Freescale MPXR2010VLT80R Pxd20 microcontroller Datasheet

Freescale Semiconductor
Data Sheet: Advance Information
Document Number: PXD20
Rev. 2, 04/2012
PXD20
416 TEPBGA
27 mm x 27 mm
PXD20 Microcontroller Data
Sheet
The PXD20 represents a new generation of 32-bit
microcontrollers targeting single-chip industrial HMI
applications. PXD20 devices are part of the PX family of
Power Architecture®-based devices. This family has been
designed with an emphasis on providing cost-effective and
high quality graphics capabilities.
176 LQFP
24 mm x 24 mm
1
2
PXD20 devices contain 2 MB internal flash memory. Serial
flash memory and DRAM interfaces are provided to allow
even greater system flexibility.
3
The PXD20:
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Includes 2 MB internal flash memory, 1 MB internal
graphics SRAM, and 64 KB system SRAM
Offers high processing performance operating at
speeds up to 125 MHz
Is optimized for low power consumption
The PXD20 is designed to reduce development and
production costs of TFT-based displays by providing a
single-chip solution with the processing and storage capacity
to host and execute real-time application software and drive
TFT displays directly.
The PXD20 features a 2D OpenVG 1.1 graphics accelerator,
Video Input Unit (VIU2) and two on-chip display control
units (DCU3 and DCULite) designed to drive two color TFT
displays simultaneously. The PXD20 includes a enhanced
QuadSPI serial flash controller and an optional DRAM
controller allowing graphics RAM expansion externally.
The PXD20 is compatible with the existing development
infrastructure of current Power Architecture devices and are
supported with software drivers, operating systems and
configuration code to assist with application development.
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Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
1.1 Device comparison . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
1.2 Block diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.3 Feature list . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
1.4 Feature details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Pinout and signal descriptions . . . . . . . . . . . . . . . . . . . . . . . . 24
2.1 176 LQFP package pinout . . . . . . . . . . . . . . . . . . . . . . 24
2.2 208 LQFP package pinout . . . . . . . . . . . . . . . . . . . . . . 25
2.3 416 TEPBGA package pinout–40 to 105°C . . . . . . . . . 26
2.4 Signal description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
System design information. . . . . . . . . . . . . . . . . . . . . . . . . . . 60
3.1 Power-up sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . 60
Electrical characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
4.1 Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
4.2 Parameter classification . . . . . . . . . . . . . . . . . . . . . . . . 62
4.3 Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . 63
4.4 Recommended operating conditions . . . . . . . . . . . . . . 64
4.5 Thermal characteristics . . . . . . . . . . . . . . . . . . . . . . . . 66
4.6 EMI (electromagnetic interference) characteristics . . . 70
4.7 Power management . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
4.8 DC electrical specifications . . . . . . . . . . . . . . . . . . . . . 75
4.9 RESET electrical characteristics . . . . . . . . . . . . . . . . . 84
4.10 Fast external crystal oscillator (4–16 MHz) electrical
characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
4.11 Slow external crystal oscillator (32 KHz) electrical
characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
4.12 FMPLL electrical characteristics. . . . . . . . . . . . . . . . . . 88
4.13 Fast internal RC oscillator (16 MHz) electrical
characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
4.14 Slow internal RC oscillator (128 kHz) electrical
characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
4.15 Flash memory electrical characteristics . . . . . . . . . . . . 90
4.16 ADC parameters. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
4.17 AC specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
4.18 AC timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102
Package mechanical data . . . . . . . . . . . . . . . . . . . . . . . . . . 128
Ordering information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129
This document contains information on a product under development. Freescale reserves the
right to change or discontinue this product without notice.
© Freescale Semiconductor, Inc., 2011–2012. All rights reserved.
Preliminary—Subject to Change Without Notice
208 LQFP
28 mm x 28 mm
Overview
1
Overview
1.1
Device comparison
Table 1. PXD20 Family Feature Set
Feature
Package
PXD20
208 LQFP
176 LQFP
CPU
416 MAPBGA
e200z4d
4 KB Instruction-Cache
16-entry Memory Management Unit (MMU)
Floating Point Unit (FPU)
Signal Processing Extension (SPE)
Execution speed
Static–125 MHz
Flash memory (ECC)
2 MB
RAM (ECC)
64 KB
On-chip graphics RAM (no ECC)
1 MB
MPU
16 entry
eDMA
16 channels
DRAM controller
No
OpenVG Graphics Accelerator
(GFX2D)
Yes
Yes (OpenVG 1.1)
Display Control Unit (DCU3)
Yes
Display Control Unit Lite (DCULite)
No
Yes
Timing Controller (TCON) and RSDS
interface
No
Yes
Video Input Unit (VIU2)
Yes
QuadSPI serial flash interface
Yes
Stepper Motor Controller (SMC)
4 motors
6 motors
Stepper Stall Detect (SSD)
Yes
Sound Generator Module (SGM)
Yes
32 kHz external crystal oscillator
Yes
Real Time Counter and Autonomous
Periodic Interrupt (RTC/API)
Yes
Periodic interrupt timer (PIT)
Software Watchdog Timer (SWT)
System Timer Module (STM)
Timed I/O
8 ch, 32-bit
Yes
4 ch, 32-bit
20 ch, 16-bit: IC / OC / OPWM
8 ch, 16-bit: IC / OC
4 ch, 16-bit: IC / OC / OPWM / QDEC
PXD20 Microcontroller Data Sheet, Rev. 2
2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
Table 1. PXD20 Family Feature Set (continued)
Feature
Package
Analog-to-Digital Converter (ADC)
PXD20
176 LQFP
208 LQFP
16 channels, 10-bit
CAN (64 mailboxes)
416 MAPBGA
20 channels, 10-bit
3 × CAN
CAN sampler
Yes
Serial communication interface
3 × LIN
4 × LIN
SPI
2 × SPI
3 × SPI
I2C
GPIO
Debug
4
128
150
Nexus Class 3 (4MDO)
177
Nexus Class 3 (12MDO)
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
3
Overview
1.2
Block diagram
PXD20 Block Diagram
Crossbar Masters
System
Debug
VREG
JTAG
Oscillator
Nexus
Class 3+
e200z4d Core
(4 KB I-Cache)
FMPLL x 2
RTC/32 kHz
Oscillator
Z160
2D
GFX
VIU2
DCU
Lite
DCU
TCON
RSDS
MMU
Interrupt
Controller
16-ch DMA
Crossbar Switch (XBAR)
Memory Protection Unit (MPU)
PIT
SWT
STM
Boot
Assist
Module
(BAM)
2 MB
Flash
ECC
64 KB
SRAM
1 MB
Graphics
SRAM
RLE
Decode
PBRIDGE
Quad
SPI V02
DRAM
Interface
Crossbar Slaves
Communications I/O System
eMIOS A
16-ch
ADC
CAN
DCU
DMA
DRAM
ECC
eMIOS
FMPLL
GFX
I2 C
JTAG
MMU
PBRIDGE
PIT
RLE
eMIOS B
16-ch
3x
CAN
4x
UART/LIN
– Analog-to-digital converter
– Controller area network controller
– Display control unit
– Direct memory access controller
– Dynamic random-access memory
– Error correction code
– Timed input/output
– Frequency-modulated phase-locked loop
– OpenVG graphics accelerator
– Inter-integrated circuit controller
– Joint Test Action Group interface
– Memory management unit
– Peripheral I/O bridge
– Periodic interrupt timer
– Run length encoding
3x
SPI
4x
I2C
RTC
RSDS
SGM
SMD SSD
SPI
SRAM
STM
SWT
TCON
UART/LIN
VIU2
VLE
VREG
SGM
20-ch
ADC
10-bit
SSD
6x
SMD
– Real time clock
– Reduced-swing differential sgnal interface
– Sound generator module
– Stepper motor driver/stepper stall detect
– Serial peripheral interface controller
– Sraric random-access memory
– System timer module
– Software watchdog timer
– Timing controller
– Universal asynchronous receiver/transmitter/
local interconnect network
– Video input unit
– Variable-length execution set
– Voltage regulator
Figure 1. PXD20 block diagram
PXD20 Microcontroller Data Sheet, Rev. 2
4
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
1.3
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Feature list
Dual-issue, 32-bit Power Architecture Book E compliant CPU core complex (e200z4d)
— Memory Management Unit (MMU)
— 4 KB, 2/4-way instruction cache
2 MB on-chip ECC flash memory with:
— Flash memory controller
— Prefetch buffers
64 KB on-chip ECC SRAM
1 MB on-chip non-ECC graphics SRAM with two-port graphics SRAM controller
Memory Protection Unit (MPU) with up to 16 region descriptors and 32-byte region granularity to provide basic
memory access permission and ensure separation between different codes and data
Interrupt Controller (INTC) with 181 peripheral interrupt sources and eight software interrupts
Two Frequency-Modulated Phase-Locked Loops (FMPLLs)
— Primary FMPLL (FMPLL0) provides a system clock up to 125 MHz
— Auxiliary FMPLL (FMPLL1) is available for use as an alternate, modulated or non-modulated clock source to
eMIOS modules, QuadSPI and as alternate clock to the DCU and DCU-Lite for pixel clock generation
Crossbar switch architecture enables concurrent access of peripherals, flash memory or RAM from multiple bus
masters
16-channel Enhanced Direct Memory Access controller (eDMA) with multiple transfer request sources using a DMA
channel multiplexer
Boot Assist Module (BAM) with 8 KB dedicated ROM for embedded boot code supports boot options including
download of boot code via a serial link (CAN or SCI)
Two Display Control Units (DCU3 and DCULite) for direct drive of up to two TFT LCD displays up to XGA
resolution
Timing Controller (TCON) and RSDS interface for the DCU3 module
2D OpenVG 1.1 and raster graphics accelerator (GFX2D)
Video Input Unit (VIU2) supporting 8/10-bit ITU656 video input, YUV to RGB conversion, video down-scaling,
de-interlacing, contrast adjustment and brightness adjustment.
DRAM controller supporting DDR1, DDR2, LPDDR1 and SDR DRAMs
Stepper Motor Controller (SMC)
— High-current drivers for as many as six stepper motors driven in full dual H-bridge configuration
— Stepper motor return-to-zero and stall detection module
— Stepper motor short circuit detection
Sound Generator Module (SGM)
— 4-channel mixer
— Supports PCM wave playback and synthesized tones
— Optional PWM or I2S outputs
Two 16-channel Enhanced Modular Input Output System (eMIOS) modules
— Support a range of 16-bit Input Capture, Output Compare, Pulse Width Modulation and Quadrature Decode
functions
10-bit Analog-to-Digital Converter (ADC) with a maximum conversion time of 1 s
— Up to 20 internal channels
— Up to 8 external channels
Three Deserial Serial Peripheral Interface (DSPI) modules for full-duplex, synchronous, communications with
external devices
QuadSPI serial flash memory controller
— Supports single, dual and quad IO serial flash memory
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
5
Overview
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— Interfaces to external, memory-mapped serial flash memories
— Supports simultaneous addressing of 2 external serial flashes to achieve up 80 MB/s read bandwidth
RLE decoder supporting memory to memory decoding of RLE data in conjunction with eDMA
Four local interconnect network (LINFlex) controller modules
— Capable of autonomous message handling (master), autonomous header handling (slave mode), and UART
support
— Compliant with LIN protocol rev 2.1
Three controller-area network (FlexCAN) modules
— Compliant with the CAN protocol version 2.0 C
— 64 configurable buffers
— Programmable bit rate of up to 1 Mb/s
Four Inter-Integrated Circuit (I2C) internal bus controllers with master/slave bus interface
Low-power loop controlled pierce crystal oscillator supporting 4–16MHz external crystal or resonator
Real Time Counter (RTC) with clock source from internal 128 kHz or 16 MHz oscillator supporting autonomous
wake-up with 1 ms resolution with maximum timeout of 2 seconds
— Support for real time counter (RTC) with clock source from external 32 KHz crystal oscillator, supporting
wake-up with 1 s resolution and maximum timeout of one hour
— RTC optionally clocked by fast 4–16 MHz external oscillator
System timers:
— Four-channel 32-bit System Timer Module (STM)
— Eight-channel 32-bit Periodic Interrupt Timer (PIT) module (including ADC trigger)
— Software Watchdog Timer (SWT)
System Integration Unit Lite (SIUL) module to manage external interrupts, GPIO and pad control
System Status and Configuration Module (SSCM)
— Provides information for identification of the device, last boot mode, or debug status
— Provides an entry point for the censorship password mechanism
Clock Generation Module (MC_CGM) to generate system clock sources and provide a unified register interface,
enabling access to all clock sources
Clock Monitor Unit (CMU)
— Monitors the integrity of the fast (4–16 MHz) external crystal oscillator and the primary FMPLL (FMPLL0)
— Acts as a frequency meter, measuring the frequency of one clock source and comparing it to a reference clock
Mode Entry Module (MC_ME)
— Controls the device power mode, i.e., RUN, HALT, STOP, or STANDBY
— Controls mode transition sequences
— Manages the power control, voltage regulator, clock generation and clock management modules
Power Control Unit (MC_PCU) to implement standby mode entry/exit and control connections to power domains
Reset Generation Module (MC_RGM) to manage reset assertion and release to the device at initial power-up
Nexus Development Interface (NDI) per IEEE-ISTO 5001-2008 Class 3 standard with additional Class 4 features:
— Watchpoint Triggering
— Processor Overrun Control
Device/board boundary-scan testing supported per Joint Test Action Group (JTAG) of IEEE (IEEE 1149.1)
On-chip voltage regulator controller for regulating the 3.3–5 V supply voltage down to 1.2 V for core logic (requires
external ballast transistor)
Package:1
— 176 LQFP, 0.5 mm pitch, 24 mm  24 mm outline
1. See the device comparison table for package offerings for each device in the family.
PXD20 Microcontroller Data Sheet, Rev. 2
6
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
— 208 LQFP, 0.5 mm pitch, 28 mm  28 mm outline
— 416 TEPBGA, 1mm ball pitch, 27 mm  27 mm outline
1.4
1.4.1
Feature details
Low-power operation
The PXD20 is designed for optimized low-power operation and dynamic power management of the CPU and peripherals.
Power management features include software-controlled clock gating of peripherals and multiple power domains to minimize
leakage in low-power modes.
There are three low-power modes:
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STANDBY
STOP
HALT
and five dynamic power modes — RUN[0..3] and DRUN. All low-power modes use clock gating to halt the clock for all or part
of the device.
STANDBY mode turns off the power to the majority of the chip to offer the lowest power consumption mode.
The device can be awakened from STANDBY mode via from any of up to 23 I/O pins, a reset or from a periodic wake-up using
a low power oscillator. If required, it is possible to enable the internal 16 MHz oscillator, the external 4–16 MHz oscillator and
the external 32 KHz oscillator.
In STANDBY mode the contents of the CPU, on-chip peripheral registers and potentially some of the volatile memory are lost.
The two possible configurations in STANDBY mode are:
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The device retains 64 KB of the on-chip SRAM, but the content of the graphics SRAM is lost.
The device retains 8 KB of the on-chip SRAM, but the content of the graphics SRAM is lost.
STOP mode maintains power to the entire device allowing the retention of all on-chip registers and memory, and providing a
faster recovery low power mode than the lowest-power STANDBY mode. There is no need to reconfigure the device before
executing code. The clocks to the CPU and peripherals are halted and can be optionally stopped to the oscillator or PLL at the
expense of a slower start-up time.
STOP is entered from RUN mode only. Wake-up from STOP mode is triggered by an external event or by the internal periodic
wake-up, if enabled.
RUN modes are the main operating modes where the entire device can be powered and clocked and from which most processing
activity is done. Four dynamic RUN modes are supported—RUN0 - RUN3. The ability to configure and select different RUN
modes enables different clocks and power configurations to be supported with respect to each other and to allow switching
between different operating conditions. The necessary peripherals, clock sources, clock speed and system clock prescalers can
be independently configured for each of the four RUN modes of the device.
HALT mode is a reduced activity, low power mode intended for moderate periods of lower processing activity. In this mode the
CPU system clocks are stopped but user-selected peripheral tasks can continue to run. It can be configured to provide more
efficient power management features (switch-off PLL, flash memory, main regulator, etc.) at the cost of longer wake up latency.
The system returns to RUN mode as soon as an event or interrupt is pending.
Table 2 summarizes the operating modes of the PXD20.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
7
Overview
Table 2. Operating mode summary1
16 MHz IRC
4–16 MHz OSC
128 kHz IRC
32 KHz X OSC
Periodic Wake-up
Wake-up input
VREG mode
VREG start-up
IRC Wake-up
Flash Recovery
OSC Stabilization
PLL Lock
S/W Reconfig
Mode switch over
On
OP OP
On
OP
On
OP
—
—
FP
—
—
—
—
—
—
—
On
OP OP
On
OP
On
OP OP OP
FP
—
—
—
—
—
—
TBD
On CG CG OP OP
On
OP OP OP
LP 350 µs 4 µs 20 µs 1 ms 200 µs — 24 µs
Auxiliary PLL
Primary PLL
OP OP OP
Flash
Graphics RAM
On
Wake-up time2
Clock sources
RAM
RUN
Peripherals
CPU
GFX accelerator
DRAM controller
Operating mode
SoC features
3
HALT
CG
OP OP OP
3
STOP
CG
CG CG OP
3
STANDBY
Off
Off
Off
64 Off
KB4
Off
Off
OP OP OP OP OP OP
LP 350 µs 8 µs 100 µs 1 ms 200 µs Var 28 µs
Off
Off
Off
8 Off
KB5
Off
Off
OP OP OP OP OP OP
LP 200 µs 8 µs 100 µs 1 ms 200 µs Var 28 µs
POR
500 µs 8 µs 100 µs 1 ms 200 µs
BAM
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Table Key:
On—Powered and clocked
OP—Optionally configurable to be enabled or disabled (clock gated)
CG—Clock Gated, Powered but clock stopped
Off-—Powered off and clock gated
FP—VREG Full Performance mode
LP—VREG Low Power mode, reduced output capability of VREG but lower power consumption
Var—Variable duration, based on the required reconfiguration and execution clock speed
BAM—Boot Assist Module Software and Hardware used for device start-up and configuration
A high level summary of some key durations that need to be considered when recovering from low power modes. This
does not account for all durations at wake up. Other delays will be necessary to consider including, but not limited to the
external supply start-up time.
IRC Wake-up time must not be added to the overall wake-up time as it starts in parallel with the VREG.
All other wake-up times must be added to determine the total start-up time.
Either 64 KB or 8 KB available.
64 KB of the RAM contents is retained, but not accessible in STANDBY mode.
8 KB of the RAM contents is retained, but not accessible in STANDBY mode.
Dependent on boot option after reset.
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Additional notes on low power operation:
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Fast wake-up using the on-chip 16 MHz internal RC oscillator allows rapid execution from RAM on exit from low
power modes
The 16 MHz internal RC oscillator supports low speed code execution and clocking of peripherals when it is selected
as the system clock and can also be used as the PLL input clock source to provide fast start-up without the external
oscillator delay
The device includes an internal voltage regulator that includes the following features:
PXD20 Microcontroller Data Sheet, Rev. 2
8
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
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Regulates input to generate all internal supplies
Manages power gating
External ballast transistor for high power regulator
Low-Power and Ultra-Low-Power regulators support operation when in STOP and STANDBY modes,
respectively, to minimize power consumption
— Startup on-chip regulators in <350 µs for rapid exit of STOP and STANDBY modes
— Low voltage detection on main supply and 1.2 V regulated supplies.
1.4.2
e200z4d core
The e200z4d Power Architecture core provides the following features:
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1.4.3
Dual issue, 32-bit Power Architecture Book E compliant CPU
Implements the VLE APU for reduced code footprint
In-order execution and retirement
Precise exception handling
Branch processing unit
— Dedicated branch address calculation adder
— Branch target prefetching using 8-entry BTB
Supports independent instruction and data accesses to different memory subsystems, such as SRAM and Flash memory
via independent Instruction and Data BIUs.
Load/store unit
— 2 cycle load latency
— Fully pipelined
— Big and Little endian support
— Misaligned access support
64-bit General Purpose Register file
Dual AHB 2.v6 64-bit System buses
Memory Management Unit (MMU) with 16-entry fully-associative TLB and multiple page size support
4 KB, 2/4-Way Set Associative Instruction Cache
Signal Processing Extension (SPE1.1) APU supporting SIMD fixed-point operations using the 64-bit General Purpose
Register file.
Embedded Floating-Point (EFP2) APU supporting scalar and vector SIMD single-precision floating-point operations,
using the 64-bit General Purpose Register file.
Nexus Class 3 real-time Development Unit
Dynamic power management of execution units, cache and MMU
Crossbar switch (XBAR)
The XBAR multi-port crossbar switch supports simultaneous connections between seven master ports and eight slave ports.
The crossbar supports a 32-bit address bus width and a 64-bit data bus width.
The crossbar allows concurrent transactions to occur from any master port to any slave port but one of those transfers must be
an instruction fetch from internal flash. If a slave port is simultaneously requested by more than one master port, arbitration
logic selects the higher priority master and grants it ownership of the slave port. All other masters requesting that slave port are
stalled until the higher priority master completes its transactions. Requesting masters having equal priority are granted access
to a slave port in round-robin fashion, based upon the ID of the last master to be granted access.
The crossbar provides the following features:
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
9
Overview
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1.4.4
Seven master ports:
— e200z4d core instruction port
— e200z4d core complex load/store data port
— eDMA controller
— DCU
— DCU-Lite
— VIU
— 2D Graphics Accelerator (GFX2D)
Seven slave ports:
— Platform Flash Controller (2 Ports)
— Platform SRAM Controller
— Graphics SRAM Controller (2 Ports)
— QuadSPI serial flash Controller and RLE Decoder
— Peripheral Bridge
32-bit internal address bus, 64-bit internal data bus
Programmable Arbitration Priority
— Requesting masters can be treated with equal priority and will be granted access to a slave port in round-robin
fashion, based upon the ID of the last master to be granted access or a priority order can be assigned by software
at application run time
Temporary dynamic priority elevation of masters
Enhanced Direct Memory Access (eDMA)
The eDMA module is a controller capable of performing complex data movements via 16 programmable channels, with
minimal intervention from the host processor. The hardware micro architecture includes a DMA engine which performs source
and destination address calculations, and the actual data movement operations, along with an SRAM-based memory containing
the transfer control descriptors (TCD) for the channels. This implementation is utilized to minimize the overall block size. The
eDMA module provides the following features:
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1.4.5
16 channels support independent 8-, 16- or 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, periodic timer interrupt or eDMA channel request
Each DMA channel can optionally send an interrupt request to the CPU on completion of a single value or block
transfer
DMA transfers possible between system memories, QuadSPI, RLE Decoder, SPIs, I2C, ADC, eMIOS and General
Purpose I/Os (GPIOs)
Programmable DMA Channel Mux allows assignment of any DMA source to any available DMA channel with up to
a total of 64 potential request sources.
Interrupt Controller (INTC)
The INTC (interrupt controller) provides priority-based preemptive scheduling of interrupt requests, suitable for statically
scheduled hard real-time systems.
For high priority interrupt requests, the time from the assertion of the interrupt request from the peripheral to when the processor
is executing the interrupt service routine (ISR) has been minimized. The INTC provides a unique vector for each interrupt
request source for quick determination of which ISR needs to be executed. It also provides an ample number of priorities so that
PXD20 Microcontroller Data Sheet, Rev. 2
10
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
lower priority ISRs do not delay the execution of higher priority ISRs. To allow the appropriate priorities for each source of
interrupt request, the priority of each interrupt request is software configurable.
When multiple tasks share a resource, coherent accesses to that resource need to be supported. The INTC supports the priority
ceiling protocol for coherent accesses. By providing a modifiable priority mask, the priority can be raised temporarily so that
all tasks which share the resource can not preempt each other.
Multiple processors can assert interrupt requests to each other through software settable interrupt requests. These same software
settable interrupt requests also can be used to break the work involved in servicing an interrupt request into a high priority
portion and a low priority portion. The high priority portion is initiated by a peripheral interrupt request, but then the ISR asserts
a software settable interrupt request to finish the servicing in a lower priority ISR. Therefore these software settable interrupt
requests can be used instead of the peripheral ISR scheduling a task through the RTOS. The INTC provides the following
features:
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•
•
•
•
•
1.4.6
Unique 9-bit vector for each of the possible 128 separate interrupt sources
Eight software triggerable interrupt sources
16 priority levels with fixed hardware arbitration within priority levels for each interrupt source
Ability to modify the ISR or task priority.
— Modifying the priority can be used to implement the Priority Ceiling Protocol for accessing shared resources.
External non maskable interrupt directly accessing the main CPU critical interrupt mechanism
32 external interrupts
QuadSPI serial flash memory controller
The QuadSPI module enables use of external serial flash memories supporting single, dual and quad modes of operation. It
features the following:
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•
•
•
•
•
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•
1.4.7
Maximum serial clock frequency 80 MHz
Memory mapped read access for AHB crossbar switch masters
Automatic serial flash read command generation by CPU, eDMA, DCU, or DCU-Lite read access on AHB bus
Supports single, dual and quad serial flash read commands
Simultaneous mode:
— Supports concurrent read of two external serial flashes
— The quad data streams from the two flashes can be recombined in the QuadSPI to achieve up to 80 MB/s read
bandwidth with 80 MHz serial flash
1664-bit buffer with speculative fetch and buffer flush mechanisms to maximize read bandwidth of serial flash
DMA support
All Serial Flash program, erase, read and configuration commands available via IP bus interface.
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 GPIO features the following:
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•
Up to four levels of internal pin multiplexing, allowing exceptional flexibility in the allocation of device functions for
each package
Centralized general purpose input output (GPIO) control
All GPIO pins can be independently configured to support pull-up, pull down, or no pull
Reading and writing to GPIO supported both as individual pins and 16-bit wide ports
All peripheral pins can be alternatively configured as both general purpose input or output pins except ADC channels
which support alternative configuration as general purpose inputs
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
11
Overview
•
•
•
Direct readback of the pin value supported on all digital output pins through the SIU
Configurable digital input filter that can be applied to up to 24 general purpose input pins for noise elimination on
external interrupts
Register configuration protected against change with soft lock for temporary guard or hard lock to prevent
modification until next reset.
1.4.8
On-chip flash memory with ECC
The PXD20 microcontroller has the following flash memory features:
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•
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•
2 MB of flash memory
— Typical flash memory access time: 0 wait-state for buffer hits, 3 wait-states for page buffer miss at 125 MHz
— Two 4 × 128-bit page buffers with programmable prefetch control
– One set of page buffers can be allocated for code-only, fixed partitions of code and data, all available for any
access
– One set of page buffers allocated to Display Controller Units, Graphics Accelerator and the eDMA
— 64-bit ECC with single-bit correction, double-bit detection for data integrity
Small block flash arrangement to support features such as boot block, EEPROM Emulation, operating system block.
— 816 KB
— 264 KB
— 2128 KB
— 6256 KB
Hardware managed Flash writes, erase and verify sequence
Censorship protection scheme to prevent Flash content visibility
1.4.9
Static random-access memory (SRAM)
The PXD20 microcontroller has 64 KB general-purpose on-chip SRAM with the following features:
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•
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•
•
Typical SRAM access time: 1 wait-state for reads and 32-bit writes
32-bit ECC with single-bit correction, double bit detection for data integrity
Supports byte (8-bit), half word (16-bit), word (32-bit) and double-word (64-bit) writes for optimal use of memory
User transparent ECC encoding and decoding for byte, half word, and word accesses
Separate internal power domains applied to 56 KB and 8 KB SRAM blocks during STANDBY modes to retain
contents during low power mode.
1.4.10
On-chip graphics SRAM
The PXD20 microcontroller has 1 MB on-chip graphics SRAM with the following features:
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•
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•
Two crossbar slave ports:
— One dedicated to the 2D Graphics Accelerator (GFX2D) access
— One dedicated to all other crossbar masters
Usable as general purpose SRAM
Supports byte (8-bit), half word (16-bit), word (32-bit) and double-word (64-bit) writes for optimal use of memory
RAM controller with hardware RAM fill function supporting all-zeroes or all-ones SRAM initialization
Independent data buffers (one per AHB port) for maximum system performance
— Optimized for burst transfers (read + write)
— Programmable read prefetch capabilities
PXD20 Microcontroller Data Sheet, Rev. 2
12
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
1.4.11
Memory Protection Unit (MPU)
The MPU features the following:
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•
•
•
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•
Sixteen region descriptors for per master protection
Start and end address defined with 32-byte granularity
Overlapping regions supported
Protection attributes can optionally include process ID
Protection offered for 4 concurrent read ports
Read and write attributes for all masters
Execute and supervisor/user mode attributes for processor masters
1.4.12
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2D graphics accelerator (GFX2D)
Native vector graphics rendering
— Compatible with OpenVG1.1
— Complete hardware OpenVG 1.1 rendering pipeline
— Both geometry and pixel processing
— Adaptive processing of Bezier curves and strokes
16-sample edge anti-aliasing
— High image quality, font scalability, etc.
— 4 Rotated Grid Supersampling (RGSS) AA for Flash
3D perspective texturing, reflections, and shadowing
Shading (linear or radial gradient)
Separate 2D engine for BitBlt, fill and ROP operations
Significant performance improvement when compared to software or 3D GPU-based OpenVG implementations
1.4.13
Display Control Unit (DCU3)
The DCU3 is a display controller designed to drive TFT LCD displays up to WVGA resolution using direct blit graphics and
video.
The DCU3 generates all the necessary signals required to drive the TFT LCD displays: up to 24-bit RGB data bus, Pixel Clock,
Data Enable, Horizontal-Sync and Vertical-Sync.
The flexible architecture of the DCU3 enables the display of OpenVG-rendered frame buffer content and direct blit rendered
graphics simultaneously.
An optional Timing Controller (TCON) and RSDS interface is available to directly drive the row and column drivers of a
display panel.
Internal memory resource of the device allows to easily handle complex graphics contents (pictures, icons, languages, fonts).
The DCU3 supports 4-plane blending and 16 graphics layers. Control Descriptors (CDs) associated with each of the 16 layers
enable effective merging of different resolutions into one plane to optimize use of internal memory buffers. A layer may be
constructed from graphic content of various resolutions including indexed colors of 1, 2, 4 and 8 bpp, direct colors of 16, 24
and 32 bpp, and a YUV 4:2:2 color space. The ability of the DCU3 to handle input data in resolutions as low as 1bpp, 2bpp and
4bpp enables a highly efficient use of internal memory resources of the PXD20. A special tiled mode can be enabled on any of
the 16 layers to repeat a pattern optimizing graphic memory usage.
A hardware cursor can be managed independently of the layers at blending level increasing the efficient use of the internal
DCU3 resources.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
13
Overview
To secure the content of all critical information to be displayed, a safety mode can be activated to check the integrity of critical
data along the whole system data path from the memory to the TFT pads.
The DCU3 features the following:
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Display color depth: up to 24 bpp
Generation of all RGB and control signals for TFT
Four-plane blending
Maximum number of Input Layers: 16 (fixed priority)
Dynamic Look-Up-Table (Color and Gamma Look-Up)
blending range: up to 256 levels
Transparency Mode
Gamma Correction
Tiled mode on all the layers
Hardware Cursor
Supports YCrCb 4:2:2 input data format
RLE decode inline supporting direct read of RLE compressed images from system memory
Critical display content integrity monitoring for Functional Safety support
Internal Direct Memory Access (DMA) module to transfer data from internal and / or external memory.
The DCU3 also features a Parallel Data Interface (PDI) to receive external digital video or graphic content into the DCU3. The
PDI input is directly injected into the DCU3 background plane FIFO. When the PDI is activated, all the DCU3 synchronization
is extracted from the external video stream to guarantee the synchronization of the two video sources.
The PDI can be used to:
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Connect a video camera output directly to the PDI
Connect a secondary display driver as slave with a minimum of extra cost
Connect a device gathering various Video sources
Provide flexibility to allow the DCU to be used in slave mode (external synchronization)
The PDI features the following:
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Supported color modes:
— 8-bit mono
— 8-bit color multiplexed
— RGB565
— 16-bit/18-bit RAW color
Supported synchronization modes:
— embedded ITU-R BT.656-4 (RGB565 mode 2)
— HSYNC, VSYNC
— Data Enable
Direct interface with DCU3 background plane FIFO
Synchronization generation for the DCU3
1.4.14
Display Control Unit Lite (DCULite)
The DCULite is a display controller designed to enable the PXD20 to drive a second TFT LCD display up to XGA resolution
using direct blit graphics and video. The DCULite includes all features of the DCU3, including the PDI with the following
exceptions:
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Reduced from 4-plane to 2-plane blending
Reduced from 16 layers to 4 layers
Reduced CLUT size
PXD20 Microcontroller Data Sheet, Rev. 2
14
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
1.4.15
Timing controller (TCON) and RSDS interface
The TCON enables direct drive of the row and column drivers of display panels enabling emulation of TCON ICs used in
display panels.
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Programmable Timing Generation unit featuring 12 waveform generators allowing high degree of flexibility in panel
waveform generation
Reduced Swing Differential Signaling (RSDS) interface for RGB data and pixel clock
Conforms to “RSDS ‘Intra Panel’ Interface Specification” Rev. 1.0 (National Semiconductor)
1.4.16
RLE decoder
The RLE decoder is a crossbar slave sharing a slave port with the QuadSPI module. The platform eDMA is used to stream
compressed image data into and extract decompressed data out of the RLE Decoder.
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Lossless decompression
Pixel formats supported: 8bpp, 16bpp, 24bpp and 32bpp
AHB mapped read and write registers in RLE_DEC to achieve higher throughput
Programmable fill levels of read and write buffers for initiating burst transfers
Crop feature: Support for selectively reading out a part of decompressed image data taking complete compressed data
for the full image as input.
