Figure 57. 473 MAPBGA package mechanical data (2 of 3)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
135
Package characteristics
Figure 58. 473 MAPBGA package mechanical data (3 of 3)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
136
NXP Semiconductors
Orderable parts
5
Orderable parts
M PC 5675K F F0 M MM 2 R
Qualification status
Core code
Device number
Device feature set
Device revision
Temperature range
Package identifier
Operating frequency
Tape and reel status
Device feature set
Device revision
Temperature range
Package identifier
F = FlexRay
F0 = Fab and Mask
V = –40 °C to 105 °C
M = –40 °C to 125 °C
(ambient)
MM = 257 BGA
MS= 473 BGA
Operating frequency
Tape and reel status
1 = 150 MHz
2 = 180 MHz
R = Tape and reel
(blank) = Trays
Qualification status
P = Pre-qualification
M = Fully spec. qualified, general market flow
S = Fully spec. qualified, automotive flow
Note: Not all options are available on all devices.
6
Reference documents
1. Nexus (IEEE-ISTO 5001™—2008)
2. Measurement of emission of ICs—IEC 61967-2
3. Measurement of emission of ICs—IEC 61967-4
4. Measurement of immunity of ICs—IEC 62132-4
5. Semiconductor Equipment and Materials International
3081 Zanker Road
San Jose, CA 95134 USA
(408) 943-6900
6. JEDEC specifications are available at http://www.jedec.org
7. MIL-SPEC and EIA/JESD (JEDEC) specifications are available from Global Engineering Documents at
800-854-7179 or 303-397-7956.
8. C.E. Triplett and B. Joiner, “An Experimental Characterization of a 272 PBGA Within an Automotive Engine
Controller Module,” Proceedings of SemiTherm, San Diego, 1998, pp. 47–54.
9. G. Kromann, S. Shidore, and S. Addison, “Thermal Modeling of a PBGA for Air-Cooled Applications,” Electronic
Packaging and Production, pp. 53–58, March 1998.
10. B. Joiner and V. Adams, “Measurement and Simulation of Junction to Board Thermal Resistance and Its Application
in Thermal Modeling,” Proceedings of SemiTherm, San Diego, 1999, pp. 212–220.
7
Document revision history
Table 79 summarizes revisions to this document.
Beginning with Rev. 4, this revision history uses clickable cross-references for ease of navigation. The numbers and titles in
each cross-reference are relative to the latest published release.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
137
Document revision history
Table 79. Revision history
Description of Changes
Revision
Date
1
2
6 Oct 2009 Initial release.
6 Dec 2009 Updated ball map tables, pin mux tables, supply and system pin tables.
Added PMC specifications.
3
4
2 Jul 2010 Updated ball map tables, pin mux tables, supply and system pin tables.
Updated pad specifications.
Added reset specifications section.
30 Apr 2011 Removed thickness dimension from package diagrams on cover page.
Added footnote “Do not connect pin directly to a power supply or ground” for MDO[0:15]
and MSEO[0:1] pins to Table 9 (257 MAPBGA pin multiplexing) and Table 10
(473 MAPBGA pin multiplexing).
In Table 17 (PMC electrical specifications):
• Added minimum and maximum slew rate specifications for LvdReg.
• Removed LvdC minimum and maximum hysteresis specifications
• Removed HvdC minimum and maximum hysteresis specifications
• Corrected HvcD nominal hysteresis from 1.32 to 1.36
In Table 18 (VRC SMPS recommended external devices), updated specifications for
device Q (FET).
Renamed Section 3.9, Supply current characteristics (was “Power dissipation and current
consumption”).
Renamed Table 19 (Current consumption characteristics) (was “Power dissipation
characteristics”).
In Table 19 (Current consumption characteristics):
• Updated ADC current consumption to 1.2 mA per ADC plus 0.7 mA (2.0 mA total) for
ADC0.
• Updated Run IDD to 900 mA max.
Updated Accuracy specification in Table 20 (Temperature sensor electrical
characteristics): changed “TJ = –40 °C to TA = 25 °C” to “TJ = –40 °C to TA = 125 °C,”
removed row “TJ = TA to 125 °C”.
In Table 21 (Main oscillator electrical characteristics), added symbol name FXOSCHS for
Oscillator frequency specification.
Removed “Typical” figures for these specifications.
Added footnote “ADC0 includes 0.7 mA dissipation for the temperature sensor (TSENS).”
