MPC5748GEVBUG, MPC5748G EVB User Guide

Freescale Semiconductor, Inc.
User Guide
Document Number: MPC5748GEVBUG
MPC5748G EVB User Guide
By: Alasdair Robertson
© 2015 Freescale Semiconductor, Inc. All rights reserved.
Rev. 0, 08/2015
Contents
1.
INTRODUCTION ................................................................................................................................................................................. 3
1.1.
Peripheral Daughtercards............................................................................................................................................................. 3
2.
EVB FEATURES .................................................................................................................................................................................. 3
3.
CONFIGURATION OVERVIEW ......................................................................................................................................................... 5
4.
MCU DAUGHTERCARD INFORMATION ........................................................................................................................................ 6
4.1.
4.2.
5.
Fitting a daughtercard .................................................................................................................................................................. 6
Removing a daughtercard ............................................................................................................................................................ 6
INITIAL CONFIGURATION ............................................................................................................................................................... 7
5.1.
Power Supply Configuration ....................................................................................................................................................... 7
5.1.1.
Power Supply Connectors (P21, P23) .................................................................................................................................... 7
5.1.2.
Power Switch (SW5) .............................................................................................................................................................. 8
5.1.3.
Regulator Power Jumper (J23) ............................................................................................................................................... 8
5.1.4.
Power Status LED’s and Fuse ................................................................................................................................................ 8
5.1.5.
MCU Power Supply Jumpers (J18, J19, J20, J21, J22, J23) .................................................................................................. 9
5.1.6.
Daughtercard Power Jumpers (J3 to J11) ............................................................................................................................. 10
5.1.7.
Peripheral Power Supply Jumpers (J24, J25) ....................................................................................................................... 11
5.1.8.
EVB Voltage Regulators ...................................................................................................................................................... 11
5.2.
Reset Control (J9, SW1) ............................................................................................................................................................ 13
Note that removing jumper J9 will mean that an external reset source will not reset the MCU. This will impact most debuggers
which will typically issue a reset before establishing a debug connection. .......................................................................................... 13
5.2.1.
Reset LEDs........................................................................................................................................................................... 13
5.3.
MCU Clock Configuration ........................................................................................................................................................ 14
5.3.1.
External Clock Input (P7) ..................................................................................................................................................... 15
5.3.2.
MCU Clock Configuration (J1, J2 on Daughtercard) ........................................................................................................... 15
5.4.
Debug Connectors (P8, P10) ..................................................................................................................................................... 16
5.4.1.
Debug Connector Pinouts ..................................................................................................................................................... 16
6.
COMMUNICATIONS & MEMORY INTERFACES: ........................................................................................................................ 17
6.1.
6.2.
6.3.
6.4.
6.5.
6.6.
6.7.
7.
AV INTERFACE CONNECTORS...................................................................................................................................................... 23
7.1.
7.2.
7.3.
8.
CAN Interfaces (P14, P15, J14, J15) ......................................................................................................................................... 17
LIN Interfaces (P9, P11, J10, J12) ............................................................................................................................................. 18
USB RS232 Serial Interface (P17, J16) ..................................................................................................................................... 19
USB HOST / OTG Interfaces .................................................................................................................................................... 20
Ethernet (P6, J5, J6, J7, J8, R45, R80)....................................................................................................................................... 20
FlexRay (P2, P3, J1, J2, J3, J4).................................................................................................................................................. 22
SD Card Socket (P200).............................................................................................................................................................. 23
SAI Audio Connectors (P24, P25) ............................................................................................................................................. 23
TWRPI Connectors (P26, P27) .................................................................................................................................................. 25
MLB Daughtercard Connector (P16)......................................................................................................................................... 25
USER INTERFACE (I/O) .................................................................................................................................................................... 26
8.1.
8.2.
8.3.
8.4.
8.5.
GPIO Matrix .............................................................................................................................................................................. 26
User Switches (SW3, SW4, SW6, SW7, P22) ........................................................................................................................... 27
Hex Encoder Switch (SW2, J26, P20) ....................................................................................................................................... 28
User LED’s (DS2, DS3, DS7, DS8, P19) .................................................................................................................................. 29
ADC Input Potentiometer (J17, RV1) ....................................................................................................................................... 29
9.
MCU PORT PIN EVB FUNCTIONS .................................................................................................................................................. 30
10.
DEFAULT JUMPER SUMMARY TABLE ........................................................................................................................................ 31
11.
DEFAULT JUMPER DIAGRAM ....................................................................................................................................................... 33
12.
REVISION HISTORY ......................................................................................................................................................................... 33
13.
APPENDIX .......................................................................................................................................................................................... 34
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1. Introduction
This user guide details the setup and configuration of the Freescale MPC5748G customer Evaluation
Board (hereafter referred to as the EVB). The EVB is intended to provide a mechanism for easy
evaluation of the MPC5748G family of microcontrollers, and to facilitate hardware and software
development. Various daughtercards are available which connect to the EVB via two high density
connectors. Please consult your Freescale representative for more details on daughtercard pricing and
availability.
The EVB is intended for bench / laboratory use and has been designed using normal temperature
specified components (+70°C).
This product contains components that may be damaged by electrostatic discharge. Observe precautions
for handling electrostatic sensitive devices when using this EVB and associated microcontroller.
The user manual is intended to be read alongside the respective MCU documentation available at
www.freescale.com and includes:

Reference Manuals

Product Data Sheets

Application notes

Chip Errata
1.1. Peripheral Daughtercards
The EVB has connectors for various peripheral daughtercards (for example MLB) that provide
additional peripheral functionality. These are not supplied with the EVB and must be sourced separately.
Please contact your Freescale representative for pricing and availability.
2. EVB Features
The EVB provides the following key features:










Single 10-14 V DC external power supply input with on-board regulators to provide all of the
necessary EVB and MCU voltages. Power may be supplied to the EVB via a 2.1 mm barrel style
power jack or a 2-way screw type connector. 12 V operation allows in-car use if desired.
Master power switch and regulator status LED’s.
USB Serial interface
2 x High Speed CAN transceiver routed to 3-way headers
2 x LIN interfaces routed to standard Molex headers
Main clock supplied from on board crystal or SMA connector
User reset switch with reset status LED’s
Ethernet PHY and RJ45 socket configurable as RMII or MII
USB Type A Host interface
USB Type AB (micro USB) OTG interface
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









2 x FlexRay interfaces with standard 2-pin connectors
14-pin JTAG and 50 pin Nexus (Trace) connectors
2 x High Density daughter card connectors allowing an MCU specific daughtercard to be fitted1
MLB daughtercard connector
SAI Audio board connectors (2 x 0.1 inch pitch headers and 2 x TWRPI style headers)
SD connector (mounted to the underside of the board) supporting hardware write protect and
card detection
4 user LEDs wired to MCU ports, also available at a user header
4 user pushbutton switches wired to MCU ports, also available at a user header
Hexadecimal encoded switch wired to 4 MCU ports, also available at a user header
Simple potentiometer connected to analogue input channel
NOTE
To alleviate confusion between jumpers and connector headers, all EVB
jumpers are 2 mm pitch whereas headers are 0.1 inch (2.54 mm). This
prevents inadvertently fitting a jumper to a header.
1
There is no MCU fitted to the EVB. A daughtercard must be fitted before the EVB can be used.
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Configuration Overview
3. Configuration Overview
Throughout this document, all of the default jumper and switch settings are clearly marked with “(D)”
and are shown in blue text. This allows a more rapid return to the default state of the EVB if required.
Note that the default configuration for 3-way jumpers is a header fitted between pins 1 and 2. On the
EVB, 2-way, and 3-way jumpers have been aligned such that pin1 is either to the top or to the left of the
jumper. On 2-way jumpers, the source of the signal is connected to pin1.
The EVB has been designed with ease of use in mind and has been segmented into functional blocks as
shown below. Detailed silkscreen legend has been used throughout the board to identify all switches,
jumpers and user connectors.
Figure 1. EVB Functional Blocks
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4. MCU Daughtercard information
In order to use the EVB, an MCU daughtercard must be fitted as described in the following section.
Before fitting or removing a daughtercard, ensure the EVB is powered OFF
4.1. Fitting a daughtercard
Gently place the daughtercard on the EVB connectors ensuring the correct orientation as shown in the
following figure. The connectors are polarized so the daughtercard will only fit in one orientation (with
the jumpers at the bottom of the daughtercard). Once the connectors have been located correctly, firmly
push down all four corners of the daughter card simultaneously in order to ensure the connectors are
mated. (The following picture also shows the default jumper positions for the 256BGA daughtercard)
Figure 2. Daughtercard Fitted to EVB
4.2. Removing a daughtercard
In order to prevent damage to the daughtercard connectors, it is important to remove the daughtercard
correctly. Carefully lift either the top or bottom edge of the daughtercard and it should easily lift off as
shown in the following figure (viewed from the left side of the EVB).
Figure 3. Removing a daughtercard
CAUTION
Do not attempt to lift the left or right edge of the daughtercard as this will
result in connector damage.
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Initial Configuration
5. Initial Configuration
This section details the power, reset, clocks, and debug configuration which is the minimum
configuration needed in order to power ON the EVB.
5.1. Power Supply Configuration
The Power supply
section is located in
the bottom left
corner of the EVB
The EVB requires an external power supply voltage of between 10 V-14 V DC (nominal 12 V),
minimum 2 A. This allows the EVB to be used in a vehicle if required. The 12 V input is regulated on
the EVB using two switching and three linear regulators to provide the required voltages of 5.0 V, 3.3 V
(both linear and switcher) and 1.25 V (linear). For flexibility, there are two power supply input
connectors on the EVB as detailed below:
5.1.1. Power Supply Connectors (P21, P23)

2.1 mm Barrel Connector – P21
This connector should be used to connect the supplied wall-plug mains adapter. Note – if a
replacement or alternative adapter is used, care must be taken to ensure the 2.1 mm plug uses the
correct polarisation as shown below:
Figure 4. 2.1mm Power Connector

2-Way Screw Type Connector – P23
This can be used to connect a bare wire lead to the EVB, typically from a laboratory power supply.
The polarisation of the connectors is clearly marked on the EVB. Care must be taken to ensure
correct connection.
Figure 5. 2-Lever Power Connector
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5.1.2. Power Switch (SW5)
Slide switch SW5 can be used to isolate the power supply input from the EVB voltage regulators if
required.