1.4.17
DRAM controller
The DRAM controller is a multi-port DRAM controller supporting SDR, LPDDR1, DDR-1, and DDR-2 memories. The DRAM
controller listens to the incoming requests to the seven buses in parallel and then sends commands to the DRAM from the
highest priority bus at the current time
The seven incoming 64-bit buses are:
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DCU3
DCULite
e200z4d core - instruction bus
e200z4d core - data bus
VIU2
GFX2D
eDMA
The DRAM controller features the following:
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Supports CAS latency of 2, 3, and 4 clock cycles.
Master buses
— 7 incoming master buses
— Supports 16-byte and 32-byte bursts
— Supports byte enables
— Supports 4-bit priority signal for each bus
Write buffer contains five 32-byte entries
Supports 16-wide and 32-wide SDR, DDR1, DDR2 and LPDDR1 DRAM devices
Controller supports one chip select, 8-bank DRAM system
Supports dynamic on-die termination in the host device and in the DRAM.
Supports memory sizes as small as 64Mbit
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
15
Overview
1.4.18
Video Input Unit (VIU2)
The VIU2 is a crossbar master module accepting an ITU656 compatible video input stream on a parallel interface, converting
the pixel data to RGB or YUV format and transferring the video image to internal frame buffer memory or external DRAM if
available.
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Supports 8-bit/10-bit ITU656 video input
Output formats:
— RGB888
— RGB565
— 8-bit monochrome
— YCrCb 4:2:2
Video downscaling
Contrast and Brightness adjustment
De-interlace for interlaced video image
Internal DMA engine for data transfer to memory
1.4.19
Boot assist module (BAM)
The BAM is a block of read-only memory that is programmed once by Freescale. The BAM program is executed every time
the MCU is powered-on or reset in normal mode. The BAM supports different modes of booting. They are:
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Booting from internal flash memory
Serial boot loading (A program is downloaded into RAM via CAN or LIN and then executed)
Booting from external memory
Additionally the BAM:
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Enables and manages the transition of the MCU from reset to user code execution
Configures device for serial bootload
Enables multiple bootcode starting locations out of reset through implementation of search for valid Reset
Configuration Halfword
Enables or disables software watchdog timer out of reset through BAM read of Reset Configuration Halfword option
bit
1.4.20
Enhanced Modular Input/Output System (eMIOS)
This device has two eMIOS modules, each with 16 channels supporting a range of 16-bit Input Capture, Output Compare, Pulse
Width Modulation, and Quadrature Decode functions.
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Selectable clock source from primary FMPLL, secondary FMPLL, external 4–16 MHz oscillator or 16 MHz Internal
RC oscillator on a per module basis
Timed I/O channels with 16-bit counter resolution
Buffered updates
Support for shifted PWM outputs to minimize occurrence of concurrent edges
Edge aligned output pulse width modulation
— Programmable pulse period and duty cycle
— Supports 0% and 100% duty cycle
— Shared or independent time bases
Programmable phase shift between channels
4 channels of Quadrature Decode
DMA transfer support
PXD20 Microcontroller Data Sheet, Rev. 2
16
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
1.4.21
Analog-to-digital converter (ADC)
The ADC features the following:
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10-bit A/D resolution
0–5 V or 0–3.3 V common mode conversion range
Supports conversions speeds of up to 1s
20 internal and 8 external channels support
Up to 20 single-ended inputs channels
— 10 channels configured as input only pins
– 10-bit ± 2 counts accuracy (TUE)
— 10 channels configured to have alternate function as general purpose input/output pins
– 10-bit ± 3 counts accuracy (TUE)
External multiplexer support to increase up to 27 channels
— Automatic 1 × 8 multiplexer control
— External multiplexer connected to a dedicated input channel
— Shared register between the 8 external channels
Result register available for every non-multiplexed channel
Configurable Left or Right aligned result format
Supports for one-shot, scan and injection conversion modes
Injection mode status bit implemented on adjacent 16-bit register for each result
— Supports Access to Result and injection status with single 32-bit read
Independently enabling of function for channels:
— Pre-sampling
— Offset error cancellation
— Offset Refresh
Conversion Triggering support
— Internal conversion triggering from periodic interrupt timer (PIT)
Four configurable analog comparator channels offering range comparison with triggered alarm
— Greater than
— Less than
— Out of range
All unused analog pins available as general purpose input pins
Selected unused analog pins available as general purpose pins
Power Down mode
Optional support for DMA transfer of results
1.4.22
Serial Peripheral Interface (SPI)
The SPI modules provide a synchronous serial interface for communication between the MCU and external devices.
The SPI features:
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Full duplex, synchronous transfers
Master or slave operation
Programmable master bit rates
Programmable clock polarity and phase
End-of-transmission interrupt flag
Programmable transfer baud rate
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
17
Overview
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Programmable data frames from 4 to 16 bits
Up to 3 chip select lines available, depending on package and pin multiplexing, enable 8 external devices to be selected
using external muxing from a single SPI
Eight clock and transfer attributes registers
Chip select strobe available as alternate function on one of the chip select pins for de-glitching
FIFOs for buffering up to 4 transfers on the transmit and receive side
General purpose I/O functionality on pins when not used for SPI
Queueing operation possible through use of eDMA
1.4.23
Controller Area Network (CAN) module
The PXD20 includes up to three controller area network (CAN) modules. The CAN module is a communication controller
implementing the CAN protocol according to Bosch Specification version 2.0B. The CAN protocol was designed to be used
primarily as a vehicle serial data bus, meeting the specific requirements of this field: real-time processing, reliable operation in
the EMI environment of a vehicle, cost-effectiveness and required bandwidth.
Each CAN module offers the following:
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Compliant with CAN protocol specification, Version 2.0B active
64 mailboxes, each configurable as transmit or receive
— Mailboxes configurable while module remains synchronized to CAN bus
Transmit features
— Supports configuration of multiple mailboxes to form message queues of scalable depth
— Arbitration scheme according to message ID or message buffer number
— Internal arbitration to guarantee no inner or outer priority inversion
— Transmit abort procedure and notification
Receive features
— Individual programmable filters for each mailbox
— 8 mailboxes configurable as a 6-entry receive FIFO
— 8 programmable acceptance filters for receive FIFO
Programmable clock source
— System clock
— Direct oscillator clock to avoid PLL jitter
Listen only mode capabilities
CAN Sampler
— Can catch the 1st message sent on the CAN network while the MCU is stopped. This guarantees a clean startup
of the system without missing messages on the CAN network.
— The CAN sampler is connected to one of the CAN RX pins.
1.4.24
Serial communication interface module (UART)
The PXD20 devices include up to four UART modules and support for UART Master mode, UART Slave mode and UART
mode. The modules are UART state machine compliant to the LIN 1.3 and 2.0 and 2.1 Specifications and handle UART frame
transmission and reception without CPU intervention.
The serial communication interface module offers the following:
•
UART features:
— Full-duplex operation
— Standard non return-to-zero (NRZ) mark/space format
PXD20 Microcontroller Data Sheet, Rev. 2
18
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
•
— Data buffers with 4-byte receive, 4-byte transmit
— Configurable word length (8-bit or 9-bit words)
— Error detection and flagging
– Parity, noise and framing errors
— Interrupt driven operation with 4 interrupts sources
— Separate transmitter and receiver CPU interrupt sources
— 16-bit programmable baud-rate modulus counter and 16-bit fractional
— 2 receiver wake-up methods
LIN features:
— Autonomous LIN frame handling
— Message buffer to store identifier and up to eight data bytes
— Supports message length of up to 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
– Self Test
– LIN bus stuck dominant detection
— Interrupt driven operation with 16 interrupt sources
— LIN slave mode features
– Autonomous LIN header handling
– Autonomous LIN response handling
– Discarding of irrelevant LIN responses using up to 16 ID filters
1.4.25
Inter-Integrated Circuit (I2C) controller modules
The PXD20 includes four I2C modules. Each module features the following:
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Two-wire bi-directional serial bus for on-board communications
Compatibility with I2C bus standard
Multi-master operation
Software-programmable for one of 256 different serial clock frequencies
Software-selectable acknowledge bit
Interrupt-driven, byte-by-byte data transfer
Arbitration-lost interrupt with automatic mode switching from master to slave
Calling address identification interrupt
Start and stop signal generation/detection
Repeated START signal generation
Acknowledge bit generation/detection
Bus-busy detection
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
19
Overview
1.4.26
System clocks and clock generation modules
The system clock on the PXD20 can be derived from an external oscillator, an on-chip FMPLL, or the internal 16 MHz
oscillator.
The source system clock frequency can be changed via an on-chip programmable clock divider (1 to 2). An additional
programmable peripheral bus clock divider (ratios 1 to ) is also available.
The PXD20 has two on-chip FMPLLs (primary and secondary). Each features the following:
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Input clock frequency from 4 MHz to 16 MHz
Lock detect circuitry continuously monitors lock status
Loss Of Clock (LOC) detection for reference and feedback clocks
On-chip loop filter (for improved electromagnetic interference performance and reduction of number of external
components required)
Support for frequency ramping from PLL
The primary FMPLL module is for use as a system clock source. The secondary FMPLL is available for use as an alternate,
modulated or non-modulated clock source to eMIOS modules and as alternate clock to the DCU for pixel clock generation.
The main oscillator provides the following features:
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Input frequency range 4–16 MHz
Square-wave input mode
Oscillator input mode 3.3 V (5.0 V)
Automatic level control
Low power consumption
PLL reference
The PXD20 also includes the following oscillators:
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32 KHz low power external oscillator for slow execution, low power, and RTC
Dedicated internal 128 kHz RC oscillator for low power mode operation and self wake-up
— ±10% accuracy across voltage and temperature (after factory trimming)
— Trimming registers to support improved accuracy with in-application calibration
Dedicated 16 MHz internal RC oscillator
— Used as default clock source out of reset
— Provides a clock for rapid start-up from low power modes
— Provides a back-up clock in the event of PLL or External Oscillator clock failure
— Offers an independent clock source for the SWT
— ±5% accuracy across voltage and temperature (after factory trimming)
— Trimming registers to support frequency adjustment with in-application calibration
1.4.27
Periodic interrupt timer (PIT)
The PIT features the following:
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Eight general purpose interrupt timers
Two dedicated interrupt timers for triggering ADC conversions
32-bit counter resolution
Clocked by system clock frequency
PXD20 Microcontroller Data Sheet, Rev. 2
20
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
1.4.28
Real time counter (RTC)
The Real Timer Counter supports wake-up from Low Power modes or Real Time Clock generation
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Configurable resolution for different timeout periods
— 1 s resolution for >1 hour period
— 1 ms resolution for 2 second period
Selectable clock sources from external 32 KHz crystal, external 4–16 MHz crystal, internal 128 kHz RC oscillator or
divided internal 16 MHz RC oscillator
1.4.29
System timer module (STM)
The STM is a 32-bit timer designed to support commonly required system and application software timing functions. The STM
includes a 32-bit up counter and four 32-bit compare channels with a separate interrupt source for each channel. The counter is
driven by the system clock divided by an 8-bit prescale value (1 to 256).
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One 32-bit up counter with 8-bit prescaler
Four 32-bit compare channels
Independent interrupt source for each channel
Counter can be stopped in debug mode
1.4.30
Software watchdog timer (SWT)
The SWT features the following:
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Watchdog supporting software activation or enabled out of Reset
Supports normal or windowed mode
Watchdog timer value writable once after reset
Watchdog supports optional halting during low power modes
Configurable response on timeout: reset, interrupt, or interrupt followed by reset
Clock source: 128 kHz RC oscillator
1.4.31
Stepper motor controller (SMC)
The SMC module is a PWM motor controller suitable to drive instruments in a cluster configuration or any other loads requiring
a PWM signal. The motor controller has twelve PWM channels associated with two pins each (24 pins in total) driving up to 6
stepper motors.
The SMC module includes the following features:
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10/11-bit PWM counter
11-bit resolution with selectable PWM dithering function
Left, right, or center aligned PWM
Output slew rate control
Output Short Circuit Detection
This module is suited for, but not limited to, driving small stepper and air core motors used in instrumentation applications. This
module can be used for other motor control or PWM applications that match the frequency, resolution, and output drive
capabilities of the module.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
21
Overview
1.4.32
Stepper stall detect (SSD) module
The SSD module provides a circuit to measure and integrate the induced voltage on the non-driven coil of a stepper motor using
full steps when the gauge pointer is returning to zero (RTZ).
The SSD module features the following:
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Programmable full step state
Programmable integration polarity
Blanking (recirculation) state
16-bit integration accumulator register
16-bit modulus down counter with interrupt
1.4.33
Sound generator module (SGM)
The SGM features the following:
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4-channel audio mixer
Each channel capable of independent Tone generation or Wave playback
Individual channel volume control (8-bit resolution)
Tone Mode:
— Programmable Tone frequency
— Programmable amplitude envelope: attack, duration and decay
— Programmable number of tone pulses and inter-tone duration
Wave Mode:
— One FIFO per channel working in conjunction with eDMA
— Supports standard audio sampling rates (4 kHz, 8 kHz, 11.025 kHz, 16 kHz, 22.050 kHz, 32 kHz, 44.100 kHz,
48 kHz)
— Same sample rate applies to all channels
— 8-bit, 12-bit, 16-bit input data formats
— Programmable wave duration and inter-wave duration
— Repeat mode with programmable number of wave playbacks
SGM Output:
— 16-bit PWM channel
— Integrated I2S master interface for connection to external audio DAC
1.4.34
IEEE 1149.1 JTAG controller (JTAGC)
JTAGC features the following:
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Backward compatible to standard JTAG IEEE 1149.1-2001 test access port (TAP) interface
Support for boundary scan testing
1.4.35
Nexus Development Interface (NDI)
The Nexus 3 module is compliant with Class 3 of the IEEE-ISTO 5001-2008 standard, with additional Class 4 features
available. The following features are implemented:
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Program Trace via Branch Trace Messaging (BTM). Branch trace messaging displays program flow discontinuities
(direct and indirect branches, exceptions, etc.), allowing the development tool to interpolate what transpires between
the discontinuities. Thus static code may be traced.
PXD20 Microcontroller Data Sheet, Rev. 2
22
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Overview
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Data Trace via Data Write Messaging (DWM) and Data Read Messaging (DRM). This provides the capability for the
development tool to trace reads and/or writes to selected internal memory resources.
Ownership Trace via Ownership Trace Messaging (OTM). OTM facilitates ownership trace by providing visibility of
which process ID or operating system task is activated. An Ownership Trace Message is transmitted when a new
process/task is activated, allowing the development tool to trace ownership flow.
Run-time access to embedded processor memory map via the JTAG port. This allows for enhanced download/upload
capabilities.
Watchpoint Messaging via the auxiliary pins
Watchpoint Trigger enable of Program and/or Data Trace Messaging
Data Acquisition Messaging (DQM) allows code to be instrumented to export customized information to the Nexus
Auxiliary Output Port.
Address Translation Messaging via program correlation messages displays updates to the TLB for use by the debugger
in correlating virtual and physical address information
Auxiliary interface for higher data input/output
Registers for Program Trace, Data Trace, Ownership Trace and Watchpoint Trigger.
All features controllable and configurable via the JTAG port
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
23
Pinout and signal descriptions
2
Pinout and signal descriptions
2.1
176 LQFP package pinout
176
175
174
173
172
171
170
169
168
167
166
165
164
163
162
161
160
159
158
157
156
155
154
153
152
151
150
149
148
147
146
145
144
143
142
141
140
139
138
137
136
135
134
133
VSS
VDD12
PF15 / QSPI_CLK_0 / CLKOUT / MCK0
PF14 / QSPI_IO1_0 / MDO3
PF13 / QSPI_IO0_0 / MDO2
PF12 / QSPI_IO3_0 / MDO1
PF11 / QSPI_IO2_0 / MDO0
PF10 / QSPI_PCS_0 / EVTI
PG12 / CS0_1 / PDI_DE
VSS
VDDE_B
PF9 / SCL_0 / CS1_1 / TXD_1
PF8 / SDA_0 / CS2_1 / RXD_1
PF7 / eMIOS1[15] / SCL_1
PF6 / QSPI_IO0_1 / eMIOS1[16] / PDI17_VIU9
PF5 / QSPI_IO1_1 / eMIOS1[15] / PDI16_VIU8
PF4 / eMIOS1[14] / SDA_1
PF3 / eMIOS1[21] / MSEO2
PF1 / eMIOS1[20] / MSEO
PF0 / eMIOS1[19] / EVTO
PK1 / QSPI_IO2_1 / eMIOS1[14] / PDI15_VIU7
PK0 / eMIOS1[18]
VSS
PB2 / TXD_0
PB3 / RXD_0
PJ15 / QSPI_IO3_1 / eMIOS1[9] / PDI14_VIU6
PJ14 / QSPI_CLK_1 / eMIOS1[17] / PDI_PCLK
PJ13 / QSPI_PCS_1 / eMIOS1[8] / PDI13_VIU5
PJ12 / DCU_TAG
PG11 / DCU_PCLK
PG7 / DCU_B7
PG6 / DCU_B6
PG5 / DCU_B5
PG4 / DCU_B4
PG3 / DCU_B3
PG2 / DCU_B2
VDDE_B
VSS
VDD12
PG1 / DCU_B1 / SDA_3 / eMIOS0[22]
PG0 / DCU_B0 / SCL_3 / eMIOS0[21]
PA15 / DCU_G7
PA14 / DCU_G6
VSS
Figure 2 shows the pinout for the 176-pin LQFP package.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
PXD20
176 LQFP
Top view
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
VDDE_B
PA13 / DCU_G5
PA12 / DCU_G4
PA11 / DCU_G3
PA10 / DCU_G2
PA9 / DCU_G1 / SDA_2 / eMIOS0[19]
PA8 / DCU_G0 / SCL_2 / eMIOS0[20]
PA7 / DCU_R7
PA6 / DCU_R6
VSS
VDDE_B
PA5 / DCU_R5
PA4 / DCU_R4
PA3 / DCU_R3
PA2 / DCU_R2
PA1 / DCU_R1 / SCL_1 / eMIOS0[17]
PA0 / DCU_R0 / SDA_1 / eMIOS0[18]
PM11 / TXD_2 / CNTX_2 / eMIOS0[23]
PM10 / RXD_2 / CNRX_2 / eMIOS0[16]
PM9/ PDI_PCLK/ SGM_MCLK/ eMIOS0[8]
VDDE_B
VSS
VDD12
PD15 / M3C1P / SSD3_3 / eMIOS0[15]
PD14 / M3C1M / SSD3_2 / eMIOS0[14]
PD13 / M3C0P / SSD3_1 / eMIOS0[13]
PD12 / M3C0M / SSD3_0 / eMIOS0[12]
VSSM
VDDM
PD11 / M2C1P / SSD2_3 / eMIOS0[11]
PD10 / M2C1M / SSD2_3 / eMIOS0[10]
PD9 / M2C0P / SSD2_1 / eMIOS0[9]
PD8 / M2C0M / SSD2_0
PD7 / M1C1P / SSD1_3
PD6 / M1C1M / SSD1_2 / eMIOS0[23]
PD5 / M1C0P / SSD1_1 / eMIOS0[16]
PD4 / M1C0M / SSD1_0 / eMIOS0[8]
VSSM
VDDM
PD3 / M0C1P / SSD0_3 / eMIOS0[9]
PD2 / M0C1M / SSD0_2 / eMIOS1[23]
PD1 / M0C0P / SSD0_1 / eMIOS1[16]
PD0 / M0C0M / SSD0_0 / eMIOS1[8]
VDDE_B
Note: Functions in bold are
available only on this package.
NMI / PF2
CS2_0 / eMIOS1[10] / RXD_1 / PB12
CS1_0 / eMIOS1[11] / TXD_1 / PB13
VDDE_B
VSS
VDD12
eMIOS1[12] / SDA_1 / PK10
DCU_TAG / eMIOS1[13] / SCL_1 / PK11
I2S_FS / eMIOS1[18] / SCK_0 / PB9
I2S_DO / eMIOS1[19] / SOUT_0 / PB8
I2S_SCK / eMIOS1[20] / SIN_0 / PB7
eMIOS0[23] / eMIOS0[21] / PDI0_VIU2 / PJ4
eMIOS0[16] / eMIOS0[20] / PDI1_VIU3 / PJ5
eMIOS0[15] / eMIOS0[19] / PDI2_VIU4 / PJ6
eMIOS0[14] / eMIOS0[18] / PDI3_VIU5 / PJ7
PDI_DE / eMIOS0[22] / VIU_PCLK / PJ3
eMIOS1[21] / CS0_0 / PH4
MA0 / SCK_1 / PB4
FABM / MA1 / SOUT_1 / PB5
ABS[0] / MA2 / SIN_1 / PB6
VDDE_B
VSS
VDD12
VSS
XTAL32 / AN15 / PC15
EXTAL32 / AN14 / PC14
CS0_1 / MA2 / AN13 / PC13
CS1_1 / MA1 / AN12 / PC12
CS2_1 / MA0 / AN11 / PC11
I2S_DO / AN10_MUX / PC10
AN9 / PC9
AN8 / PC8
VDDE_A
VSSE_A
VDDA
VSSA
AN7 / PC7
AN6 / PC6
AN5 / PC5
AN4 / PC4
AN3 / PC3
AN2 / PC2
AN1 / PC1
AN0 / PC0
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
DCU_VSYNC / PG8
DCU_HSYNC / PG9
DCU_DE / PG10
eMIOS0[8] / eMIOS1[9] / PDI_HSYNC_VIU1 / PJ1
eMIOS0[9] / eMIOS1[14] / PDI_VSYNC_VIU0 / PJ2
VDDE_B
VSS
eMIOS0[13] / eMIOS0[17] / PDI4_VIU6 / PJ8
eMIOS0[12] / eMIOS1[22] / PDI5_VIU7 / PJ9
eMIOS0[11] / eMIOS1[17] / PDI6_VIU8 / PJ10
eMIOS0[10] / eMIOS1[15] / PDI7_VIU9 / PJ11
RXD_0 / CNRX_0 / PB1
TXD_0 / CNTX_0 / PB0
I2S_DO / CNRX_1 / PB10
SGM_MCLK / CNTX_1 / PB11
DCU_TAG / eMIOS1[22] / PDI13_VIU5 / PM5
eMIOS1[23] / PDI14_VIU6 / PM6
VSS
VDDE_B
VDDR
VSSR
VSUP_TEST
VDD12
VSS
VDDPLL
VREG_BYPASS
EXTAL
XTAL
VRC_CTRL
RESET
eMIOS1[10] / PDI8_VIU0 / PK2
eMIOS1[11] / PDI9_VIU1 / PK3
eMIOS1[12] / PDI10_VIU2 / PK4
eMIOS1[13] / PDI11_VIU3 / PK5
eMIOS1[9] / PDI12_VIU4 / PK6
VSS
VDDE_B
eMIOS1[8] / I2S_FS / PDI15_VIU7 / PH5
eMIOS1[16] / I2S_DO / PDI16_VIU8 / PM7
eMIOS1[23] / I2S_SCK / PDI17_VIU9 / PM8
TCK / PH0
TDI / PH1
TDO / PH2
TMS / PH3
Figure 2. 176-pin LQFP pinout
PXD20 Microcontroller Data Sheet, Rev. 2
24
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Pinout and signal descriptions
2.2
208 LQFP package pinout
208
207
206
205
204
203
202
201
200
199
198
197
196
195
194
193
192
191
190
189
188
187
186
185
184
183
182
181
180
179
178
177
176
175
174
173
172
171
170
169
168
167
166
165
164
163
162
161
160
159
158
157
VSS
VDD12
PF15 / QSPI_CLK_0 / CLKOUT / MCKO
PF14 / QSPI_IO1_0 / MDO3
PF13 / QSPI_IO0_0 / MDO2
PF12 / QSPI_IO3_0 / MDO1
PF11 / QSPI_IO2_0 / MDO0
PF10 / QSPI_PCS_0 / EVTI
PG12 / CS0_1 / PDI_DE / DCULITE_B7
VSS
VDDE_B
PF9 / SCL_0 / CS1_1 / TXD_1
PF8 / SDA_0 / CS2_1 / RXD_1
PF7 / eMIOS1[15] / SCL_1 / DCULITE_B6
PF6 / QSPI_IO0_1 / eMIOS1[16] / PDI17_VIU9
PF5 / QSPI_IO1_1 / eMIOS1[15] / PDI16_VIU8
PF4 / eMIOS1[14] / SDA_B / DCULITE_B5
PF3 / eMIOS1[21] / MSEO2 / DCULITE_B4
PF1 / eMIOS1[20] / MSEO / DCULITE_B3
PF0 / eMIOS1[19] / EVTO / DCULITE_B2
PK1 / QSPI_IO2_1 / eMIOS1[14] / PDI15_VIU7
PK0 / eMIOS1[18] / DCULITE_G7
VDD12
VSS
VDDE_B
PB2 / TXD_0
PB3 / RXD_0
PJ15 / QSPI_IO3_1 / eMIOS1[9] / PDI14_VIU6
PJ14 / QSPI_CLK_1 / eMIOS1[17] / PDI_PCLK
PJ13 / QSPI_PCS_1 / eMIOS1[8] / PDI13_VIU5
PJ12 / DCU_TAG_TCON0 / DCULITE_G6
PL13 / eMIOS1[13] / DCULITE_G5
PL12 / eMIOS1[12] / DCULITE_G4
PL11 / eMIOS1[11] / DCULITE_G3
PL10 / eMIOS1[10] / DCULITE_G2
PM2 / eMIOS1[17] / DCULITE_R7/DCULITE_DE/RSDSLCKM
PG11 / DCU_PCLK / RSDSLCKP
PG7/ DCU_B7 / RSDS11M
PG6 / DCU_B6 / RSDS11P
PG5 / DCU_B5 / RSDS10M
PG4 / DCU_B4 / RSDS10P
PG3 / DCU_B3 / RSDS9M
PG2 / DCU_B2 / RSDS9P
VREF_RSDS
VDDE_B
VSS
VDD12
PG1 / DCU_B1 / SDA_3 / eMIOS0[22] / RSDS8M
PG0 / DCU_B0 / SCL_3 / eMIOS0[21] / RSDS8P
PA15 / DCU_G7 / RSDS7M
PA14 / DCU_G6 / RSDS7P
VSS
Figure 3 shows the pinout for the 208-pin LQFP package.
PXD20
208 LQFP
Top view
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
156
155
154
153
152
151
150
149
148
147
146
145
144
143
142
141
140
139
138
137
136
135
134
133
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
VDDE_B
PA13 / DCU_G5 / RSDS6M
PA12 / DCU_G4 / RSDS6P
PA11 / DCU_G3 / RSDS5M
PA10 / DCU_G2 / RSDS5P
PA9 / DCU_G1 / SDA_2 / eMIOS0[19] / RSDS4M
PA8 / DCU_G0 / SCL_2 / eMIOS0[20] / RSDS4P
PA7 / DCU_R7 / RSDS3M
PA6 / DCU_R6 / RSDS3P
VSS
VDDE_B
VREF_RSDS
PA5 / DCU_R5 / RSDS2M
PA4 / DCU_R4 / RSDS2P
PA3 / DCU_R3 / RSRS1M
PA2 / DCU_R2 / RSDS1P
PA1 / DCU_R1 / SCL_1 / eMIOS0[17] / RSDS0M
PA0 / DCU_R0 / SDA_1 / eMIOS0[18] / RSDS0P
VDDE_B
VSS
VDD12
PE7 / M5C1P / SSD5_3
PE6 / M5C1M / SSD5_2
PE5 / M5C0P / SSD5_1
PE4 / M5C0M / SSD5_0
VSSM
VDDM
PE3 / M4C1P / SSD4_3
PE2 / M4C1M / SSD4_2
PE1 / M4C0P / SSD4_1
PE0 / M4C0M / SSD4_0
PD15 / M3C1P / SSD3_3 / eMIOS0[15]
PD14 / M3C1M / SSD3_2 / eMIOS0[14]
PD13 / M3C0P / SSD3_1 / eMIOS0[13]
PD12 / M3C0M / SSD3_0 / eMIOS0[12]
VSSM
VDDM
PD11 / M2C1P / SSD2_3 / eMIOS0[11]
PD10 / M2C1M / SSD2_2 / eMIOS0[10]
PD9 / M2C0P / SSD2_1 / eMIOS0[9]
PD8 / M2C0M / SSD2_0
PD7 / M1C1P / SSD1_3
PD6 / M1C1M / SSD1_2 / eMIOS0[23]
PD5 / M1C0P / SSD1_1 / eMIOS0[16]
PD4 / M1C0M / SSD1_0 / eMIOS0[8]
VSSM
VDDM
PD3 / M0C1P / SSD0_3 / eMIOS0[9]
PD2 / M0C1M / SSD0_2 / eMIOS1[23]
PD1 / M0C0P / SSD0_1 / eMIOS1[16]
PD0 / M0C0M / SSD0_0 / eMIOS1[8]
VDDE_B
NMI / PF2
CS2_0 / eMIOS1[10] / RXD_1 / PB12
CS1_0 / eMIOS1[11] / TXD_1 / PB13
VDDE_B
VSS
VDD12
DCU_TAG / eMIOS1[12] / SDA_1 / PK10
DCULITE_TAG / eMIOS1[13] / SCL_1 / PK11
TCON11 / DCULITE_R5 / I2S_SCK/ PM0
DCULITE_R6 / I2S_FS / PM1
VDDE_B
VSS
I2S_FS / eMIOS1[18] / SCK_0 / PB9
I2S_DO / eMIOS1[19] / SOUT_0 / PB8
I2S_SCK / eMIOS1[20] / SIN_0 / PB7
eMIOS0[23] / eMIOS0[21] / PDI0_VIU2 / PJ4
eMIOS0[16] / eMIOS0[20] / PDI1_VIU3 / PJ5
eMIOS0[15] / eMIOS0[19] / PDI2_VIU4 / PJ6
eMIOS0[14] / eMIOS0[18] / PDI3_VIU5 / PJ7
PDI_DE / eMIOS0[22] / VIU_PCLK / PJ3
DCULITE_G6 / eMIOS1[21] / CS0_0 / PH4
MA0 / SCK_1 / PB4
FABM / MA1 / SOUT_1 / PB5
ABS[0] / MA2 / SIN_1 / PB6
VDDE_B
VSS
VDD12
VSS
CNRX_1 / AN19 / PL0
CNTX_1 / AN18 / PL1
eMIOS1[22] / CNRX_0 / AN17 / PL2
eMIOS1[23] / CNTX_0 / AN16 / PL3
XTAL32 / AN15 / PC15
EXTAL32 / AN14 / PC14
CS0_1 / MA2 / AN13 / PC13
CS1_1 / MA1 / AN12 / PC12
CS2_1 / MA0 / AN11 / PC11
I2S_DO / AN10_MUX / PC10
AN9 / PC9
AN8 / PC8
VDDE_A
VSSE_A
VDDA
VSSA
AN7 / PC7
AN6 / PC6
AN5 / PC5
AN4 / PC4
AN3 / PC3
AN2 / PC2
AN1 / PC1
AN0 / PC0
DCU_VSYNC_TCON2 / PG8
DCU_HSYNC_TCON1 / PG9
DCU_DE_TCON3 / PG10
eMIOS0[8] / eMIOS1[9] / PDI_HSYNC_VIU1 / PJ1
eMIOS0[9] / eMIOS1[14] / PDI_VSYNC_VIU0 / PJ2
VDDE_B
VSS
eMIOS0[13] / eMIOS0[17] / PDI4_VIU6 / PJ8
eMIOS0[12] / eMIOS1[22] / PDI5_VIU7 / PJ9
eMIOS0[11] / eMIOS1[17] / PDI6_VIU8 / PJ10
eMIOS0[10] / eMIOS1[15] / PDI7_VIU9 / PJ11
RXD_0 / CNRX_0 / PB1
TXD_0 / CNTX_0 / PB0
I2S_DO / CNRX_1 / PB10
SGM_MCLK / CNTX_1 / PB11
TCON4 / RXD_3 / CNRX_2 / PM3
TCON5 / TXD_3 / CNTX_2 / PM4
VSS
VDDE_B
VDDR
VSSR
VSUP_TEST
VDD12
VSS
VDDPLL
VREG_BYPASS
EXTAL
XTAL
VRC_CTRL
RESET
TCON6 / PDI13_VIU5 / CS2_2 / PL4
TCON7 / PDI14_VIU6 / CS1_2 / PL5
eMIOS1[18] / PDI15_VIU7 / CS0_2 / PL6
eMIOS1[19] / PDI16_VIU8 / SIN_2 / PL7
eMIOS1[20] / PDI17_VIU9 / SOUT_2 / PL8
eMIOS1[21] / PDI_PCLK / SCK_2 / PL9
VDDE_B
VSS
DCULITE_TAG / eMIOS1[10] / PDI8_VIU0 / PK2
DCULITE_DE / eMIOS1[11] / PDI9_VIU1 / PK3
DCULITE_HSYNC / eMIOS1[12] / PDI10_VIU2 / PK4
DCULITE_VSYNC / eMIOS1[13] / PDI11_VIU3 / PK5
DCULITE_PCLK / eMIOS1[9] / PDI12_VIU4 / PK6
TCON8 / DCULITE_R2 / RXD_2 / PK7
TCON9 / DCULITE_R3 / TXD_2 / PK8
TCON10 / DCULITE_R4 / I2S_DO / PK9
VSS
VDDE_B
TCK / PH0
TDI / PH1
TDO / PH2
TMS / PH3
Figure 3. 208-pin LQFP pinout
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
25
2.3
416 TEPBGA package pinout–40 to 105°C
1
A
B
C
D
E
F
G
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
H
J
K
L
M
2
3
4
5
6
7
8
9
ddr_dq[5] MVTT1
VSS
ddr_dq[6]
ddr_dqs[ VDDE_DD
ddr_dq[4]
0]
R
ddr_dm[0
P
ddr_dq[1] VSS
ddr_dq[2]
]
VDD33_D
R
ddr_dq[0] MVTT0
VSS
DR
VDDE_DD
T
PG10
PG9
PG8
R
N
10
11
12
13
14
15
16
ddr_dq[2 ddr_dq[2 ddr_dq[2 ddr_dq[2
ddr_addr ddr_addr ddr_addr ddr_addr ddr_addr
30]
31] ddr_ba[0]ddr_ba[1]ddr_ba[2]
PG12
PF14
6]
7]
8]
9]
ess[0] ess[4] ess[6] ess[8] ess[12]
ddr_dq[2
ddr_dqs[ ddr_dm[3
ddr_addr
ddr_addr ddr_addr
ddr_addr
VSS
VSS ddr_cas ddr_ras VSS ddr_web
VSS
VSS
PF13
5]
3]
]
ess[1]
ess[7] ess[9]
ess[15]
ddr_dq[2 VDDE_DD
ddr_dq[2 VDDE_DD
ddr_dram VDDE_DD
ddr_addr VDDE_DD
ddr_addr VDDE_DD
VSS
VSS
VSS
VSS
PF12
VSS
3]]
R
4]
R
_clk
DR
ess[2]
R
ess[10]
R
ddr_dq[1 ddr_dq[2 ddr_dq[2 ddr_dq[2
VDD33_D ddr_dram
ddr_addr ddr_addr VDD33_D ddr_addr ddr_addr ddr_addr
ddr_cke ddr_cs
PF11
ddr_odt
9]
0]
1]
2]
DR
_clkb
ess[3] ess[5]
DR
ess[11] ess[13] ess[14]
ddr_dq[1
VDDE_DD ddr_dq[1
VSS
7]
R
8]
VDD33_D
ddr_dq[1
MVTT3
VSS
DR
6]
ddr_dq[1 ddr_dqs[ ddr_dm[2 ddr_dq[1
5]
2]
]
4]
VDDE_DD ddr_dq[1
ddr_dq[1
VSS
R
2]
3]
ddr_dq[1
MVTT2
VSS
MVREF
1]
ddr_dqs[ ddr_dm[1 ddr_dq[1
ddr_dq[9]
VDD12
VSS
VDD12
VSS
VDD12
VSS
VDD12
1]
]
0]
VDDE_DD
ddr_dq[8] VSS
ddr_dq[7]
VSS
VDD12
VSS
VDD12
VSS
VDD12
VSS
R
ddr_dq[3]
17
18
19
20
21
22
23
24
25
26
PF10
PF8
PF5
PF3
PK0
PB3
PJ12
PL11
PG7
PG6
A
VDDE
PF15
VSS
PF1
VDDE
PJ15
PL13
VDDE
VSS
PG5
B
VSS
PF7
VDDE
PF0
VSS
PJ14
PL12
PL10
PG3
PG4
C
PF9
PF6
PF4
PK1
PB2
PJ13
PM2
VREF_RS
DS2
PG2
PG1
D
PG11
VSS
VDDE
PG0
E
PA15
PA14
PA13
PA12
F
PA11
PA9
PA8
PA7
G
PA10
VDDE
VSS
VA6
H
PA3
VREF_RS
DS1
PA5
PA4
J
VSS
PA2
VSS
PA1
PA0
K
VDD12
PM13
PM12
VDDE
PJ0
L
VDD12
VSS
VSS
VSS
VSS
VSS
VDD12
VSS
PO7
PO6
PO5
PO4
M
VSS
VDD12
VSS
VSS
VSS
VSS
VSS
VDD12
PO3
VDDE
PO2
PO1
N
VDD12
VSS
VSS
VSS
VSS
VSS
VDD12
VSS
PO0
PN15
VSS
PN14
P
VSS
VDD12
VSS
VSS
VSS
VSS
VSS
VDD12
PE7
PE6
PN13
PN12
R
VDD12
VSS
VDD12
VSS
VDD12
VSS
VDD12
VSS
PE5
PE4
PE3
PE2
T
VSS
VDD12
VSS
VDD12
VSS
VDD12
VSS
VDD12
PE1
VSSM
VDDM
PE0
U
Freescale Semiconductor
U
PJ9
PJ8
PJ2
PJ1
V
PB1
VSS
PJ11
PJ10
PD15
PD14
PD13
PD12
V
W
RESET
PB10
VDDE
PB0
PD11
VDDM
VSSM
PD10
W
Y
VSS
PM4
PM3
PB11
PD9
PD8
PD7
PD6
Y
AA
XTAL
PD5
VSSM
VDDM
PD4
AA
AB
EXTAL
PL4
VSS
VDDPLL
PD3
PD2
PD1
PD0
AB
AC
VSUP_TE
ST
PL5
PN0
PK4
PK6
PH0
PF2
PB13
PK11
PN2
PN4
PN8
PB9
PB7
PJ7
PB5
MCKO
MDO6 MDO10
MVO0
PC0
PC3
PC1
PC2
AC
AD
PL6
VDDE
PN1
VSS
PK7
PH1
VDDE
EVTI
MSEO
VSS
PN5
PN9
VDDE
PJ4
PJ3
VSS
MSEO2
MDO7
VDDE
MDO1
PC6
PC4
PC7
PC5
AD
AE
PL7
VSS
PK2
VDDE
PK8
PH2
VSS
EVTO
PM0
VDDE
PN6
PN10
VSS
PJ5
PH4
VDDE
MDO4
MDO8
VSS
MDO2
PL1
PL0
PC10
PC11
PC9
PC8
AE
AF
PL8
PL9
PK3
PK5
PK9
PH3
PB12
PK10
PM1
PN3
PN7
PN11
PB8
PJ6
PB4
PB6
MDO5
MDO9 MDO11 MDO3
PL3
PL2
PC15
PC14
PC13
PC12
AF
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
21
22
23
24
25
26
VREG_BY VRC_CTR
VDDREG
PASS
L
Figure 4. 416 TEPBGA pinout
18
19
20
VSSEH_A
DC
VDDEH_A
VSSA
DC
VDDA
Pinout and signal descriptions
26
Figure 4 shows the pinout for the 416 TEPBGA package.