In Table 22 (FMPLL electrical characteristics), added minimum and maximum values for
specification fFREE, “Free running frequency.”
In Table 23 (RC oscillator electrical characteristics):
• Added specification ΔIRCTRIM “Internal RC oscillator trimming step.”
• Removed specification ΔRCTRIM “Post trim accuracy: The variation of the PTF from the
16 MHz” (specification replaced by ΔIRCTRIM “Internal RC oscillator trimming step”).
In Table 24 (ADC conversion characteristics), updated Gain Error (GNE) to “min = –4 max
= +4 LSB“.
Added Table 30 (Code flash write access timing) and Table 31 (Data flash write access
timing).
MPC5675K Microcontroller Data Sheet, Rev. 8.1
138
NXP Semiconductors
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
5
6 Dec 2011 Editorial changes.
Enabled the use of cross-references in this revision-history table beginning with Rev. 4.
Changed title of Section 1, Introduction (was “Overview”).
Added section headings: Section 1.1, Document overview, Section 1.2, Description
In Table 1 (MPC5675K family device comparison):
• Revised the DSPI entry to reflect the proper number of chip selects on MPC5675K and
MPC5674K.
• Revised the FlexRay entry (was optional for all chips, is present on MPC5675K and
optional on the others).
• Deleted the “Clock output” entry.
In Figure 1 (MPC5675K block diagram), added SWT_0 and SWT_1.
In Section 1.6.3, Memory Protection Unit (MPU), deleted "The Memory Protection Unit
splits the physical memory into 16 different regions."
In Section 1.6.11, DRAM controller, deleted “DDR 2 (optional)”.
Revised Section 1.6.14, Deserial Serial Peripheral Interface (DSPI) modules, to reflect the
accurate number of available chip selects.
In Section 1.6.16, FlexCAN, deleted “Safety CAN features on 1 CAN module as
implemented on MPC5604P”.
In Table 17 (PMC electrical specifications):
• Removed Min and Max values for LVD 1.2 V variation at reset, LVD 1.2 V variation after
reset, LVD 1.2 V hysteresis, HVD 1.2 V variation at reset, HVD 1.2 V variation after
reset, and HVD 1.2 V hysteresis.
• Updated Nominal HVD 1.2 V Typ value to 1.36 V.
In Table 18 (VRC SMPS recommended external devices), updated the "Part description",
“Nominal”, and "Description" columns for reference designator Q.
In Table 22 (FMPLL electrical characteristics):
• Updated fREF_CRYSTAL and fREF_EXT min to 4 MHz; max to 120 MHz. For this spec, added
footnote: “PFD clock range is 4– 16 MHz. An appropriate IDF should be chosen to
divide the reference frequency to this range.”
• Updated fPLL_IN min to 4 MHz; max to 16 MHz.
• Updated fFREE min to 19 MHz; max to 60 MHz.
• Updated tlpll max to 200 µs.
• Updated tdc min to 20%; max to 80%.
• Updated CJITTER max peak-to-peak to 160 ps; removed min. Added footnote on
condition: “Core operating at 180 MHz.” Updated long-term jitter max to 6 ns.
• Updated fLCK min to –4%; max to +4%.
• Updated fUL min to –16%; max to +16%.
• Updated Modulation Depth fCS min to ±0.25%; max to±4%; fDS min to –0.5%; max to
–8%.
• Removed fMOD min; updated max to 35 kHz for LDF > 63; (2240/LDF) kHz for
31 < LDF < 63.
In Table 23 (RC oscillator electrical characteristics), changed the temperature in the
condition for fRC (was 27 °C, is 25 °C).
In Table 24 (ADC conversion characteristics), changed the maximum specification for DNL
(was 1.0 LSB, is 2 LSB).
In Section 3.18, PDI pads specifications:
• Changed bullet “VDD_HV_PDI range” to “VDD_HV_PDI range 1.8 V to 3.3 V, as
specified in the following tables” and removed sub-bullets.
• Consolidated the three sets of DC and AC specifications (for 1.8 V, 2.5 V, and 3.3 V)
into one set of specifications spanning the range 1.62–3.6 V. (Section headers 3.18.1,
3.18.2, and 3.18.3 removed, and titles of Table 38 (PDI pads DC electrical
characteristics), Table 39 (Drive current), and Table 40 (PDI pads AC electrical
characteristics) changed.)