Moving the slide switch to the right (away from the fuse) will turn the EVB OFF.

Moving the slide switch to the left (towards the fuse) will turn the EVB ON.
5.1.3. Regulator Power Jumper (J23)
All of the regulators are permanently powered from the main 12 V supply line and active with the
exception of the 1.25 V linear regulator which has a 3-way jumper to allow selection of the input
voltage.
The table below details the jumper configurations for the linear 1.25 V regulator source voltage. By
default, the regulator is powered from the 12 V supply line.
Jumper
J23
(INPUT SEL)
Position
1-2 (D)
2-3
Removed
Table 1. 1.25 V Linear Regulator Source Select (J23)
PCB Legend
Description
12V
1.25V Linear regulator is powered from main 12V
5V
1.25V Linear regulator is powered from 5V switching regulator output
1.25V Linear regulator is not powered (disabled)
5.1.4. Power Status LED’s and Fuse
When power is applied to the EVB, five green LED’s adjacent to the voltage regulators show the
presence of the supply voltages as follows:





LED DS4 – Indicates that the 1.25V linear regulator is enabled and working correctly
LED DS5 – Indicates that the 5.0V linear regulator is enabled and working correctly
LED DS6 – Indicates that the 3.3V linear regulator is enabled and working correctly
LED DS9 – Indicates that the 5.0V switching regulator is enabled and working correctly
LED DS10 – Indicates that the 3.3V switching regulator is enabled and working correctly
If no LED’s are illuminated when power is applied to the EVB and the regulators are correctly enabled
using the appropriate jumpers, it is possible that either power switch SW5 is in the “OFF” position or
that the fuse F1 has blown. The fuse is provided to protect the external power supply and for EVB
circuitry reverse-bias protection. If the fuse has blown, check the polarity of your power supply and
replace the fuse with a 20 mm 1.5 A fast blow fuse.
Note that the fuse will not protect against one of the EVB regulators being shorted. If this happens,
damage is likely to occur to the EVB and / or components.
CAUTION
In the event of a short in the regulator output, the regulator and/or the
shorted component may be hot
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Initial Configuration
5.1.5. MCU Power Supply Jumpers
(J18, J19, J20, J21, J22, J23)
The MCU Daughtercard
power jumpers are in the
bottom left quarter of the
EVB, above the power
area
All of the regulated power supplies are routed to the MCU daughtercard via jumpers. This allows each
power supply to be individually isolated and facilitates current measurement at the respective jumper.
Note that only the daughtercard is connected to the power lines after the jumpers so MCU current
measurements are accurate. There are an additional two jumpers that control the voltages used by EVB
peripherals connected to the VDD_HV_A and VDD_HV_B domains as described in section 5.1.7.
Figure 6. Power Supply Jumper Schematic
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The power supply jumper description table is shown in the following table:
Jumper
J18
1V25L
J19
5V0S
J20
3V3L
J21
5V0L
J22
3V3S
J23
INPUT SEL
(Above Power
Jack)
Table 2. Daughter Card Power Supply Jumpers (on main board)
Position
PCB Legend
Description
Fitted (D)
1.25V Linear regulator output is routed to daughter card
Removed
1.25V Linear regulator output is disconnected from daughtercard
Fitted (D)
5.0V Switching regulator output is routed to daughter card
Removed
5.0V Switching regulator output is disconnected from daughtercard
Fitted (D)
3.3V Linear regulator output is routed to daughter card
Removed
3.3V Linear regulator output is disconnected from daughtercard
Fitted (D)
5.0V Linear regulator output is routed to daughter card
Removed
5.0V Linear regulator output is disconnected from daughtercard
Fitted (D)
3.3V Switching regulator output is routed to daughter card
Removed
3.3V Switching regulator output is disconnected from daughtercard
1-2 (D)
12V
1.25v Linear regulator is powered by main 12V input
2-3
5V
1.25v Linear regulator is powered by output from 5.0V switching reg
Removed
1.25v Linear regulator is not powered (disabled)
5.1.6. Daughtercard Power Jumpers (J3 to J11)
The following power control jumpers are located on the MCU daughtercard. Note that not all of the
jumpers will be on each daughtercard variant.
Jumper
J3
ADC0
J4
ADC1
J5
HVA
J6
HVB
J7
HVC
Position
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
Table 3. MCU Power Supply Jumpers (on daughtercard)
PCB Legend
Description
3V3
MCU ADC0 pin is connected to 3.3V (Linear)
5V0
MCU ADC0 pin is connected to 5.0V (Linear)
MCU ADC0 pin is not connected to power
3V3
MCU ADC1 pin is connected to 3.3V (Linear)
5V0
MCU ADC1 pin is connected to 5.0V (Linear)
MCU ADC1 pin is not connected to power
3V3
MCU VDD_HV_A domain is connected to 3.3V (Switching Regulator)
5V0
MCU VDD_HV_A domain is connected to 5.0V (Switching Regulator)
MCU VDD_HV_A domain is not connected to power
3V3
MCU VDD_HV_B domain is connected to 3.3V (Switching Regulator)
5V0
MCU VDD_HV_B domain is connected to 5.0V (Switching Regulator)
MCU VDD_HV_B domain is not connected to power
3V3
MCU VDD_HV_C domain is connected to 3.3V (Switching Regulator)
5V0
MCU VDD_HV_C domain is connected to 5.0V (Switching Regulator)
MCU VDD_HV_C domain is not connected to power
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Initial Configuration
Jumper
J8 2
FLA
J9
REG
J10
VDDLV
J11
DAC
Position
Fitted (D)
Removed
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
PCB Legend
3V3
5V0
REG
1V25L
HVA
USR
Description
MCU VDD_HV_FLA pin is connected to 3.3v (Switching Regulator)
MCU VDD_HV_C domain is connected to 5.0V (Switching Regulator)
MCU ballast transistor collector is connected to 3.3V (Switching)
MCU ballast transistor collector is connected to 5.0V(Switching)
MCU ballast transistor collector is not connected to power
MCU VDD_LV domain is powered from ballast transistor
MCU VDD_LV domain is powered from 1.25V Linear regulator
MCU VDD_LV domain is not powered
MCU VIN1_CMP_REF is powered from VDD_HV_A
MCU VIN1_CMP_REF is powered from user testpoint (TPH3)
MCU VIN1_CMP_REF is not powered
5.1.7. Peripheral Power Supply Jumpers (J24, J25)
The peripheral power
jumpers are in the bottom
left quarter of the EVB,
above the power area
There are two additional power supply jumpers controlling the I/O voltage for the peripherals on the
EVB in the HVA and HVB voltage domains.
The settings on these jumpers must match the VDD_HV_A and VDD_HV_B jumper voltage setting on
the MCU daughtercard.
The default configuration matches the MCU daughtercard default configuration with both jumpers set to
3.3V.
Jumper
J24
HVA
J25
HVB
Position
1-2 (D)
2-3
Removed
1-2 (D)
2-3
Removed
Table 4. Peripheral Power Control (J24, J25)
PCB Legend
Description
3V3
EVB peripherals in HVA domain are set to use I/O voltage of 3.3V
5V0
EVB peripherals in HVA domain are set to use I/O voltage of 5.0V
Invalid Configuration, avoid!
3V3
EVB peripherals in HVB domain are set to use I/O voltage of 3.3V
5V0
EVB peripherals in HVB domain are set to use I/O voltage of 5.0V
Invalid Configuration, avoid!
5.1.8. EVB Voltage Regulators
The following table shows the usage of each EVB voltage regulator. This provides a useful cross
reference point should any regulator be disabled. In addition, the distribution of the peripheral voltages
HVA (J24) and HVB (J25) are shown.
2
Note that jumper J8 (FLA) jumper must only be fitted when VDD_HV_A (J5) is connected to 3.3V.
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Table 5. Power Supply Distribution
Regulator
12V
(Unregulated)
P12V
5.0V
Switcher
5V0_SR
3
Used On
All voltage regulators (switching and Linear, jumper selectable on 1.25V linear)
1.25V linear regulator LED supply via FET
MCU Daughtercard connector
MLB Daughtercard connector
FlexRay transceiver VBAT pin
Daughtercard connector (post daughtercard power jumper)
Daughtercard connector (direct feed via zero ohm link)
Peripheral power control jumpers (position 2-3)
CAN transceivers VCC (main power)
USB RS232 (FTDI) transceiver (main power and protection diode)
USB Host / OTG transceiver power (VBAT) pin
FlexRay Transceiver power pins (VCC / VBUF)
SAI Audio connector
Input to 1.25V linear regulator (in alternate jumper configuration)
3.3V
Switcher
3V3_SR
Daughtercard connector (post daughtercard power jumper)
Daughtercard connector (direct feed via zero ohm link)
Peripheral power control jumpers (position 1-2)
Reset LED’s (user and target)
USB HOST / OTG transceiver I/O voltage (USB operation is fixed at 3.3V)3
Ethernet Transceiver supply and I/O (Ethernet operation is fixed at 3.3V) 3
SAI Audio connector
MLB Daughtercard connector
SD Card power supply / pullup resistors (SD Card operation is fixed at 3.3V)3
User LED’s supply voltage
Hex encoder switch supply voltage
User pushbutton switches supply voltage
5.0V
Linear
5V0_LR
Daughtercard connector (post daughtercard power jumper)
Daughtercard connector (direct feed via zero ohm link)
3.3V
Linear
3V3_LR
Daughtercard connector (post daughtercard power jumper)
Daughtercard connector (direct feed via zero ohm link)
MLB Daughtercard connector
ADC Input Pot (user variable resistor)
1.25V
Linear
1V25_LR
Daughtercard connector (post daughtercard power jumper)
Daughtercard connector (direct feed via zero ohm link)
J24 PER_HVA
Reset control circuitry (including reset pullup)
JTAG Pullup resistors & reference voltage
CAN Transceiver I/O Voltage select
LIN Transceiver Enable (and I/O voltage select)
USB RS232 (FTDI) transceiver I/O voltage select
FlexRay Transceiver I/O Voltage select (and pullups)
J25 PER_HVB
Nexus Connector reference voltage and Pullups
These voltages are fixed due to device specifications and cannot be changed.
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Initial Configuration
Note that the JTAG pins are in domain VDD_HV_A whereas the Nexus pins are VDD_HV_B.
Normally this would mean that for trace, the HVA and HVB domains should be at the same voltage
however some development tools can automatically adapt to the voltages on the trace signals. Please
consult your tools vendor for further details.
5.2. Reset Control (J9, SW1)
The reset circuitry and
switch are located in the
top left quarter of the
EVB next to theRJ45
connector
The MCU has a single bi-directional open drain Reset pin. Rather than connect multiple devices to the
reset pin directly, a reset-in and reset-out buffering scheme has been implemented on the EVB as shown
in Figure 7 below. The reset “in” from the reset switch (SW1) and the debug connectors are logically
OR’d together using an AND gate and then connected to the buffer to provide an open-drain output.
The “reset-out” circuitry provides a buffered reset signal that can be used to drive any circuitry requiring
a reset control from the MCU.
Figure 7. EVB Reset Control
Jumper J9 is used to disconnect the reset signal from the external reset sources if required.
Jumper
J9 (EN)
Position
Fitted (D)
Removed
Table 6. Reset Control (J9)
PCB Legend
Description
Reset from reset switch and debug connectors is active
Reset from reset switch and debug connectors is inactive
Note that removing jumper J9 will mean that an external reset source will not reset the MCU. This will
impact most debuggers which will typically issue a reset before establishing a debug connection.
5.2.1. Reset LEDs
As can be seen in Figure 7 above, there are two reset LED’s that can be used to identify the source /
cause of a reset:
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RED LED D1 (titled “MCU”) will illuminate if:

The MCU issues a reset (in this condition ONLY this LED will be illuminated and LED DS1
will be off)

There is a target reset (ie from the reset switch or from the debugger in which case LED DS1
will be ON)
YELLOW LED DS1 (titled “USR”) will illuminate when an external hardware device issues a reset to
the MCU:

The reset switch is pressed

There is a reset being driven from one of the debug connectors
LED DS1 (Yellow)
OFF
OFF
LED D1 (Red)
OFF
ON
ON
OFF
ON
ON
Table 7. Reset LED Decoding
Description
No Reset being issued from MCU or external logic
MCU has issued a reset
External reset issued from switch or debug BUT not being issued to MCU
(check J9 is fitted on the EVB)
External reset issued from reset switch or debug and has been issued to MCU.
5.3. MCU Clock Configuration
There are 2 clock configuration jumpers on the daughtercard and an external clock input connector on
the main board to allow an externally generated clock to be supplied if desired. See Figure 8 below.
Figure 8. EVB Clock Selection
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Initial Configuration
5.3.1. External Clock Input (P7)
The external SMA
clock connector is
located in the top left
corner of the EVB
The external clock input on the EVB is applied via SMA connector P7. When driving an external clock
into the SMA connector, the jumpers on the daughtercard must be reconfigured to route the external
clock to the MCU.
Note that the following conditions must be met when supplying an external clock:

The clock frequency must be between 8MHz and 40MHz

The amplitude of the clock input should not exceed the voltage being driven into the
VDD_HV_A pins. This is selectable between 3.3V and 5.0V on the daughtercard.
5.3.2. MCU Clock Configuration (J1, J2 on Daughtercard)
There are two external clock crystals on the MPC5748G daughtercards:

40MHz fast external crystal for clocking the main system clock

32KHz slow external crystal for accurate time of day keeping
The 40MHz crystal is connected to the MCU XTAL and EXTAL pins via 3-way jumper headers as
shown in the diagram above. These jumpers allow an external clock to be routed from the SMA
connector (P7) on the main board if desired. The default configuration is with both daughtercard
jumpers (J1 and J2) set to position 1-2 which routes the external 40MHz crystal to the MCU pins. If you
wish to supply a clock via the SMA connector on the main EVB, move the daughtercard jumpers J1 and
J2 to position 2-3.
The 32 KHz external crystal is permanently connected to the MCU EXTAL32 and XTAL32 pins and
has no configuration options.
Jumper
J1 (XTAL)
J2 (EXTAL)
Table 8.
Position
1-2 (D)
2-3
1-2 (D)
2-3
EXTAL Clock Source Selection (J1, J2 Daughtercard)
PCB Legend
Description
Y1
MCU XTAL signal is routed to crystal Y1
GND
MCU XTAL signal is Grounded (for ext clock mode)4
Y1
MCU EXTAL signal is routed to crystal Y1
EXT
MCU EXTAL signal is routed from EVB SMA P7
4
Note that the XTAL pin is left open by default with J1 in position 2-3. Resistor R34 must be populated with a zero
ohm resistor in order to ground the XTAL pin.
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15
5.4. Debug Connectors (P8, P10)
The EVB provides two debug connectors:
The JTAG and
Nexus debug
connectors are in
the top right corner
of the EVB

Standard 14 pin JTAG

50 Pin Nexus connector (Samtec ASP-148422-01, Nexus Standard HP50 connector)
There is no user configuration required to use the connectors however the following points should be
noted:

The JTAG connector is routed to the JTAG signals in the default position which are powered
from the MCU VDD_HV_A power domain. The Nexus signals are located in the VDD_HV_B
power domain. If you are using Nexus, you may have to ensure that the VDD_HV_A and
VDD_HV_B domains are at the same voltage. Consult your tools vendor for specific information