Pinout and signal descriptions
2.4
Signal description
The following sections provide signal descriptions and related information about the signals’ functionality and configuration.
2.4.1
Pad configuration during reset phases
All pads have a fixed configuration under reset.
During the power-up phase, all pads are forced to tristate.
After power-up phase, all pads are floating with the following exceptions:
•
•
•
•
PB[5] (FAB) is pull-down. Without external strong pull-up the device starts fetching from flash memory.
RESET pad is driven low. This is released only after PHASE2 reset completion.
Fast (4-16 MHz) external oscillator pads (EXTAL, XTAL) are tristate.
The following pads are pull-up:
— PB[6]
— PH[0]
— PH[1]
— PH[3]
2.4.2
Voltage supply pins
Voltage supply pins are used to provide power to the device. Two dedicated pins are used for 1.2 V regulator stabilization.
Table 3. Voltage supply pin descriptions
Pin number
Supply pin
Function
176 LQFP
VDD121
1.2 V core supply (1.08 V - 1.32 V)
208 LQFP
416 TEPBGA
23, 50, 67, 110, 138, 23, 58, 79, 136, 162, K10,K12,K14,K16,L
175
186, 207
11,L13,L15,L17,M1
0,M16,N11,N17,P1
0,P16,R11,R17,T10
,T12,T14,T16,U11,
U13,U15,U17
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
27
Pinout and signal descriptions
Table 3. Voltage supply pin descriptions (continued)
Pin number
Supply pin
Function
176 LQFP
VSS
1.2 V ground
208 LQFP
416 TEPBGA
7, 18, 36, 49, 66, 68, 7, 18, 38, 47, 57, 64,
111, 123, 133, 139, 78, 80, 137, 147,
154, 167, 176
157, 163, 185, 199,
208
VDD12 ground and VDDPLL ground
(VSSPLL)
24
24
AB3,AD10,AD16,A
D4,AE13,AE19,AE2
,AE7,B11,B14,B19,
B2,B25,B5,B8,C12,
C15,C17,C21,C3,C
6,C9,E2,E24,F3,H2
,H25,J3,K11,K13,K
15,K17,K24,L10,L1
2,L14,L16,L2,M11,
M12,M13,M14,M15,
M17,M3,N10,N12,N
13,N14,N15,N16,P
11,P12,P13,P14,P1
5,P17,P2,P25,R10,
R12,R13,R14,R15,
R16,R3,T11,T13,T1
5,T17,U10,U12,U14
,U16,V2,Y1
—
VDDE_B
3.3 V I/O supply. This supply is shared with
internal flash, 16 MHz IRC oscillator and
4–16MHz crystal oscillator.
6, 19, 37, 48, 65, 89, 6, 19, 37, 48, 56, 63, AD13,AD19,AD2,A
112, 122, 132, 140, 77, 105, 138, 146, D7,AE10,AE16,AE4
166
156, 164, 184, 198 ,B17,B21,B24,C19,
E25,H24,L25,N24,
W3
VDDA2
3.3 V/5 V reference voltage and analog
supply for A/D converter. This supply is
shared with the SXOSC.
79
95
AC22
VSSA
Reference ground and analog ground for A/D
converter
80
96
AD22
VDDR
Voltage regulator VREG supply
20
20
AA4
VSSR
Voltage regulator ground
21
21
—
VDDE_A2
3.3 V/5 V I/O supply. This supply is shared
with the SXOSC.
77
93
AD23
VSSE_A
3.3 V/5 V I/O supply ground
78
94
AC23
VDDM
Stepper motor 3.3 V/5 V pad supply. SSD
shares this supply.
94, 104
110, 120, 130
U25,W24,AA25
VSSM
Stepper motor ground
95, 105
111, 121, 131
U24,W24,AA24
1.2 V PLL supply
25
25
AB4
9 V - 12 V flash test analog write signal
22
22
AC1
VDD_DR
1.8V, 2.5V, and 3.3V DDR SDRAM supply
—
—
C2,C5,C8,C11,C14,
E3,H3,L3,N3,T3
VDD33_DR
Functional supply for SDRAM pads (where
available must be >= VDD_DR)
—
—
D6, D12, F4, R4
VDDPLL
VSUP_TEST3
PXD20 Microcontroller Data Sheet, Rev. 2
28
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Pinout and signal descriptions
1
Decoupling capacitors must be connected between these pins and the nearest VSS pin.
VDDA must be at the same voltage as VDDE_A.
3
This signal needs to be connected to ground during normal operation.
2
2.4.3
Pad types
The pads available for system pins and functional port pins are described in:
•
•
•
•
The port pin summary in Table 1;
The pad type descriptions in Table 3-6;
Section 43.5.3.8, “Pad Configuration Registers (PCR0–PCR184) and Section 43.5.3.9, “Pad Configuration Registers
(PCR185–PCR281);
The device data sheet.
2.4.4
System pins
The system pins are listed in Table 4.
Table 4. System pin descriptions
System pin
Function
I/O
direction
Pad
type
RESET
configuration1
I/O
M
Pin number
176 LQFP
208 LQFP
416 TEPBGA
Input, weak pull
up
30
30
W1
RESET
Bidirectional reset with
Schmitt-Trigger
characteristics and noise
filter.
EXTAL
Analog input to the oscillator
amplifier circuit. Input for the
clock generator in bypass
mode.
I
X
—
27
27
AB1
XTAL
Analog output of the
oscillator amplifier circuit.
Needs to be grounded if
oscillator bypass mode is
used.
O
X
—
28
28
AA1
EXTAL32
Analog input of the 32KHz
oscillator amplifier circuit.
O
S
—
70
86
AF24
XTAL32
Analog output of the 32 KHz
oscillator amplifier circuit.
Input for the clock generator
in bypass mode.
I
S
—
69
85
AF23
I/O
S
Input, none
45
53
AC7
Analo
g
—
29
29
AA3
Analo
g
—
—
145, 165
J24,D24
—
—
26
26
AA2
NMI
Non-Maskable Interrupt
VRC_CTRL Voltage Regulator external
NPN Ballast base control
pin
VREF_
RSDS2
RSDS interface reference
voltage
VREG_
BYPASS3
Pin used for factory testing
I
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
29
Pinout and signal descriptions
1
Reset configuration is given as I/O direction and pull direction (for example, “Input, pullup”).
Although this signal is not a supply for RSDS pads, it needs to be terminated in an external capacitor with a value of 47 pF.
3
VREG_BYPASS should be pulled down externally.
2
2.4.5
Nexus pins
On the 176 LQFP and the 208 LQFP package options a reduced set of Nexus pins are optionally available, multiplexed with
GPIO pins.
On the 416 TEPBGA package option all Nexus pins are dedicated to Nexus only.
Table 5. Nexus pins
System pin
Function
Pin number1
Pad
type
PCR
176 LQFP
208 LQFP
416 TEPBGA
EVTI
Nexus Event In
M
PCR[80]
169
201
A17
EVTO
Nexus Event Out
M
PCR[70]
157
189
C20
MCKO
Nexus Msg Clock Out
F
PCR[85]
174
206
B18
MSEO[0]
Nexus Msg Start/End Out
M
PCR[71]
158
190
B20
MSEO[2]
Nexus Msg Start/End Out
M
PCR[73]
159
191
A20
MDO[0]
Nexus Msg Data Out
M
PCR[81]
170
202
D16
MDO[1]
Nexus Msg Data Out
M
PCR[82]
171
203
C16
MDO[2]
Nexus Msg Data Out
M
PCR[83]
172
204
B16
MDO[3]
Nexus Msg Data Out
M
PCR[84]
173
205
A16
EVTI
Nexus Event In
M
PCR[197]
n/a
n/a
AD8
EVTO
Nexus Event Out
M
PCR[198]
n/a
n/a
AE8
MCKO
Nexus Msg Clock Out
F
PCR[200]
n/a
n/a
AC17
MSEO[0]
Nexus Msg Start/End Out
M
PCR[199]
n/a
n/a
AD9
MSEO[2]
Nexus Msg Start/End Out
M
PCR[201]
n/a
n/a
AD17
MDO[0]
Nexus Msg Data Out
M
PCR[185]
n/a
n/a
AC20
MDO[1]
Nexus Msg Data Out
M
PCR[186]
n/a
n/a
AD20
MDO[2]
Nexus Msg Data Out
M
PCR[187]
n/a
n/a
AE20
MDO[3]
Nexus Msg Data Out
M
PCR[188]
n/a
n/a
AF20
MDO[4]
Nexus Msg Data Out
M
PCR[189]
n/a
n/a
AE17
MDO[5]
Nexus Msg Data Out
M
PCR[190]
n/a
n/a
AF17
MDO[6]
Nexus Msg Data Out
M
PCR[191]
n/a
n/a
AC18
MDO[7]
Nexus Msg Data Out
M
PCR[192]
n/a
n/a
AD18
PXD20 Microcontroller Data Sheet, Rev. 2
30
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Pinout and signal descriptions
Table 5. Nexus pins (continued)
System pin
Function
Pin number1
Pad
type
PCR
176 LQFP
208 LQFP
416 TEPBGA
MDO[8]
Nexus Msg Data Out
M
PCR[193]
n/a
n/a
AE18
MDO[9]
Nexus Msg Data Out
M
PCR[194]
n/a
n/a
AF18
MDO[10]
Nexus Msg Data Out
M
PCR[195]
n/a
n/a
AC19
MDO[11]
Nexus Msg Data Out
M
PCR[196]
n/a
n/a
AF19
1
On the 176 LQFP and 208 LQFP package options the Nexus pins are multiplexed with other GPIO. On the 416 TEPBGA
package, there are additional dedicated Nexus pins.
2.4.6
DRAM interface
The DRAM interface pins are listed in Table 6.
Table 6. DRAM interface pin summary
Port pin1
Function
I/O
direction
Pad
type
PCR
RESET
config2
Pin number
416 TEPBGA
DRAM Data Bus
DDR_DQ[31]
DRAM Data Bus [31]
I/O
DDR
PCR[237] None, None
A6
DDR_DQ[30]
DRAM Data Bus [30]
I/O
DDR
PCR[238] None, None
A5
DDR_DQ[29]
DRAM Data Bus [29]
I/O
DDR
PCR[239] None, None
A4
DDR_DQ[28]
DRAM Data Bus [28]
I/O
DDR
PCR[240] None, None
A3
DDR_DQ[27]
DRAM Data Bus [27]
I/O
DDR
PCR[241] None, None
A2
DDR_DQ[26]
DRAM Data Bus [26]
I/O
DDR
PCR[242] None, None
A1
DDR_DQ[25]
DRAM Data Bus [25]
I/O
DDR
PCR[243] None, None
B1
DDR_DQ[24]
DRAM Data Bus [24]
I/O
DDR
PCR[244] None, None
C4
DDR_DQ[23]
DRAM Data Bus [23]
I/O
DDR
PCR[245] None, None
C1
DDR_DQ[22]
DRAM Data Bus [22]
I/O
DDR
PCR[246] None, None
D4
DDR_DQ[21]
DRAM Data Bus [21]
I/O
DDR
PCR[247] None, None
D3
DDR_DQ[20]
DRAM Data Bus [20]
I/O
DDR
PCR[248] None, None
D2
DDR_DQ[19]
DRAM Data Bus [19]
I/O
DDR
PCR[249] None, None
D1
DDR_DQ[18]
DRAM Data Bus [18]
I/O
DDR
PCR[250] None, None
E4
DDR_DQ[17]
DRAM Data Bus [17]
I/O
DDR
PCR[251] None, None
E1
DDR_DQ[16]
DRAM Data Bus [16]
I/O
DDR
PCR[252] None, None
F1
DDR_DQ[15]
DRAM Data Bus [15]
I/O
DDR
PCR[253] None, None
G1
DDR_DQ[14]
DRAM Data Bus [14]
I/O
DDR
PCR[254] None, None
G4
DDR_DQ[13]
DRAM Data Bus [13]
I/O
DDR
PCR[255] None, None
H1
DDR_DQ[12]
DRAM Data Bus [12]
I/O
DDR
PCR[256] None, None
H4
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
31
Pinout and signal descriptions
Table 6. DRAM interface pin summary (continued)
Port pin1
Function
I/O
direction
Pad
type
PCR
RESET
config2
Pin number
416 TEPBGA
DDR_DQ[11]
DRAM Data Bus [11]
I/O
DDR
PCR[257] None, None
J1
DDR_DQ[10]
DRAM Data Bus [10]
I/O
DDR
PCR[258] None, None
K4
DDR_DQ[9]
DRAM Data Bus [9]
I/O
DDR
PCR[259] None, None
K1
DDR_DQ[8]
DRAM Data Bus [8]
I/O
DDR
PCR[260] None, None
L1
DDR_DQ[7]
DRAM Data Bus [7]
I/O
DDR
PCR[261] None, None
L4
DDR_DQ[6]
DRAM Data Bus [6]
I/O
DDR
PCR[262] None, None
M4
DDR_DQ[5]
DRAM Data Bus [5]
I/O
DDR
PCR[263] None, None
M1
DDR_DQ[4]
DRAM Data Bus [4]
I/O
DDR
PCR[264] None, None
N4
DDR_DQ[3]
DRAM Data Bus [3]
I/O
DDR
PCR[265] None, None
N1
DDR_DQ[2]
DRAM Data Bus [2]
I/O
DDR
PCR[266] None, None
P4
DDR_DQ[1]
DRAM Data Bus [1]
I/O
DDR
PCR[267] None, None
P1
DDR_DQ[0]
DRAM Data Bus [0]
I/O
DDR
PCR[268] None, None
R1
DRAM Data Strobes
DDR_DQS[3]
DRAM Data Strobe [3]
I/O
DDR
PCR[232] None, None
B3
DDR_DQS[2]
DRAM Data Strobe [2]
I/O
DDR
PCR[231] None, None
G2
DDR_DQS[1]
DRAM Data Strobe [1]
I/O
DDR
PCR[230] None, None
K2
DDR_DQS[0]
DRAM Data Strobe [0]
I/O
DDR
PCR[229] None, None
N2
DRAM Data Enables
DDR_DM[3]
DRAM Data Enable [3]
Output
DDR
PCR[236]
Output,
None
B4
DDR_DM[2]
DRAM Data Enable [2]
Output
DDR
PCR[235]
Output,
None
G3
DDR_DM[1]
DRAM Data Enable [1]
Output
DDR
PCR[234]
Output,
None
K3
DDR_DM[0]
DRAM Data Enable [0]
Output
DDR
PCR[233]
Output,
None
P3
DDR_A[15]
DRAM address [15]
Output
DDR
PCR[217]
Output,
None
B15
DDR_A[14]
DRAM address [14]
Output
DDR
PCR[216]
Output,
None
D15
DDR_A[13]
DRAM address [13]
Output
DDR
PCR[215]
Output,
None
D14
DDR_A[12]
DRAM address [12]
Output
DDR
PCR[214]
Output,
None
A14
DDR_A[11]
DRAM address [11]
Output
DDR
PCR[213]
Output,
None
D13
DRAM Address
PXD20 Microcontroller Data Sheet, Rev. 2
32
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Pinout and signal descriptions
Table 6. DRAM interface pin summary (continued)
Port pin1
Function
I/O
direction
Pad
type
PCR
RESET
config2
Pin number
416 TEPBGA
DDR_A[10]
DRAM address [10]
Output
DDR
PCR[212]
Output,
None
C13
DDR_A[9]
DRAM address [9]
Output
DDR
PCR[211]
Output,
None
B13
DDR_A[8]
DRAM address [8]
Output
DDR
PCR[210]
Output,
None
A13
DDR_A[7]
DRAM address [7]
Output
DDR
PCR[209]
Output,
None
B12
DDR_A[6]
DRAM address [6]
Output
DDR
PCR[208]
Output,
None
A12
DDR_A[5]
DRAM address [5]
Output
DDR
PCR[207]
Output,
None
D11
DDR_A[4]
DRAM address [4]
Output
DDR
PCR[206]
Output,
None
A11
DDR_A[3]
DRAM address [3]
Output
DDR
PCR[205]
Output,
None
D10
DDR_A[2]
DRAM address [2]
Output
DDR
PCR[204]
Output,
None
C10
DDR_A[1]
DRAM address [1]
Output
DDR
PCR[203]
Output,
None
B10
DDR_A[0]
DRAM address [0]
Output
DDR
PCR[202]
Output,
None
A10
DRAM Bank Address
DDR_BA[2]
DRAM Bank Address[2]
Output
DDR
PCR[220]
Output,
None
A9
DDR_BA[1]
DRAM Bank Address[1]
Output
DDR
PCR[219]
Output,
None
A8
DDR_BA[0]
DRAM Bank Address[0]
Output
DDR
PCR[218]
Output,
None
A7
DDR_CAS
Column Address Strobe
Output
DDR
PCR[221]
Output,
None
B6
DDR_RAS
Row Address Strobe
Output
DDR
PCR[227]
Output,
None
B7
DDR_WEB
Write Enable
Output
DDR
PCR[228]
Output,
None
B9
DDR_ODT
DRAM On-die termination
Output
DDR
PCR[226]
Output,
Pull Down
D5
DDR_CLK
DRAM Clock
Output
DDR
PCR[225]
Output,
None
C7
DRAM Control
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
33
Pinout and signal descriptions
Table 6. DRAM interface pin summary (continued)
Port pin1
Function
I/O
direction
Pad
type
PCR
Pin number
RESET
config2
416 TEPBGA
DDR_CLKB
DRAM Clock bar
Output
DDR
NA
Output,
None
D7
DDR_CK
DRAM Clock Enable
Output
DDR
PCR[222]
Output,
Pull Down
D8
DDR_CS
DRAM Chip Select
Output
DDR
PCR[223]
Output,
None
D9
MVREF
DDR Reference Voltage
Input
—
NA
—
J4
MVTT
DRAM Termination Voltage
Input
—
NA
—
F2,J2,M2,R2
1
2
These port pins are disabled and unpowered on packages where the DRAM interface is not bonded out.
Reset configuration is given as I/O direction and pull direction (for example, “Input, pullup”).
2.4.7
VIU muxing
The DCU3, DCULite and VIU2 modules share the same pins for input video. It is, however, possibile to feed independent video
streams to VIU2 and DCU3 (operating in narrow mode). Figure 5 explains the pin sharing arrangement.
DE
PDI_PCLK
Direct feed of PDI interface
to DCU3 or DCULite
VSYNC
HSYNC
DATA[17:0]
DATA[7:0]
DATA[17:8]
VIU_PCLK
VIU[9:0]
VIU2
DCU3
PDI
DCULite
PDI
RGB565
RGB888
8-bit mono
YUV422
XBAR
Figure 5. VIU2, DCU3, and DCULite pin sharing
VIU input data selection is done based on select bit (bit 0) of Miscellaneous control register (0xC3FE0340).
•
•
•
VIU pix data: VIU[9:0]
Select bit 1’b0: PDI[7:0],HSYNC,VSYNC
Select bit 1’b1: PDI[17:8]
PXD20 Microcontroller Data Sheet, Rev. 2
34
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Pinout and signal descriptions
2.4.8
SGM muxing
The SGM shares pins between the PWM output signals and the I2S bus signals as shown in the “Port pin summary” table. When
the PWM function is enabled in the SGM (SGMCTL[PWME]) the PWM (PWMO, PWMOA) signals are available. When the
PWM function is disabled the I2S bus signals (I2S_DO, I2S_SCK) are available.
2.4.9
RSDS special function muxing
Ports PA[0:15], PG[0:7], PG[11] and PM[2] have the RSDS signalling option as a special function. The SIUL allocates pad
control registers to these functions (PCR[270:282]), but because these pads share a common pin with the normal GPIO pins
they do not operate in the same way as the normal GPIO ports. PG[11] in particular has a special configuration separate from
the other pads.
The special-function pads are output-only, and the associated PCR[OBE] bit is controlled by the TCON_CTRL1 register
(TCON_BYPASS and RSDS_MODE bits). However, the alternate function selection is taken from the associated normal GPIO
pad. This allows selection of the DCU3 function as the alternate function of the pad and then the TCON module to select if the
output style is TCON/RSDS or digital RGB format.
Therefore, when the TCON bypass is active (bypass disabled with or without RSDS active), it is important not to configure the
normal GPIO ports for output operation with a non-DCU3 alternate function on ports PA[0:15] and PG[0:7].