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
139
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
5
6 Dec 2011 In Section 3.19, DRAM pad specifications, added the note “0.7 V overshoot/undershoot
can be allowed to occur repeatedly throughout the product expected lifetime and will
not cause any long term reliability issue.”
(cont.)
In Table 45 (DRAM pads DC electrical specifications (VDD_HV_DRAM = 3.3 V)):
• Updated VDD_HV_DRAM_VTT minimum value to VDD_HV_DRAM_VREF – 0.05 (changed
“×” to “–”)
• Updated VIL maximum value to VDD_HV_DRAM_VREF – 0.2 (changed “×” to “–”)
• Removed ODT conditions for VOH and VOL
.
• Updated VOL maximum value to VDD_HV_DRAM_VTT – 0.8 (changed “×” to “–”)
In Table 48 (DRAM pads DC electrical specifications (VDD_HV_DRAM = 2.5 V)), removed
ODT conditions for VOH and VOL
.
In Table 51 (DRAM pads DC electrical specifications (VDD_HV_DRAM = 1.8 V)):
• Changed the minimum specification for VDD_HV_DRAM (was 1.7 V, is 1.62 V).
• Removed ODT conditions for VOH and VOL
• Updated VOH minimum value to 1.42 V
• Updated VOL maximum value to 0.28 V
.
Added Section 3.20.2, RESET_SUP_B pin characteristics.
Updated Note under Section 3.21.4.2, External VREG mode.
Updated Figure 18 (External VREG mode, RESET_SUP rises after VDD_HV_xxx are
stable) to add TRSTSUP
.
Added Section 3.22.2.1, Standard interface timing, and revised the specifications in
Table 62 (JTAG pin AC electrical characteristics).
Added Section 3.22.2.2, Interface timing for Full Cycle mode.
Replaced the contents of Section 3.22.3, Nexus timing, with the following:
• Table 64 (Nexus debug port timing Div mode = 2) and Figure 29 (Nexus SDR (Even
divisor) timing)
• Table 65 (Nexus debug port timing Divide by 3 SDR mode) and Figure 30 (Nexus SDR
output timing for DIV=3)
• Table 66 (Nexus debug port timing DIVIDE by 4 DDR mode) and Figure 31 (Nexus DDR
mode timing)
In Section 5, Orderable parts, updated the orderable part numbers.
Updated the entry for Rev. 4 in this revision history.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
140
NXP Semiconductors
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
6
6 Feb 2012 In Section 1.5, Feature list, removed “Replicated 32 channel eDMA controller” under
“Interrupts”.
In Table 9 (257 MAPBGA pin multiplexing), changed “A2: ebi_Dn” to “A2: ebi_ADn“ for
balls H17, J17, K14, AND K15.
In Table 10 (473 MAPBGA pin multiplexing), changed “A2: ebi_Dn” to “A2: ebi_ADn“ for
balls C22, D22, F21, F23, G20, G21, G22, G23, H20, J20, J21, J22, J23, K21, K22,
K23, M22, M23, N20, N21, N22, N23, P20, P21, T20, T21, U21, V21, W21, Y21, Y22,
and AA23.
In Table 11 (Absolute maximum ratings):
• Removed “incl. analog pins TBD” for IINJPAD
.
• Added numerical data to Note 3.
In Table 17 (PMC electrical specifications), added min/max information for LvdC and
HvdC.
In Table 21 (Main oscillator electrical characteristics), split “Oscillator start-up time” into
two lines and added numerical data.
In Table 22 (FMPLL electrical characteristics):
• Added line numbers to table.
• Changed TBD to “—“ and added numerical data for fsys
• Changed TBDs to numerical data for fLORL, fLORH, and fSCM
• Changed TBD to “—“ for Cjitter
.
.
.
In Table 24 (ADC conversion characteristics):
• Changed tADC_E conditions from TBD to 60 MHz.
• Changed CP2 max value from TBD to 0.8 pF.
• Added a footnote to TUE specs noting that sample averaging is required.
• Changed TUE min and max values from TBDs to numerical data.
• Changed THD min value from TBD to –72 dB.
In Table 25 (Code flash memory program and erase electrical specifications), Table 26
(Data flash memory program and erase electrical specifications), Table 28 (Code flash
read access timing) and Table 29 (Data flash read access timing), corrected the line
numbering.