The Nexus signals are not bonded out in every MCU package. Before using Nexus, please ensure
the MCU fitted to the EVB (via the daughtercard) supports the Nexus signals.
5.4.1. Debug Connector Pinouts
The following tables list the pinouts for each of the debug connectors used on the EVB
Pin No
1
3
5
7
9
11
13
Function
TDI
TDO
TCLK
EVTI
RESET
VREF
RDY
Table 9. 14-Pin JTAG Debug Connector Pinout
Connection
Pin No
Function
PC0
2
GND
PC1
4
GND
PH9
6
GND
PL8
8
N/C
JTAG-RSTx
10
TMS
PER_HVA
12
GND
--14
JCOMP
Connection
GND
GND
GND
--PH10
GND
10K Pulldown
Pin No
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
Table 10. 50-pin Samtec (Nexus) Debug Connector Pinout
Function
Connection
Pin No
Function
MSEO_0
PL9
2
VREF
MSEO_1
PL11
4
TCK
GND
GND
6
TMS
MDO0
PL2
8
TDI
MDO1
PL3
10
TDO
GND
GND
12
JCOMP
MDO2
PL4
14
RDY
MDO3
PL5
16
EVTI
GND
GND
18
EVTO
MCKO
PL10
20
RESET
MDO4
PL6
22
RST_OUT
GND
GND
24
GND
MDO5
PL7
26
CLKOUT
MDO6
PL13
28
TD/WT
GND
GND
30
GND
Connection
PER_HVB
PH9
PH10
PC0
PC1
10K Pulldown
--PL8
PL12
DBUG_RST
MCU_RST
GND
Test Point
--GND
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Freescale Semiconductor, Inc.
Communications & Memory Interfaces:
Pin No
31
33
35
37
39
41
43
45
47
49
Function
MDO7
MDO8
GND
MDO9
MDO10
GND
MD011
MDO12
GND
MDO15
Connection
PL14
PL15
GND
PM0
PM1
GND
PM2
PM7
GND
PM10
Pin No
32
34
36
38
40
42
44
46
48
50
Function
DAI1
DAI2
GND
ARBREQ
ARBGRT
GND
MDO13
MDO14
GND
N/C
Connection
----GND
----GND
PM8
PM9
GND
---
6. Communications & Memory Interfaces:
This section details the communication interface and storage peripherals that are implemented on the
EVB.
6.1. CAN Interfaces (P14, P15, J14, J15)
The CAN Physical
interface circuits are
located on the left
edge of the EVB
The EVB incorporates two identical CAN interface circuits connected to MCU CAN0 and CAN1 using
MC33901 transceivers. Both transceivers are configured for high speed operation by pulling pin 8 to
GND via a 4.7K Ohm resistor. There are test points to allow the Select pin to be driven high if desired.
The MC33901 is pin compatible with other CAN transceivers supporting full CAN FD data rates.
For flexibility, the CAN transceiver I/O is connected to a standard 0.1” connector (P14 for CAN1 / P15
for CAN0) rather than using non standard DB9 connectors. The pinout of these headers is shown below
and is also detailed on the PCB silkscreen
1
H
L
GND
Figure 9. CAN Physical Interface Connectors
The CAN0 and CAN1 MCU TX/RX signals are jumpered as shown in the table below to allow the
transceivers to be isolated from the respective MCU pin if desired. The default configuration is with all
jumper headers fitted routing the TX and RX signals to the MCU.
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17
Jumper
J15 (CAN0)
Posn 1-2
J15 (CAN0)
Posn 3-4
Position
FITTED (D)
Removed
FITTED (D)
Removed
J14 (CAN1)
Posn 1-2
J14 (CAN1)
Posn 3-4
FITTED (D)
Removed
FITTED (D)
Removed
Table 11. CAN Control Jumpers (J51, J53)
PCB Legend
Description
MCU CAN0_TX signal (PB0) is routed to CAN interface
TX
MCU CAN0_TX signal (PB0) is not routed to CAN interface
MCU CAN0_RX signal (PB1) is routed to CAN interface
RX
MCU CAN0_RX signal (PB1) is not routed to CAN interface
TX
RX
MCU CAN1_TX signal (PC10) is routed to CAN interface
MCU CAN1_TX signal (PC10) is not routed to CAN interface
MCU CAN1_RX signal (PC11) is routed to CAN interface
MCU CAN1_RX signal (PC11) is not routed to CAN interface
NOTE
Care should be taken when fitting the jumper headers to the 2x2 jumper
blocks J14 and J15 as they can easily be fitted in the incorrect orientation.
Jumper headers should be fitted horizontally.
The CAN TX / RX MCU pins are powered from the VDD_HV_A domain, which is configured between
3.3V and 5.0V on the daughtercard using jumper J5. The CAN transceivers I/O voltage is connected to
the PER_HVA net configured with jumper J24 on the main EVB. Care must be taken to ensure that the
MCU VDD_HV_A and PER_HVA supplies are the same when using the CAN transceiver.
6.2. LIN Interfaces (P9, P11, J10, J12)
The LIN Physical
interface circuits are
located on the left
edge of the EVB
The EVB incorporates two identical LIN transceiver circuits connected to MCU LIN0 and LIN1 using a
Freescale MC33662LEF transceiver supporting both master and slave mode (jumper selectable)
The output from the LIN transceiver is connected to a standard 4-pin Molex connector as used on most
other Freescale EVB’s supporting LIN as shown in the following figure:
Figure 10. LIN Molex Physical Interface Connector
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Freescale Semiconductor, Inc.
Communications & Memory Interfaces:
The LIN0 and LIN1 MCU TX/RX signals are jumpered as shown in the following to allow the
transceivers to be isolated from the respective MCU pin if desired. The default configuration is with all
jumper headers fitted routing the TX and RX signals to the MCU.
Each transceiver also has a master mode enable jumper which is fitted by default to configure the
transceiver for Master mode. To configure the transceiver for slave mode, remove the respective
“Master_EN” jumper.
Jumper
J10 (LIN0)
Posn 1-2
J10 (LIN0)
Posn 3-4
J11
(Master_EN)
J12 (LIN1)
Posn 1-2
J12 (LIN1)
Posn 3-4
J13
(Master_EN)
Table 12. LIN Control Jumpers (J10, J11, J12, J13)
Position
PCB Legend
Description
FITTED (D)
MCU LIN0_RX signal (PB3) is routed to LIN0 interface
RX
Removed
MCU LIN0_RX signal (PB3) is not routed to LIN0 interface
FITTED (D)
MCU LIN0_TX signal (PB2) is routed to LIN0 interface
TX
Removed
MCU LIN0_TX signal (PB2) is not routed to LIN0 interface
FITTED (D)
LIN0 is configured in Master Mode
Removed
LIN0 is configured in Slave Mode
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
RX
TX
MCU LIN1_TX signal (PC7) is routed to LIN1 interface
MCU LIN1_TX signal (PC7) is not routed to LIN1 interface
MCU LIN1_RX signal (PC6) is routed to LIN interface
MCU LIN1_RX signal (PC6) is not routed to LIN interface
LIN1 is configured in Master Mode
LIN1 is configured in Slave Mode
NOTE
Care should be taken when fitting the jumper headers to the 2x2 jumper
blocks J10 and J12 as they can easily be fitted in the incorrect orientation.
Jumper headers should be fitted horizontally
The LIN TX / RX MCU pins are powered from the VDD_HV_A domain, which is configured between
3.3V and 5.0V on the daughtercard using jumper J5. The LIN transceivers enable pin is connected to the
PER_HVA net configured with jumper J24 on the main EVB. Care must be taken to ensure that the
MCU VDD_HV_A and PER_HVA supplies are the same when using the LIN transceiver.
Note that in order for the LIN transceiver to function, external power must be supplied via pin 3 of the
molex connector as detailed in Figure 10.
6.3. USB RS232 Serial Interface (P17, J16)
The USB RS232
interface is on the
left hand edge of the
board (USB Type B
socket)
The EVB incorporates a USB RS232 serial interface providing RS232 connectivity via a direct USB
connection between the PC and the EVB. The circuit contains an FTDI FT2232D USB to Serial
interface which should automatically install the drivers for two additional COM ports on your PC. Note
that only one of these is used so you will need to try both (usually the higher numbered COM port is the
active one). For more information on the USB drivers and general fault finding, consult the FTDI
website at http://www.ftdichip.com/
The MCU LIN2 signals are routed to the FTDI transceiver via a 2-way jumper header (J16) allowing the
transceiver to be isolated from the MCU pin if desired. The default configuration is with the jumper
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19
header fitted, routing the TX and RX signals from the MCU to the FTDI transceiver. No other
configuration is required.
Jumper
J16
Posn 1-2
J16
Posn 3-4
Position
FITTED (D)
Removed
FITTED (D)
Removed
Table 13. USB RS232 Control Jumpers
PCB Legend
Description
MCU LIN2_RX signal (PC9) is routed to the FTDI interface
RX
MCU LIN2_RX signal (PC9) is not routed to the FTDI interface
MCU LIN2_TX signal (PC8) is routed to the FTDI interface
TX
MCU LIN2_TX signal (PC8) is not routed to the FTDI interface
NOTE
Care should be taken when fitting the jumper headers to the 2x2 jumper
block J16 as they can easily be fitted in the incorrect orientation. Jumper
headers should be fitted horizontally.
The MCU LIN2 (SCI) pins are powered from the VDD_HV_A domain, which is configured between