For PG[11], the PCR[282] OBE bit is fully controlled by the TCON module and will become an output whenever the DCU3
alternate option is selected. Therefore, only select the DCU3 function on this pin when ready to configure it as a clock for a TFT
panel.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
35
Functional ports
Pinout and signal descriptions
36
2.4.10
The functional port pins are listed in Table 7. The following pad types are available for system pins and functional port pins:
•
•
•
•
•
•
•
•
S — Slow (pad_ssr, pad_ssr_hv)
M — Medium (pad_msr, pad_msr_hv)
F — Fast (pad_fc)
J — Input/output with analog features (pad_tgate, pad_tgate_hv)
Analog — Input only with analog features (pad_ae, pad_ae_hv)
SMD — Stepper Motor Detector
DDR — DDR pads
RSDS — RSDS pads
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Table 7. Port pin summary
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PORT A
Freescale Semiconductor
PA[0]
PCR[0]
Option 0
Option 1
Option 2
Option 3
GPIO[0]
DCU_R0
SDA_1
eMIOS0[18]
RSDS0P
SIUL
DCU3
I2C_1
PWM/Timer
I/O
M/
RSDS
None,
none
116
139
K26
PA[1]
PCR[1]
Option 0
Option 1
Option 2
Option 3
GPIO[1]
DCU_R1
SCL_1
eMIOS0[17]
RSDS0M
SIUL
DCU3
I2C_1
PWM/Timer
I/O
M/
RSDS
None,
none
117
140
K25
PA[2]
PCR[2]
Option 0
Option 1
Option 2
Option 3
GPIO[2]
DCU_R2
—
—
RSDS1P
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
118
141
K23
PA[3]
PCR[3]
Option 0
Option 1
Option 2
Option 3
GPIO[3]
DCU_R3
—
—
RSDS1M
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
119
142
J23
PA[4]
PCR[4]
Option 0
Option 1
Option 2
Option 3
GPIO[4]
DCU_R4
—
—
RSDS2P
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
120
143
J26
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[5]
Option 0
Option 1
Option 2
Option 3
GPIO[5]
DCU_R5
—
—
RSDS2M
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
121
144
J25
PA[6]
PCR[6]
Option 0
Option 1
Option 2
Option 3
GPIO[6]
DCU_R6
—
—
RSDS3P
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
124
148
H26
PA[7]
PCR[7]
Option 0
Option 1
Option 2
Option 3
GPIO[7]
DCU_R7
—
—
RSDS3M
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
125
149
G26
PA[8]
PCR[8]
Option 0
Option 1
Option 2
Option 3
GPIO[8]
DCU_G0
SCL_2
eMIOS0[20]
RSDS4P
SIUL
DCU3
I2C_2
PWM/Timer
I/O
M/
RSDS
None,
none
126
150
G25
PA[9]
PCR[9]
Option 0
Option 1
Option 2
Option 3
GPIO[9]
DCU_G1
SDA_2
eMIOS0[19]
RSDS4M
SIUL
DCU3
I2C_2
PWM/Timer
I/O
M/
RSDS
None,
none
127
151
G24
PA[10]
PCR[10]
Option 0
Option 1
Option 2
Option 3
GPIO[10]
DCU_G2
—
—
RSDS5P
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
128
152
H23
PA[11]
PCR[11]
Option 0
Option 1
Option 2
Option 3
GPIO[11]
DCU_G3
—
—
RSDS5M
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
129
153
G23
PA[12]
PCR[12]
Option 0
Option 1
Option 2
Option 3
GPIO[12]
DCU_G4
—
—
RSDS6P
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
130
154
F26
PA[13]
PCR[13]
Option 0
Option 1
Option 2
Option 3
GPIO[13]
DCU_G5
—
—
RSDS6M
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
131
155
F25
Pinout and signal descriptions
37
PA[5]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PA[14]
PCR[14]
Option 0
Option 1
Option 2
Option 3
GPIO[14]
DCU_G6
—
—
RSDS7P
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
134
158
F24
PA[15]
PCR[15]
Option 0
Option 1
Option 2
Option 3
GPIO[15]
DCU_G7
—
—
RSDS7M
SIUL
DCU3
—
—
I/O
M/
RSDS
None,
none
135
159
F23
PB[0]
PCR[16]
Option 0
Option 1
Option 2
Option 3
GPIO[16]
CANTX_0
TXD_0
—
—
SIUL
FlexCAN_0
LINFlex_0
—
I/O
S
None,
none
13
13
W4
PB[1]
PCR[17]
Option 0
Option 1
Option 2
Option 3
GPIO[17]
CANRX_0
RXD_0
—
—
SIUL
FlexCAN_0
LINFlex_0
—
I/O
S
None,
none
12
12
V1
PB[2]
PCR[18]
Option 0
Option 1
Option 2
Option 3
GPIO[18]
TXD_0
—
—
—
SIUL
LINFlex_0
—
—
I/O
S
None,
none
153
183
D21
PB[3]
PCR[19]
Option 0
Option 1
Option 2
Option 3
GPIO[19]
RXD_0
—
—
—
SIUL
LINFlex_0
—
—
I/O
S
None,
none
152
182
A22
PB[4]
PCR[20]
Option 0
Option 1
Option 2
Option 3
GPIO[20]
SCK_1
MA0
—
—
SIUL
DSPI_1
ADC
—
I/O
S
None,
none
62
74
AF15
PB[5]
PCR[21]
Option 0
Option 1
Option 2
Option 3
GPIO[21]
SOUT_1
MA1
FABM
—
SIUL
DSPI_1
ADC
Control
I/O
S
Input,
pulldown
63
75
AC16
PORT B
Pinout and signal descriptions
38
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[22]
Option 0
Option 1
Option 2
Option 3
GPIO[22]
SIN_1
MA2
ABS[0]
—
SIUL
DSPI_1
ADC
Control
I/O
S
Input,
pullup
64
76
AF16
PB[7]
PCR[23]
Option 0
Option 1
Option 2
Option 3
GPIO[23]
SIN_0
eMIOS1[20]
I2S_SCK/PWMOA
—
SIUL
DSPI_0
PWM/Timer
SGM
I/O
S
None,
none
55
67
AC14
PB[8]
PCR[24]
Option 0
Option 1
Option 2
Option 3
GPIO[24]
SOUT_0
eMIOS1[19]
I2S_DO/PWMO
—
SIUL
DSPI_0
PWM/Timer
SGM
I/O
S
None,
none
54
66
AF13
PB[9]
PCR[25]
Option 0
Option 1
Option 2
Option 3
GPIO[25]
SCK_0
eMIOS1[18]
I2S_FS
—
SIUL
DSPI_0
PWM/Timer
SGM
I/O
M
None,
none
53
65
AC13
PB[10] PCR[26]
Option 0
Option 1
Option 2
Option 3
GPIO[26]
CANRX_1
I2S_DO/PWMO
—
—
SIUL
FlexCAN_1
SGM
—
I/O
S
None,
none
14
14
W2
PB[11] PCR[27]
Option 0
Option 1
Option 2
Option 3
GPIO[27]
CANTX_1
SGM_MCLK
—
—
SIUL
FlexCAN_1
SGM
—
I/O
S
None,
none
15
15
Y4
PB[12] PCR[28]
Option 0
Option 1
Option 2
Option 3
GPIO[28]
RXD_1
eMIOS1[10]
CS2_0
—
SIUL
LINFlex_1
PWM/Timer
DSPI_0
I/O
S
None,
none
46
54
AF7
PB[13] PCR[29]
Option 0
Option 1
Option 2
Option 3
GPIO[29]
TXD_1
eMIOS1[11]
CS1_0
—
SIUL
LINFlex_1
PWM/Timer
DSPI_0
I/O
S
None,
none
47
55
AC8
PB[14]
—
—
Reserved
—
—
—
—
—
—
—
—
PB[15]
—
—
Reserved
—
—
—
—
—
—
—
—
39
Pinout and signal descriptions
PB[6]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PORT C
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PC[0]
PCR[30]
Option 0
Option 1
Option 2
Option 3
GPIO[30]
—
—
—
ANS[0]
SIUL
—
—
—
I/O
J
None,
none
88
104
AC21
PC[1]
PCR[31]
Option 0
Option 1
Option 2
Option 3
GPIO[31]
—
—
—
ANS[1]
SIUL
—
—
—
I/O
J
None,
none
87
103
AC25
PC[2]
PCR[32]
Option 0
Option 1
Option 2
Option 3
GPIO[32]
—
—
—
ANS[2]
SIUL
—
—
—
I/O
J
None,
none
86
102
AC26
PC[3]
PCR[33]
Option 0
Option 1
Option 2
Option 3
GPIO[33]
—
—
—
ANS[3]
SIUL
—
—
—
I/O
J
None,
none
85
101
AC24
PC[4]
PCR[34]
Option 0
Option 1
Option 2
Option 3
GPIO[34]
—
—
—
ANS[4]
SIUL
—
—
—
I/O
J
None,
none
84
100
AD24
PC[5]
PCR[35]
Option 0
Option 1
Option 2
Option 3
GPIO[35]
—
—
—
ANS[5]
SIUL
—
—
—
I/O
J
None,
none
83
99
AD26
PC[6]
PCR[36]
Option 0
Option 1
Option 2
Option 3
GPIO[36]
—
—
—
ANS[6]
SIUL
—
—
—
I/O
J
None,
none
82
98
AD21
PC[7]
PCR[37]
Option 0
Option 1
Option 2
Option 3
GPIO[37]
—
—
—
ANS[7]
SIUL
—
—
—
I/O
J
None,
none
81
97
AD25
PC[8]
PCR[38]
Option 0
Option 1
Option 2
Option 3
GPIO[38]
—
—
—
ANS[8]
SIUL
—
—
—
I/O
J
None,
none
76
92
AE26
Pinout and signal descriptions
40
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PC[9]
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Option 0
Option 1
Option 2
Option 3
GPIO[39]
—
—
—
ANS[9]
SIUL
—
—
—
I/O
J
None,
none
75
91
AE25
PC[10] PCR[40]
Option 0
Option 1
Option 2
Option 3
GPIO[40]
—
I2S_DO/PWMO
—
ANS[10]
SIUL
—
SGM
—
I/O
J
None,
none
74
90
AE23
PC[11] PCR[41]
Option 0
Option 1
Option 2
Option 3
GPIO[41]
—
MA0
CS2_1
ANS[11]
SIUL
—
ADC
DSPI_1
I/O
J
None,
None
73
89
AE24
PC[12] PCR[42]
Option 0
Option 1
Option 2
Option 3
GPIO[42]
—
MA1
CS1_1
ANS[12]
SIUL
—
ADC
DSPI_1
I/O
J
None,
None
72
88
AF26
PC[13] PCR[43]
Option 0
Option 1
Option 2
Option 3
GPIO[43]
—
MA2
CS0_1
ANS[13]
SIUL
—
ADC
DSPI_1
I/O
J
None,
None
71
87
AF25
PC[14] PCR[44]
Option 0
Option 1
Option 2
Option 3
GPIO[44]
—
—
—
ANS[14]
EXTAL32
SIUL
—
—
—
I/O
J
None,
None
70
86
AF24
PC[15] PCR[45]
Option 0
Option 1
Option 2
Option 3
GPIO[45]
—
—
—
ANS[15]
XTAL32
SIUL
—
—
—
I/O
J
None,
None
69
85
AF23
PORT D
41
PD[0]
PCR[46]
Option 0
Option 1
Option 2
Option 3
GPIO[46]
M0C0M
SSD0_0
eMIOS1[8]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
90
106
AB26
PD[1]
PCR[47]
Option 0
Option 1
Option 2
Option 3
GPIO[47]
M0C0P
SSD0_1
eMIOS1[16]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
91
107
AB25
Pinout and signal descriptions
PCR[39]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PD[2]
PCR[48]
Option 0
Option 1
Option 2
Option 3
GPIO[48]
M0C1M
SSD0_2
eMIOS1[23]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
92
108
AB24
PD[3]
PCR[49]
Option 0
Option 1
Option 2
Option 3
GPIO[49]
M0C1P
SSD0_3
eMIOS0[9]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
93
109
AB23
PD[4]
PCR[50]
Option 0
Option 1
Option 2
Option 3
GPIO[50]
M1C0M
SSD1_0
eMIOS0[8]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
96
112
AA26
PD[5]
PCR[51]
Option 0
Option 1
Option 2
Option 3
GPIO[51]
M1C0P
SSD1_1
eMIOS0[16]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
97
113
AA23
PD[6]
PCR[52]
Option 0
Option 1
Option 2
Option 3
GPIO[52]
M1C1M
SSD1_2
eMIOS0[23]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
98
114
Y26
PD[7]
PCR[53]
Option 0
Option 1
Option 2
Option 3
GPIO[53]
M1C1P
SSD1_3
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
99
115
Y25
PD[8]
PCR[54]
Option 0
Option 1
Option 2
Option 3
GPIO[54]
M2C0M
SSD2_0
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
100
116
Y24
PD[9]
PCR[55]
Option 0
Option 1
Option 2
Option 3
GPIO[55]
M2C0P
SSD2_1
eMIOS0[9]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
101
117
Y23
PD[10] PCR[56]
Option 0
Option 1
Option 2
Option 3
GPIO[56]
M2C1M
SSD2_2
eMIOS0[10]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
102
118
W26
Pinout and signal descriptions
42
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PD[11] PCR[57]
Option 0
Option 1
Option 2
Option 3
GPIO[57]
M2C1P
SSD2_3
eMIOS0[11]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
103
119
W23
PD[12] PCR[58]
Option 0
Option 1
Option 2
Option 3
GPIO[58]
M3C0M
SSD3_0
eMIOS0[12]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
106
122
V26
PD[13] PCR[59]
Option 0
Option 1
Option 2
Option 3
GPIO[59]
M3C0P
SSD3_1
eMIOS0[13]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
107
123
V25
PD[14] PCR[60]
Option 0
Option 1
Option 2
Option 3
GPIO[60]
M3C1M
SSD3_2
eMIOS0[14]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
108
124
V24
PD[15] PCR[61]
Option 0
Option 1
Option 2
Option 3
GPIO[61]
M3C1P
SSD3_3
eMIOS0[15]
—
SIUL
SMD
SSD
PWM/Timer
I/O
SMD
None,
None
109
125
V23
PORT E
PCR[62]
Option 0
Option 1
Option 2
Option 3
GPIO[62]
M4C0M
SSD4_0
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
126
U26
PE[1]
PCR[63]
Option 0
Option 1
Option 2
Option 3
GPIO[63]
M4C0P
SSD4_1
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
127
U23
PE[2]
PCR[64]
Option 0
Option 1
Option 2
Option 3
GPIO[64]
M4C1M
SSD4_2
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
128
T26
43
Pinout and signal descriptions
PE[0]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PE[3]
PCR[65]
Option 0
Option 1
Option 2
Option 3
GPIO[65]
M4C1P
SSD4_3
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
129
T25
PE[4]
PCR[66]
Option 0
Option 1
Option 2
Option 3
GPIO[66]
M5C0M
SSD5_0
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
132
T24
PE[5]
PCR[67]
Option 0
Option 1
Option 2
Option 3
GPIO[67]
M5C0P
SSD5_1
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
133
T23
PE[6]
PCR[68]
Option 0
Option 1
Option 2
Option 3
GPIO[68]
M5C1M
SSD5_2
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
134
R24
PE[7]
PCR[69]
Option 0
Option 1
Option 2
Option 3
GPIO[69]
M5C1P
SSD5_3
—
—
SIUL
SMD
SSD
—
I/O
SMD
None,
None
—
135
R23
PF[0]
PCR[70]
Option 0
Option 1
Option 2
Option 3
GPIO[70]
eMIOS1[19]
EVTO
DCULITE_B2
—
SIUL
PWM/Timer
NEXUS
DCULite
I/O
M
None,
None
157
189
C20
PF[1]
PCR[71]
Option 0
Option 1
Option 2
Option 3
GPIO[71]
eMIOS1[20]
MSEO
DCULITE_B3
—
SIUL
PWM/Timer
NEXUS
DCULite
I/O
M
None,
None
158
190
B20
PF[2]
PCR[72]
Option 0
Option 1
Option 2
Option 3
GPIO[72]
NMI
—
—
—
SIUL
NMI
—
—
I/O
S
None,
None
45
53
AC7
PORT F
Pinout and signal descriptions
44
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[73]
Option 0
Option 1
Option 2
Option 3
GPIO[73]
eMIOS1[21]
MSEO
DCULITE_B4
—
SIUL
PWM/Timer
NEXUS
DCULite
I/O
M
None,
None
159
191
A20
PF[4]
PCR[74]
Option 0
Option 1
Option 2
Option 3
GPIO[74]
eMIOS1[14]
SDA_1
DCULITE_B5
—
SIUL
PWM/Timer
I2C_1
DCULite
I/O
M
None,
None
160
192
D19
PF[5]
PCR[75]
Option 0
Option 1
Option 2
Option 3
GPIO[75]
QUADSPI_IO1_B
eMIOS1[15]
VIU8_PDI16
—
SIUL
QuadSPI
PWM/Timer
VIU2/PDI
I/O
M
None,
None
161
193
A19
PF[6]
PCR[76]
Option 0
Option 1
Option 2
Option 3
GPIO[76]
QUADSPI_IO0_B
eMIOS1[16]
VIU9_PDI17
—
SIUL
QuadSPI
PWM/Timer
VIU2/PDI
I/O
M
None,
None
162
194
D18
PF[7]
PCR[77]
Option 0
Option 1
Option 2
Option 3
GPIO[77]
eMIOS1[15]
SCL_1
DCULITE_B6
—
SIUL
PWM/Timer
I2C_1
DCULite
I/O
M
None,
None
163
195
C18
PF[8]
PCR[78]
Option 0
Option 1
Option 2
Option 3
GPIO[78]
SDA_0
CS2_1
RXD_1
—
SIUL
I2C_0
DSPI_1
LINFlex_1
I/O
S
None,
None
164
196
A18
PF[9]
PCR[79]
Option 0
Option 1
Option 2
Option 3
GPIO[79]
SCL_0
CS1_1
TXD_1
—
SIUL
I2C_0
DSPI_1
LINFlex_1
I/O
S
None,
None
165
197
D17
PF[10] PCR[80]
Option 0
Option 1
Option 2
Option 3
GPIO[80]
QUADSPI_PCS_A
—
EVTI
—
SIUL
QuadSPI
—
NEXUS
I/O
M
None,
None
169
201
A17
PF[11] PCR[81]
Option 0
Option 1
Option 2
Option 3
GPIO[81]
QUADSPI_IO2_A
—
MDO0
—
SIUL
QuadSPI
—
NEXUS
I/O
M
None,
None
170
202
D16
Pinout and signal descriptions
45
PF[3]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PF[12] PCR[82]
Option 0
Option 1
Option 2
Option 3
GPIO[82]
QUADSPI_IO3_A
—
MDO1
—
SIUL
QuadSPI
—
NEXUS
I/O
M
None,
None
171
203
C16
PF[13] PCR[83]
Option 0
Option 1
Option 2
Option 3
GPIO[83]
QUADSPI_IO0_A
—
MDO2
—
SIUL
QuadSPI
—
NEXUS
I/O
M
None,
None
172
204
B16
PF[14] PCR[84]
Option 0
Option 1
Option 2
Option 3
GPIO[84]
QUADSPI_IO1_A
—
MDO3
—
SIUL
QuadSPI
—
NEXUS
I/O
M
None,
None
173
205
A16
PF[15] PCR[85]
Option 0
Option 1
Option 2
Option 3
GPIO[85]
QUADSPI_CLK_A
CLKOUT
MCKO
—
SIUL
QuadSPI
Control
NEXUS
I/O
F
None,
None
174
206
B18
PORT G
Freescale Semiconductor
PG[0]
PCR[86]
Option 0
Option 1
Option 2
Option 3
GPIO[86]
DCU_B0
SCL_3
eMIOS0[21]
RSDS8P
SIUL
DCU3
I2C_3
PWM/Timer
I/O
M
None,
None
136
160
E26
PG[1]
PCR[87]
Option 0
Option 1
Option 2
Option 3
GPIO[87]
DCU_B1
SDA_3
eMIOS0[22]
RSDS8M
SIUL
DCU3
I2C_3
PWM/Timer
I/O
M
None,
None
137
161
D26
PG[2]
PCR[88]
Option 0
Option 1
Option 2
Option 3
GPIO[88]
DCU_B2
—
—
RSDS9P
SIUL
DCU3
—
—
I/O
M
None,
None
141
166
D25
PG[3]
PCR[89]
Option 0
Option 1
Option 2
Option 3
GPIO[89]
DCU_B3
—
—
RSDS9M
SIUL
DCU3
—
—
I/O
M
None,
None
142
167
C25
Pinout and signal descriptions
46
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[90]
Option 0
Option 1
Option 2
Option 3
GPIO[90]
DCU_B4
—
—
RSDS10P
SIUL
DCU3
—
—
I/O
M
None,
None
143
168
C26
PG[5]
PCR[91]
Option 0
Option 1
Option 2
Option 3
GPIO[91]
DCU_B5
—
—
RSDS10M
SIUL
DCU3
—
—
I/O
M
None,
None
144
169
B26
PG[6]
PCR[92]
Option 0
Option 1
Option 2
Option 3
GPIO[92]
DCU_B6
—
—
RSDS11P
SIUL
DCU3
—
—
I/O
M
None,
None
145
170
A26
PG[7]
PCR[93]
Option 0
Option 1
Option 2
Option 3
GPIO[93]
DCU_B7
—
—
RSDS11M
SIUL
DCU3
—
—
I/O
M
None,
None
146
171
A25
PG[8]
PCR[94]
Option 0
Option 1
Option 2
Option 3
GPIO[94]
DCU_VSYNC
—
—
—
SIUL
DCU3
—
—
I/O
M
None,
None
1
1
T4
PG[9]
PCR[95]
Option 0
Option 1
Option 2
Option 3
GPIO[95]
DCU_HSYNC
—
—
—
SIUL
DCU3
—
—
I/O
M
None,
None
2
2
T2
PG[10] PCR[96]
Option 0
Option 1
Option 2
Option 3
GPIO[96]
DCU_DE
—
—
—
SIUL
DCU3
—
—
I/O
M
None,
None
3
3
T1
PG[11] PCR[97]
Option 0
Option 1
Option 2
Option 3
GPIO[97]
DCU_PCLK
—
—
RSDSCLKP SIUL
DCU3
—
—
I/O
F
None,
None
147
172
E23
PG[12] PCR[98]
Option 0
Option 1
Option 2
Option 3
GPIO[98]
CS0_1
PDI_DE
DCULITE_B7
I/O
M
None,
None
168
200
A15
—
SIUL
DSPI_1
PDI
DCULite
Pinout and signal descriptions
47
PG[4]
Port
pin
PCR
Alternate
function1
PG[13]
—
—
PG[14]
—
PG[15]
—
I/O
direction
Pad RESET
Type4 config5
Pin number
Special
function2
Peripheral3
Reserved
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
GPIO[99]
TCK
—
—
—
SIUL
JTAG
—
—
I/O
S
Input,
Pull Up
41
49
AC6
PH[1]6 PCR[100] Option 0
Option 1
Option 2
Option 3
GPIO[100]
TDI
—
—
—
SIUL
JTAG
—
—
I/O
S
Input,
Pull Up
42
50
AD6
PH[2]6 PCR[101] Option 0
Option 1
Option 2
Option 3
GPIO[101]
TDO
—
—
—
SIUL
JTAG
—
—
I/O
M
Output,
None
43
51
AE6
PH[3]6 PCR[102] Option 0
Option 1
Option 2
Option 3
GPIO[102]
TMS
—
—
—
SIUL
JTAG
—
—
I/O
S
Input,
Pull Up
44
52
AF6
PH[4]
PCR[103] Option 0
Option 1
Option 2
Option 3
GPIO[103]
CS0_0
eMIOS1[21]
DCULITE_G6
—
SIUL
DSPI_0
PWM/Timer
DCULite
I/O
M
None,
None
61
73
AE15
PH[5]
PCR[104] Option 0
Option 1
Option 2
Option 3
GPIO[104]
VIU7_PDI15
I2S_FS
eMIOS1[8]
—
SIUL
VIU2/PDI
SGM
PWM/Timer
I/O
S
None,
None
38
—
—
Function
176 LQFP 208 LQFP 416 TEPBGA
PORT H
PH[0]6 PCR[99]
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Option 0
Option 1
Option 2
Option 3
Freescale Semiconductor
PH[6]
—
—
Reserved
—
—
—
—
—
—
—
—
PH[7]
—
—
Reserved
—
—
—
—
—
—
—
—
PH[8]
—
—
Reserved
—
—
—
—
—
—
—
—
PH[9]
—
—
Reserved
—
—
—
—
—
—
—
—
PH[10]
—
—
Reserved
—
—
—
—
—
—
—
—
Pinout and signal descriptions
48
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
PH[11]
—
—
PH[12]
—
PH[13]
I/O
direction
Pad RESET
Type4 config5
Pin number
Special
function2
Peripheral3
Reserved
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
PH[14]
—
—
Reserved
—
—
—
—
—
—
—
—
PH[15]
—
—
Reserved
—
—
—
—
—
—
—
—
Function
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PORT J
PCR[105] Option 0
Option 1
Option 2
Option 3
GPIO[105]
DCULITE_B6
—
I2S_DO / PWMO
—
SIUL
DCULite
—
SGM
I/O
M
None,
None
—
—
L26
PJ[1]
PCR[106] Option 0
Option 1
Option 2
Option 3
GPIO[106]
VIU1_PDI_HSYNC
eMIOS1[9]
eMIOS0[8]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
4
4
U4
PJ[2]
PCR[107] Option 0
Option 1
Option 2
Option 3
GPIO[107]
VIU0_PDI_VSYNC
eMIOS1[14]
eMIOS0[9]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
5
5
U3
PJ[3]
PCR[108] Option 0
Option 1
Option 2
Option 3
GPIO[108]
VIU_PCLK
eMIOS0[22]
PDI_DE
—
SIUL
VIU2
PWM/Timer
PDI
I/O
S
None,
None
60
72
AD15
PJ[4]
PCR[109] Option 0
Option 1
Option 2
Option 3
GPIO[109]
VIU2_PDI0
eMIOS0[21]
eMIOS0[23]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
56
68
AD14
PJ[5]
PCR[110] Option 0
Option 1
Option 2
Option 3
GPIO[110]
VIU3_PDI1
eMIOS0[20]
eMIOS0[16]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
M
None,
None
57
69
AE14
PJ[6]
PCR[111] Option 0
Option 1
Option 2
Option 3
GPIO[111]
VIU4_PDI2
eMIOS0[19]
eMIOS0[15]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
58
70
AF14
Pinout and signal descriptions
49
PJ[0]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PJ[7]
PCR[112] Option 0
Option 1
Option 2
Option 3
GPIO[112]
VIU5_PDI3
eMIOS0[18]
eMIOS0[14]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
59
71
AC15
PJ[8]
PCR[113] Option 0
Option 1
Option 2
Option 3
GPIO[113]
VIU6_PDI4
eMIOS0[17]
eMIOS0[13]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
8
8
U2
PJ[9]
PCR[114] Option 0
Option 1
Option 2
Option 3
GPIO[114]
VIU7_PDI5
eMIOS1[22]
eMIOS0[12]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
9
9
U1
PJ[10]
PCR[115] Option 0
Option 1
Option 2
Option 3
GPIO[115]
VIU8_PDI6
eMIOS1[17]
eMIOS0[11]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
10
10
V4
PJ[11]
PCR[116] Option 0
Option 1
Option 2
Option 3
GPIO[116]
VIU9_PDI7
eMIOS1[15]
eMIOS0[10]
—
SIUL
VIU2/PDI
PWM/Timer
PWM/Timer
I/O
S
None,
None
11
11
V3
PJ[12]
PCR[117] Option 0
Option 1
Option 2
Option 3
GPIO[117]
DCU_TAG
—
DCULITE_G6
—
SIUL
DCU3
—
DCULite
I/O
M
None,
None
148
178
A23
PJ[13]
PCR[118] Option 0
Option 1
Option 2
Option 3
GPIO[118]
QUADSPI_PCS_B
eMIOS1[8]
VIU5_PDI13
—
SIUL
QuadSPI
PWM/Timer
VIU2/PDI
I/O
M
None,
None
149
179
D22
PJ[14]
PCR[119] Option 0
Option 1
Option 2
Option 3
GPIO[119]
QUADSPI_CLK_B
eMIOS1[17]
PDI_PCLK
—
SIUL
QuadSPI
PWM/Timer
PDI
I/O
F
None,
None
150
180
C22
PJ[15]
PCR[120] Option 0
Option 1
Option 2
Option 3
GPIO[120]
QUADSPI_IO3_B
eMIOS1[9]
VIU6_PDI14
—
SIUL
QuadSPI
PWM/Timer
VIU2/PDI
I/O
M
None,
None
151
181
B22
Pinout and signal descriptions
50
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PORT K
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[121] Option 0
Option 1
Option 2
Option 3
GPIO[121]
eMIOS1[18]]
—
—
—
SIUL
PWM/Timer
—
—
I/O
M
None,
None
155
187
A21
PK[1]
PCR[122] Option 0
Option 1
Option 2
Option 3
GPIO[122]
QUADSPI_IO2_B
eMIOS1[14]
VIU7_PDI15
—
SIUL
QuadSPI
PWM/Timer
VIU2/PDI
I/O
M
None,
None
156
188
D20
PK[2]
PCR[123] Option 0
Option 1
Option 2
Option 3
GPIO[123]
VIU0_PDI8
eMIOS1[10]
DCULITE_TAG
—
SIUL
VIU2/PDI
PWM/Timer
DCULite
I/O
M
None,
None
31
39
AE3
PK[3]
PCR[124] Option 0
Option 1
Option 2
Option 3
GPIO[124]
VIU1_PDI9
eMIOS1[11]
DCULITE_DE
—
SIUL
VIU2/PDI
PWM/Timer
DCULite
I/O
M
None,
None
32
40
AF3
PK[4]
PCR[125] Option 0
Option 1
Option 2
Option 3
GPIO[125]
VIU2_PDI10
eMIOS1[12]
DCULITE_HSYNC
—
SIUL
VIU2/PDI
PWM/Timer
DCULite
I/O
M
None,
None
33
41
AC4
PK[5]
PCR[126] Option 0
Option 1
Option 2
Option 3
GPIO[126]
VIU3_PDI11
eMIOS1[13]
DCULITE_VSYNC
—
SIUL
VIU2/PDI
PWM/Timer
DCULite
I/O
M
None,
None
34
42
AF4
PK[6]
PCR[127] Option 0
Option 1
Option 2
Option 3
GPIO[127]
VIU4_PDI12
eMIOS1[9]
DCULITE_PCLK
—
SIUL
VIU2/PDI
PWM/Timer
DCULite
I/O
F
None,
None
35
43
AC5
PK[7]
PCR[128] Option 0
Option 1
Option 2
Option 3
GPIO[128]
RXD_2
DCULITE_R2
TCON[8]
—
SIUL
LINFlex_2
DCULite
TCON
I/O
M
None,
None
—
44
AD5
51
Pinout and signal descriptions
PK[0]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PK[8]
PCR[129] Option 0
Option 1
Option 2
Option 3
GPIO[129]
TXD_2
DCULITE_R3
TCON[9]
—
SIUL
LINFlex_2
DCULite
TCON
I/O
M
None,
None
—
45
AE5
PK[9]
PCR[130] Option 0
Option 1
Option 2
Option 3
GPIO[130]
I2S_DO / PWMO
DCULITE_R4
TCON[10]
—
SIUL
SGM
DCULite
TCON
I/O
M
None,
None
—
46
AF5
PK[10]
PCR[131] Option 0
Option 1
Option 2
Option 3
GPIO[131]
SDA_1
eMIOS1[12]
DCULITE_TAG
—
SIUL
I2C_1
PWM/Timer
DCULite
I/O
S
None,
None
51
59
AF8
PK[11]
PCR[132] Option 0
Option 1
Option 2
Option 3
GPIO[132]
SCL_1
eMIOS1[13]
DCU_TAG / TCON[3]
—
I/O
SIUL
I2C_1
PWM/Timer
DCU3 / TCON
S
None,
None
52
60
AC9
PK[12]
—
—
Reserved
—
—
—
—
—
—
—
—
PK[13]
—
—
Reserved
—
—
—
—
—
—
—
—
PK[14]
—
—
Reserved
—
—
—
—
—
—
—
—
PK[15]
—
—
Reserved
—
—
—
—
—
—
—
—
PORT L
Freescale Semiconductor
PL[0]
PCR[133] Option 0
Option 1
Option 2
Option 3
GPIO[133]
—
CANRX_1
—
ANS[19]
SIUL
—
FlexCAN_1
—
I/O
M/
None,
ANALO None
G
—
81
AE22
PL[1]
PCR[134] Option 0
Option 1
Option 2
Option 3
GPIO[134]
—
CANTX_1
—
ANS[18]
SIUL
—
FlexCAN_1
—
I/O
M/
None,
ANALO None
G
—
82
AE21
PL[2]
PCR[135] Option 0
Option 1
Option 2
Option 3
GPIO[135]
—
CANRX_0
eMIOS1[22]
ANS[17]
SIUL
—
FlexCAN_0
PWM/Timer
I/O
S/
None,
ANALO None
G
—
83
AF22
Pinout and signal descriptions
52
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PL[3]
PCR[136] Option 0
Option 1
Option 2
Option 3
GPIO[136]
—
CANTX_0
eMIOS1[23]
ANS[16]
PL[4]
PCR[137] Option 0
Option 1
Option 2
Option 3
GPIO[137]
CS2_2
VIU5_PDI13
TCON[6]
PL[5]
PCR[138] Option 0
Option 1
Option 2
Option 3
PL[6]
Peripheral3
I/O
direction
Pad RESET
Type4 config5
I/O
S/
None,
ANALO None
G
—
SIUL
DSPI_2
VIU2/PDI
TCON
I/O
M
GPIO[138]
CS1_2
VIU6_PDI14
TCON[7]
—
SIUL
DSPI_2
VIU2/PDI
TCON
I/O
PCR[139] Option 0
Option 1
Option 2
Option 3
GPIO[139]
CS0_2
VIU7_PDI15
eMIOS1[18]
—
SIUL
DSPI_2
VIU2/PDI
PWM/Timer
PL[7]
PCR[140] Option 0
Option 1
Option 2
Option 3
GPIO[140]
SIN_2
VIU8_PDI16
eMIOS1[19]
—
PL[8]
PCR[141] Option 0
Option 1
Option 2
Option 3
GPIO[141]
SOUT_2
VIU9_PDI17
eMIOS1[20]
PL[9]
PCR[142] Option 0
Option 1
Option 2
Option 3
PL[10]
PL[11]
176 LQFP 208 LQFP 416 TEPBGA
53
—
84
AF21
None,
None
—
31
AB2
M
None,
None
—
32
AC2
I/O
S
None,
None
—
33
AD1
SIUL
DSPI_2
VIU2/PDI
PWM/Timer
I/O
S
None,
None
—
34
AE1
—
SIUL
DSPI_2
VIU2/PDI
PWM/Timer
I/O
S
None,
None
—
35
AF1
GPIO[142]
SCK_2
PDI_PCLK
eMIOS1[21]
—
SIUL
DSPI_2
PDI
PWM/Timer
I/O
S
None,
None
—
36
AF2
PCR[143] Option 0
Option 1
Option 2
Option 3
GPIO[143]
eMIOS1[10]
DCULITE_G2
—
—
SIUL
PWM/Timer
DCULite
—
I/O
M
None,
None
—
174
C24
PCR[144] Option 0
Option 1
Option 2
Option 3
GPIO[144]
eMIOS1[11]
DCULITE_G3
—
—
SIUL
PWM/Timer
DCULite
—
I/O
M
None,
None
—
175
A24
Pinout and signal descriptions
SIUL
—
FlexCAN_0
PWM/Timer
Pin number
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PL[12]
PCR[145] Option 0
Option 1
Option 2
Option 3
GPIO[145]
eMIOS1[12]
DCULITE_G4
—
—
SIUL
PWM/Timer
DCULite
—
I/O
M
None,
None
—
176
C23
PL[13]
PCR[146] Option 0
Option 1
Option 2
Option 3
GPIO[146]
eMIOS1[13]
DCULITE_G5
—
—
SIUL
PWM/Timer
DCULite
—
I/O
M
None,
None
—
177
B23
PL[14]
—
—
Reserved
—
—
—
—
—
—
—
—
PL[15]
—
—
Reserved
—
—
—
—
—
—
—
—
PORT M
Freescale Semiconductor
PM[0]
PCR[147] Option 0
Option 1
Option 2
Option 3
GPIO[147]
I2S_SCK / PWMOA
DCULITE_R5
TCON[11]
—
SIUL
SGM
DCULite
TCON
I/O
M
None,
None
—
61
AE9
PM[1]
PCR[148] Option 0
Option 1
Option 2
Option 3
GPIO[148]
I2S_FS
DCULITE_R6
—
—
SIUL
SGM
DCULite
—
I/O
M
None,
None
—
62
AF9
PM[2]
PCR[149] Option 0
Option 1
Option 2
Option 3
GPIO[149]
eMIOS1[17]
DCULITE_R7
DCULITE_DE
I/O
M
None,
None
—
173
D23
PM[3]
PCR[150] Option 0
Option 1
Option 2
Option 3
GPIO[150]
CANRX_2
RXD_3
TCON[4]
—
SIUL
FlexCAN_2
LINFlex_3
TCON
I/O
M
None,
None
—
16
Y3
PM[4]
PCR[151] Option 0
Option 1
Option 2
Option 3
GPIO[151]
CANTX_2
TXD_3
TCON[5]
—
SIUL
FlexCAN_2
LINFlex_3
TCON
I/O
M
None,
None
—
17
Y2
PM[5]
PCR[152] Option 0
Option 1
Option 2
Option 3
GPIO[152]
VIU5_PDI13
eMIOS1[22]
DCU_TAG
—
SIUL
VIU2/PDI
PWM/Timer
DCU3
I/O
M
None,
None
16
—
—
RSDSCLKM SIUL
PWM/Timer
DCULite
DCULite
Pinout and signal descriptions
54
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[153] Option 0
Option 1
Option 2
Option 3
GPIO[153]
VIU6_PDI14
eMIOS1[23]
DCULITE_TAG
—
SIUL
VIU2/PDI
PWM/Timer
DCULite
I/O
M
None,
None
17
—
—
PM[7]
PCR[154] Option 0
Option 1
Option 2
Option 3
GPIO[154]
VIU8_PDI16
I2S_DO / PWMO
eMIOS1[16]
—
SIUL
VIU2/PDI
SGM
PWM/Timer
I/O
S
None,
None
39
—
—
PM[8]
PCR[155] Option 0
Option 1
Option 2
Option 3
GPIO[155]
VIU9_PDI17
I2S_SCK / PWMOA
eMIOS1[23]
—
SIUL
VIU2/PDI
SGM
PWM/Timer
I/O
S
None,
None
40
—
—
PM[9]
PCR[156] Option 0
Option 1
Option 2
Option 3
GPIO[156]
PDI_PCLK
SGM_MCLK
eMIOS0[8]
—
SIUL
PDI
SGM
PWM/Timer
I/O
M
None,
None
113
—
—
PM[10] PCR[157] Option 0
Option 1
Option 2
Option 3
GPIO[157]
RXD_2
CANRX_2
eMIOS0[16]
—
SIUL
LINFlex_2
FlexCAN_2
PWM/Timer
I/O
S
None,
None
114
—
—
PM[11] PCR[158] Option 0
Option 1
Option 2
Option 3
GPIO[158]
TXD_2
CANTX_2
eMIOS0[23]
—
SIUL
LINFlex_2
FlexCAN_2
PWM/Timer
I/O
S
None,
None
115
—
—
PM[12] PCR[159] Option 0
Option 1
Option 2
Option 3
GPIO[159]
DCULITE_B7
—
I2S_SCK / PWMOA
—
SIUL
DCULite
—
SGM
I/O
M
None,
None
—
—
L24
PM[13] PCR[160] Option 0
Option 1
Option 2
Option 3
GPIO[160]
DCULITE_PCLK
—
SGM_MCLK
—
SIUL
DCULite
—
SGM
I/O
F
None,
None
—
—
L23
PM[14]
—
—
Reserved
—
—
—
—
—
—
—
—
PM[15]
—
—
Reserved
—
—
—
—
—
—
—
—
55
Pinout and signal descriptions
PM[6]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PORT N
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PN[0]
PCR[161] Option 0
Option 1
Option 2
Option 3
GPIO[161]
DCULITE_HSYNC
—
TCON[4]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AC3
PN[1]
PCR[162] Option 0
Option 1
Option 2
Option 3
GPIO[162]
DCULITE_VSYNC
—
TCON[5]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AD3
PN[2]
PCR[163] Option 0
Option 1
Option 2
Option 3
GPIO[163]
DCULITE_R0
RXD_2
VIU0_PDI8
—
SIUL
DCULite
LINFlex_2
VIU2/PDI
I/O
M
None,
None
—
—
AC10
PN[3]
PCR[164] Option 0
Option 1
Option 2
Option 3
GPIO[164]
DCULITE_R1
TXD_2
VIU1_PDI9
—
SIUL
DCULite
LINFlex_2
VIU2/PDI
I/O
M
None,
None
—
—
AF10
PN[4]
PCR[165] Option 0
Option 1
Option 2
Option 3
GPIO[165]
DCULITE_R2
—
TCON[6]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AC11
PN[5]
PCR[166] Option 0
Option 1
Option 2
Option 3
GPIO[166]
DCULITE_R3
—
TCON[7]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AD11
PN[6]
PCR[167] Option 0
Option 1
Option 2
Option 3
GPIO[167]
DCULITE_R4
—
TCON[8]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AE11
PN[7]
PCR[168] Option 0
Option 1
Option 2
Option 3
GPIO[168]
DCU_LITE_R5
—
TCON[9]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AF11
Pinout and signal descriptions
56
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
PCR[169] Option 0
Option 1
Option 2
Option 3
GPIO[169]
DCULITE_R6
—
TCON[10]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AC12
PN[9]
PCR[170] Option 0
Option 1
Option 2
Option 3
GPIO[170]
DCULITE_R7
—
TCON[11]
—
SIUL
DCULite
—
TCON
I/O
M
None,
None
—
—
AD12
PN[10] PCR[171] Option 0
Option 1
Option 2
Option 3
GPIO[171]
DCULITE_G0
RXD_3
VIU2_PDI10
—
SIUL
DCULite
LINFlex_3
VIU2/PDI
I/O
M
None,
None
—
—
AE12
PN[11] PCR[172] Option 0
Option 1
Option 2
Option 3
GPIO[172]
DCULITE_G1
TXD_3
VIU3_PDI11
—
SIUL
DCULite
LINFlex_3
VIU2/PDI
I/O
M
None,
None
—
—
AF12
PN[12] PCR[173] Option 0
Option 1
Option 2
Option 3
GPIO[173]
DCULITE_G2
—
eMIOS0[17]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
R26
PN[13] PCR[174] Option 0
Option 1
Option 2
Option 3
GPIO[174]
DCULITE_G3
—
eMIOS0[18]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
R25
PN[14] PCR[175] Option 0
Option 1
Option 2
Option 3
GPIO[175]
DCULITE_G4
—
eMIOS0[19]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
P26
PN[15] PCR[176] Option 0
Option 1
Option 2
Option 3
GPIO[176]
DCULITE_G5
—
eMIOS0[20]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
P24
GPIO[177]
DCULITE_G6
—
eMIOS0[21]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
P23
PORT P
PP[0]
57
PCR[177] Option 0
Option 1
Option 2
Option 3
Pinout and signal descriptions
PN[8]
Port
pin
PCR
Alternate
function1
Function
Special
function2
Peripheral3
I/O
direction
Pad RESET
Type4 config5
Pin number
176 LQFP 208 LQFP 416 TEPBGA
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
PP[1]
PCR[178] Option 0
Option 1
Option 2
Option 3
GPIO[178]
DCULITE_G7
—
eMIOS0[22]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
N26
PP[2]
PCR[179] Option 0
Option 1
Option 2
Option 3
GPIO[179]
DCULITE_B0
CANRX_2
VIU4_PDI12
—
SIUL
DCULite
FlexCAN_2
VIU2/PDI
I/O
M
None,
None
—
—
N25
PP[3]
PCR[180] Option 0
Option 1
Option 2
Option 3
GPIO[180]
DCULITE_B1
CANTX_2
PDI_DE
—
SIUL
DCULite
FlexCAN_2
PDI
I/O
M
None,
None
—
—
N23
PP[4]
PCR[181] Option 0
Option 1
Option 2
Option 3
GPIO[181]
DCULITE_B2
—
eMIOS0[11]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
M26
PP[5]
PCR[182] Option 0
Option 1
Option 2
Option 3
GPIO[182]
DCULITE_B3
—
eMIOS0[13]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
M25
PP[6]
PCR[183] Option 0
Option 1
Option 2
Option 3
GPIO[183]
DCULITE_B4
—
eMIOS0[15]
—
SIUL
DCULite
—
PWM/Timer
I/O
M
None,
None
—
—
M24
PP[7]
PCR[184] Option 0
Option 1
Option 2
Option 3
GPIO[184]
DCULITE_B5
—
I2S_FS
—
SIUL
DCULite
—
SGM
I/O
M
None,
None
—
—
M23
PP[8]
—
—
Reserved
—
—
—
—
—
—
—
—
PP[9]
—
—
Reserved
—
—
—
—
—
—
—
—
PP[10]
—
—
Reserved
—
—
—
—
—
—
—
—
PP[11]
—
—
Reserved
—
—
—
—
—
—
—
—
Pinout and signal descriptions
58
Table 7. Port pin summary (continued)
Freescale Semiconductor
Table 7. Port pin summary (continued)
Port
pin
PCR
PP[12]
—
—
PP[13]
—
PP[14]
PP[15]
1
PXD20 Microcontroller Data Sheet, Rev. 2
Preliminary—Subject to Change Without Notice
2
3
4
5
6
Alternate
function1
I/O
direction
Pad RESET
Type4 config5
Pin number
Special
function2
Peripheral3
Reserved
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
—
—
Reserved
—
—
—
—
—
—
—
—
Function
176 LQFP 208 LQFP 416 TEPBGA
Alternate functions are chosen by setting the values of the PCR[PA] bitfields inside the SIUL module.