In Table 30 (Code flash write access timing):
• Removed fWRITE for 60 MHz.
• Corrected the line numbering.
• Changed TBD to “—“.
In Table 31 (Data flash write access timing):
• Removed fWRITE for 60 MHz.
• Corrected the line numbering.
• Changed TBD to “—“.
In Table 32 (System SRAM memory read/write access timing):
• Changed name from “read access timing” to “read/write access timing”.
• Changed symbol to sREAD/WRITE
.
• Removed sREAD/WRITE for 60 MHz.
Removed table “System SRAM memory write access timing”.
In Table 38 (PDI pads DC electrical characteristics), corrected the line numbering.
In Table 61 (DDR and DDR2 (DDR2-400) SDRAM timing specifications):
• removed tDQSEN and the associated footnotes.
• Corrected the line numbering.
In Table 62 (JTAG pin AC electrical characteristics), corrected the line numbering.
In Table 67 (External interrupt timing (NMI IRQ)):
• Changed TIPWL min value from TBD to 3.
• Changed TIPWH min value from TBD to 3.
• Changed TICYC min value from TBD to 6.
• Changed all units from ns to tCYC
.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
141
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
6
6 Feb 2012 In Table 68 (External interrupt timing (GPIO IRQ)):
• Changed TIPWL min value from TBD to 3.
(cont.)
• Changed TIPWH min value from TBD to 3.
• Changed TICYC min value from TBD to 6.
• Changed all units from ns to tCYC
.
In Table 77 (I2C SCL and SDA input timing specifications), corrected the line numbering.
6.1
7
30 Mar 2012 No content changes, technical or editorial, were made in this revision.
Change bars are identical to those in Rev. 6.
Removed the “preliminary” footers throughout.
Changed “Data Sheet: Advance Information” to “Data Sheet: Technical Data” on page
Removed the “product under development” disclaimer on page 1.
18 May 2012 Minor editorial changes and improvements throughout.
In Section 1.3, Device comparison, Table 1 (MPC5675K family device comparison),
• Changed the CPU/Data Cache entry from "16 KB, 4-way with EDC (SoR)" to "16 KB,
4-way with Parity (SoR)".
• Added footnotes to stipulate the peripheral instances that are used on derivative
devices:
- Added footnote to MPC5673K DSPI module: “DSPI_0 and DSPI_1.“
- Added footnote to MPC5673K I2C module: “I2C_0 and I2C_1.“
- Added footnote to MPC5673K LinFlex module: “LinFlex_0, LinFlex_1, and LinFlex_2“
In Section 1.4, Block diagram:
• Added missing modules (PMC, SPE2, VLE, and flash.
• Added an arrow each from Core_0 and Core_1 to the XBAR modules to represent the
data path.
• Updated the Redundancy Checkers to reflect the actual implementation.
• Renamed the “JTAG/Nexus” block to “Debug”, with JTAG and Nexus shown as
submodules.
In Section 1.5, Feature list, changed “Junction temperature sensor” to “Silicon substrate
(die) temperature sensor”.
In Section 1.6.1, High-performance e200z7d core processor and Section 1.6.9, Cache
memory, removed the bullet “Supports tag and data parity" and added the following
bullets:
— Supports tag and data cache parity
— Supports EDC for instruction cache
In Section 1.6.19, System Timer Module (STM), changed “Duplicated periphery to
guarantee that safety targets (SIL3) are achieved” to “Replicated periphery to provide
safety measures respective to high safety integrity levels (for example, SIL 3, ASIL D)”
In Section 1.6.20.2, Cross Triggering Unit (CTU), changed “DMA support with safety
features” to “Supports safety measures using DMA”.
In Section 1.6.21, Redundancy Control and Checker Unit (RCCU), changed “Duplicated
module to guarantee highest possible diagnostic coverage (check of checker)” to
“Duplicated module to enable high diagnostic coverage (check of checker)”.
In Section 1.6.22, Software Watchdog Timer (SWT),
• Changed “Duplicated periphery to guarantee that safety targets (SIL3) are achieved” to
“Replicated periphery to provide safety measures respective to high safety integrity
levels (for example, SIL 3, ASIL D)”.
• Changed “Allows high level of safety (SIL3 monitor)” to “Provides measures to target
high safety integrity levels (for example, SIL 3, ASIL D)”.