3.3V and 5.0V on the daughtercard using jumper J5. The FTDI transceiver I/O voltage pin is connected
to the PER_HVA net configured with jumper J24 on the main EVB. Care must be taken to ensure that
the MCU VDD_HV_A and PER_HVA supplies are the same when using the FTDI transceiver.
6.4. USB HOST / OTG Interfaces
The USB interfaces
are on the top right
quarter on the board
on the top edge
The EVB includes Type A (Host) and Type AB (OTG) USB interfaces, routed to standard and micro
USB sockets respectively. Each USB circuit contains a USB83340 transceiver with a shared USB power
switch. There is no user configuration required on either of the USB circuits.
The USB transceivers have a 3.3V (only) interface. All of the USB0 (connected to the OTG transceiver)
and USB1 (connected to the HOST transceiver) signals are in the VDD_HV_A domain and must be
configured as 3.3V via daughtercard jumper J5. If VDD_HV_A is set to 5V, the USB0 and USB1 MCU
signals should be left tri-stated to prevent damage to the USB transceivers.
6.5. Ethernet (P6, J5, J6, J7, J8, R45, R80)
The USB interfaces
are on the top right
quarter on the board
on the top edge
The MPC5748G supports both MII and RMII Ethernet interfaces. The EVB incorporates a DP83848c
transceiver supporting both MII and RMII modes. The transceiver is connected to a pulse J1011F21PNL
RJ45 connector which includes a built-in isolation transformer.
The default configuration, with all 2-way jumpers fitted and all 3-way jumpers in position 1-2,
configures the transceiver for MII mode with the reset signal to the PHY being driven from the MCU
Reset out (eg any reset causing the MCU Reset line to assert will reset the PHY)
In order to configure the EVB for RMII mode, jumpers J5, J6 and J7 need to be changed as described in
Table 14 below. In addition, a surface mount 0Ω resistor needs to be de-soldered and moved as shown in
the figure below. This option is fitted as a resistor instead of a jumper to maintain signal integrity on the
Ethernet clock signal.
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Freescale Semiconductor, Inc.
Communications & Memory Interfaces:
For MII mode (default) R45 should have a jumper populated as shown. For RMII mode, remove R45
and fit it between R45 and R80
For RMII mode
remove R45 and re-fit
in this position
Figure 11. MII / RMII Clock Selection Resistor
To change the reset routing so that the Ethernet PHY can be reset via MCU pin PI11 (rather than being
tied to the MCU reset), jumper J8 should be moved to position 2-3
Jumper
J5
J6
(X1)
J7
(X2)
J8
(RST)
R45 (R80)
Table 14. Ethernet Control jumpers (J5, J6, J7, J8, R45, R80)
Position
PCB Legend
Description
1-2 (D)
MII
Ethernet PHY is configured in MII mode
2-3
R
Ethernet PHY is configured in RMII mode
Removed
Invalid Configuration, avoid!
1-2 (D)
Ethernet PHY X2 clock is connected to 25MHz xtal
2-3
Ethernet PHY X2 clock is not connected to 25MHz xtal5, 6
1-2 (D)
Ethernet PHY X1 clock is connected to 25MHz xtal
2-3
Ethernet PHY X1 clock is driven from 50MHz xtal
Removed
Ethernet PHY X1 clock is disconnected (invalid configuration, avoid)
1-2 (D)
NORM
The Ethernet PHY will be reset along with MCU reset
2-3
PI11
The Ethernet PHY reset is controlled via MCU pin PI11 (Pulled high)
Removed
Invalid Configuration, avoid!
Fitted R45
MII Mode – Clock is supplied from PHY to MCU
R45 to R80
RMII Mode – Clock is supplied from external 50MHz oscillator to MCU
The MCU Ethernet signals are all in the VDD_HV_B domain. The Ethernet PHY will ONLY function
with 3.3V I/O so VDD_HV_B must be set to 3.3V on the MCU daughtercard before the Ethernet is
used. If VDD_HV_B is set to 5V, the signals routed to the Ethernet PHY (see the EVB schematics) must
be left as tristate.
5
If jumper J7 is in position 1-2 (25MHz XTAL), J6 must be fitted and R45 must be fitted.
If jumper J7 is in position 2-3 (50MHz oscillator), J6 must be removed and R45 must be removed and placed
between R45 and R80
6
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21
6.6. FlexRay (P2, P3, J1, J2, J3, J4)
The FlexRay
interface is in the top
right corner of the
EVB on the top edge
The EVB incorporates two FlexRay TJA1080TS/N interfaces connected to MCU FlexRay channels A
and B and routed to two Molex 1.25mm pitch PicoBlade shrouded headers (standard on many Freescale
EVB’s). Jumpers are provided to disconnect the MCU signals from the FlexRay interface if required as
well as providing general configuration.
By default, all of the jumper headers are fitted which routes the MCU signals to the FlexRay physical
interface as well as configuring the controller for a default mode of operation (Transmitter enabled,
Receiver enabled, not in low power mode). Please consult the FlexRay transceiver and general FlexRay
specifications before changing any of the mode jumpers.
Table 15. FlexRay Configuration Jumpers (J1, J2, J3, J4)
PCB Legend
Description
Jumper
Position
FlexRay A
J3
Posn 1-2
J3
Posn 3-4
J3
Posn 5-6
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
J2
Posn 1-2
J2
Posn 3-4
J2
Posn 5-6
J2
Posn 7-8
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
FlexRay B
J4
Posn 1-2
J4
Posn 3-4
J4
Posn 5-6
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
J1
Posn 1-2
J1
Posn 3-4
J1
Posn 5-6
J1
Posn 7-8
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
FITTED (D)
Removed
TX
TXEN
RX
BGE
EN
STBN
WAKE
TX
TXEN
RX
BGE
EN
STBN
WAKE
MCU PC5 is connected to FlexRay A transceiver TX
MCU PC5 is not connected to FlexRay A transceiver TX
MCU PE2 is connected to FlexRay A transceiver TXEN
MCU PE2 is not connected to FlexRay A transceiver TXEN
MCU PE3 is connected to FlexRay A transceiver RX
MCU PE3 is not connected to FlexRay A transceiver RX
FlexRay A PHY Bus Guardian Enable (Transmitter is enabled)
FlexRay A PHY transmitter is disabled (Receive only mode)
FlexRay A PHY is enabled
FlexRay A PHY is disabled
FlexRay A PHY will not enter Standby Mode
FlexRay A PHY will enter Standby Mode
FlexRay A PHY Wakeup signal pulled low
FlexRay A PHY Wakeup signal pulled high
MCU PE4 is connected to FlexRay B transceiver TX
MCU PE4 is not connected to FlexRay B transceiver TX
MCU PC4 is connected to FlexRay B transceiver TXEN
MCU PC4 is not connected to FlexRay B transceiver TXEN
MCU PE5 is connected to FlexRay B transceiver RX
MCU PE5 is not connected to FlexRay B transceiver RX
FlexRay B PHY Bus Guardian Enable (Transmitter is enabled)
FlexRay B PHY transmitter is disabled (Receive only mode)
FlexRay B PHY is enabled
FlexRay B PHY is disabled
FlexRay B PHY will not enter Standby Mode
FlexRay B PHY will enter Standby Mode
FlexRay B PHY Wakeup signal pulled low
FlexRay B PHY Wakeup signal pulled high
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AV Interface Connectors
The MCU FlexRay pins are powered from the VDD_HV_A domain, which is configured between 3.3V
and 5.0 V on the daughtercard using jumper J5. The FlexRay tranceivers I/O voltage pin is connected to
the PER_HVA net configured with jumper J24 on the main EVB. Care must be taken to ensure that the
MCU VDD_HV_A and PER_HVA supplies are the same when using the FlexRay transceiver.
Important:
The EVB daughtercards are supplied with a 40 MHz crystal which is a requirement for FlexRay in
order to generate the correct clock timing. If you have changed the default crystal on the daughtercard
and wish to use FlexRay, you must ensure a 40 MHz crystal is fitted.
6.7. SD Card Socket (P200)
The SD socket is
mounted on the
underside of the
board in the top left
corner
The EVB supports a 4-bit SD interface (note that MPC5748G supports 8-bit SD data) which is routed to
a full sized SD card connector on the underside of the EVB. There is no user configuration required.
The SD socket has hardware card detection (routed to PA0) and write protection (routed to PH8) status
outputs which will be grounded when active.
The MCU SD card signals are all in the VDD_HV_A domain. The SD card specification is for an
interface voltage of between 2.7V and 3.6V so the SD card can only be used when VDD_HV_A is set to
3.3V (PER_HVA has no impact on the voltage on the SD card)
CAUTION
If VDD_HV_A is set to 5V, damage may be caused to an SD card if an
attempt is made to access it in software. If you need to leave the SD card
in the socket with VDD_HV_A set to 5V, ensure all the SD card pads are
left as high impedance
7. AV Interface Connectors
This section details the Audio / Video interface connectors on the EVB. Each of these connectors can be