PCR[PA] = 00 selects Option 0
PCR[PA] = 01 selects Option 1
PCR[PA] = 10 selects Option 2
PCR[PA] = 11 selects Option 3
This is intended to select the output functions. To use one of the input functions, the PCR[IBE] bit must be written to ‘1’, regardless of the values selected in
the PCR[PA] bitfields. For this reason, the value corresponding to an input only function is reported as “—”.
Special functions are enabled independently from the standard digital pin functions. Enabling standard I/O functions in the PCR registers may interfere with
their functionality. ADC functions are enabled using the PCR[APC] bit; other functions are enabled by enabling the respective module.
Using the PSMI registers in the System Integration Unit Lite (SIUL), different pads can be multiplexed to the same peripheral input. Please see the SIUL chapter
of the PXD20 Microcontroller Reference Manual for details.
See the “Pad types” section for an explanation of the letters in this column.
Reset configuration is given as I/O direction and pull, e.g., “Input, pullup”.
Out of reset pins PH[0:3] are available as JTAG pins (TCK, TDI, TDO and TMS respectively). It is up to the user to configure pins PH[0:3] when needed.
Pinout and signal descriptions
59
System design information
3
System design information
3.1
Power-up sequencing
The preferred power-up sequence for PXD20 is as follows:
1.
Generic IO supplies or noise-free supplies, consisting of:
— VDDA
— VDDE_A
— VDDE_B
— VDDM
— VDD_DR
— VDD33_DR
— VDDPLL
Figure 6. Power-up sequencing
PXD20 Microcontroller Data Sheet, Rev. 2
60
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
System design information
Figure 7. Power-down sequencing
2.
3.
4.
All 3.3V supplies (VDDE_B and VDD33_DR) should be ramped up first, and then the rest of the I/O supplies should
be ramped up (VDDA, VDDE_A, VDDM, and VDD_DR).
VDDR, the regulator input supply, should be the last supply to ramp up; all supplies can be ramped up together as long
as VDDR is included. So all 5V supplies should be ramped up after the 3.3 V supplies, and if all the supplies are of
the same level, they can be ramped up together as well.
LV supply (VDD12). If Vreg is in bypass mode and the core supply (1.2 V) is supplied externally, then this should be
the last supply given.
NOTE
For DDR, the 3.3 V supply (VDD33_DR) should come before VDD_DR.
This sequence ensures that when VREG releases its LVDs, the IO and other HV segments
are powered properly. This is important because PXD20 doesn't monitor LVDs on IO HV
supplies.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
61
Electrical characteristics
4
Electrical characteristics
4.1
Introduction
This section contains electrical characteristics of the device as well as temperature and power considerations.
This product contains devices to protect the inputs against damage due to high static voltages. However, it is advisable to take
precautions to avoid application of any voltage higher than the specified maximum rated voltages.
To enhance reliability, unused inputs can be driven to an appropriate logic voltage level (VDD or VSS). This could be done by
internal pull up and pull down, which is provided by the product for most general purpose pins.
The parameters listed in the following tables represent the characteristics of the device and its demands on the system.
In the tables where the device logic provides signals with their respective timing characteristics, the symbol “CC” for Controller
Characteristics is included in the Symbol column.
In the tables where the external system must provide signals with their respective timing characteristics to the device, the symbol
“SR” for System Requirement is included in the Symbol column.
4.2
Parameter classification
The electrical parameters shown in this supplement are guaranteed by various methods. To give the
customer a better understanding, the classifications listed in Table 8 are used and the parameters are tagged
accordingly in the tables where appropriate.
Table 8. Parameter classifications
Classification tag
Tag description
P
Those parameters are guaranteed during production testing on each individual device.
C
Those parameters are achieved by the design characterization by measuring a statistically
relevant sample size across process variations.
T
Those parameters are achieved by design characterization on a small sample size from typical
devices under typical conditions unless otherwise noted. All values shown in the typical column
are within this category.
D
Those parameters are derived mainly from simulations.
NOTE
The classification is shown in the column labeled “C” in the parameter
tables where appropriate.
PXD20 Microcontroller Data Sheet, Rev. 2
62
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.3
Absolute maximum ratings
Table 9. Absolute maximum ratings
Value
Symbol
VDDA
C
SR
Parameter
D Voltage on VDDA pin (ADC reference) with
respect to ground (VSSA)
VSSA
SR
D Voltage on VSSA (ADC reference) pin with
respect VSS
VDDPLL
CC
D Voltage on VDDPLL (1.2 V PLL supply) pin with
respect to ground (VSSPLL)
VDDR
SR
D Voltage on VDDR pin (regulator supply) with
respect to ground (VSSR)
Conditions
Min
Max
–0.3
+5.5
Relative to VDD VDD – 0.3
Unit
SpecID
V
D1.1
VDD + 0.3
VSS – 0.1
VSS+0.1
V
D1.2
1.08
1.32
V
D1.3
V
D1.4
Relative to VDD VDD – 0.3
–0.3
VDD + 0.3
+5.5
Relative to VDD VDD – 0.3
VDD + 0.3
VSSR
SR
D Voltage on VSSR (regulator ground) pin with
respect to VSS
VSS – 0.1
VSS + 0.1
V
D1.5
VDD12
CC
D Voltage on VDD12 pin with respect to ground
(VSS12)
1.08
1.4
V
D1.6
VSS12
CC
D Voltage on VSS12 pin with respect to VSS
VSS – 0.1
VSS + 0.1
V
D1.7
VDDE_A1
SR
D Voltage on VDDE_A (I/O supply) pin with
respect to ground (VSSE_A)
–0.3
+5.5
V
D1.8
VDDE_B1
SR
D Voltage on VDDE_B (I/O supply) pin with
respect to ground (VSS)
–0.3
+3.6
V
D1.9
VDDM1
SR
D Voltage on VDDM (stepper motor supply) pin
with respect to ground (VSSM)
–0.3
+5.5
V
D1.10
VSS2
SR
D I/O supply ground
0
0
V
D1.11
VDD_DR
D Voltage on VDDDDR with respect to VSS
–0.3
3.6
V
D1.12
VRSDS
D Voltage on VDDRSDS with respect to VSS
–0.3
3.6
V
D1.13
VIN
SR
D Voltage on any GPIO pin with respect to ground
(VSS)
–0.3
VDDmax
(VDDE max of
that
segment)
V
IINJPAD
SR
D Injected input current on any pin during
overload condition
–10
10
mA
IINJSUM
SR
D Absolute sum of all injected input currents
during overload condition
–50
50
T Storage temperature
–55
150
°C
D1.17
2000
V
D1.18
TSTORAGE SR
ESDHBM
SR
T ESD Susceptibility (Human Body Model)
D1.15
D1.16
1
Throughout the remainder of this document VDD refers collectively to I/O voltage supplies, i.e., VDDE_A, VDDE_B, and VDDM,
unless otherwise noted.
2
Throughout the remainder of this document VSS refers collectively to I/O voltage supply grounds, i.e., VSSE_A, VSSPLL, and
VSSM, unless otherwise noted.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
63
Electrical characteristics
NOTE
Stresses exceeding the recommended absolute maximum ratings may cause permanent
damage to the device. This is a stress rating only and functional operation of the device at
these or any other conditions above those indicated in the operational sections of this
specification are not implied. Exposure to absolute maximum rating conditions for
extended periods may affect device reliability. During overload conditions (VIN > VDD or
VIN < VSS), the voltage on pins with respect to ground (VSS) must not exceed the
recommended values.
4.4
Recommended operating conditions
Table 10. Recommended operating conditions (3.3 V)
Value
Symbol
C
Parameter
Conditions
Min
VDDA1
Unit
SpecID
V
D2.1
Max
SR P Voltage on VDDA pin (ADC reference) with re+3.0
spect to ground (VSS)
D
Relative to VDD VDD – 0.1
+3.6
VDD + 0.1
VSSA
SR P Voltage on VSSA (ADC reference) pin with
respect VSS
VSS – 0.1
VSS + 0.1
V
D2.2
VDDPLL
CC P Voltage on VDDPLL (1.2 V PLL supply) pin
with respect to ground (VSSPLL)
1.08
1.32
V
D2.3
VDDR2
SR P Voltage on VDDR pin (regulator supply) with
+3.0
respect to ground (VSSR)
D
Relative to VDD VDD – 0.1
+3.6
V
D2.4
VSSR
SR D Voltage on VSSR (regulator ground) pin with
respect to VSS
VSS – 0.1
VSS + 0.1
V
D2.5
1.08
1.4
V
D2.6
V
D2.7
V
D2.8
VDD123,4 CC P Voltage on VDD12 pin with respect to ground
(VSS12)
VSS12
VDD
5,6,7
VSS8
CC D Voltage on VSS12 pin with respect to VSS
SR P Voltage on VDD pins (VDDE_A, VDDE_B,
VDD_DR, VDDM) with respect to ground (VSS)
VDD + 0.1
VSS – 0.1
VDDmin
SR D I/O supply ground
5
VSS + 0.1
VDDmax
5
0
0
V
D2.9
VDDE_A9 SR P Voltage on VDDE_A (I/O supply) pin with
respect to ground (VSSE_A)
+3.0
+3.6
V
D2.10
VDDE_B
SR P Voltage on VDDE_B (I/O supply) pin with
respect to ground (VSSE_B)
+3.0
+3.6
V
D2.11
VDDM
SR P Voltage on VDDM (stepper motor supply) pin
with respect to ground (VSSM)
+3.0
+3.6
V
D2.12
VDD_DR
P Voltage on VDDDDR with respect to VSS
+1.62
+3.6
V
D2.13
VSS_DR
D Voltage on VSSRSDS with respect to VSS
+1.62
+3.6
V
D2.14
VRSDS
P Voltage on VDDDDR with respect to VSS
+3.0
+3.6
V
D2.15
TVDD
SR D VDD slope to ensure correct power up10
12
V/ms
D2.16
°C
D2.17
TA
SR P Ambient temperature under bias
–40
105
TJ
SR D Junction temperature under bias
–40
140
D2.18
PXD20 Microcontroller Data Sheet, Rev. 2
64
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
1
100 nF capacitance needs to be provided between VDDA/VSSA pair.
10 F capacitance must be connected between VDDR and VSS12 because of a sharp surge due to external ballast.
3
VDD12 cannot be used to drive any external component.
4
Each VDD12/VSS12 supply pair should have a 10 F capacitor. Absolute combined maximum capacitance is 40 F. Preferably,
all the VDD12 supply pads should be shorted and then connected to a 4  10 F capacitance. This is to ensure the ESR of
external capacitance does not exceed 0.2 . A 100 nF capacitor must be placed close to the pin.
5
VDD refers collectively to I/O voltage supplies, i.e., VDDE_A, VDDE_B, VDD_DR, and VDDM.
6
100 nF capacitance needs to be provided between each VDD/VSS pair. VDDmin value for is 3 V for VDDE_A & VDDM as well
as for VDDE_B, while it is 1.62 V for VDD_DR. VDD max value is 3.6 V for VDDE_A & VDDM as well as for VDDE_B &
VDD_DR.
7
Full electrical specification cannot be guaranteed when voltage drops below 3.0V. In particular, ADC electrical characteristics
and I/O’s DC electrical specification may not be guaranteed.
When voltage drops below VLVDHVL device is reset.
8
VSS refers collectively to I/O voltage supply grounds, i.e., VSSE_A, VSS, and VSSM unless otherwise noted.
9
VDDE_A should not be less than VDDA.
10 Guaranteed by device validation.
2
Table 11. Recommended operating conditions (5.0 V)
Value
Symbol
VDDA1
C
Parameter
Conditions
SR P Voltage on VDDA pin (ADC reference) with respect to ground (VSS)
D
Voltage drop2
D
Min
Max
+4.5
+5.5
+3.0
+5.5
Relative to VDD VDD – 0.1
VDD + 0.1
Unit
SpecID
V
D2.19
VSSA
SR D Voltage on VSSA (ADC reference) pin with
respect VSS
VSS – 0.1
VSS + 0.1
V
D2.20
VDDPLL
CC P Voltage on VDDPLL (1.2 V PLL supply) pin
with respect to ground (VSSPLL)
1.08
1.32
V
D2.21
VDDR3
SR P Voltage on VDDR pin (regulator supply) with
respect to ground (VSSR)
D
Voltage drop2
+3.0
+3.6
V
D2.22
+3.0
+3.6
D
Relative to VDD VDD – 0.1
VDD + 0.1
VSSR
SR D Voltage on VSSR (regulator ground) pin with
respect to VSS
VSS – 0.1
VSS + 0.1
V
D2.23
VDD124,5
CC P Voltage on VDD12 pin with respect to ground
(VSS12)
1.08
1.4
V
D2.24
V
D2.25
V
D2.26
VSS12
CC D Voltage on VSS12 pin with respect to VSS
VDD6,7
SR P Voltage on VDD pins (VDDE_A, VDDE_B,
VDD_DR, VDDMA, VDDMB, VDDMC) with
respect to ground (VSS)
VSS8
VSS – 0.1
Voltage
drop2
VDDmin
VSS + 0.1
VDDmax
6
0
0
V
D2.27
SR P Voltage on VDDE_A (I/O supply) pin with
respect to ground (VSSE_A)
+4.5
+5.5
V
D2.28
VDDE_B10 SR P Voltage on VDDE_B (I/O supply) pin with
respect to ground (VSSE_B
+3.0
+3.6
V
D2.29
VDDE_A
SR D I/O supply ground
6
9
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
65
Electrical characteristics
Table 11. Recommended operating conditions (5.0 V) (continued)
Value
Symbol
C
Parameter
Conditions
Min
Max
Unit
SpecID
VDDM
SR P Voltage on VDDMA (stepper motor supply)
pin with respect to ground (VSSMA)
+4.5
+5.5
V
D2.30
VDD_DR11
P Voltage on VDD_DR with respect to VSS
+1.62
+3.6
V
D2.31
VSS_DR
D Voltage on VSSRSDS with respect to VSS
+1.62
+3.6
V
D2.32
VRSDS
P Voltage on VDD_DR with respect to VSS
+3.0
+3.6
V
D2.33
12
V/ms
D2.34
–40
105
°C
D2.35
–40
105
–40
140
TVDD
SR D VDD slope to ensure correct power up
12
SR P Ambient temperature under bias
TA
TJ
SR D Junction temperature under bias
D2.36
1
100 nF capacitance needs to be provided between VDDA/VSSA pair.
Full functionality cannot be guaranteed when voltage drops below 4.5 V. In particular, I/O DC and ADC electrical characteristics
may not be guaranteed below 4.5 V during the voltage drop sequence.
3 10 F capacitance must be connected between V
DDR and VSS12. It is recommended that this cap should be placed, as close
as possible to the DUT pin on board.
4 V
DD12 cannot be used to drive any external component.
5 Each V
DD12/VSS12 supply pair should have a 10 F capacitor. Absolute combined maximum capacitance is 40 F. Preferably,
all the VDD12 supply pads should be shorted and then connected to a 410 F capacitance. This is to ensure the ESR of
external capacitance does not exceed 0.2 . A 100 nF capacitor must be placed close to the pin.
6 V
DD refers collectively to I/O voltage supplies, i.e., VDDE_A, VDDE_B, VDDE_DR, VDDMA, VDDMB and VDDMC. VDDmin value for
is 4.5 V for VDDE_A & VDDM, 3 V VDDE_B, while it is 1.62 V for VDD_DR. VDD max value is 5.5 V for VDDE_A & VDDM
and 3.6 V for VDDE_B & VDD_DR.
7 100 nF capacitance needs to be provided between each V /V
DD SS pair.
8 V
refers
collectively
to
I/O
voltage
supply
grounds,
i.e.,
V
SS
SSE_A, VSSE_B, VSSE_A, VSSE_E, VSSMA, VSSMB and VSSMC) unless
otherwise noted.
9 V
DDE_A should not be less than VDDA.
10 VDDE_B cannot go beyond 3.6V under any operating condition.
11 VDD_DR can be 1.8, 2.5 and 3.3V (typical) based on type of SDR memory.
12
Guaranteed by device validation
2
4.5
Thermal characteristics
Table 12. Thermal characteristics for 176-pin LQFP1
Symbol
RJA
C
CC
Parameter
Conditions
D Junction to Ambient Natural
Convection2
Single layer board –1s
Convection2
Value
Unit
SpecID
36
°C/W
D3.1
RJA
CC
D Junction to Ambient Natural
Four layer board –2s2p
29
°C/W
D3.2
RJMA
CC
D Junction to Ambient2
@200 ft./min., single layer
board –1s
28
°C/W
D3.3
RJMA
CC
D Junction to Ambient2
@200 ft./min., Four layer
board –2s2p
23
°C/W
D3.4
RJB
CC
D Junction to Board3
18
°C/W
D3.5
RJCtop
CC
D Junction to Case (Top)4
5
°C/W
D3.6
PXD20 Microcontroller Data Sheet, Rev. 2
66
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 12. Thermal characteristics for 176-pin LQFP1 (continued)
Symbol
JT
C
CC
Parameter
Conditions
D Junction to Package Top Natural Convection5
Value
Unit
SpecID
2
°C/W
D3.7
1
Thermal characteristics are targets based on simulation that are subject to change per device characterization.
Junction-to-Ambient Thermal Resistance determined per JEDEC JESD51-3 and JESD51-6. Thermal test board meets
JEDEC specification for this package.
3
Junction-to-Board thermal resistance determined per JEDEC JESD51-8. Thermal test board meets JEDEC specification for
the specified package.
4
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.
5
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.
2
Table 13. Thermal characteristics for 208-pin LQFP1
Symbol
RJA
C
CC
Parameter
Conditions
D Junction to Ambient Natural
Convection2
Single layer board –1s
Convection2
Value
Unit
SpecID
34
°C/W
D3.8
RJA
CC
D Junction to Ambient Natural
Four layer board –2s2p
27
°C/W
D3.9
RJMA
CC
D Junction to Ambient2
@200 ft./min., single layer
board –1s
27
°C/W
D3.10
RJMA
CC
D Junction to Ambient2
@200 ft./min., Four layer
board –2s2p
22
°C/W
D3.11
RJB
CC
D Junction to Board3
—
18
°C/W
D3.12
RJCtop
CC
D Junction to Case (Top)4
—
5
°C/W
D3.13
JT
CC
D Junction to Package Top Natural Convection5
—
2
°C/W
D3.14
1
Thermal characteristics are targets based on simulation that are subject to change per device characterization.
Junction-to-Ambient Thermal Resistance determined per JEDEC JESD51-3 and JESD51-6. Thermal test board meets JEDEC
specification for this package.
3
Junction-to-Board thermal resistance determined per JEDEC JESD51-8. Thermal test board meets JEDEC specification for
the specified package.
4 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.
5
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.
2
Table 14. Thermal characteristics for 416-pin TEPBGA1
Symbol
C
Parameter
Conditions
Convection2
RJA
CC
D Junction to Ambient Natural
RJA
CC
D Junction to Ambient Natural Convection2
Ambient2
RJMA
CC
D Junction to
RJMA
CC
D Junction to Ambient2
RJB
CC
D Junction to Board3
RJCtop
CC
D Junction to Case (Top)
4
Value
Unit
SpecID
Single layer board –1s
26
°C/W
D3.15
Four layer board –2s2p
18
°C/W
D3.16
@200 ft./min., single layer
board –1s
20
°C/W
D3.17
@200 ft./min., Four layer
board –2s2p
15
°C/W
D3.18
—
10
°C/W
D3.19
—
6
°C/W
D3.20
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
67
Electrical characteristics
Table 14. Thermal characteristics for 416-pin TEPBGA1 (continued)
Symbol
JT
C
CC
Parameter
D Junction to Package Top Natural Convection5
Conditions
Value
Unit
SpecID
—
2
°C/W
D3.21
1
Thermal characteristics are targets based on simulation that are subject to change per device characterization.
Junction-to-Ambient Thermal Resistance determined per JEDEC JESD51-3 and JESD51-6. Thermal test board meets
JEDEC specification for this package.
3
Junction-to-Board thermal resistance determined per JEDEC JESD51-8. Thermal test board meets JEDEC specification for
the specified package.
4
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.
5
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.
2
4.5.1
General notes for specifications at maximum junction temperature
An estimate of the chip junction temperature, TJ, can be obtained from the equation:
TJ = TA + (RJA * PD)
Eqn. 1
where:
TA= ambient temperature for the package (oC)
RJA= junction to ambient thermal resistance (oC/W)
PD= power dissipation in the package (W)
The thermal resistance values used are based on the JEDEC JESD51 series of standards to provide consistent values for
estimations and comparisons. The difference between the values determined for the single-layer (1s) board compared to a
four-layer board that has two signal layers, a power and a ground plane (2s2p), demonstrate that the effective thermal resistance
is not a constant. The thermal resistance depends on the:
•
•
•
•
Construction of the application board (number of planes)
Effective size of the board which cools the component
Quality of the thermal and electrical connections to the planes
Power dissipated by adjacent components
Connect all the ground and power balls to the respective planes with one via per ball. Using fewer vias to connect the package
to the planes reduces the thermal performance. Thinner planes also reduce the thermal performance. When the clearance
between the vias leave the planes virtually disconnected, the thermal performance is also greatly reduced.
As a general rule, the value obtained on a single-layer board is within the normal range for the tightly packed printed circuit
board. The value obtained on a board with the internal planes is usually within the normal range if the application board has:
•
•
•
One oz. (35 micron nominal thickness) internal planes
Components are well separated
Overall power dissipation on the board is less than 0.02 W/cm2
The thermal performance of any component depends on the power dissipation of the surrounding components. In addition, the
ambient temperature varies widely within the application. For many natural convection and especially closed box applications,
the board temperature at the perimeter (edge) of the package is approximately the same as the local air temperature near the
device. Specifying the local ambient conditions explicitly as the board temperature provides a more precise description of the
local ambient conditions that determine the temperature of the device.
PXD20 Microcontroller Data Sheet, Rev. 2
68
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
At a known board temperature, the junction temperature is estimated using the following equation:
TJ = TB + (RJB * PD)
Eqn. 2
where:
TB= board temperature for the package perimeter (oC)
RJB= junction-to-board thermal resistance (oC/W) per JESD51-8S
PD= power dissipation in the package (W)
When the heat loss from the package case to the air does not factor into the calculation, an acceptable value for the junction
temperature is predictable. Ensure the application board is similar to the thermal test condition, with the component soldered to
a board with internal planes.
The thermal resistance is expressed as the sum of a junction-to-case thermal resistance plus a case-to-ambient thermal
resistance:
RJA = RJC + RCA
Eqn. 3
where:
RJA = junction to ambient thermal resistance (oC/W)
RJC= junction to case thermal resistance (oC/W)
RCA= case to ambient thermal resistance (oC/W)
RJC s device related and is not affected by other factors. The thermal environment can be controlled to change the
case-to-ambient thermal resistance, RCA. For example, change the air flow around the device, add a heat sink, change the
mounting arrangement on the printed circuit board, or change the thermal dissipation on the printed circuit board surrounding
the device. This description is most useful for packages with heat sinks where 90% of the heat flow is through the case to heat
sink to ambient. For most packages, a better model is required.
A more accurate two-resistor thermal model can be constructed from the junction-to-board thermal resistance and the
junction-to-case thermal resistance. The junction-to-case thermal resistance describes when using a heat sink or where a
substantial amount of heat is dissipated from the top of the package. The junction-to-board thermal resistance describes the
thermal performance when most of the heat is conducted to the printed circuit board. This model can be used to generate simple
estimations and for computational fluid dynamics (CFD) thermal models.
To determine the junction temperature of the device in the application on a prototype board, use the thermal characterization
parameter (JT) to determine the junction temperature by measuring the temperature at the top center of the package case using
the following equation:
TJ = TT + (JT x PD)
Eqn. 4
where:
TT= thermocouple temperature on top of the package (oC)
JT= thermal characterization parameter (oC/W)
PD= power dissipation in the package (W)
The thermal characterization parameter is measured in compliance with the JESD51-2 specification using a 40-gauge type T
thermocouple epoxied to the top center of the package case. Position the thermocouple so that the thermocouple junction rests
on the package. Place a small amount of epoxy on the thermocouple junction and approximately 1 mm of wire extending from
the junction. Place the thermocouple wire flat against the package case to avoid measurement errors caused by the cooling
effects of the thermocouple wire.
References:
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
69
Electrical characteristics
Semiconductor Equipment and Materials International
805 East Middlefield Rd.
Mountain View, CA 94043
(415) 964-5111
MIL-SPEC and EIA/JESD (JEDEC) specifications are available from Global Engineering Documents at 800-854-7179 or
303-397-7956.
JEDEC specifications are available on the WEB at http://www.jedec.org.
4.6
EMI (electromagnetic interference) characteristics
Table 15. EMI testing specifications1 2
Symbol
Radiated
Emissions
Parameter
VEME
Conditions
Clocks
Device Configuration,
test conditions and EM
testing per standard
IEC61967-2
FOSC — 8 MHz, External
Crystal
FCPU —124 MHz
FBUS —124 MHz
No PLL Frequency
Modulation
FOSC — 8 MHz, External
Crystal
FCPU —124 MHz
FBUS —124 MHz
2% PLL Frequency
Modulation
1
2
Frequency
Range
Level
(Typ)
Unit
150 kHz –
50 MHz
19
dBµV
50 MHz –
150 MHz
30
150 MHz –
500 MHz
25
500 MHz –
1000 MHz
19
IEC Level
K
150 kHz –
50 MHz
15
50 MHz –
150 MHz
24
150 MHz –
500 MHz
17
500 MHz –
1000 MHz
14
IEC Level
L
dBµV
The reported emission level is the value of the maximum emission, rounded up to the next whole number.
IEC Level Maximum:, L is less than or equal to 24 dBµV, K is less than or equal to 30 dBµV.
4.7
4.7.1
Power management
Voltage regulator electrical characteristics
The internal voltage regulator requires an external NPN (BCP68 or NJD2873) ballast to be connected as shown in Figure 8 s
well as an external capacitance (CREG) to be connected to the device in order to provide a stable low voltage digital supply to
the device. Capacitances should be placed on the board as near as possible to the associated pins. Care should also be taken to
limit the serial inductance of the board to less than 15 nH.
PXD20 Microcontroller Data Sheet, Rev. 2
70
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
For the PXD20 microcontroller, 100 nF should be placed between each VDD12/VSS12 supply pair and also between the
VDDPLL/VSSPLL pair. Additionally, 10 F should be placed between the VDDR pin and the adjacent VSS pin.
VDDR = 3.0 V to 3.6 V / 4.5 V to 5.5 V, TA = –40 to 105 °C, unless otherwise specified.
VDDR
VRC_CTRL
VDD12
Figure 8. External NPN ballast connections
Table 16. Voltage regulator electrical characteristics
Symbol
VDDR
TJ
IREG
IL
VDD12
SR
C
Parameter
P Power supply
SR D Junction temperature
CC
CC
T Current consumption
T Output current capacity
CC D Output voltage (value @ IL = 0 @ 27°C)
Max
Unit
SpecID
—
3.0
5.5
V
D5.1
—
–40
140
°C
D5.2
Reference included,
@ 55 °C No load
@ Full load
—
mA
D5.3
DC load current
—
450
mA
D5.4
Pre-trimming sigma
< 7 mV
—
1.330
V
D5.5
D5.6
1.26
1.29
T Output voltage (value @ IL = Imax)
Post-trimming
1.145
—
4 capacitances of
10 µF each
10 × 4
—
µF
D
ESR of external cap
0.05
0.2
ohm
D
1 bond wire R + 1
pad R
0.2
1
ohm
0
15
nH
D5.7
—
–30
dB
D5.8
10% to 90%
of IL (max) in
100 ns
D5.9
CC D Bonding Inductance for Bipolar Base Control pad
@ DC @ no load
Cload = 10 µF × 4
D
@ 200 kHz @ no load
–100
D
@ DC @ 400 mA
–30
D
@ 200 kHz @ 400 mA
–30
CC D
CC
2
11
Post-trimming
CC D Power supply rejection
tSU
Min
P
SR D External decoupling/stability capacitor
LBOND
Conditions
T
Load current transient
Cload = 10 µF × 4
—
Start-up time after input supply stabilizes1
Cload = 10 µF × 4
—
500
µs
D5.10
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
71
Electrical characteristics
1
Time after the input supply to the voltage regulator has ramped up (VDDR) and the voltage regulator has asserted the Power
OK signal.