In Section 1.6.25, Cyclic Redundancy Checker (CRC) unit, in the sentence “Key engine to
be coupled with communication periphery where CRC application is added to allow
implementation of safe communication protocol”, changed “allow” to “support”.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
142
NXP Semiconductors
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
7
18 May 2012 In Section 3.2, Absolute maximum ratings, Table 11 (Absolute maximum ratings),
• Deleted footnote to the Max value “Absolute maximum voltages are currently maximum
burn-in voltages. Absolute maximum specifications for device stress have not yet been
determined.”
(cont.)
• Added footnote to VDD_HV_DRAM: “As the VDD_HV_DRAM_VREF supply should always be
constrained by the VDD_HV_DRAM supply for example through a voltage divider network
per the JEDEC specification, the maximum ratings for the VDD_HV_DRAM supply should
be used for the VDD_HV_DRAM_VREF reference as well.”
• Changed absolute max rating for VDD_LV_PLL from 1.4 to 1.32.
• Added footnote to Min value of TSTG: “If the ambient temperature is at or above the
minimum storage temperature and below the recommended minimum operating
temperature, power may be applied to the device safely. However, functionality is not
guaranteed and a power cycle must be administered if in internal regulation mode or an
assertion of RESET_SUP_B must be administered if in external regulation mode once
device enters into the recommended operating temperature range.“
In Section 3.3, Recommended operating conditions, Table 12 (Recommended operating
conditions),
• For TA and TJ, added footnote “When determining if the operating temperature
specifications are met, either the ambient temperature or junction temperature
specification can be used. It is not necessary that both specifications be met at all
times. However, it is critical that the junction temperature specification is not exceeded
under any condition.”
• For TA, changed the Max temperature spec for the 257 package from 105 to 125 and
deleted footnote: “Preliminary data.”
In Section 3.8.1, PMC electrical specifications, Table 17 (PMC electrical specifications),
• No. 4 LvdC and No. 5 HvdC threshold were specified as rising edge and hysteresis. The
specification is changed to rising edge / falling edge.
• Removed No. 6, VddStepC, and renumbered subsequent lines.
In Section 3.9, Supply current characteristics, Table 19 (Current consumption
characteristics), added a footnote to No. 3. Idd_HV_FLA. “The current specified for
Idd_HV_FLA includes current consumed during programming and erase operations.”
In Section 3.12, FMPLL electrical characteristics, Table 22 (FMPLL electrical
characteristics), replaced “fsys” with “fFMPLLOUT” in rows for CJITTER, fLCK, fUL, fCS/fDS
,
and footnote 9.
In Section 3.14.1, Input impedance and ADC accuracy:
• Changed “CS being substantially a switched capacitance...” to “CS and CP2 being
substantially a switched capacitance...”
• Changed “and the sum of RS + RF + RL + RSW + RAD, ...” to “and the sum of RS + RF, ...”
• Changed the equation
R + R + R + R
+ R
S
F
L
SW
AD
1
2
--------------------------------------------------------------------------
V •
< -- LSB
A
R
EQ
R + R
S
F
1
2
--------------------
to
V •
< -- LSB
A
R
EQ
• Added new spec after line 3 for tADC_S_PMC, C: Parameter: Sample time of internal
PMC channels. Conditions: - , Min : 717, Typ : - , Max : - , Unit : nS.
In Section 3.17.1, GP pads DC specifications, Table 33 (GP pads DC electrical
characteristics), added new spec for “Input pad capacitance”, No. 21.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
143
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
7
18 May 2012 In Section 3.18, PDI pads specifications, Table 38 (PDI pads DC electrical
characteristics), added footnote to table: “Over- and undershoots occurring due to
impedance mismatch of the external driver and the transmission line at PDI pads in
input mode can be allowed up to 0.7 V repeatedly throughout the product expected
lifetime and will not cause any long term reliability issue.”
(cont.)
In Section 5, Orderable parts,
• Removed “3 = 220 MHz” under Operating frequency heading and changed the
Operating frequency of the example from “3” to “2”.
• Deleted Table 73 (Orderable part number summary).
MPC5675K Microcontroller Data Sheet, Rev. 8.1
144
NXP Semiconductors
Document revision history
Table 79. Revision history (continued)
Description of Changes
Revision
Date
8
29 October In Table 1 (MPC5675K family device comparison):
2013
• added “(ECC)” to all code flash and data flash memory regions.
• footnote 6 changed to “any two of the three I2C can be chosen”.