used to add additional daughtercards (not supplied) to add functionality.
7.1. SAI Audio Connectors (P24, P25)
The SAI audio
connector is on the
bottom edge of the
EVB
The EVB includes two 0.1” headers that can be used to interface to an SAI audio board (available
separately, please consult your Freescale representative). There is no EVB configuration required when
using these connectors other than to ensure the EVB is switched off prior to fitting or removing the
daughtercard.
The pinout of the connectors is shown below for reference and these connectors can also be used for
GPIO connectivity
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
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23
Pin No
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
Table 16. 50-pin SAI Audio Daughtercard Connector P24
Function
Connection
Pin No
Function
3.3V
3V3_SR
2
GND
SAI0_DATA3
PF2
4
GND
SAI0_DATA2
PF3
6
GND
SAI0_DATA1
PF4
8
GND
SAI0_DATA0
PF5
10
GND
SAI0_BCLK
PF1
12
GND
SAI0_SYNC
PB10
14
GND
SAI0_MCLK
PF0
16
GND
eMIOS1_7H
PH5
18
GND
I2C_SCL3
PE11
20
GND
I2C_SDA3
PE10
22
GND
SAI1_DATA0
PJ2
24
GND
SAI1_BCLK
PJ3
26
GND
eMIOS1_6H
PH4
28
GND
SAI1_SYNC
PF6
30
GND
SAI1_MCLK
PF7
32
GND
I2C_SCL2
PE9
34
GND
I2C_SDA2
PE8
36
GND
SAI2_DATA0
PI14
38
GND
SAI2_BCLK
PJ1
40
GND
SAI2_SYNC
PJ0
42
GND
SAI2_MCLK
PI15
44
GND
eMIOS1_5H
PH3
46
GND
GPIO Control
PA5
48
GND
5.0V
5V0_SR
50
GND
Connection
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
Pin No
1
3
5
7
9
11
13
15
17
19
Table 17. 20-pin SAI Audio Daughtercard Connector P25
Function
Connection
Pin No
Function
N/C
N/C
2
GND
DSPI0_SIN
PA12
4
GND
DSPI0_SOUT
PA13
6
GND
DSPI0_SCK
PA14
8
GND
DSPI0_SS0
PA15
10
GND
DSPI3_SOUT
PG2
12
GND
DSPI3_SS3
PG3
14
GND
DSPI3_SCK
PG4
16
GND
DSPI3_SIN
PG5
18
GND
N/C
N/C
20
GND
Connection
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
Note that connector P25 is not populated and must be fitted if required
CAUTION
Before the daughtercard is installed or removed, the EVB must be
powered OFF to prevent potential damage to the EVB or daughter card
components.
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Freescale Semiconductor, Inc.
AV Interface Connectors
The TWRPI
connectors are at
the bottom right
hand corner
7.2. TWRPI Connectors (P26, P27)
The EVB includes two fine pitch TWRPI headers that can be used to interface to an SAI audio board
(available separately, please consult your Freescale representative) along with the 0.1” headers
mentioned in the section above. There is no EVB configuration required when using these connectors
other than to ensure the EVB is switched off prior to fitting or removing the daughtercard. The pinout of
the connectors is shown below for reference.
Pin No
1
3
5
7
9
11
13
15
17
19
Pin No
1
3
5
7
9
11
13
15
17
19
Function
5V
GND
GND
GND
ADC1
GND
GND
GND
ID0
GND
Table 18. TWRPI Connector P26
Connection
Pin No
5V0_SR
2
GND
4
GND
6
GND
8
PD6
10
GND
12
GND
14
GND
16
7
PD7
18
GND
20
Function
GND
I2C0_SCL
GND
GND
DSPI0_SIN
DSPI0_SS0
GND
GPIO0/IRQ
GPIO2
GPIO4
Table 19. TWRPI Connector P27
Connection
Pin No
GND
2
PO0
4
GND
6
GND
8
PA12
10
PA15
12
GND
14
PK3
16
PK1
18
PK4
20
Function
3.3V
3.3V
GND
ADC0
GND
ADC2
GND
GND
ID17
Connection
3V3_SR
3V3_LR
GND
PD5
GND
PD4
GND
GND
PD8
Function
GND
I2C0_SDA
GND
GND
DSPI0_SOUT
DSPI0_SCK
GND
GPIO1
GPIO3
N/C
Connection
GND
PO1
GND
GND
PA13
PA14
GND
PK0
PK2
N/C
7.3. MLB Daughtercard Connector (P16)
The MLB
daughtercard
connector is on the
RHS of the EVB
There is a 40-pin interface connector on the EVB for connecting an MLB (Media Local Bus)
daughtercard. There is no hardware configuration possible at EVB level for this connector.
MLB Daughtercards are available direct from SMSC
As with all daughtercards, the EVB must be powered OFF to prevent damage to the EVB or daughter
card components.
7
ID0 and ID1 have a 10K pullup to 3V3
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
Freescale Semiconductor, Inc.
25
8. User Interface (I/O)
This section details the user I/O available on the EVB and includes the GPIO matrix, switches, LED’s
and the ADC variable resistor.
The GPIO matrix is
on the bottom edge
of the EVB above
the SAI audio
connector
8.1. GPIO Matrix
All of the available GPIO pins (those not already used for existing EVB peripherals) are available at the
GPIO matrix shown below. The matrix provides an easy to follow, intuitive, space saving grid of 0.1”
header through-hole pads. Users can solder wires, fit headers or simply insert a scope probe into the
respective pad.
To use the matrix, simply read the port letter from the top or bottom row of text then the pad number
from the columns on the left or right of the matrix. For example, the 1st pad available on Port B is PB5
as highlighted in green below.
Figure 12. GPIO Matrix
If a pad is populated in the matrix, it means this is available for exclusive use as GPIO. The exception to
this are the port pins detailed below which are also shared with switches or user LED’s (shaded red in
the matrix diagram above).
PG2, PG3, PG4, PG5 – User LED’s 1..4
PD0, PD1, PD2, PD3 – HEX Encoder Switch
PA1,PA2, PF9, PF11 – User pushbutton Switches
In addition there are GPIO pins that are shared with the SAI Audio and TWRPI connectors as detailed
below and shaded orange. These are totally available unless the SAI / TWRPI headers are being used.
PA[12..15], PD[4..8], PG[2..5], PK[0..4], PO[0..1]
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
26
Freescale Semiconductor, Inc.
User Interface (I/O)
8.2. User Switches (SW3, SW4, SW6, SW7, P22)
The user pushbutton
switches are in the
bottom left corner of
the EVB
There are 4 active high (pulled low, driven to 3.3V) pushbutton switches (SW3, SW4, SW6, SW7)
connected to a 4 way header (P22) in a box titled “User Switches”. The switches are also directly
connected to MCU ports so no additional wiring is required unless you require to route these to a
different GPIO port.
The switches are connected as follows:
Table 20. User Pushbutton Switches (SW3, SW4, SW6, SW7)
Number
MCU Pin
P18 Connection Pin
1
PA1
Pin1 (UpperMost)
2
PA2
Pin2
3
PF9
Pin3
4
PF11
Pin4
Switch
SW3
SW4
SW6
SW7
NOTE
The MCU ports used on the user pushbutton switches are also routed to
the GPIO matrix.
There are zero ohm resistors on the direct connections between each
switch and the MCU pins. These can be removed if required to isolate the
switch from the respective MCU pin (useful if the switch is being
manually routed to another pin on the GPIO matrix).
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
Freescale Semiconductor, Inc.
27
8.3. Hex Encoder Switch (SW2, J26, P20)
The hex encoder
switch is located
above the user
pushbutton switches
There is a single hex encoded 16 position rotary switch on the EVB. This outputs a binary encoded hex
value (active high) on 4 MCU ports (Port D[0..3]) as well as a 4 pin header P20. There is a jumper J26
which can be used to isolate the supply to the hex encoder if required. This prevents any voltage being
asserted on the MCU pins irrespective of the position of the switch
Position
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
F
Jumper
J26
(3V3)
HEX_SW4
(PD3, P20-4)
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
Table 21. Hex Encoder Switch (SW2)
HEX_SW3
HEX_SW2
(PD2, P20-3)
(PD1, P20-2)
0
0
0
0
0
1
0
1
0
1
1
0
1
1
1
1
0
0
0
0
0
1
0
1
1
0
1
0
1
1
1
1
HEX_SW1
(PD0, P20-1)
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
Table 22. Hex Encoder Switch Power Jumper (J26)
Position
PCB Legend
Description
FITTED (D)
The hex encoder switch is powered with 3.3V (functional)
Removed
The hex encoder switch is not powered and will not drive outputs
NOTE
The MCU ports used on the user pushbutton switches are also routed to
the GPIO matrix.
There are zero ohm resistors on the direct connections between the switch
output and the MCU pins. These can be removed if required to isolate the
switch from the respective MCU pin (useful if the switch is being
manually routed to another pin on the GPIO matrix).
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
28
Freescale Semiconductor, Inc.
User Interface (I/O)
8.4. User LED’s (DS2, DS3, DS7, DS8, P19)
The user LED’s are
above the user
switches in the lower
right quarter
There are four active low user LED’s connected directly to 4 MCU ports (PG[2..5]) as well as to a 4 pin
header.
Table 23. User LEDs (DS2, DS3, DS7, DS8, P19)
Number
MCU Pin
P19 Connection Pin
1
PG2
Pin1 (Upper Pin)
2
PG3
Pin2
3
PG4
Pin3
4