Table 17. Low-power voltage regulator electrical characteristics
Symbol
TJ
IREG
IL
VDD12
C
Parameter
SR D Junction temperature
CC
CC
T Current consumption
T Output current capacity
CC D Output voltage
P
Conditions
Min
Max
Unit
SpecID
—
–40
140
°C
D5.2
Reference included,
@ 55 °C No load
@ Full load
—
µA
D5.3
DC load current
—
15
mA
D5.4
Pre-trimming sigma
< 7 mV
—
1.33
V
D5.5
1.14
1.32
Post-trimming
5
600
Table 18. Ultra low-power voltage regulator electrical characteristics
Symbol
TJ
IREG
IL
VDD12
C
SR D Junction temperature
CC
CC
T Current consumption
T Output current capacity
CC D Output voltage (value @ IL = 0 @ 27°C)
P
4.7.2
Parameter
Conditions
Min
Max
Unit
SpecID
—
–40
140
°C
D5.2
Reference included,
@ 55 °C No load
@ Full load
—
µA
D5.3
DC load current
—
5
mA
D5.4
Pre-trimming sigma
< 7 mV
—
1.33
V
D5.5
1.14
1.32
Post-trimming
2
100
Voltage monitor electrical characteristics
The device implements a Power On Reset module to ensure correct power-up initialization, as well as four low voltage detectors
to monitor the VDD and the VDD12 voltage while device is supplied:
•
•
•
•
•
POR monitors VDD during the power-up phase to ensure device is maintained in a safe reset state
LVDHV3 monitors VDD to ensure device reset below minimum functional supply
LVDHV5 monitors VDD when application uses device in the 5.0V ±10% range
LVDLVCOR monitors power domain No. 1
LVDLVBKP monitors power domain No. 0
PXD20 Microcontroller Data Sheet, Rev. 2
72
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 19. Low voltage monitor electrical characteristics
Symbol
VPORH
1
2
C
Value2
Conditions1
Parameter
CC C Power-on reset threshold
Unit
SpecID
V
D5.11
Min
Typ
Max
1.5
—
2.7
—
—
2.8
D5.12
TA = 25°C,
after trimming
VLVDHV3H
CC C LVDHV3 low voltage detector high threshold
VLVDHV3L
CC C LVDHV3 low voltage detector low threshold
2.7
—
—
D5.13
VLVDHV5H
CC C LVDHV5 low voltage detector high threshold
—
—
4.37
D5.14
VLVDHV5L
CC C LVDHV5 low voltage detector low threshold
4.2
—
—
D5.15
VLVDLVCORH CC C LVDLVCOR low voltage detector high threshold
—
—
1.185
D5.16
VLVDLVCORL CC C LVDLVCOR low voltage detector low threshold
1.095
—
—
D5.17
VDD = 3.3V ±10% / 5.0V ± 10%, TA = –40 to 105°C, unless otherwise specified.
All values need to be confirmed during device validation.
4.7.3
Low voltage domain power consumption
Table 20 provides DC electrical characteristics for significant application modes. These values are indicative values; actual
consumption depends on the application.
Table 20. DC electrical characteristics
Symbol
C
Value2
Conditions1
Parameter
Unit
Min Typ
IDDMAX2
CC D RUN mode maximum
average current
IDDRUN4
CC P RUN mode typical
average current5
IDDHALT
CC C HALT mode current6
P
IDDSTOP
CC D STOP mode current7
Max
—
—
250 276.633 mA
fCPU = 125 MHz, Dual Display Drive
with external DRAM, 416 TEPBGA
package option only
—
—
275
—
fCPU = 125 MHz, Single Display Drive,
no external DRAM, 176 LQFP / 208
LQFP package options
—
—
240
—
Slow internal RC oscillator (128 kHz) TA = 25 oC
running
TB = 105 oC
—
17.5
21.5
—
35
43.5
Slow internal RC oscillator (128 kHz) TA = –40oC
running
TA = 0oC
—
645
—
—
—
1100
—
P
o
TA = 25 C
—
1531
1615
D
TA =
55oC
—
3.8
—
D
TA = 85oC
—
9.7
—
P
o
D
TA = 105 C
— 17.67
mA
mA
A
mA
18.46
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
73
Electrical characteristics
Table 20. DC electrical characteristics (continued)
Symbol
C
Parameter
Conditions
Value2
1
Unit
Min Typ
IDDSTDBY2 CC D STANDBY2 mode
current8
D
(64K SRAM on)
P
SXOSC (32 KHz9) ON and RTC
running
TA = –40oC
—
470
—
TA = 0 C
—
480
—
TA = 25oC
o
—
481
490
o
—
525
—
o
TA = 55 C
D
Max
D
TA = 85 C
—
650
—
P
TA = 105oC
—
870
910
63
—
CC D
SXOSC (32 KHz) and RTC OFF
TA = –40oC
o
D
TA = 0 C
85
—
TA =
25oC
93
100
D
TA =
55oC
95
—
D
TA = 85oC
190
—
390
430
—
415
—
TA = 0oC
—
422
—
TA = 25oC
—
426
430
TA =
55oC
—
575
—
D
TA =
85oC
—
680
—
P
TA = 105oC
—
810
915
P
P
IDDSTDBY1 CC D STANDBY1 mode
current
D
(8K SRAM on)10
P
SXOSC (32KHz) ON and RTC
running
D
TA =
105oC
TA =
–40oC
TA = –40oC
20
—
TA =
0oC
22
—
TA =
25oC
29
45
D
TA =
55oC
47
—
D
TA = 85oC
118
—
236
310
CC D
SXOSC (32 KHz) and RTC OFF
D
P
TA =
P
105oC
A
A
A
A
1
VDD = 3.0 V to 5.5 V, TA = –40 to 105 °C, unless otherwise specified.
IDDMAX is composed of the current consumption on all supplies (VDD12, VDDE_A, VDDE_B, VDDA, VDDR, VDDM, VDDPLL, and
VDD_DR). It does not include current consumption linked to I/Os toggling which is highly dependent on the application. The
given value is thought to be a worst case value with all peripherals running, and code fetched from code flash while modify
operation on-going on data flash. It is to be noticed that this value can be significantly reduced by application; switch-off not
used peripherals (default), reduce peripheral frequency through internal prescaler, fetch from RAM most used functions, use
low power mode when possible.
3 HIgher current may be sinked by device during power-up and standby exit. Please refer to inrush current in Table 21.
4
RUN current measured with typical application and accesses on both flash and RAM.
5 Data and Code Flash in Normal Power. Code fetched from RAM: DCUs running with 20MHz pixel clock, QuadSPI fetching data
at 80MHz, GPU accessing internal SRAM and external DRAM, DMA, RLE, and VIU active, Serial IPs CAN and LIN in loop
back mode, DSPI as Master, PLL as system Clock (4 x Multiplier) peripherals on (eMIOS/ADC/SMD/SSD/SGM) and running
at max frequency, periodic SW/WDG timer reset enabled.
2
PXD20 Microcontroller Data Sheet, Rev. 2
74
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
6
Flash in Low Power. RCOSC 128 kHz and RCOSC 16 MHz ON. 10 MHz XTAL clock. FlexCAN: instances: 0, 1ON (clocked
but no reception or transmission), LINFLEX: instances 0, 1, 2 ON (clocked but no reception or transmission). eMIOS: instance:
0, 1 ON - 16 channels on with PWM20K Hz. DSPI: instance: 0 (clocked but no communication). DCUs, TCON, VIU, GPU clock
gated, RTC/API ON.PIT ON. STM ON. ADC ON but not converting.
7
No clock, RC 16MHz off, RCI 128 kHz on, PLL off, HPvreg off, ULPVreg/LPVreg on. All possible peripherals off and clock
gated. Flash in power down mode.
8 ULPreg ON, HP/LPVreg off, 64 KB RAM on, device configured for minimum consumption, all possible modules switched off.
9
32 KHz oscillator operates at 32,768 Hz.
10
ULPreg ON, HP/LPVreg off, 8 KB RAM on, device configured for minimum consumption, all possible modules switched off.
4.8
DC electrical specifications
4.8.1
DC specification for CMOS090LP2 library @ VDDE = 3.3 V
NOTE
These pad specifications are applicable for pads in the Digital segment Only. See the
“GPIO power bank supplies and functionality” table in the “Voltage Regulators and Power
Supplies” chapter of the reference manual for details.
Table 21. DC electrical specifications
Value
Symbol
C
Parameter
Condition
Min
Max
Unit
SpecID
Vdd
SR P Core supply voltage
—
1.08
1.47
V
D9.1
Vdde
SR P I/O supply voltage
—
3.0
3.6
V
D9.2
Vdd33
SR P I/O pre-driver supply voltage
—
3.0
3.6
V
D9.3
Vih_c
SR P CMOS input buffer high
voltage
With hysteresis enabled
0.65  Vdde
Vdde + 0.3
V
D9.4
With hysteresis disabled
0.55  Vdde
Vdde + 0.3
SR P CMOS input buffer low
voltage
With hysteresis enabled
Vss – 0.3
0.35  Vdde
V
D9.5
With hysteresis disabled
Vss – 0.3
0.40  Vdde
—
0.1  Vdde
—
V
D9.6
Vil_c
Vhys_c
SR
T CMOS input buffer hysteresis
Vih_fod_h
SR P 5 V tolerant CMOS input
buffer high voltage
With hysteresis enabled 0.65  Vdd33 Vdd33 + 0.3
V
D9.7
Vil_fod_h
SR P 5 V tolerant CMOS input
buffer low voltage
With hysteresis enabled
Vss – 0.3
0.35  Vdd33
V
D9.8
—
25
150
A
D9.9
Iact_s
SR
T Selectable weak
pullup/pulldown current
Iinact_d
SR P Digital pad input leakage
current
Weak pull inactive
–2.5
2.5
A
D9.10
Iinact_a
SR P Analog pad input leakage
current
Weak pull inactive
–150
150
A
D9.11
0.8  Vdde
—
V
D9.12
Voh
SR P Output high voltage
—
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
75
Electrical characteristics
Table 21. DC electrical specifications (continued)
Value
Symbol
C
Parameter
Condition
Min
Max
Unit
SpecID
SR P Output low voltage
—
—
0.2  Vdde
V
D9.13
Voh_pci
SR P PCI output high voltage
—
0.9  Vdde
—
V
D9.14
Vol_pci
SR P PCI output low voltage
—
—
0.1  Vdde
V
D9.15
—
0.2  Vdd33
Vol
Vol_fod_h
SR P Fast open-drain output low
voltage
Iol_fod_h = 10 mA
D9.16
Table 22. Drive current, VDDE=3.3 V (±10%)
1
2
Pad
C
Drive mode
Minimum Ioh (mA)1
Minimum Iol (mA)2
pad_fc
C
00
16.1
24
01
31.8
47.9
10
47.2
70.6
11
77
114.5
pad_msr
P
All
61.9
83.6
pad_ssr
P
All
61.9
83.6
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 23. Supply leakage
Pad
C
VDD
VDDE
(Typ/Max)
VDD33
(Typ/Max)
pad_fc
D
90 A
3 nA / 4 A
1 nA / 30 A
pad_msr
—
—
—
pad_ssr
—
—
—
PXD20 Microcontroller Data Sheet, Rev. 2
76
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.8.2
DC specification for CMOS090LP2fg library @ VDDE = 5.0 V
NOTE
These pad specifications are applicable for pads in the Analog segment Only. See the
“GPIO power bank supplies and functionality” table in the “Voltage Regulators and Power
Supplies” chapter of the reference manual for details.
Table 24. DC electrical specifications
Value
Symbol
C
Parameter
Condition
Min
Max
Unit
SpecID
Vdd
SR P Core supply voltage
—
1.08
1.32
V
D9.17
Vdde
SR P I/O supply voltage
—
4.5
5.5
V
D9.18
Vdd33
SR P I/O pre-driver supply voltage
—
3.0
3.6
V
D9.19
Vih_hys
SR P CMOS input buffer high
voltage
With hysteresis enabled
0.65  Vdde
Vdde + 0.3
V
D9.20
Vil_hys
SR P CMOS input buffer low
voltage
With hysteresis enabled
Vss – 0.3
0.35  Vdde
V
D9.21
Vih
SR P CMOS input buffer high
voltage
With hysteresis disabled 0.55  Vdde
Vdde + 0.3
V
D9.22
Vil
SR P CMOS input buffer low
voltage
With hysteresis disabled
Vss – 0.3
0.40  Vdde
V
D9.23
—
0.1  Vdde
—
V
D9.24
Vhys
SR
T CMOS input buffer hysteresis
Pull_Ioh
SR P Weak pullup current
—
35
135
A
D9.25
Pull_Iol
SR P Weak pulldown current
—
35
200
A
D9.26
Iinact_d
SR P Digital pad input leakage
current
Weak pull inactive
–2.5
2.5
A
D9.27
Iinact_a
SR P Analog pad input leakage
current
Weak pull inactive
–150
150
A
D9.28
Voh
SR P Slew rate controlled output
high voltage
—
0.8  Vdde
—
V
D9.29
Vol
SR P Slew rate controlled output
low voltage
—
—
0.2  Vdde
V
D9.30
SR P Low swing output pad output
high voltage
—
2.64
—
V
D9.31
Ioh_msr
SR C pad_msr_hv Ioh
—
11.6
40.7
mA
D9.32
Iol_msr
SR C pad_msr_hv Iol
—
17.7
68.2
mA
D9.33
Ioh_ssr
SR C pad_ssr_hv Ioh
—
6.0
21.3
mA
D9.34
Iol_ssr
SR C pad_ssr_hv Iol
—
9.2
36.3
mA
D9.35
Ioh_multv_h SR C pad_multv_hv Ioh
s
High swing mode
10
40
mA
D9.36
Ioh_multv_l SR C pad_multv_hv Ioh
s
Low swing mode
TBD
TBD
mA
D9.37
High/low swing mode
12
56
mA
D9.38
Voh_ls
Iol_multv
SR C pad_multv_hv Iol
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
77
Electrical characteristics
Table 24. DC electrical specifications (continued)
Value
Symbol
C
Parameter
Condition
Min
Max
Unit
SpecID
SR D Pad_tgate_hv input
resistance
—
250
800

D9.39
SR D pad_pupd_hv resistance
mismatch
—
—
5
%
D9.40
pupd_leak
SR D pad_pupd_hv leakage
current
—
0.1
75000
pA
D9.41
pupd200k
SR D pad_pupd_hv 200 k
resistance
—
130
280
k
D9.42
pupd100k
SR D pad_pupd_hv 100 k
resistance
—
65
140
k
D9.43
SR D pad_pupd_hv 5 k
resistance
—
1.4
5.2
k
D9.44
Unit
SpecID
Rtgate
pupd_rm
pupd5k
Table 25. DC electrical specifications
Value
Symbol
Parameter
Condition
Min
Max
Vdd
SR Core supply voltage
—
1.08
1.32
V
D9.45
Vdde
SR I/O supply voltage
—
3.0
3.6
V
D9.46
Vdd33
SR I/O pre-driver supply voltage
—
3.0
3.6
V
D9.47
Vih_hys
SR CMOS input buffer high
voltage
With hysteresis enabled
0.65  Vdde
Vdde + 0.3
V
D9.48
Vil_hys
SR CMOS input buffer low
voltage
With hysteresis enabled
Vss – 0.3
0.35  Vdde
V
D9.49
Vih
SR CMOS input buffer high
voltage
With hysteresis disabled
0.55  Vdde
Vdde + 0.3
V
D9.50
Vil
SR CMOS input buffer low
voltage
With hysteresis disabled
Vss – 0.3
0.40  Vdde
V
D9.51
SR CMOS input buffer hysteresis
—
0.1  Vdde
—
V
D9.52
Pull_Ioh
SR Weak pullup current
—
15
70
A
D9.53
Pull_Iol
SR Weak pulldown current
—
15
95
A
D9.54
Iinact_d
SR Digital pad input leakage
current
Weak pull inactive
–2.5
2.5
A
D9.55
Iinact_a
SR Analog pad input leakage
current
Weak pull inactive
–150
150
A
D9.56
Voh
SR Slew rate controlled output
high voltage
—
0.8  Vdde
—
V
D9.57
Vol
SR Slew rate controlled output
low voltage
—
—
0.2  Vdde
V
D9.58
Vhys
PXD20 Microcontroller Data Sheet, Rev. 2
78
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 25. DC electrical specifications (continued)
Value
Symbol
Parameter
Condition
Min
Max
Unit
SpecID
Ioh_msr
SR pad_msr_hv Ioh
—
5.4
21
mA
D9.59
Iol_msr
SR pad_msr_hv Iol
—
8.1
38.6
mA
D9.60
Ioh_ssr
SR pad_ssr_hv Ioh
—
2.8
11.2
mA
D9.61
Iol_ssr
SR pad_ssr_hv Iol
—
4.2
20.6
mA
D9.62
High swing mode
—
TBD
mA
D9.63
High/low swing mode
—
TBD
mA
D9.64
SR Pad_tgate_hv input
resistance
—
325
1250

D9.65
SR pad_pupd_hv resistance
mismatch
—
—
5
%
D9.66
pupd_leak
SR pad_pupd_hv leakage
current
—
0.1
75000
pA
D9.67
pupd200k
SR pad_pupd_hv 200 k
resistance
—
130
280
k
D9.68
pupd100k
SR pad_pupd_hv 100 k
resistance
—
65
140
k
D9.69
SR pad_pupd_hv 5 k
resistance
—
1.7
7.7
k
D9.70
Ioh_multv_h SR pad_multv_hv Ioh
s
Iol_multv
SR pad_multv_hv Iol
Rtgate
pupd_rm
pupd5k
Table 26. Supply leakage
VDD
VDDE
VDD33
Pad
Typ
Max
Typ
Max
Typ
Max
pad_msr_hv
0.818 nA
83.7 nA
0.81 nA
118 nA
—
—
pad ssr_hv
0.818 nA
83.7 nA
0.858 nA
88.7 nA
—
—
pad_i_hv
0.307 nA
48.4 nA
88.2 pA
30 nA
—
—
biasref_hv
—
—
—
—
—
—
core_v_det_hv
0
0
—
—
0
0
core_v_det_lp_hv
0
0
—
—
—
—
corner_esdpadcell_hv
—
—
—
—
—
—
corner_esdpadcell_id00_hv
—
—
—
—
—
—
corner_esdpadcell_id11_hv
—
—
—
—
—
—
corner_esdpadcell_lp_hv
—
—
—
—
—
—
esd_term_35_84_hv
—
—
—
—
—
—
pad_9v_hv
0
0
—
—
—
—
pad_ae_hv
—
—
—
—
—
—
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
79
Electrical characteristics
Table 26. Supply leakage (continued)
VDD
VDDE
VDD33
Pad
Typ
Max
Typ
Max
Typ
Max
pad_esdspacer_hv
—
—
—
—
—
—
pad_tgate_hv
—
—
—
—
—
—
pad_vdd33_hv
—
—
—
—
—
—
pad_vdde_hv
0
0
—
—
0
0
pad_vddint3v_hv
0
0
—
—
0
0
pad_vddint_hv
0
0
—
—
—
—
pad_vss_hv
0
0
—
—
—
—
pad_vsse_hv
0
0
—
—
—
—
pad_vssint3v_hv
0
0
—
—
—
—
pad_vssint_hv
0
0
—
—
—
—
spcr_17_82_hv
—
—
—
—
—
—
spcr_35_84_hv
—
—
—
—
—
—
spcr_71_88_hv
—
—
—
—
—
—
spcr_143_38_hv
—
—
—
—
—
—
spcr_vdde_lvl_hv
—
—
—
—
—
—
Table 27. AVG IDDE specifications
Cell
Period (ns)
Load (pF)1
VDDE (V)
Drive/slew select
IDDE (mA)
pad_msr_hv2
24
50
5.5
11
14
62
50
5.5
01
5.3
317
50
5.5
00
1.1
425
200
5.5
00
3
37
50
5.5
11
9
130
50
5.5
01
2.5
650
50
5.5
00
0.5
840
200
5.5
00
1.5
pad_ssr_hv2
1
2
All loads are lumped loads.
Average current is for pad configured as output only. Use pad_i current for input.
PXD20 Microcontroller Data Sheet, Rev. 2
80
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.8.3
DC specification for CMOS090_ddr library @ VDDE = 3.3 V
Table 28. DC electrical specifications at 3.3 V VDDE
Value
Symbol
Vdd
Parameter
SR Core supply voltage
Min
Max
1.08
1.32
1.08
1.47
Unit
SpecID
V
D9.71
Vdde
SR I/O supply voltage
3.0
3.6
V
D9.72
Vdd33
SR I/O pre-driver supply voltage
3.0
3.6
V
D9.73
SR Input reference voltage
1.3
1.7
V
D9.74
Vref
Vtt
SR Termination voltage
Vref – 0.05
Vref + 0.05
V
D9.75
Vih
SR Input high voltage
Vref + 0.20
—
V
D9.76
Vil
SR Input low voltage
—
Vref – 0.2
V
D9.77
Voh
SR Output high voltage
Vtt + 0.8
—
V
D9.78
Vol
SR Output low voltage
—
Vtt – 0.8
V
D9.79
Table 29. Output drive current @ VDDE = 3.3 V (±10%)
4.8.4
Pad
C
Drive mode
Minimum Ioh (mA)
Minimum Iol (mA)
pad_st_acc
P
111
–16
16
pad_st_dq
P
111
–16
16
pad_st_clk
P
111
–16
16
pad_st
P
111
–16
16
pad_st_odt
P
111
–16
16
pad_st_ck
P
111
–16
16
DC specification for CMOS090_ddr library @ VDDE = 2.5 V
Table 30. DC electrical specifications at 2.5 V VDDE
Value
Symbol
Vdd
C
SR
P
Parameter
Core supply voltage
Min
Max
1.08
1.32
1.08
1.47
Unit
SpecID
V
D9.80
Vdde
SR
P
I/O supply voltage
2.3
2.7
V
D9.81
Vdd33
SR
P
I/O pre-driver supply voltage
3.0
3.6
V
D9.82
Vref
SR
P
Input reference voltage
0.49  Vdde
0.51  Vdde
V
D9.83
Vtt
SR
P
Termination voltage
Vref – 0.04
Vref + 0.04
V
D9.84
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
81
Electrical characteristics
Table 30. DC electrical specifications at 2.5 V VDDE (continued)
Value
Symbol
C
Parameter
Min
Max
Unit
SpecID
Vih
SR
P
Input high voltage
Vref + 0.15
—
V
D9.85
Vil
SR
P
Input low voltage
—
Vref – 0.15
V
D9.86
Voh
SR
P
Output high voltage
Vtt + 0.81
—
V
D9.87
Vol
SR
P
Output low voltage
—
Vtt – 0.81
V
D9.88
Table 31. Output drive current @ VDDE = 2.5 V (±200mV)
Pad
C
Drive mode
Minimum Ioh (mA)
Minimum Iol (mA)
Libraries
pad_st_acc
P
011
–16.2
16.2
6MDDR
pad_st_dq
P
011
–16.2
16.2
6MDDR
pad_st_ck
P
011
–16.2
16.2
6MDDR
4.8.5
DC specification for CMOS090_ddr library @ VDDE = 1.8 V
Table 32. DC electrical specifications for 1.8 V VDDE
Value
Symbol
Vdd
C
SR
P
Parameter
Core supply voltage
Min
Max
1.08
1.32
1.08
1.47
Unit
SpecID
V
D9.89
Vdde
SR
P
I/O supply voltage
1.7
1.9
V
D9.90
Vdd33
SR
P
I/O pre-driver supply voltage
3.0
3.6
V
D9.91
Vref
SR
P
Input reference voltage
0.49  Vdde
0.51  Vdde
V
D9.92
Vtt
SR
P
Termination voltage
Vref – 0.04
Vref + 0.04
V
D9.93
Vih
SR
P
Input high voltage
Vref + 0.125
—
V
D9.94
Vil
SR
P
Input low voltage
—
Vref – 0.125
V
D9.95
Voh
SR
P
Output high voltage
Vtt + 0.81
—
V
D9.96
Vol
SR
P
Output low voltage
—
Vtt – 0.81
V
D9.97
Table 33. Output drive current @ VDDE = 1.8 V (±100mV)
Pad
pad_st_acc
P
Drive mode
Minimum Ioh (mA)
Minimum Iol (mA)
Libraries
000
–3.57
3.57
6MDDR
001
–7.84
7.84
010
–5.36
5.36
110
–13.4
13.4
PXD20 Microcontroller Data Sheet, Rev. 2
82
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 33. Output drive current @ VDDE = 1.8 V (±100mV) (continued)
Pad
pad_st_dq
pad_st_clk
Drive mode
Minimum Ioh (mA)
Minimum Iol (mA)
Libraries
000
–3.57
3.57
6MDDR
001
–7.84
7.84
010
–5.36
5.36
110
–13.4
13.4
000
–3.57
3.57
001
–7.84
7.84
010
–5.36
5.36
110
–13.4
13.4
P
P
6MDDR
Table 34. ODT DC electrical characteristics
Value
Symbol
Rtt
SR
C
Parameter
Condition
C Effective impedance
value
PXD20 supports only 150 ohm termination and
that can be enabled by enabling any bit of the
termination control register (all of them are
OR’ed).
Min
Typ
Max
120
150
180
Unit
SpecID

D9.98
Table 35. core_v_det_odt and core_v_det33_odt specifications
VDDE
C
VDD
Vtrip max (V)
Vtrip min
Hysteresis min (V)
3.5
C
Rising
0.79
0.44
0.07
C
Falling
0.56
0
C
Rising
0.65
0.3
C
Falling
0.33
0
C
0.0
1.40
0.3
1.62
Rising
0.16
—
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
83
Electrical characteristics
4.9
RESET electrical characteristics
The device implements a dedicated bidirectional RESET pin.
Figure 9. Start-up reset requirements
VRESET
hw_rst
VDD
‘1’
VIH
VIL
‘0’
filtered by
hysteresis
filtered by
lowpass filter
WFRST
filtered by
lowpass filter
unknown reset
state
device under hardware reset
WFRST
WNFRST
Figure 10. Noise filtering on reset signal
PXD20 Microcontroller Data Sheet, Rev. 2
84
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 36. Reset electrical characteristics
Symbol
C
Value2
Conditions1
Parameter
Unit SpecID
Min
VIH
SR P Input High Level CMOS
Schmitt Trigger
—
VIL
SR P Input low Level CMOS
Schmitt Trigger
—
–0.4
—
VHYS
CC3 D Input hysteresis CMOS
Schmitt Trigger
—
0.1 VDD
VOL
CC4 P Output low level
Push Pull, IOL = 2mA,
VDD = 5.0V ± 10%, ipp_hve = 0
(recommended)
D
C
Ttr
WFRST
D8.1
0.35 VDD
V
D8.2
—
—
V
D8.3
—
—
0.1 VDD
V
D8.4
Push Pull, IOL = 1mA,
VDD = 5.0V ± 10%, ipp_hve = 15
—
—
0.1 VDD
Push Pull, IOL = 1mA,
VDD = 3.3V ± 10%, ipp_hve = 1
(recommended)
—
—
0.5
CC4 T Output transition time output pin6 CL = 25pF,
MEDIUM configuration
VDD = 5.0V ± 10%, ipp_hve = 0
—
—
10
ns
D8.5
CL = 50pF,
VDD = 5.0V ± 10%, ipp_hve = 0
—
—
20
CL = 100pF,
VDD = 5.0V ± 10%, ipp_hve = 0
—
—
40
CL = 25pF,
VDD = 3.3V ± 10%, ipp_hve = 1
—
—
12
CL = 50pF,
VDD = 3.3V ± 10%, ipp_hve = 1
—
—
25
CL = 100pF,
VDD = 3.3V ± 10%, ipp_hve = 1
—
—
40
—
—
—
70
ns
D8.6
—
400
—
—
ns
D8.7
—
10
—
—
µA
D8.8
SR P RESET Input Filtered Pulse
|IWPU| CC4 P Weak pullup current absolute value
1
3
4
5
6
Max
V
WNFRST SR P RESET Input Not Filtered Pulse
2
Typ
0.65 VDD — VDD + 0.4
VDD = 3.3V ±10% / 5.0V ±10%, TA = –40 to +105oC, unless otherwise specified
All values need to be confirmed during device validation.
Data based on characterization results, not tested in production
Guaranteed by design simulation.
This is a transient configuration during power-up, up to the end of reset PHASE2 (refer to RGM module section of the reference
manual).
CL calculation should include device and package capacitance (CPKG < 5pF).
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
85
Electrical characteristics
4.10
Fast external crystal oscillator (4–16 MHz) electrical
characteristics
This device implements the fast external oscillator (FXOSC) using a low power Loop Controlled Pierce Oscillator (LCP)
configuration.
Table 37. Fast external crystal oscillator electrical characteristics
Value
Symbol
Parameter
Conditions
16
MHz
O9.1
—
—
µA
O9.2
41
502
ms
O9.3
Max
Loop controlled Pierce
4.0
—
—
100
C
Crystal oscillator range
iOSC
P
Startup current
tUPOSC
C
Oscillator start-up time
tCQOUT
D
Clock quality check time-out
—
0.45
—
2.5
s
O9.4
fCMFA
D
Clock monitor failure assert
frequency
—
200
400
800
kHz
O9.5
fEXT
D
External square wave input
frequency2
—
2.0
—
50
MHz
O9.6
tEXTL
D
External square wave pulse
width low
—
9.5
—
—
ns
O9.7
tEXTH
D
External square wave pulse
width high
—
9.5
—
—
ns
O9.8
tEXTR
D
External square wave rise time
—
—
—
1
ns
O9.9
tEXTF
D
External square wave fall time
—
—
—
1
ns
O9.10
CIN
D
Input capacitance
EXTAL and XTAL pins
—
7
—
pF
O9.11
—
0.75 
VDDPLL
—
—
V
O9.12
—
—
VDDPLL
+ 0.3
—
—
0.25 
VDDPLL
V
O9.13
VSSPLL
– 0.3
—
—
—
180
—
mV
O9.14
—
1.0
—
V
O9.15
P
EXTAL pin input high
voltage2
Loop controlled Pierce
T
VIL,EXTAL
P
EXTAL pin input low voltage2
—
T
VHYS,EXTAL
C
EXTAL pin input hysteresis2
VPP,EXTAL
C
EXTAL pin oscillation amplitude
1
SpecID
Typ
fOSC
VIH,EXTAL
2
Unit
Min
Loop controlled Pierce
fOSC = 4 MHz, C = 22 pF
Maximum value is for extreme cases using high Q, low frequency crystals
PXD20 Microcontroller Data Sheet, Rev. 2
86
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.11
Slow external crystal oscillator (32 KHz) electrical characteristics
The device provides a slow external oscillator/resonator driver (SXOSC). The 32 KHz oscillator operates at 32,768 Hz.
PC[15]
PC[15]
Resonator
Crystal
CX
RF
PC[14]
PC[14]
CY
DEVICE
DEVICE
Figure 11. Crystal oscillator and resonator connection scheme
NOTE
PC[14]/PC[15] must not be directly used to drive external circuits.
VDD
VDDMIN
VXTAL
1/fXOSCLP
VXOSCLP
90%
10%
TXOSCLPSU
valid internal clock
Figure 12. Slow external crystal oscillator electrical characteristics
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
87
Electrical characteristics
Table 38. Slow external crystal oscillator electrical characteristics
Symbol
C
SR
fXOSCLP
3
VXOSCLP CC
3
TXOSCLPS CC
Unit SpecID
Min
Typ
Max
32
—
40
kHz
O10.1
VDDA=3.3V10%,
VDDE_A=3.3V10%
1.12
1.33
1.74
V
O10.2
VDDA=5.0V10%,
VDDE_A=5.0V10%
1.12
1.37
1.74
—
—
—
5
µA
O10.3
—
—
—
2
s
O10.4
C Oscillator frequency
C Oscillation amplitude
CC3 D Oscillator consumption
IXOSCLP
Value2
Conditions1
Parameter
D Oscillator start-up time
U
VIH
SR
C Input high level CMOS Oscillator bypass mode 0.65VDDA
0.65VDDE_A
Schmitt Trigger
—
VDDA+0.4
VDDE_A+0.4
V
O10.5
VIL
SR
C Input low level CMOS
Schmitt Trigger
—
0.35VDDA
0.35VDDE_A
V
O10.6
Oscillator bypass mode
VSS–0.4
1
VDD = 3.3 V ±10% / 5.0 V ±10%, TA = –40 to +105 °C, unless otherwise specified
All values need to be confirmed during device validation.
3
Granted by device validation
2
4.12
FMPLL electrical characteristics
The device provides a frequency-modulated phase-locked loop (FMPLL) module to generate a fast system clock from the fast
external oscillator driver.
Table 39. FMPLL electrical characteristics
Symbol
fPLLIN
SR
C
Value2
Conditions1
Parameter
T PLL reference clock3
Unit SpecID
Min
Typ
Max
—
4
—
120
—
47.5
—
52.5
MHz O11.1
PLLIN
SR
fPLLOUT
CC4
T PLL output clock frequency
—
15
—
2505
fCPU
CC4
T System clock frequency
—
—
—
1256 MHz O11.4
TLOCK
CC4
T PLL lock time
Stable oscillator (fPLLIN = 10 MHz)
—
—
100
µs
O11.5
TPKJIT
CC4
T PLL jitter
fPLLOUT (PHI i.e. FMPLL O/P) =
–509
15.625 MHz @ 10 MHz resonator
—
509
ps
O11.6
TLTJIT
CC4
T PLL long term jitter
fPLLIN = 10 MHz (resonator)
–2.4
—
2.4
ns
O11.7
IPLL
CC7
D Current Consumption (Normal TA = 25°C
Mode for Analog Supply)
—
—
500
µA
O11.8
T PLL reference clock duty
cycle3
%
O11.2
MHz O11.3
1
VDDPLL = 1.2 V ±10%, TA = –40 to 105 °C, unless otherwise specified.
All values need to be confirmed during device validation.
3
PLLIN clock retrieved directly from XOSCHS clock. Input characteristics are granted when oscillator is used in functional
mode. When bypass mode is used, oscillator input clock should verify fPLLIN and PLLIN.
2
PXD20 Microcontroller Data Sheet, Rev. 2
88
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4
Data based on device simulation.
2x sys clock required for generation of DDR timing.
6
fCPU of 125 MHz can be achieved only at temperatures up to 105 °C with a maximum FM depth of 2%.