• Flexray module made optional for MPC5675K also.
Added new sections - Section 3.17.3, I/O pad current specifications, Section 3.18.1, PDI
pad current specifications and Section 3.19.4, DRAM Pad Current Specifications.
Added new sections - Section 3.17.4, Power Sequence Pin States for GPIO Pads,
Section 3.18.2, Power Sequence Pin States for PDI Pads and Section 3.19.5, Power
Sequence Pin States for DRAM Pads.
In Section 3.22.8.1, MII receive signal timing (RXD[3:0], RX_DV, RX_ER, and RX_CLK),
changed the text from “In addition, the system clock frequency must exceed four times
the RX_CLK frequency.” to “In addition, the system clock frequency must exceed two
times the RX_CLK frequency”.
In Section 3.22.8.2, MII transmit signal timing (TXD[3:0], TX_EN, TX_ER, TX_CLK),
changed the text from “In addition, the system clock frequency must exceed four times
the TX_CLK frequency.” to “In addition, the system clock frequency must exceed two
times the TX_CLK frequency”.
Added a foot note for TCK pin in Table 7 (257 MAPBGA system pins) and Table 8
(473 MAPBGA system pins) - “If LBIST is enabled, an external pull between 1K and
100K ohm must be connected from TCK to either power or ground to avoid LBIST
failures”.
In Table 11 (Absolute maximum ratings), changed max absolute maximum ratings from
3.6 V to 3.63 V for all 3 V rails.
In Table 12 (Recommended operating conditions),
• changed recommended operating conditions from 3.6 V to 3.63 V for all 3 V rails.
• added a footnote for VDD_HV_ADRx - “If this supply is not above its absolute minimum
recommended operating level, LBIST operations can fail”.
Removed the table footnote - “These specifications are design targets and are subject to
change per device characterization” from Table 12 (Recommended operating
conditions), Table 13 (Thermal characteristics for package options), Table 25 (Code
flash memory program and erase electrical specifications), Table 26 (Data flash
memory program and erase electrical specifications) and Table 33 (GP pads DC
electrical characteristics).
In Table 17 (PMC electrical specifications):
• added row for Vadctol
• changed typical value of VDD_LV_COR from 1.28 V to 1.24 V.
• updated voltage levels for VDD_LV_COR LvdC and HvdC.
.
,
• updated the wording for “VDD_LV_COR” parameter.
• added new voltage levels for LvdReg.
• removed “LVD 3.3 V variation at reset”, “LVD 3.3 V variation after reset”, and “LVD 3.3
V hysteresis” entries for “LvdReg” parameter.
In Table 24 (ADC conversion characteristics), added a sentence on 7th table note - “The
ADC1 self test limit for the S2 algorithm needs to be modified by the user to
accommodate for the increased TUE limit of +/-10 counts when operating the device in
internal regulation mode. This can be accomplished by reading the current value from
the test flash and subtracting 4 counts before storing the value to the ADC1 Self Test
Analog Watchdog Register 2 (STAW2R)”.
In Table 26 (Data flash memory program and erase electrical specifications), description
of TDWPROGRAM changed to “Single word (32 bits) program time”.
In Table 33 (GP pads DC electrical characteristics),
• added rows for VILRSB and VIHRSB
.
• in IIL, added two new rows for two new parameters to specify the spec for analog pad
leakage for shared and single ADC pads - “Input leakage current (All single ADC
channels)” and “Input leakage current (All shared ADC channels)”.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
NXP Semiconductors
145
Document revision history
Revision
Date
Description of Changes
8 (Contd..)
29 October 2013 In Table 58 (RESET sequences), changed min values of TDRB and TERLB from 60
to 50 ms and typ values from 65 to 60 ms.
In Table 62 (JTAG pin AC electrical characteristics), updated the footnote to -
“fTCK = 1/tTCK. fTCK must not exceed 1/4 the frequency of the system clock
(SYS_CLK).”
Reverted the first term of Equation 11.
8.1
24 April 2020 Changed Freescale to NXP throughout the data sheet.
MPC5675K Microcontroller Data Sheet, Rev. 8.1
146
NXP Semiconductors
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Document Number: MPC5675K
Rev. 8.1
04/2020
相关型号:
SPC56AP54L5
32-bit Power Architecture® based MCU with 1088 KB Flash memory and 80 KB RAM for automotive chassis and safety applications
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