7
Data based on characterization results, not tested in production
5
4.13
Fast internal RC oscillator (16 MHz) electrical characteristics
The device provides a fast internal RC oscillator (FIRC). This is used as the default clock at the power-up of the device.
Table 40. Fast internal oscillator electrical characteristics
Symbol
C
Parameter
Conditions
Value2
1
Unit SpecID
Min
Typ
Max
CC3 P RC oscillator high frequency
TA = 25 °C, trimmed
—
16
—
IRCMRUN
CC3 D RC oscillator high frequency current in running mode
TA = 25 °C, trimmed
—
—
200
µA
O12.2
IRCMPWD
CC3 D RC oscillator high frequency current in power
down mode
TA = 25 °C
—
—
10
µA
O12.3
—
–5
—
+5
%
O12.5
fRCM
RCMVAR CC4 C RC oscillator variation in temperature and
supply with respect to fRC at TA = 55 °C in
high-frequency configuration
MHz O12.1
1
VDD = 3.3 V ±10% / 5.0 V ±10%, TA = –40 to 105 °C, unless otherwise specified.
All values need to be confirmed during device validation.
3 Guaranteed by device simulation, not tested in production
4 Guaranteed by device characterization, not tested in production
2
4.14
Slow internal RC oscillator (128 kHz) electrical characteristics
The device provides a slow internal RC oscillator (SIRC). This can be used as the reference clock for the RTC module.
Table 41. Slow internal RC oscillator electrical characteristics
Symbol
C
Parameter
Value2
Conditions1
Unit SpecID
Min
Typ
Max
fRCL
CC3 P RC oscillator low frequency
TA = 25 °C, trimmed
—
128
—
kHz
O13.1
IRCL
CC3
D RC oscillator low frequency current
TA = 25 °C, trimmed
—
—
5
µA
O13.2
RCLTRI
M
CC3
C RC oscillator precision after trimming of
fRCL
TA = 25 °C
–2
—
+2
%
O13.3
–10
—
+10
%
O13.4
RCLVAR CC3 C RC oscillator variation in temperature and High frequency config3
supply with respect to fRC at TA = 55 °C in uration
high frequency configuration
1
VDD = 3.3 V ± 10% / 5.0 V ± 10%, TA = –40 to +105 °C, unless otherwise specified.
All values need to be confirmed during device validation.
3
Guaranteed by device simulation, not tested in production
2
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
89
Electrical characteristics
4.15
Flash memory electrical characteristics
Table 42. Program and erase specifications
Symbol
C
Min
Value
Parameter
Typical
Value1
Initial
Max2
Max3
Unit
SpecID
Tdwprogram
C Double Word (64 bits) Program Time4
—
22
500
s
D14.1
T16kpperase
C 16 KB Block Pre-program and Erase Time
—
500
5000
ms
D14.2
T32kpperase
C 32 KB Block Pre-program and Erase Time
—
600
5000
ms
D14.3
T128kpperase
C 128 KB Block Pre-program and Erase Time
—
1300
7500
ms
D14.4
1
Typical program and erase times assume nominal supply values and operation at 25 °C. All times are subject to change
pending device characterization.
2 Initial factory condition: < 100 program/erase cycles, 25 °C, typical supply voltage.
3
The maximum program & erase times occur after the specified number of program/erase cycles. These maximum values are
characterized but not guaranteed.
4
Actual hardware programming times. This does not include software overhead.
Table 43. Flash module life
Value
Symbol
C
Parameter
Min
Typ
Unit
SpecID
P/E
C Number of program/erase cycles per block
for 16 KB, 48KB and 64KB blocks, across
full operating temperature range (Tj)
—
100,000
—
P/E
cycles
D14.5
P/E
C Number of program/erase cycles per block
for 128KB and 256KB blocks, across full
operating temperature range (Tj)
—
1, 000
100,000
P/E
cycles
D14.6
Blocks with 0 – 1,000 P/E
cycles
20
—
Years
D14.8
Blocks with 1,001 –
10,000 P/E cycles
10
—
Years
Blocks with 10,001 –
100,000 P/E cycles
5
—
Years
Data
C Minimum data retention at 85 °C average
retention
ambient temperature1
1
Conditions
Ambient temperature averaged over duration of application, not to exceed recommended product operating temperature
range.
PXD20 Microcontroller Data Sheet, Rev. 2
90
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.16
ADC parameters
The device provides a 10-bit Successive Approximation Register (SAR) Analog to Digital Converter.
Offset Error OSE
Gain Error GE
1023
1022
1021
1020
1019
1 LSB ideal = VDDA / 1024
1018
(2)
code out
7
(1)
6
(1) Example of an actual transfer curve
5
(5)
(2) The ideal transfer curve
(3) Differential non-linearity error (DNL)
4
(4) Integral non-linearity error (INL)
(4)
(5) Center of a step of the actual transfer curve
3
(3)
2
1
1 LSB (ideal)
0
1
2
3
4
5
6
7
1017 1018 1019 1020 1021 1022 1023
Vin(A) (LSBideal)
Offset Error OSE
Figure 13. ADC characteristics and error definitions
4.16.1
Input impedance and ADC accuracy
In the following analysis, the input circuit corresponding to the precise channels is considered.
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; furthermore, it sources
charge during the sampling phase, when the analog signal source is a high-impedance source.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
91
Electrical characteristics
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.
In fact a current sink contributor is represented by the charge sharing effects with the sampling capacitance: CS being
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 CS equal to 3 pF, a resistance of 330 k is obtained (REQ
= 1 / (fc × CS), where fc represents the conversion rate at the considered channel). To minimize the error induced by the voltage
partitioning between this resistance (sampled voltage on CS) and the sum of RS + RF + RL + RSW + RAD, the external circuit
must be designed to respect the Equation 5:
Eqn. 5
R S + R F + R L + R SW + R AD
V A  ---------------------------------------------------------------------------  1
--- LSB
R EQ
2
Equation 5 generates a constraint for external network design, in particular on resistive path. Internal switch resistances (RSW
and RAD) can be neglected with respect to external resistances.
EXTERNAL CIRCUIT
INTERNAL CIRCUIT SCHEME
VDD
Source
RS
VA
Filter
RF
Current Limiter
Channel
Selection
Sampling
RSW1
RAD
RL
CF
CP1
CP2
CS
RS Source Impedance
RF Filter Resistance
CF Filter Capacitance
Current Limiter Resistance
RL
RSW1 Channel Selection Switch Impedance
RAD Sampling Switch Impedance
CP Pin Capacitance (two contributions, CP1 and CP2)
CS Sampling Capacitance
Figure 14. Input equivalent circuit (precise channels)
PXD20 Microcontroller Data Sheet, Rev. 2
92
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
EXTERNAL CIRCUIT
INTERNAL CIRCUIT SCHEME
VDD
Source
Filter
RS
Current Limiter
RF
RS
RF
CF
RL
RSW
RAD
CP
CS
Extended
Switch
Sampling
RSW1
RSW2
RAD
RL
CF
VA
Channel
Selection
CP1
CP3
CP2
CS
Source Impedance
Filter Resistance
Filter Capacitance
Current Limiter Resistance
Channel Selection Switch Impedance (two contributions RSW1 and RSW2)
Sampling Switch Impedance
Pin Capacitance (three contributions, CP1, CP2 and CP3)
Sampling Capacitance
Figure 15. Input equivalent circuit (extended channels)
A second aspect involving the capacitance network shall be considered. Assuming the three capacitances CF, CP1 and CP2 are
initially charged at the source voltage VA (refer to the equivalent circuit reported in Figure 14): A charge sharing phenomenon
is installed when the sampling phase is started (A/D switch close).
Voltage Transient on CS
VCS
VA
VA2
V <0.5 LSB
1
2
1 < (RSW + RAD) CS << TS
2 = RL (CS + CP1 + CP2)
VA1
TS
t
Figure 16. Transient behavior during sampling phase
In particular two different transient periods can be distinguished:
•
A first and quick charge transfer from the internal capacitance CP1 and CP2 to the sampling capacitance CS occurs (CS
is supposed initially completely discharged): considering a worst case (since the time constant in reality would be
faster) in which CP2 is reported in parallel to CP1 (call CP = CP1 + CP2), the two capacitances CP and CS are in series,
and the time constant is
CP  CS
 1 =  R SW + R AD   --------------------CP + CS
Eqn. 6
Equation 6 can again be simplified considering only CS as an additional worst condition. In reality, the transient is
faster, but the A/D converter circuitry has been designed to be robust also in the very worst case: the sampling time TS
is always much longer than the internal time constant:
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
93
Electrical characteristics
Eqn. 7
 1   R SW + R AD   C S « T S
The charge of CP1 and CP2 is redistributed also on CS, determining a new value of the voltage VA1 on the capacitance
according to Equation 8:
Eqn. 8
V A1   C S + C P1 + C P2  = V A   C P1 + C P2 
•
A second charge transfer involves also CF (that is typically bigger than the on-chip capacitance) through the resistance
RL: again considering the worst case in which CP2 and CS were in parallel to CP1 (since the time constant in reality
would be faster), the time constant is:
Eqn. 9
 2  R L   C S + C P1 + C P2 
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 TS, a constraints on RL sizing is obtained:
Eqn. 10
10   2 = 10  R L   C S + C P1 + C P2   TS
Of course, RL shall be sized also according to the current limitation constraints, in combination with RS (source
impedance) and RF (filter resistance). Being CF definitively bigger than CP1, CP2 and CS, then the final voltage VA2
(at the end of the charge transfer transient) will be much higher than VA1. Equation 11 must be respected (charge
balance assuming now CS already charged at VA1):
Eqn. 11
VA2   C S + C P1 + C P2 + C F  = V A  C F + V A1   C P1 + C P2 + C S 
The two transients above are not influenced by the voltage source that, due to the presence of the RFCF filter, is not able to
provide the extra charge to compensate the voltage drop on CS with respect to the ideal source VA; the time constant RFCF of
the filter is very high with respect to the sampling time (TS). The filter is typically designed to act as anti-aliasing.
Analog Source Bandwidth (VA)
TC 2 RFCF (Conversion Rate vs. Filter Pole)
fF  f0 (Anti-aliasing Filtering Condition)
Noise
2 f0 fC (Nyquist)
f0
f
Anti-Aliasing Filter (fF = RC Filter pole)
fF
f
Sampled Signal Spectrum (fC = conversion Rate)
f0
fC
f
Figure 17. Spectral representation of input signal
PXD20 Microcontroller Data Sheet, Rev. 2
94
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Calling f0 the bandwidth of the source signal (and as a consequence the cut-off frequency of the anti-aliasing filter, fF),
according to the Nyquist theorem the conversion rate fC must be at least 2f0; it means that the constant time of the filter is greater
than or at least equal to twice the conversion period (TC). Again the conversion period TC is longer than the sampling time TS,
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 RFCF is definitively much higher than the
sampling time TS, so the charge level on CS cannot be modified by the analog signal source during the time in which the
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 CS; from the two charge balance equations above, it is simple to derive Equation 12 between the ideal and real sampled
voltage on CS:
Eqn. 12
C P1 + C P2 + C F
VA
----------- = -------------------------------------------------------V A2
C P1 + C P2 + C F + C S
From this formula, in the worst case (when VA is maximum, that is for instance 5V), assuming to accept a maximum error of
half a count, a constraint is evident on CF value:
Eqn. 13
C F  2048  C S
4.16.2
ADC electrical characteristics
Table 44. ADC electrical characteristics
Symbol
C
Value2
Conditions1
Parameter
Min
Typ
Max
Unit
SpecID
VSSA
SR D Voltage on VSSA (ADC
reference) pin with respect to ground (VSS)3
—
–0.1
—
0.1
V
D15.1
VDDA
SR D Voltage on VDDA pin
(ADC reference) with respect to ground (VSS)
—
VDDE_A – 0.
1
—
VDDE_A + 0.1
V
D15.2
VAINx
SR D Analog input voltage4
—
VSSA – 0.1
—
VDDA + 0.1
V
D15.3
fADC
SR D ADC analog frequency
—
6
—
32
MHz
D15.4
—
1.5
µs
D15.5
µs
D15.6
µs
D15.7
tADC_PU SR D ADC power up delay
tADC_S CC5 T Sample time6
—
fADC = 32 MHz,
ADC_conf_sample_input =
17
0.5
fADC = 6 MHz,
ADC_conf_sample_input =
127
tADC_C CC5 T Conversion time7
fADC = 32 MHz,
ADC_conf_comp = 2
0.625
—
—
21
—
—
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
95
Electrical characteristics
Table 44. ADC electrical characteristics (continued)
Symbol
C
Value2
1
Parameter
Conditions
Min
Typ
Max
Unit
SpecID
CS
CC5 D ADC input sampling
capacitance
—
—
—
3
pF
D15.8
CP1
CC5 D ADC input pin
capacitance 1
—
—
—
3
pF
D15.9
CP2
CC5 D ADC input pin
capacitance 2
—
—
—
1
pF
D15.10
CP3
CC5 D ADC input pin
capacitance 3
—
—
—
1
pF
D15.11
RSW1
CC5 D Internal resistance of
analog source
—
—
—
3
k
D15.12
RSW2
CC5 D Internal resistance of
analog source
—
—
—
2
k
D15.13
RAD
CC5 D Internal resistance of
analog source
—
—
—
0.1
k
D15.14
IINJ
SR
Current injection on one
ADC input, different from
the converted one
–10
—
10
mA
D15.15
INL
CC5 P Integral Non Linearity
No overload
–1.5
—
1.5
LSB
D15.16
DNL
CC5
P Differential Non Linearity No overload
–1.0
—
1.0
LSB
D15.17
OFS
CC5 T Offset error
—
0.5
—
LSB
D15.18
GNE
CC5 T Gain error
—
0.6
—
LSB
D15.19
TUEX
CC T Total Unadjusted Error for No overload
extended channel
–3
—
3
LSB
D15.21
TUEP
CC5 T Total Unadjusted Error for No overload
precise channels, input
overload conditions on
only pins
adjacent channel
–2
—
2
LSB
D15.22
—
—
CC5 T Total Unadjusted Error for No overload
extended channel,
overload conditions on
adjacent channel
–3
—
3
LSB
—
—
—
LSB
TUEX
1
2
3
4
5
6
7
T Input current Injection
After offset cancellation
—
LSB
D15.23
VDDA = 3.3 V ± 10% / 5.0 V ± 10%, TA = –40 to +105 °C, unless otherwise specified.
All values need to be confirmed during device validation.
Analog and digital VSS must be common (to be tied together externally).
VAINx may exceed VSSA and VDDA limits, remaining on absolute maximum ratings, but the results of the conversion will be
clamped respectively to 0x000 or 0x3FF
Guaranteed by design
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.
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’s register with the conversion result.
PXD20 Microcontroller Data Sheet, Rev. 2
96
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.17
AC specifications
4.17.1
AC specification for CMOS090LP2 library @ VDDE = 3.3 V
Table 45. Functional pad type AC specifications
Name
pad_ssr
pad_fc
pad_msr
1
2
C
C
C
C
Prop. delay (ns)
L>H / H>L1
Rise/fall edge (ns)
Drive load
(pF)
Drive/slew
rate select
Min
Max
Min
Max
MSB, LSB
—
4.5 / 4.5
—
2.2 / 2.2
50
—
8/8
—
6/6
200
—
45 / 45
—
22 / 22
50
—
60 / 60
—
28 / 28
200
—
90 / 90
—
42 / 42
50
—
110 / 110
—
50 / 50
200
—
430 / 430
—
210 / 210
50
—
480 / 480
—
220 / 220
200
—
2.5 / 2.5
—
1.2 / 1.2
10
00
—
2.5 / 2.5
—
1.2 / 1.2
20
01
—
2.5 / 2.5
—
1.2 / 1.2
30
10
—
2.5 / 2.5
—
1.2 / 1.2
50
112
—
4.0 / 4.5
—
1.02 / 1.4
50
112
—
7.3 / 8.3
—
3.5 / 4.2
200
—
24 / 22
—
9.1 / 10.3
50
—
33 / 31
—
14 / 15
200
—
49 / 44
—
18 / 21
50
—
60 / 53
—
24 / 25
200
—
332 / 302
—
126 / 151
50
—
362 / 325
—
136 / 158
200
112
10
01
00
10
01
00
L>H signifies low-to-high propagation delay and H>L signifies high-to-low propagation delay.
Can be used on the tester.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
97
Electrical characteristics
4.17.2
AC specification for CMOS090LP2fg library @ VDDE = 5.0 V
Table 46. Functional pad type AC specifications
Name
pad_msr_hv2
C
C
Prop. delay (ns)
L>H / H>L1
Rise/fall edge (ns)
Drive load
(pF)
Min
Max
Min
Max
4.6 / 3.7
12 / 12
2.2 / 2.2
5.3 / 5.9
50
13 / 10
32 / 32
9/9
22 / 22
200
Drive/slew
rate select
MSB, LSB
113
104
N/A
pad_ssr_hv2
C
12 / 13
28 / 34
5.6 / 6
12 / 15
50
23 / 23
52 / 59
11 / 14
28 / 31
200
69 / 71
152 / 165
34 / 35
70 / 74
50
95 / 90
205 / 220
44 / 51
96 / 96
200
7.3 / 5.7
19 / 18
4.4 / 4.3
10 / 11
50
24 / 19
58 / 58
17 / 15
40 / 42
200
01
00
113
104
N/A
pad_i_hv
C
26 / 27
61 / 69
13 / 13
30 / 34
50
49 / 45
115 / 115
27 / 23
61 / 61
200
137 / 142
320 / 330
72 / 74
156 / 164
50
182 / 172
420 / 420
90 / 85
200 / 200
200
0.5 / 0.5
1.9 / 1.9
0.3 / 0.3
1.5 / 1.5
0.5
01
00
N/A
1
L>H signifies low-to-high propagation delay and H>L signifies high-to-low propagation delay.
For input buffer timing, look at pad_i_hv.
3 Can be used on the tester.
4
This drive select value is not supported. If selected, it will be approximately equal to 11.
2
4.17.3
AC specification for CMOS090LP2fg library @ VDDE = 3.3 V
Table 47. Functional pad AC type specifications
Name
pad_msr_hv
Prop. delay (ns)
L>H / H>L
Rise/fall edge (ns)
Drive load
(pF)
Min
Max
Min
Max
5.8 / 4.4
18 / 17
2.7 / 2.1
7.6 / 8.5
50
16 / 13
46 / 49
11.2 / 8.6
30 / 34
200
Drive/slew
rate select
MSB, LSB
N/A
11
10
14 / 16
37 / 45
6.5 / 6.7
15.5 / 19
50
27 / 27
69 / 82
15 / 13
38 / 43
200
83 / 86
200 / 210
38 / 38
86 / 86
50
113 / 109
270 / 285
53 / 46
120 / 120
200
01
00
PXD20 Microcontroller Data Sheet, Rev. 2
98
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 47. Functional pad AC type specifications (continued)
Prop. delay (ns)
L>H / H>L
Name
pad_ssr_hv
Rise/fall edge (ns)
Drive load
(pF)
Min
Max
Min
Max
9.2 / 6.9
27 / 28
5.5 / 4.1
15 / 17
50
30 / 23
81 / 87
21 / 16
57 / 63
200
MSB, LSB
11
N/A
pad_i_hv
4.17.4
Drive/slew
rate select
10
31 / 31
80 / 90
15.4 / 15.4
38 / 42
50
58 / 52
144 / 155
32 / 26
82 / 85
200
162 / 168
415 / 415
80 / 82
190 / 190
50
216 / 205
533 / 540
106 / 95
250 / 250
200
0.5 / 0.5
3/3
0.4 / 0.4
1.5 / 1.5
0.5
01
00
N/A
Pad AC specifications (3.3 V, PAD3V5V = 1)
Table 48. Pad AC specifications (3.3 V, PAD3V5V = 1)1
No.
1
2
3
4
Pad
Slow
Medium
Fast
Pull Up/Down
(3.6 V max)
Parameter
Classification
1
2
Tswitchon1
(ns)
Rise/Fall2
(ns)
Frequency
(MHz)
Current slew
(mA/ns)
Load drive
(pF)
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
3
—
40
4
—
40
—
—
4
0.01
—
2
25
3
—
40
6
—
50
—
—
2
0.01
—
2
50
3
—
40
10
—
75
—
—
2
0.01
—
2
100
3
—
40
14
—
100
—
—
2
0.01
—
2
200
1
—
15
2
—
12
—
—
40
2.5
—
7
25
1
—
15
4
—
25
—
—
20
2.5
—
7
50
1
—
15
8
—
40
—
—
13
2.5
—
7
100
1
—
15
14
—
70
—
—
7
2.5
—
7
200
1
—
6
1
—
4
—
—
72
3
—
40
25
1
—
6
1.5
—
7
—
—
55
3
—
40
50
1
—
6
3
—
12
—
—
40
3
—
40
100
1
—
6
5
—
18
—
—
25
3
—
40
200
—
—
—
—
—
7500
—
—
—
—
—
—
50
D
C
C
C
n/a
Propagation delay from VDD/2 of internal signal to Pchannel/Nchannel on condition
Slope at rising/falling edge
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
99
Electrical characteristics
4.17.5
AC specification for CMOS090_ddr library @ VDDE = 3.3 V
Table 49. AC specifications at 3.3 V VDDE
Name
pad_st_acc
pad_st_dq
pad_st_clk
4.17.6
C
C
C
C
Prop. delay (ns)
L>H / H>L
Rise/fall edge (ns)
Drive load
(pF)
Min
Max
Min
Max
1.4/1.4
2.4/2.4
3.1/2.5
5.6/5.4
5
1.7/1.7
2.7/2.7
0.9/1.1
1.7/2.0
20
1.4/1.4
2.4/2.4
3.1/2.5
5.6/5.4
5
1.7/1.7
2.7/2.7
0.9/1.1
1.7/2.0
20
1.4/1.4
2.4/2.4
3.1/2.5
5.7/5.7
5
1.6/1.6
2.6/2.6
1.1/1.3
2.3/2.3
20
Drive/slew
rate select
Libraries
MSB, LSB
111
6MDDR
111
6MDDR
111
6MDDR
AC specification for CMOS090_ddr library @ VDDE = 2.5 V
Table 50. AC specifications at 2.5 V VDDE
Name
pad_st_acc
pad_st_dq
pad_st_clk
C
C
C
C
Prop. delay (ns)
L>H / H>L
Rise/fall edge (ns)
Drive load
(pF)
Min
Max
Min
Max
1.4/1.5
2.5/2.4
2.1/2.1
4.3/4.1
5
1.7/1.7
2.8/2.7
0.6/0.7
1.1/1.3
20
1.4/1.5
2.5/2.4
2.1/2.1
4.3/4.1
5
1.7/1.7
2.8/2.7
0.6/0.7
1.1/1.3
20
1.4/1.4
2.4/2.4
2.1/2.1
4.4/4.1
5
1.1/1.6
2.7/2.7
0.6/0.7
1.6/1.8
20
Drive/slew
rate select
Libraries
MSB, LSB
011
6MDDR
011
6MDDR
011
6MDDR
PXD20 Microcontroller Data Sheet, Rev. 2
100
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.17.7
AC specification for CMOS090_ddr library @ VDDE = 1.8 V
Table 51. AC electrical specifications at 1.8 V VDD
Name
pad_st_acc
pad_st_dq
pad_st_clk
Prop. delay (ns)
L>H / H>L
C
C
C
C
Rise/fall edge (ns)
Drive load
(pF)
Min
Max
Min
Max
1.4/1.4
2.4/2.4
0.6/1.0
2.7/2.6
5
1.7/1.7
2.8/2.7
0.2/0.4
0.5/0.6
20
1.4/1.5
2.4/2.5
1.1/1.1
3.0/2.7
5
1.7/1.7
2.8/2.8
0.4/0.4
0.7/0.7
20
1.4/1.5
2.4/2.4
1.0/1.1
2.9/2.7
5
1.7/1.7
2.8/2.7
0.3/0.4
0.6/0.7
20
1.4/1.5
2.5/2.5
1.5/1.1
3.1/2.6
5
1.7/1.8
2.8/2.8
0.4/0.4
0.7/0.6
20
1.4/1.4
2.4/2.4
0.6/1.0
2.7/2.6
5
1.7/1.7
2.8/2.7
0.2/0.4
0.5/0.6
20
1.4/1.5
2.4/2.5
1.1/1.1
3.0/2.7
5
1.7/1.7
2.8/2.8
0.4/0.4
0.7/0.7
20
1.4/1.5
2.4/2.4
1.0/1.1
2.9/2.7
5
1.7/1.7
2.8/2.7
0.3/0.4
0.6/0.7
20
1.4/1.5
2.5/2.5
1.5/1.1
3.1/2.6
5
1.7/1.8
2.8/2.8
0.4/0.4
0.7/0.6
20
1.4/1.4
2.4/2.4
0.4/0.6
2.7/2.7
5
1.6/1.6
2.7/2.7
0.7/0.9
1.8/3.4
20
1.4/1.4
2.4/2.4
1.1/1.1
3.0/2.8
5
1.7/1.7
2.7/2.7
0.3/0.4
1.0/1.1
20
1.4/1.4
2.4/2.4
0.9/1.1
3.0/2.8
5
1.6/1.6
2.7/2.7
0.3/0.4
0.9/1.0
20
1.4/1.5
2.5/2.5
1.5/1.2
3.2/2.6
5
1.7/1.8
2.7/2.7
0.4/0.4
1.1/1.2
20
Drive/slew
rate select
Libraries
MSB, LSB
000
6MDDR
001
010
110
000
6MDDR
001
010
110
000
6MDDR
001
010
110
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
101
Electrical characteristics
4.18
AC timing
4.18.1
IEEE 1149.1 interface timing
Table 52. JTAG interface timing1
Num
Symbol
1
tJCYC
2
tJDC
C
CC2
Characteristic
Min
Max
Unit
SpecID
D TCK Cycle Time
100
—
ns
A1.1
2
D TCK Clock Pulse Width (Measured at VDD/2)
40
60
ns
A1.2
2
CC
3
tTCKRISE
CC
D TCK Rise and Fall Times (40% – 70%)
—
3
ns
A1.3
4
tTMSS, tTDIS
CC2
D TMS, TDI Data Setup Time
5
—
ns
A1.4
5
tTMSH, tTDIH
CC2
D TMS, TDI Data Hold Time
25
—
ns
A1.5
tTDOV
CC2
D TCK Low to TDO Data Valid
—
35
ns
A1.6
7
tTDOI
CC2
D TCK Low to TDO Data Invalid
0
—
ns
A1.7
8
tTDOHZ
CC2
D TCK Low to TDO High Impedance
—
30
ns
A1.8
9
tBSDV
CC2
D TCK Falling Edge to Output Valid
—
35
ns
A1.9
10
tBSDVZ
CC2
D TCK Falling Edge to Output Valid out of High
Impedance
—
50
ns
A1.10
11
tBSDHZ
CC2
D TCK Falling Edge to Output High Impedance
—
50
ns
A1.11
12
tBSDST
CC2
D Boundary Scan Input Valid to TCK Rising Edge
50
—
ns
A1.12
13
tBSDHT
CC2
D TCK Rising Edge to Boundary Scan Input Invalid
50
—
ns
A1.13
6
1
These specifications apply to JTAG boundary scan only. JTAG timing specified at VDD = 3.0 V to 3.6 V, TA = –40 to 105 °C,
and CL = 50 pF with SRC = 0b01.
2 Parameter values guaranteed by design.
TCK
2
3
2
1
3
Figure 18. JTAG test clock input timing
PXD20 Microcontroller Data Sheet, Rev. 2
102
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
TCK
4
5
TMS, TDI
6
7
8
TDO
Figure 19. JTAG test access port timing
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
103
Electrical characteristics
TCK
9
11
Output
Signals
10
Output
Signals
12
13
Input
Signals
Figure 20. JTAG boundary scan timing
PXD20 Microcontroller Data Sheet, Rev. 2
104
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.18.2
Nexus debug interface
Table 53. Nexus debug port timing1
Num
1
Symbol
tMCYC
C
Characteristic
Min
Max
Unit
SpecID
CC2
D MCKO Cycle Time
15
—
ns
A2.1
2
2
tMDC
CC
D MCKO Duty Cycle
40
60
%
A2.2
3
tMDOV
CC2
D MCKO Low to MDO Data Valid3
0.1
0.2
tMCYC
A2.3
4
tMSEOV
CC2
D MCKO Low to MSEO Data Valid3
0.1
0.2
tMCYC
A2.4
tEVTOV
2
D MCKO Low to EVTO Data Valid
0.1
0.2
tMCYC
A2.5
2
D EVTI Pulse Width
4
—
tTCYC
A2.6
2
5
6
tEVTIPW
CC
CC
3
7
tEVTOPW
CC
D EVTO Pulse Width
1
—
tMCYC
A2.7
8
tTCYC
CC2
D TCK Cycle Time4
100
—
ns
A2.8
tTDC
CC2
D TCK Duty Cycle
40
60
%
A2.9
10
tNTDIS, tNTMSS
CC2
D TDI, TMS Data Setup Time
25
—
ns
A2.10
11
tNTDIH,
tNTMSH
CC2
D TDI, TMS Data Hold Time
5
—
ns
A2.11
12
tJOV
CC2
D TCK Low to TDO Data Valid
0
35
ns
A2.12
9
1
JTAG specifications in this table apply when used for debug functionality. All Nexus timing relative to MCKO is measured from
50% of MCKO and 50% of the respective signal. Nexus timing specified at VDD = 3.0 V to 3.6 V, TA = –40 to 105 °C, and
CL = 50 pF (Cl = 30 pF on MCKO), with SRC = 0b10 for MCKO and 0b11 for others.
2 Parameter values guaranteed by design.
3 MDO, MSEO, and EVTO data is held valid until next MCKO low cycle.
4 The system clock frequency needs to be three times faster that the TCK frequency.
Nexus Dual Data Rate is not supported. The timings are mentioned for dedicated pins on 416TEPBGA package. The max value
for #2, 3, and 4 above, are 0.3 of tMCYC for shared Nexus ports.
1
2
MCKO
3
4
5
MDO
MSEO
EVTO
Output Data Valid
Figure 21. Nexus output timing
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
105
Electrical characteristics
TCK
9
8
9
Figure 22. Nexus TCK timing
TCK
10
11
TMS, TDI
12
TDO
Figure 23. Nexus TDI, TMS, TDO timing
4.18.3
Interface to TFT LCD panels (DCU3 and DCULite)
Figure 24 depicts the LCD interface timing for a generic active matrix color TFT panel. In this figure
signals are shown with positive polarity. The sequence of events for active matrix interface timing is:
PXD20 Microcontroller Data Sheet, Rev. 2
106
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
•
•
•
•
PCLK latches data into the panel on its positive edge (when positive polarity is selected). In active
mode, PCLK runs continuously. This signal frequency could be from 5 to 66 MHz depending on
the panel type.
HSYNC causes the panel to start a new line. It always encompasses at least one PCLK pulse.
VSYNC causes the panel to start a new frame. It always encompasses at least one HSYNC pulse.
DE acts like an output enable signal to the LCD panel. This output enables the data to be shifted
onto the display. When disabled, the data is invalid and the trace is off.
VSYNC
LINE 1
HSYNC
LINE 2
LINE 3
LINE 4
LINE n-1
LINE n
HSYNC
DE
1
2
3
m-1
m
PCLK
LD[23:0]
Figure 24. TFT LCD interface timing overview1
4.18.3.1
Interface to TFT LCD panels—pixel level timings
Figure 25 depicts the horizontal timing (timing of one line), including both the horizontal sync pulse and
data. All parameters shown in the diagram are programmable. This timing diagram corresponds to positive
polarity of the PCLK signal (meaning the data and sync signals change on the rising edge) and active-high
polarity of the HSYNC, VSYNC and DE signals. The user can select the polarity of the HSYNC and
VSYNC signals via the SYN_POL register, whether active-high or active-low. The default is active-high.
The DE signal is always active-high.
Pixel clock inversion and a flexible programmable pixel clock delay are also supported. They are
programmed via the DCU Clock Confide Register (DCCR) in the system clock module.
The DELTA_X and DELTA_Y parameters are programmed via the DISP_SIZE register. The PW_H,
BP_H and FP_H parameters are programmed via the HSYN PARA register. The PW_V, BP_V and FP_V
parameters are programmed via the VSYN_PARA register.
1. In Figure 24, the “LD[23:0]” signal is “line data,” an aggregation of the DCU’s RGB signals—R[0:7], G[0:7] and B[0:7].
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
107
Electrical characteristics
Table 54. LCD interface timing parameters—horizontal and vertical
Num
C
Characteristic
Value
Unit
SpecID
31.25
ns
A3.1
tPCP
CC1
D
Display pixel clock period
2
tPWH
CC
1
D
HSYNC pulse width
PW_H × tPCP
ns
A3.2
3
tBPH
CC1
D
HSYNC back porch width
BP_H × tPCP
ns
A3.3
4
tFPH
CC
1
D
HSYNC front porch width
5
tSW
CC1
D
Screen width
6
tHSP
CC
1
D
7
tPWV
CC1
8
tBPV
CC
1
—
tFPV
CC1
—
—
1
1
Symbol
FP_H × tPCP
ns
A3.4
DELTA_X × tPCP
ns
A3.5
HSYNC (line) period
(PW_H + BP_H + FP_H + DELTA_X )
× tPCP
ns
A3.6
D
VSYNC pulse width
PWV × tHSP
ns
A3.7
D
VSYNC back porch width
BP_V × tHSP
ns
A3.8
D
VSYNC front porch width
FP_V × tHSP
ns
A3.9
tSH
CC
1
D
Screen height
DELTA_Y × tHSP
ns
A3.10
tVSP
CC1
D
VSYNC (frame) period
(PW_V + BP_V + FP_V + DELTA_Y )
× tHSP
ns
A3.11
Parameter values guaranteed by design.
tHSP
Start of line
tPWH
tFPH
tSW
tBPH
tPCP
PCLK
LD[23:0]
Invalid Data
1
2
3
DELTA_X
Invalid Data
HSYNC
DE
Figure 25. Horizontal sync timing
PXD20 Microcontroller Data Sheet, Rev. 2
108
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
tVSP
tSH
tBPV
tPWV
Start of Frame
tFPV
tHCP
HSYNC
LD[23:0]
(Line Data)
1
Invalid Data
2
DELTA_Y
3
Invalid Data
HSYNC
DE
Figure 26. Vertical sync pulse
4.18.3.2
Interface to TFT LCD panels—access level
Table 55. LCD interface timing parameters1,2,3,4—Access Level
Num
1
2
3
4
5
Symbol
C
Characteristic
Min.
Value
Typical
Value
Max.
Value
Unit
SpecID
1
tCKP
CC5
D PDI Clock Period
31.25
—
—
ns
A3.12
2
tCHD
CC5
D Duty cycle
40
—
60
%
A3.13
3
tDSU
CC5
D interface data setup time
6
—
—
ns
A3.14
4
tDHD
CC5
D PDI interface data access hold time
1
—
—
ns
A3.15
5
tCSU
CC5
D PDI interface control signal setup time
3
—
—
ns
A3.16
6
tCHD
CC5
D PDI interface control signal hold time
1
—
—
ns
A3.17
7
—
CC5
D TFT interface data valid after pixel clock
—
—
6
ns
A3.18
8
—
CC5
D TFT interface HSYNC valid after pixel clock
—
—
5
ns
A3.19
9
—
CC5
D TFT interface VSYNC valid after pixel clock
—
—
5.5
ns
A3.20
10
—
CC5
D TFT interface DE valid after pixel clock
—
—
5.6
ns
A3.21
11
—
CC5
D TFT interface hold time for data and control
bits
2
—
—
ns
A3.22
12
—
CC5
D Relative skew between the data bits
—
—
3.7
ns
A3.23
The characteristics in this table are based on the assumption that data is output at +ve edge and displays latch data on –ve
edge.
Intrabit skew is less than 2 ns.
Load CL = 50 pf for frequency up to 20 MHz.
Load CL = 25 pf for display freq from 20 to 32 MHz.
Parameter values guaranteed by design.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
109
Electrical characteristics
tCHD
tCSU
tDSU
tDHD
HSYNC
VSYNC
DDE
PCLK
tCKH
tCKL
LD[23:0]
Figure 27. LCD Interface timing parameters—access level
4.18.4
RSDS interface to TFT LCD panels
Table 56. RSDS electrical characteristics
Symbol
C
Value2
Conditions1
Parameter
Unit SpecID
Min
Typ
Max
AVDD SR P Voltage on VSSE_A pin with respect
to ground (VSS)
—
3.0
3.3
3.6
V
A4.1
IDDTX SR P Current Consumption: RSDS Transmitter — Single Cell
—
—
2.7
—
mA
A4.2
IDDPD SR P Power Down Current
—
—
10
—
µA
A4.3
IDDBG SR P Current Consumption of Bandgap
and buffer
—
—
100
—
µA
A4.4
Fmax SR P Data Frequency
—
—
60
85
MHz
A4.5
VOD SR P Differential Output Voltage
RL = 100 Ohms
—
200
400
mV
A4.6
VOFF SR P Offset Voltage
VCM ±5%
0.5
1.2
1.5
V
A4.7
tR / tF SR P Output Rise / Fall times
20% to 80%, VOD=200mV, CL = 5pF
—
500
—
ps
A4.8
—
—
3
—
ns
A4.9
tXdelay SR P Tx Delay
1
2
SR P Termination Resistance (external)
5% variation
—
100
—
Ohms A4.10
SR P Transmitter Settling time
After power down, high to low
—
10
—
µs
A4.11
SR D Transmitter Delay
Data in to Tx out
—
8
—
ns
A4.12
VDDA = 3.3 V ± 10% TA = –40 to 105 °C, unless otherwise specified.
All values need to be confirmed during device validation.
PXD20 Microcontroller Data Sheet, Rev. 2
110
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Figure 28. TCON/RSDS timing diagram
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
111
Electrical characteristics
4.18.5
DRAM interface
DDR Interface specification from ‘MCD — 32 Bit Automotive MCU — CMOS090LP2’ I/O Pad
Specification Revision 1.5 — May14th 2008.
This device supports SDR, DDR1, DDR2 half and full strengths, as well as LPDDR half and full speeds.
Table 57 shows the SRE settings for the different modes.
Table 57. Pad mode configurations
ipp_sre[2:0]
Mode
000
1.8V LPDDR Half Speed
001
1.8V LPDDR Full Speed
010
1.8V DDR2 Half Strength
011
2.5V DDR1
100
Not supported
101
Not supported
110
1.8V DDR2 Full Strength
111
SDR
NOTE:
The specifications given in Table 58 are preliminary.
Table 58. LPDDR, DDR, and DDR2 (DDR2-250) SDRAM timing specifications1 2 3
No.
Symbol
1
F
1.1
tCK
2
VIX-AC
3
tCH
4
5
tCL
tDQSS
Parameter
Min
Max
Unit
CC Frequency of Operation (Clock Period)
N/A
125
MHz
CC Clock period
N/A
8
ns
CC MCK AC differential crosspoint voltage4
VDDE_DR × 0.5 – 0.1 VDDE_DR × 0.5 + 0.1
CC CK HIGH pulse width 4, 5
CC CK LOW pulse
width 4, 5
CC Skew between MCK and DQS
transitions5, 6
V
0.47
0.53
TCK
0.47
0.53
tCK
150
150
ps
6
tOS(base) CC Address and control output setup time relative to MCK
rising edge5, 6
(tCK/2) – 1000
N/A
ps
7
tOH(base) CC Address and control output hold time relative to MCK
rising edge5, 6
(tCK/2) + 1000
N/A
ps
8
tDS1(base) CC DQ and DM output setup time relative to DQS5, 6
(tCK/4) – 750
N/A
ps
9
tDH1(base) CC DQ and DM output hold time relative to DQS5, 6
(tCK/4) + 750
N/A
ps
–(tCK/4) – 600
(tCK/4) – 600
ps
TBD
TBD
ps
5
10
tDQSQ
CC DQS-DQ skew for DQS and associated DQ inputs
11
tDQSEN
CC DQS window start position related to CAS read
command4, 5, 6, 7, 8
1
At recommended operating conditions with VDDE_DR of ±5%.
VDDE_DR value is 1.8 for DDR2 mode, 2.5 V for DDR1 mode, and 1.8 V for LPDDR mode.
3 C at –40, 140, 25 oC.
Z
2
PXD20 Microcontroller Data Sheet, Rev. 2
112
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4
Measured with clock pin loaded with differential 100 ohm termination resistor.
All transitions measured at mid-supply (VDDE_DR/2).
6
Measured with all outputs except the clock loaded with 50 ohm termination resistor to VDDE_DR/2.
7
In this window, the first rising edge of DQS should occur. From the start of the window to DQS rising edge, DQS should be low.
8 Window position is given for t
DQSEN = 2.0 tCK. For other values of tDQSEN, window position is shifted accordingly.
5
4.18.5.1
2.5V DDR1
Table 59. SSTL_2 Class II 2.5V DDR DC specifications
Symbol C
Parameter
Condition
Min
Nom
Max
Units
Notes
SpecID
Vddet
P
I/O Supply Voltage
—
2.30
2.50
2.70
V
JESD8-9B
A5.1
Vdd
P
Core Supply Voltage
—
1.08
1.20
1.32
V
—
A5.2
Vref(dc)
P
Input Reference
Voltage
—
1.13
1.25
1.38
V
JESD8-9B
A5.3
Vtt
P
Termination Voltage
—
Vref – 0.04
vref
Vref + 0.04
V
JESD8-9B
A5.4
Vih(dc)
C
DC Input Logic High
—
Vref + 0.15
—
vddet + 0.3
V
JESD8-9B
A5.5
Vil(dc)
C
DC Input Logic Low
—
–0.3
—
Vref – 0.15
V
JESD8-9B
A5.6
Vih(ac)
C
AC Input Logic High
—
Vref + 0.31
—
—
V
JESD8-9B
A5.7
Vil(ac)
C
AC Input Logic Low
—
—
—
Vref – 0.31
V
JESD8-9B
A5.8
Iin
P
Pad input Leakage
Current
—
—
—
±10
µA
—
A5.9
Voh
C
Output High Voltage
Level
—
vddet – 0.35
—
—
V
—
A5.10
Vol
C
Output Low Voltage
Level
—
—
—
0.35
V
—
A5.11
Ioh(dc)
C Output min source dc Vout = Voh
current
–16.2
—
—
mA
vddet = 2.3 V
Voh = 1.95 V
A5.12
Iol(dc)
C
16.2
—
—
mA
vddet = 2.3 V
Vol = 0.35 V
A5.13
Output min sink dc
current
Vout = Vol
The SSTL_2 differential input switch point is at Vref = 0.50 × Vddet.
Note that the JEDEC SSTL_2 specifications (JESD8-9B) for an SSTL interface for class II operation supersedes any
specification in this document.
The SSTL_2 Class II output with ipp_sre[2:0] set to enabling SSTL_2 2.5V DDR1 mode, at the destination, have a rise/fall time
(10–90%) between 1 ns and 2 ns over process, voltage, and temperature driving a 70 ohm transmission line with 0.167 ns td
terminated at the destination with 70 ohms to Vtt (0.5 × vddet) with 4.0 pf, representing the DDR input capacitance.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
113
Electrical characteristics
Vtt
70 ohms
Z0=70 td= 0.167ns
ipp_do
pad_st/pad_st_odt
4pF
PAD
Figure 29. SSTL_2 Class II test load
4.18.5.2
1.8V DDR2
Table 60. SSTL_18 Class II 1.8V DDR2 DC specifications
Symbol C
Parameter
Condition
Min
Nom
Max
Units
Notes
SpecID
Vddet
P
I/O Supply Voltage
—
1.7
1.8
1.9
V
JESD8-15A
A5.14
Vdd
P
Core Supply Voltage
—
1.08
1.2
1.32
V
—
A5.15
Input Reference
Voltage
—
0.833
0.9
1.0869
V
JESD8-15A
A5.16
Vref(dc) P
Vtt
P
Termination Voltage
—
Vref – 0.04
Vref
Vref + 0.04
V
JESD8-15A
A5.17
Vih(dc)
C
DC Input Logic High
—
Vref + 0.125
—
vddet + 0.3
V
JESD8-15A
A5.18
Vil(dc)
C
DC Input Logic Low
—
–0.3
—
Vref – 0.125
V
JESD8-15A
A5.19
Vih(ac)
C
AC Input Logic High
—
Vref + 0.25
—
—
V
JESD8-15A
A5.20
Vil(ac)
C
AC Input Logic Low
—
—
—
Vref – 0.25
V
JESD8-15A
A5.21
Iin
P
Pad input Leakage
Current
—
—
—
±10
µA
—
A5.22
Voh
C
Output High Voltage
Level
—
vddet – 0.28
—
—
V
—
A5.23
Vol
C
Output Low Voltage
Level
—
—
—
0.28
V
—
A5.24
Ioh(dc)
C Output min source dc Vout = Voh
current
–13.4
—
—
mA
JESD8-15A
vddet = 1.7 V
Voh = 1.42 V
A5.25
Iol(dc)
C
13.4
—
—
mA
JESD8-15A
vddet = 1.7 V
Vol = 0.28 V
A5.26
Output min sink dc
current
Vout = Vol
The SSTL_18 differential input switch point is at Vref = 0.50 × Vddet.
Note that the Jedec SSTL_18 specifications (JESD8-15a) for an SSTL interface for class II operation supersedes any
specification in this document.
The SSTL_18 Class II output with ipp_sre[2:0] set to enabling sstl_2 1.8V DDR2 mode, at the destination, have a rise/fall time
(10–90%) between 0.4 ns and 1.0 ns over process, voltage, and temperature driving a 70 ohm transmission line with 0.167 ns
PXD20 Microcontroller Data Sheet, Rev. 2
114
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
td terminated at the destination with 70 ohms to Vtt (0.5 × Vddet) with 4.0 pf, representing the DDR2 input capacitance. See
Figure 30 (SSTL_18 Class II test load).
Vtt
70
Z0=70 td= 0.167ns
ipp_do
pad_st/pad_st_odt
4pF
PAD
Figure 30. SSTL_18 Class II test load
4.18.5.3
1.8V LPDDR
Table 61. 1.8V LPDDR DC specifications
Symbol C
vddet
vdd
Parameter
Condition
Min
Nom
Max
Units
Notes
SpecID
P I/O Supply Voltage
—
1.7
1.8
1.9
V
JESD79-4
A5.27
P Core Supply Voltage
—
1.08
1.2
1.32
V
—
A5.28
Data Inputs (DQ, DM, DQS)
A5.29
Vih(dc)
C DC Input Logic High
—
vddet × 0.7
—
vddet+0.3
V
JESD79-4
A5.30
Vil(dc)
C DC Input Logic Low
—
–0.3
—
vddet × 0.3
V
JESD79-4
A5.31
Vih(ac)
C AC Input Logic High
—
vddet × 0.8
—
vddet + 0.3
V
JESD79-4
A5.32
Vil(ac)
C AC Input Logic low
—
–0.3
—
vddet × 0.2
V
JESD79-4
A5.33
Data Outputs (DQ, DQS)
A5.34
Voh
C Output High Voltage
Level
Ioh = –0.1mA
vddet × 0.9
—
—
V
JESD79-4
A5.35
Vol
C Output Low Voltage
Level
Iol = 0.1mA
—
—
vddet × 0.1
V
JESD79-4
A5.36
Note that the final JEDEC LPDDR SDRAM specifications (JESD79-4) for LPDDR operation supersedes any specification in
this document.
The SSTL_18 output with ipp_sre[2:0] set to enabling 1.8V LPDDR mode, at the destination, have a rise/fall time (10–90%)
between 0.4 ns and 1.0 ns over process, voltage, and temperature driving a 70 ohm transmission line with 0.167 ns td terminated
at the destination with 70 ohms to Vtt (0.5 × vddet) with 4.0 pf, representing the DDR input capacitance. See Figure 30
(SSTL_18 Class II test load).
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
115
Electrical characteristics
4.18.6
Video Input Unit timing
Clock
fPIX_CLK
tDHD
tDSU
Data
Figure 31. VIU2 timing diagram
Table 62. VIU2 timing parameters
Parameter C
Min
Typ
Max
Unit
SpecID
D VIU2 pixel clock frequency
—
—
64
MHz
A6.1
tDSU
D VIU2 data setup time
4
—
—
ns
A6.2
tDHD
D VIU2 data hold time
1
—
—
ns
A6.3
fPIX_CK
4.18.7
Description
External Interrupt (IRQ) and Non-Maskable Interrupt (NMI) Timing
Table 63. IRQ and NMI timing
Num
2
C
Characteristic
Min.
Value
Max.
Value
Unit
SpecID
tIPWL
CC1 D IRQ/NMI Pulse Width Low
200
—
ns
A7.1
2
tIPWH
CC1
200
—
ns
A7.2
3
tICYC
CC1 D IRQ/NMI Edge to Edge Time2
400
—
ns
A7.3
1
1
Symbol
D IRQ/NMI Pulse Width High
Parameter values guaranteed by design.
Applies when IRQ/NMI pins are configured for rising edge or falling edge events, but not both.
1,2
1,2
3
Figure 32. IRQ and NMI timing
PXD20 Microcontroller Data Sheet, Rev. 2
116
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.18.8
eMIOS timing
Table 64. eMIOS timing1
Num
Symbol
C
Characteristic
Min.
value2
Max.
value
Unit
SpecID
1
tMIPW
CC3 D eMIOS Input Pulse Width
4
—
tCYC
A8.1
2
tMOPW
CC3 D eMIOS Output Pulse Width
1
—
tCYC
A8.2
1
eMIOS timing specified at fSYS = 64 MHz, VDD12 = 1.14 V to 1.32 V, VDDE_x = 3.0 V to 5.5 V, TA = –40 to 105 °C, and
CL = 50 pF with SRC = 0b00.
2
There is no limitation on the peripheral for setting the minimum pulse width, the actual width is restricted by the pad delays.
Refer to the pad specification section for the details.
3 Parameter values guaranteed by design.
4.18.9
FlexCAN timing
The CAN functions are available as TX pins at normal I/O pads and as RX pins at the always on domain.
There is no filter for the wakeup dominant pulse. Any high-to-low edge can cause wakeup if configured.
Table 65. FlexCAN timing1
Num
Symbol
C
Characteristic
Min. value
Max.
value
Unit
SpecID
1
tCANOV
CC2 D CTNX Output Valid after CLKOUT Rising Edge (Output
Delay)
—
22.48
ns
A10.1
2
tCANSU
CC2 D CNRX Input Valid to CLKOUT Rising Edge (Setup
Time)
—
12.46
ns
A10.2
1
FlexCAN timing specified at fSYS = 64 MHz, VDD12 = 1.14 V to 1.32 V, VDDE_x = 3.0 V to 5.5 V, TA = –40 to 105 °C, and CL
= 50 pF with SRC = 0b00.
2
Parameter values guaranteed by design.
4.18.10 Deserial Serial Peripheral Interface (DSPI)
Table 66. DSPI timing1
Num
Symbol
C
Characteristic
Min
Max
Unit
SpecID
tSCK
CC2
D SCK Cycle TIme3,4
605
—
ns
A11.1
tCSC
CC2
Delay6
—
—
ns
A11.2
3
tASC
CC2
D After SCK
20
—
ns
A11.3
4
tSDC
CC2
D SCK Duty Cycle
tSCK/2 – 2ns
tSCK/2 + 2ns
ns
A11.4
5
tA
CC2
D Slave Access Time
(PCSx active to SOUT driven)
—
25
ns
A11.5
6
tDIS
CC2
D Slave SOUT Disable Time
(PCSx inactive to SOUT High-Z or invalid)
—
25
ns
A11.6
1
2
D PCS to SCK
Delay7
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
117
Electrical characteristics
Table 66. DSPI timing1 (continued)
Num
7
8
9
10
1
2
3
4
5
6
7
8
Symbol
tSUI
tHI
tSUO
tHO
CC2
CC2
CC2
CC2
C
Characteristic
Min
Max
Unit
D Data Setup Time for Inputs
Master (MTFE = 0)
Slave
Master (MTFE = 1, CPHA = 0)8
Master (MTFE = 1, CPHA = 1)
20
10
5
35
—
—
—
—
ns
ns
ns
ns
D Data Hold Time for Inputs
Master (MTFE = 0)
Slave
Master (MTFE = 1, CPHA = 0)8
Master (MTFE = 1, CPHA = 1)
–4
10
26
–4
—
—
—
—
ns
ns
ns
ns
D Data Valid (after SCK edge)
Master (MTFE = 0)
Slave
Master (MTFE = 1, CPHA=0)
Master (MTFE = 1, CPHA=1)
—
—
—
—
15
20
30
15
ns
ns
ns
ns
D Data Hold Time for Outputs
Master (MTFE = 0)
Slave
Master (MTFE = 1, CPHA = 0)
Master (MTFE = 1, CPHA = 1)
–15
5.5
0
–15
—
—
—
—
ns
ns
ns
ns
SpecID
A11.7
A11.8
A11.9
A11.10
DSPI timing specified at VDDE_x = 3.0 V to 3.6 V, TA = –40 to 105 °C, and CL = 50 pF with SRC = 0b10.
Parameter values guaranteed by design.
The minimum SCK Cycle Time restricts the baud rate selection for given system clock rate.
The actual minimum SCK Cycle Time is limited by pad performance.
Maximum clock possible is System clock/2.
The maximum value is programmable in DSPI_CTARx[PSSCK] and DSPI_CTARx[CSSCK], program PSSCK=2 & CSSCK = 2
The maximum value is programmable in DSPI_CTARx[PASC] and DSPI_CTARx[ASC]
This delay value is corresponding to SMPL_PT=00b which is bit field 9 and 8 of DSPI_MCR register.
PXD20 Microcontroller Data Sheet, Rev. 2
118
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
2
3
PCSx
1
4
SCK Output
(CPOL=0)
4
SCK Output
(CPOL=1)
7
SIN
8
First Data
Last Data
Data
10
SOUT
First Data
9
Data
Last Data
Figure 33. DSPI classic SPI timing — Master, CPHA = 0
PCSx
SCK Output
(CPOL=0)
8
SCK Output
(CPOL=1)
7
SIN
Data
First Data
10
SOUT
First Data
Last Data
9
Data
Last Data
Figure 34. DSPI classic SPI timing — Master, CPHA = 1
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
119
Electrical characteristics
3
2
PCSx
1
4
SCK Input
(CPOL=0)
4
SCK Input
(CPOL=1)
5
First Data
SOUT
7
6
Data
Last Data
Data
Last Data
8
First Data
SIN
9
10
Figure 35. DSPI classic SPI timing — Slave, CPHA = 0
PCSx
SCK Input
(CPOL=0)
SCK Input
(CPOL=1)
9
5
10
SOUT
First Data
7
SIN
Data
Last Data
Data
Last Data
6
8
First Data
Figure 36. DSPI classic SPI timing — Slave, CPHA = 1
PXD20 Microcontroller Data Sheet, Rev. 2
120
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
3
PCSx
4
1
2
SCK Output
(CPOL=0)
4
SCK Output
(CPOL=1)
7
SIN
8
First Data
Last Data
Data
10
SOUT
9
First Data
Data
Last Data
Figure 37. DSPI modified transfer format timing — Master, CPHA = 0
PCSx
SCK Output
(CPOL=0)
SCK Output
(CPOL=1)
8
7
SIN
First Data
Data
10
SOUT
First Data
Data
Last Data
9
Last Data
Figure 38. DSPI modified transfer format timing — Master, CPHA = 1
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
121
Electrical characteristics
3
2
PCSx
1
SCK Input
(CPOL=0)
4
4
SCK Input
(CPOL=1)
10
9
5
First Data
SOUT
Data
Last Data
8
7
Data
First Data
SIN
6
Last Data
Figure 39. DSPI modified transfer format timing — Slave, CPHA = 0
PCSx
SCK Input
(CPOL=0)
SCK Input
(CPOL=1)
9
5
10
First Data
SOUT
7
SIN
Data
Last Data
Data
Last Data
6
8
First Data
Figure 40. DSPI modified transfer format timing — Slave, CPHA = 1
PXD20 Microcontroller Data Sheet, Rev. 2
122
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
4.18.11 I2C timing
Table 67. I2C input timing specifications—SCL and SDA
Num
Characteristic
Min. Value
Max. Value
Unit
SpecID
2
—
IP-Bus Cycle2
A12.1
2
CC1
2
—
1
CC
D Clock low time
8
—
IP-Bus Cycle
A12.2
4
—
CC1
D Data hold time
0.0
—
ns
A12.3
6
—
CC1
D Clock high time
4
—
IP-Bus Cycle2
A12.4
—
CC1
D Data setup time
0.0
—
ns
A12.5
8
—
1
CC
D Start condition setup time (for repeated
start condition only)
2
9
—
CC1
D Stop condition setup time
2
7
1
C
—
1
2
Symbol
D Start condition hold time
—
2
IP-Bus Cycle
A12.6
—
IP-Bus Cycle2
A12.7
Parameter values guaranteed by design.
Inter Peripheral Clock is the clock at which the I2C peripheral is working in the device
Table 68. I2C Output timing specifications—SCL and SDA
Num
11
21
—
CC2
C
Characteristic
D Start condition hold time
Min. Value
Max. Value
Unit
SpecID
6
—
IP-Bus Cycle3
A12.8
Cycle2
A12.9
—
CC2
D Clock low time
10
—
4
3
—
CC2
D SCL/SDA rise time
—
99.6
ns
A12.10
41
—
CC2
D Data hold time
7
—
IP-Bus Cycle2
A12.11
—
CC2
D SCL/SDA fall time
—
99.5
ns
A12.12
51
1
IP-Bus
—
CC2
1
7
—
CC2
D Data setup time
2
—
IP-Bus
81
—
CC2
D Start condition setup time (for repeated
start condition only)
20
—
IP-Bus Cycle2
A12.15
91
—
CC2
D Stop condition setup time
10
—
IP-Bus Cycle2
A12.16
6
1
Symbol
D Clock high time
10
—
IP-Bus
Cycle2
A12.13
Cycle2
A12.14
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
Parameter values guaranteed by design.
3 Inter Peripheral Clock is the clock at which the I2C peripheral is working in the device
4 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.
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
123
Electrical characteristics
6
2
5
SCL
4
1
3
8
7
9
SDA
Figure 41. I2C input/output timing
4.18.12 QuadSPI timing
The following notes apply to Table 69 and Table 70:
•
•
•
•
•
•
•
•
All data is based on a negative edge data launch from PXD20 and a positive edge data capture, as shown in the timing
diagrams in this section.
The supply conditions, over a temperature range of –45 C to 125 C/150 C, are as follows:
— I/O voltage: 3.0 V, Core supply: 1.2 V
— I/O voltage: 3.3 V, Core supply: 1.2 V
— I/O voltage: 3.6 V, Core supply: 1.2 V
The actual frequency at which the device can work will be a combination of this data and the clock pad profile.
All measurements are considering 70% of VDDE levels for clock pin and 50% of VDDE level for data pins.
Timings assume a setting of 0x0000_000x for QSPI_SMPR register (see the reference manual for details).
A negative value of hold is an indication of pad delay on the clock pad (delay b/w actual edge capturing data in the
device vs. edge appearing at the pin).
Measurements are with a load of 50 pF on output pins
The clock profile is measured at 30% to 70% levels of VDDE.
Table 69. QuadSPI timing specifications, maximum temperature 125 C
Value
Symbol
C
Parameter
Min
Typ
Max
Unit
SpecID
Tcq
CC T Clock to Q delay
3.8
5.3
12.1
ns
A13.1
Ts
CC T Setup time for incoming data
7.6
9
13.2
ns
A13.2
Th
CC T Hold time requirement for incoming data
–13
–8.5
–7.5
ns
A13.3
tr
CC T Clock pad rise time
0.5
0.7
1.0
ns
A13.4
tf
CC T Clock pad fall time
0.8
0.8
1.2
ns
A13.5
The numbers in Figure 42 and Figure 43 correspond to events as described in Table 70.
PXD20 Microcontroller Data Sheet, Rev. 2
124
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Table 70. QuadSPI timing events
Number
Event
1
Last address out
2
Address captured at flash memory
3
Data out from flash memory
4
Ideal data capture edge
5
Delayed data capture edge with QSPI_SMPR=0x0000_000X
6
Delayed data capture edge with QSPI_SMPR=0x0000_002X
7
Delayed data capture edge with QSPI_SMPR=0x0000_004X
8
Delayed data capture edge with QSPI_SMPR=0x0000_006X
1
tCQ
SCK
DO
1. Last address out
Figure 42. QuadSPI output timing
1
tCQ
2
3
4
5
6
7
8
SCK
tS
DO
tH
DI
1.
2.
3.
4.
5.
6.
7.
8.
Last address out
Address captured at flash
Data out from flash
Ideal data capture edge
Delayed data capture edge with QSPI_SMPR=0x0000_000x
Delayed data capture edge with QSPI_SMPR=0x0000_002x
Delayed data capture edge with QSPI_SMPR=0x0000_004x
Delayed data capture edge with QSPI_SMPR=0x0000_006x
Figure 43. QuadSPI input timing
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
125
Electrical characteristics
tR
tF
70%
VDDE
30%
SCK
Figure 44. QuadSPI clock profile
4.18.13 TCON/RSDS timing
The following notes apply to Table 71:
•
•
•
Measurement condition: Vdde/Vdd33 = 3.3 V ± 10%, Vdd = 1.2 V ± 10%, Vss/Vsse = 0 V, T = –40 to 105°C
Termination: 100  ± 5%
VREFH_RSDS terminations of 47 F
Table 71. TCON/RSDS timing
Value
Symbol
C
Parameter
Condition
Unit SpecID
Min
Typ
Max
391
—
471
mV
A14.1
VOD
CC
C Differential output voltage RSDS mode
VOS
CC
C Common mode voltage
100  termination between
Pad_p and Pad_n
1.17
—
1.4
V
A14.2
tr
CC
C Rise time
Transition from 20% to 80%
606
—
844
ps
A14.3
tf
CC
C Fall time
Transition from 20% to 80%
607
—
842
ps
A14.4
tplh
CC
D Propagation delay, low to
high
—
—
2.65
—
ns
A14.5
tphl
CC
D Propagation delay, high to
low
—
—
2.47
—
ns
A14.6
tdz
CC
D Start-up time
—
—
200
—
s
A14.7
CC
C Skew between different
RSDS lines
—
—
—
ps
A14.8
123
tskew
Max and min skew between
clock and data pads
1
There are eight programmable bits to provide 256 different skew numbers with various combinations of these bits.
Default value of all the eight skew options are all “1”.
3 All “0” combination of eight bits is not valid.
2
PXD20 Microcontroller Data Sheet, Rev. 2
126
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Electrical characteristics
Figure 45. Rise/fall transition, part 1
Figure 46. Rise/fall transition, part 2
TR
TF
80%
+VOD
pad_p - pad_n
0V Differential
20%
–VOD
Figure 47. Illustration of tr, tf, and VOD
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
127
Package mechanical data
5
Package mechanical data
6
Ordering information
M PX D 20 20 V LT 125 R
Qualification status
Brand
Family
Class
Flash memory size
Temperature range
Package identifier
Operating frequency
Tape and reel indicator
Qualification status
P = Pre-qualification (engineering samples)
M = Fully spec. qualified, general market flow
S = Fully spec. qualified, automotive flow
Temperature range
V = –40 °C to 105 °C
(ambient)
Package identifier
LU = 176 LQFP
LT = 208 LQFP
VU = 416 PBGA
Family
D = Display Graphics
N = Connectivity/Network
R = Performance/Real Time Control
S = Safety
Operating frequency
80 = 80 MHz
120 = 120 MHz
Flash Memory Size
05 = 512 KB
10 = 1 MB
Tape and reel status
R = Tape and reel
(blank) = Trays
Note: Not all options are available on all devices. See Table 72 for more information.
Figure 48. PXD20 orderable part number description
Table 72. PXD20 orderable part number summary
Part number
Flash/SRAM
Package
Speed
(MHz)
MPXD2020VLU125
2 MB / 64 KB
176 LQFP (24 mm x 24 mm)
125
MPXD2020VVU125
2 MB / 64 KB
416 PBGA (27 mm x 27 mm)
125
MPXD2020VLT125
2 MB / 64 KB
208 LQFP (28 mm x 28 mm)
125
PXD20 Microcontroller Data Sheet, Rev. 2
128
Preliminary—Subject to Change Without Notice
Freescale Semiconductor
Revision history
7
Revision history
Table 73. Revision history
Revision
Date
Description
1
30 Sep 2011
Initial release.
2
27 Apr 2012
Editorial updates and improvements throughout the document.
In Figure 4 (416 TEPBGA pinout), corrected pin P25 to VSS.
In Section 3, System design information, added Figure 6 (Power-up sequencing) and
Figure 7 (Power-down sequencing).
In Table 10 (Recommended operating conditions (3.3 V)), changed maximum Tj from
150 oC to 140 oC.
In Table 11 (Recommended operating conditions (5.0 V)), changed maximum Tj from
150 oC to 140 oC.
In Table 16 (Voltage regulator electrical characteristics):
— Changed maximum Tj from 150 oC to 140 oC.
— Changed VDD12 post-trimming minimum value from 1.270 V to 1.26 V and
maximum value from 1.280 V to 1.29 V.
— Removed footnote: “All values in this table are PRELIMINARY.”
In Section 4.7.1, Voltage regulator electrical characteristics. added Table 17
(Low-power voltage regulator electrical characteristics) and Table 18 (Ultra
low-power voltage regulator electrical characteristics).
In Table 19 (Low voltage monitor electrical characteristics), updated the following
values:
— VLVDHV3H maximum from 2.8 V to 2.9 V
— VLVDHV3L minimum from 2.7 V to 2.5 V
— VLVDHV5H maximum from 4.37 V to 4.4 V
— VLVDHV5L minimum from 4.2 V to 3.9 V
In Table 20 (DC electrical characteristics):
— Updated IDDRUN typical values for Dual Display Drive from 235 to 275 mA; for
Single Display Drive from 306 to 240 mA.
— Updated typical IDDHALT current at 25 oC from 12.67 mA to 17.5 mA.
— Updated typical IDDHALT current at 105 oC from 33.1 mA to 35 mA.
— Updated maximum IDDHALT current at 25 oC from 18.26 mA to 21.5 mA.
— Updated maximum IDDHALT current at 105 oC from 36.41 mA to 43.5 mA.
— In IDDHALT specification, changed TB = 105 oC to TA = 105 oC.
In Table 40 (Fast internal oscillator electrical characteristics), removed RCMTRIM
specification.
In Table 41 (Slow internal RC oscillator electrical characteristics), removed
RCMTRIM specification.
In Table 44 (ADC electrical characteristics), added offset error value of 0.5 typical, and
gain error value of 0.6 typical. Removed minimum and maximum values for both
specifications.
In Section 4.18.5, DRAM interface:
— Added Table 58 (LPDDR, DDR, and DDR2 (DDR2-250) SDRAM timing
specifications).
— Removed Table 56 (AC Specs for SDR mode (VDDE_DR = 3.3 V)), Table 57 (AC
Specs for DDR2 mode (VDDE_DR = 1.8 V)), Table 58 (AC Specs for DDR1 mode
(VDDE_DR = 2.5 V)), and Table 59 (AC Specs for LPMDDR mode (VDDE_DR = 1.8
V)).
PXD20 Microcontroller Data Sheet, Rev. 2
Freescale Semiconductor
Preliminary—Subject to Change Without Notice
129
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Document Number: PXD20
Rev. 2
04/2012
Preliminary—Subject to Change Without Notice
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