PG5
Pin4
Switch
DS2
DS3
DS7
DS8
NOTE
The MCU ports used on the LEDs are also routed to the GPIO matrix.
There are zero ohm resistors on the direct connections between each LED
and the MCU pins. These can be removed if required to isolate the LED
from the respective MCU pin (useful if the LED is being manually routed
to another pin on the GPIO matrix).
8.5. ADC Input Potentiometer (J17, RV1)
The ADC Pot is to
the right of the user
LED’s in the lower
right corner
There is a small variable resistor RV1 on the EVB which routes a voltage between 0v and 3.3V to MCU
pin PB4. This is useful for quick ADC testing. Jumper J17 which is fitted by default can be removed to
disconnect MCU PB4 from RV1 if desired.
Jumper
J17
Position
FITTED (D)
Removed
Table 24. ADC Input Potentiometer Enable (J19)
PCB Legend
Description
Output from RV1 is routed to MCU PB4 pin
MCU PB4 is not connected to RV1
There is also a test point TP18 connected to the variable resistor output for monitoring purposes.
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
Freescale Semiconductor, Inc.
29
9. MCU Port Pin EVB Functions
The table below shows what each MCU pin is used for on the EVB. Note that not all MCU pins will be
available depending on the device package being used.
No
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
No
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
PortA
SD Card
GPIO 2
GPIO 2
Ethernet
GPIO
SAI Audio
MLB
Ethernet
Ethernet
Ethernet
Ethernet
Ethernet
GPIO 5
GPIO 5
GPIO 5
GPIO 5
PortI
SD Card
SD Card
SD Card
SD Card
USB1
USB1
USB0
USB1
MLB
GPIO
GPIO
Ethernet
GPIO 1
GPIO 1
SAI Audio
SAI Audio
Table 25. Port Pin Functions
PortC
PortD
PortE
JTAG
GPIO 3
MLB
JTAG
GPIO 3
MLB
USB1
GPIO 3
FlexA
USB1
GPIO 3
FlexA
FlexB
GPIO 5
FlexB
FlexA
GPIO 5
FlexB
LIN1
GPIO 5
SD Card
LIN1
GPIO 5
SD Card
RS232
GPIO 5
SAI Audio
RS232
GPIO
SAI Audio
CAN1
GPIO
SAI Audio
CAN1
GPIO
SAI Audio
Flex
GPIO
Ethernet
Flex
GPIO 1
Ethernet
Flex
MLB
USB1
Flex
MLB
USB1
PortB
CAN0
CAN0
LIN0
LIN0
ADC Pot
GPIO
GPIO
GPIO
EXTAL32
XTAL32
SAI Audio
GPIO
GPIO
MLB
MLB
MLB
PortJ
SAI Audio
SAI Audio
SAI Audio
SD Card
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
PortK
GPIO 5
GPIO 5
GPIO 5
GPIO 5
GPIO 5
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
PortL
GPIO
GPIO
NEXUS
NEXUS
NEXUS
NEXUS
NEXUS
NEXUS
JTAG
NEXUS
NEXUS
NEXUS
NEXUS
NEXUS
NEXUS
NEXUS
PortM
NEXUS
NEXUS
NEXUS
GPIO
GPIO
GPIO
GPIO
NEXUS
NEXUS
NEXUS
NEXUS
GPIO
GPIO
GPIO
GPIO
GPIO
1
Shared with MLB header (via no populated zero ohm resistors)
2
Shared with user switches
3
Shared with Hex Encoder Switch
4
Shared with user LED’s
5
Shared with TWRPI (P26, P27) or SAI Audio P25
PortN
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
PortF
SAI Audio
SAI Audio
SAI Audio
SAI Audio
SAI Audio
SAI Audio
SAI Audio
SAI Audio
GPIO
GPIO 2
GPIO
GPIO 2
GPIO
GPIO
Ethernet
Ethernet
PortG
Ethernet
Ethernet
GPIO 4, 5
GPIO 4 , 5
GPIO 4, 5
GPIO 4 , 5
GPIO
GPIO
GPIO
MLB
USB1
USB1
Ethernet
Ethernet
USB1
USB1
PortO
GPIO 5
GPIO 5
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
PortP
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
GPIO
USB0
USB0
USB0
USB0
PortH
Ethernet
Ethernet
Ethernet
SAI Audio
SAI Audio
SAI Audio
MLB
MLB
SD Card
JTAG
JTAG
USB1
USB1
GPIO
GPIO
GPIO
PortQ
USB0
USB0
USB0
USB0
USB0
USB0
USB0
USB0
-
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
30
Freescale Semiconductor, Inc.
Default Jumper Summary Table
10. Default Jumper Summary Table
The following tables detail the default (D) jumper configuration of the EVB and daughtercards
Table 26. Default Jumper Positions (Main Board)
Jumper
J1
J1
J1
J1
J2
J2
J2
J2
J3
J3
J3
J4
J4
J4
Posn 1-2
Posn 3-4
Posn 5-6
Posn 7-8
Posn 1-2
Posn 3-4
Posn 5-6
Posn 7-8
Posn 1-2
Posn 3-4
Posn 5-6
Posn 1-2
Posn 3-4
Posn 5-6
J5
J6 (X1)
J7 (X2)
J8 (RST)
J9 (EN)
J10 (LIN0) 1-2
J10 (LIN0) 3-4
J11 (Master_EN)
J12 (LIN1) 1-2
J12 (LIN1) 3-4
J13 (Master_EN)
J14 (CAN1) 1-2
J14 (CAN1) 3-4
J15 (CAN0) 1-2
J15 (CAN0) 3-4
J16 Posn 1-2
J16 Posn 3-4
J17
J18 (1V25L)
J19 (5V0S)
J20 (3V3L)
J21 (5V0L)
J22 (3V3S)
J23 (INPUT SEL)
J24 (HVA)
J25 (HVB)
J26 (3V3)
Default
Posn
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
1-2 (D)
1-2 (D)
1-2 (D)
1-2 (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
Fitted (D)
1-2 (D)
1-2 (D)
1-2 (D)
Fitted (D)
PCB
Legend
BGE
EN
STBN
WAKE
BGE
EN
STBN
WAKE
TX
TXEN
RX
TX
TXEN
RX
MII
NORM
RX
TX
RX
TX
TX
RX
TX
RX
RX
TX
12V
3V3
3V3
Description
FlexRay B PHY Bus Guardian Enable (Transmitter is enabled)
FlexRay B PHY is enabled
FlexRay B PHY will not enter Standby Mode
FlexRay B PHY Wakeup signal pulled low
FlexRay A PHY Bus Guardian Enable (Transmitter is enabled)
FlexRay A PHY is enabled
FlexRay A PHY will not enter Standby Mode
FlexRay A PHY Wakeup signal pulled low
MCU PC5 is connected to FlexRay A transceiver TX
MCU PE2 is connected to FlexRay A transceiver TXEN
MCU PE3 is connected to FlexRay A transceiver RX
MCU PE4 is connected to FlexRay B transceiver TX
MCU PC4 is connected to FlexRay B transceiver TXEN
MCU PE5 is connected to FlexRay B transceiver RX
Ethernet PHY is configured in MII mode
Ethernet PHY X2 clock is connected to 25MHz xtal
Ethernet PHY X1 clock is connected to 25MHz xtal
The Ethernet PHY will be reset along with MCU reset
Reset from reset switch and debug connectors is active
MCU LIN0_RX signal (PB3) is routed to LIN0 interface
MCU LIN0_TX signal (PB2) is routed to LIN0 interface
LIN0 is configured in Master Mode
MCU LIN1_TX signal (PC7) is routed to LIN1 interface
MCU LIN1_RX signal (PC6) is routed to LIN interface
LIN1 is configured in Master Mode
MCU CAN1_TX signal (PC10) is routed to CAN interface
MCU CAN1_RX signal (PC11) is routed to CAN interface
MCU CAN0_TX signal (PB0) is routed to CAN interface
MCU CAN0_RX signal (PB1) is routed to CAN interface
MCU LIN2_RX signal (PC9) is routed to the FTDI interface
MCU LIN2_TX signal (PC8) is routed to the FTDI interface
Output from RV1 is routed to MCU PB4 pin
1.25V Linear regulator output is routed to daughter card
5.0V Switching regulator output is routed to daughter card
3.3V Linear regulator output is routed to daughter card
5.0V Linear regulator output is routed to daughter card
3.3V Switching regulator output is routed to daughter card
1.25V Linear regulator is powered from main 12V
EVB peripherals in HVA domain are set to use I/O voltage of 3.3V
EVB peripherals in HVB domain are set to use I/O voltage of 3.3V
The hex encoder switch is powered with 3.3V (functional)
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
Freescale Semiconductor, Inc.
31
Table 27. Default Jumper Positions (Daughtercards)
Jumper
1 (XTAL)
J2 (EXTAL)
J3 (ADC0)
J4 (ADC1)
J5 (HVA)
J6 (HVB)
J7 (HVC)
J8 (FLA )
J9 (REG)
J10 (VDDLV)
J11 (DAC)
J12
J13
Default
Posn
1-2 (D)
1-2 (D)
1-2 (D)
1-2 (D)
1-2 (D)
1-2 (D)
1-2 (D)
Fitted (D)
1-2 (D)
1-2 (D)
1-2 (D)
Fitted (D)
1-2 (D)
PCB
Legend
Y1
Y1
3V3
3V3
3V3
3V3
3V3
3V3
REG
HVA
Description
MCU XTAL signal is routed to crystal Y1
MCU EXTAL signal is routed to crystal Y1
MCU ADC0 pin is connected to 3.3V (Linear)
MCU ADC1 pin is connected to 3.3V (Linear)
MCU VDD_HV_A domain is connected to 3.3V (Switching Regulator)
MCU VDD_HV_B domain is connected to 3.3V (Switching Regulator)
MCU VDD_HV_C domain is connected to 3.3V (Switching Regulator)
MCU VDD_HV_FLA pin is connected to 3.3v (Switching Regulator)
MCU ballast transistor collector is connected to 3.3V (Switching)
MCU VDD_LV domain is powered from ballast transistor
MCU VIN1_CMP_REF is powered from VDD_HV_A
Ballast collector supply is enabled (jumper can be used for current measure)
** Only valid on certain devices – External Ballast enabled.
Note that not all jumpers will be present on all of the daughtercards.
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
32
Freescale Semiconductor, Inc.
Default Jumper Diagram
11. Default Jumper Diagram
The diagram below shows the location and configuration of the default jumpers of the main board and
provides an easy to use cross reference. By default all of the jumpers are fitted to the daughtercard (3
way jumpers in position 1-2).
NOTE
Following figure is of an older board revision however there were no
additional jumpers and no jumpers have moved position.
Figure 13. Default Jumper Position
12. Revision History
Date
August 2015
Substantial changes
Initial release
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
Freescale Semiconductor, Inc.
33
13. Appendix
The following EVB schematics are detailed in the following sections:

Main EVB (motherboards)

324BGA Daughtercard

256BGA Daughtercard

176QFP Daughtercard

100QFP Daughtercard (MPC5746C only)
MPC5748G EVB User Guide, User Guide, Rev. 0, 08/2015
34
Freescale Semiconductor, Inc.
Main EVB
5
4
3
2
1
MPC574xx Customer Evaluation Board (X-MPC574XG-MB)
Table Of Contents:
D
Power - Main input and Linear voltage regulators
Power - Switching voltage regulators
Daughter Card Connectors (Sockets)
Reset and External Clock Input
JTAG and Nexus Connectors
Comms - CAN and LIN
Comms - RS232 (USB FTDI interface)
Comms - USB Interfaces
Comms - Ethernet
Comms - FlexRAY
Audio - SAI Audio. AVB and TWRPI headers
AV - MOST Interface
Memory - SD Card Slot
User - Switches, LED's and Potentiometer
User - GPIO Pin Matrix
C
Sheet 2
Sheet 3
Sheet 4
Sheet 5
Sheet 6
Sheet 7
Sheet 8
Sheet 9
Sheet 10
Sheet 11
Sheet 12
Sheet 13
Sheet 14
Sheet 15
Sheet 16
Caution:
These schematics are provided for reference purposes only. As such,
Freescale does not make any warranty, implied or otherwise, as to the
suitability of circuit design or component selection (type or value) used in
these schematics for hardware design using the Freescale MPC574xG family
of Microprocessors. Customers using any part of these schematics as a
basis for hardware design, do so at their own risk and Freescale does not
assume any liability for such a hardware design.
B
Revision Information
Rev Date
0.1 01 Feb 2012
X1 19 Feb 2012
X2 28 Feb 2012
X3 11 Mar 2013
X4 13 Mar 2013
X5 14 Mar 2013
X6 29 Mar 2013
X7 02 Apr 2013
A
17 Apr 2013
AX1 24 Jun 2013
AX2 10 July 2013
AX3 12 July 2013
B
12 July 2013
BX1 20 Aug 2013
C
20 Aug 2013
CX1 18 Dec 2013
CX2 05 May 2014
CX3 25 June 2014
CX4 26 June 2014
CX5 26 June 2014
CX6 18 Aug 2014
CX7 03 Sept 2014
D
24 Sept 2014
D1 14 Aug 2015
Designer
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Comments
Start of capture, Working version
1st release for internal review (Complete Board)
2nd release for internal review (split into main board and DC)
Final review (including new USB transceiver)
Version sent to Pre Layout, incorporating fixes from review
Component consolodation, Few minor changes. Sent to Layout
Changes made during layout to Daughtercard Connectors
LAY RefDes Resequence and SCH BackAnnotate
Post Layout (Back Annotated). Matches PCB RevA
Fixes and changes to RevA Prototype design
Added CAN Term (DNP)
Corrected ground on ADC Pot
Production Release
Change to Ethernet 50MHz clock control
Production Release
CAN transceivers -> MC33901, ENET clock in RMII mode
Added comment about LM1117 VREG output
PH3..5 now GPIO matrix (was SAI), PM4, PD13, PM3 to SAI
Minor changes made during layout (no component changes)
Part Manager Tidy up
Added additional connector with DSPI Signals for AVB
Added additional TWRPI header (Sheet 12)
Released to Production (RevD PCB)
Tidy up Schematics for UM (RevD PCB)
D
C
B
3 Different test points used in design:
TPVx - Through Hole Pad small
TPHx - Through Hile Pad Large (for standard 0.1" header).
Also used on IO Matrix (IOMx)
TPX
- Surface Mount Wire Loop
Notes:
-
A
All components and board processes are to be ROHS compliant
All small capacitors are 0402 unless otherwise stated
All resistors are 0603 5% 0.1w unless otherwise stated. All zero ohm links are 0603
All connectors and headers are denoted Px and are 2.54mm pitch unless otherwise stated
All jumpers are denoted Jx. Jumpers are 2mm pitch
Jumper default positions are shown in the schematics. For 3 way jumpers, default is always posn 1-2.
2 Pin jumpers generally have the "source" on pin 1.
- All switches are denoted SWx
- All test points (SMT wire loop style) are denoted TPx
- Test point Vias (just through hole pads) are denoted TPVx
Signals (ports) have not been routed via busses as this makes it harder to determine where each signal goes.
Automotive Microcontroller Applications
East Kilbride, Scotland
Freescale General Business Use
This document contains information proprietary to Freescale and shall not be used for engineering design,
procurement or manufacture in whole or in part without the express written permission of Freescale
A
Freescale AISG Applications, East Kilbride
Designer:
Drawing Title:
A. Robertson
MPC574xx Customer EVB Main Board
Drawn by:
Page Title:
User notes are given throughtout the schematics.
A. Robertson
Index and Title Page
Specific PCB LAYOUT notes are detailed in ITALICS
Approved:
Size
B
Document Number
Date:
Friday, August 14, 2015
5
A. Robertson
4
3
2
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
1
of
16
5
4
3
2
1
Power Input and Linear Voltage Regulators
Input 12V DC nominal (range 10v - 14v)
See note on schematic sheet 3 regarding 3.3V regulator when running at < 11V)
2
VFused
+
C33
68UF
(CC7343-43
25V)
GND
GND
+ C27
10UF
(35V
TANT)
5V0_LR
P12V
1% resitors
1
ADJ
100
Rfb2
R70
300
1
1
1
1
1
1
1
1
GND
C
3V3_LR
U16
3
Rfb1
R73
1
GND18
4
2
TAB_VOUT
VOUT
1
1
GND17
IN
TAB_VOUT
VOUT
4
2
1% resitors
1
IN
GND16
3.3V Linear Regulator (800mA Max **)
U15
3
GND15
GND
GND Test Points for underside of board
5.0V Linear Regulator (800mA Max **)
P12V
GND14
GND Test Points, Top Side
C32
1000UF
(c200 rad
pol 50V)
2
B
(2 Screw
Connector)
C
GND12
R76
+ C30
10UF
(35V TANT)
0
R274
560
LM1117MPX-ADJ
R272
+ C28
10UF
(35V
TANT)
TP16
ADJ
1
Rfb1
R74
100
R77
Rfb2
R71
158
R271 5.6
+ C31
10UF
(35V TANT)
0
R273
270
Vout = 1.25(1 + (R2/R1))
= 3.295V
DS5
C
TP17
LM1117MPX-ADJ
0
Vout = 1.25(1 + (R2/R1))
= 5.0V
1
1
A
A
P23
D202
B340A
(3A)
1
+
C269
1000pF
(0402 50V)
GND13
Main EVB
Power In
1
Fuse Holder
C268
0.1UF
(0603
50V)
1
F1
1
VSwitched
1
GND1 GND2 GND3 GND4 GND5 GND6 GND7 GND8 GND9 GND10
P12V
L5
27uH (3A)
1
2
1
12V-IN
(10v-14v)
D
GND11
1
2.1mm Barrel
P21 Connector
1
2
3
Test and reference points
(Power Switch)
3
2
5
SW5
1
4
1
Power Supply Input and Filter
C
D
DS6
A
C
LED GREEN
A
LED GREEN
GND
GND
Could also use 2x82 Ohm resistors for RFB2 but not in agile...
B
B
1.25V Linear Regulator (800mA Max **)
R283 1.8K
A
3
2
3
+ C26
10UF
(35V
TANT)
IN
TAB_VOUT
VOUT
ADJ
1% resitors
1
Rfb1
R72 100
DNP
LM1117MPX-ADJ
Rfb2
R284
Vout = 1.25(1 + (R2/R1))
= 1.25V
A
GND
1V25_LR
4
2
0
R75
1
3
1
U14
2
5V0_SR
C
LED GREEN
1
The LM1117 linear regulators provide a maximum output
current of 800mA in ideal conditions. The current
requirement for each regulator is in the region of 10's
of mA (significantly under the maximum rating) so
these regulators will run cool on the EVB.
DS4
J23
P12V
** Notes on Linear Regulator LM1117
Q1
BSH103
P12V
0
DNP
R285
0
+ C29
10UF
(35V TANT)
TP15
R305
1K
Automotive Microcontroller
Applications
East Kilbride, Scotland
1K Load
resistor to
ensure proper
regulation if
1.25V MCU
jumper removed
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
GND
Page Title:
1.25V for External core supply. Simpler to use linear rather than switcher so can safely
power from 5V switcher (slight ripple not an issue) for reduced heat dissipation
5
4
Power Input and Linear Voltage Regulators
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
2
of
16
5
4
3
2
1
Switching Voltage Regulators and Supply Jumpers
Global MCU Daughtercard
Supply Jumpers and DC power
5.0v Switching Regulator
Vout = 1.21(1 + Rfb2/Rfb1) = 4.98V
(All Resistors 1% 0603_CC)
Rfb1 R295
D
R294
1.0K
P12V
0
R268
5V0_SR
Rfb2
R296 1.47K
To Daughtercard
Connectors
GND
R298 1.65K
0
DNP
DC_P12V
2
2
C267
0.1UF
(0603
50V)
ON/OFF SW_OUT
NC
L6
1
1
D5
B340A
0
DNP
MCU_5V0_S
DC_5V0_S
4
DC_5V0_S
4
MCU_3V3_S
4
DC_3V3_S
4
MCU_5V0_L
4
DC_5V0_L
4
MCU_3V3_L
4
DC_3V3_L
4
MCU_1V25_L
4
DC_1V25_L
4
J22
2
1
+ C36
150uF
2
R263
TP19
0
DNP
MCU_3V3_S
DC_3V3_S
5V0_LR
R300
560
APXE100ARA151MF80G
J21
1
2
MCU_5V0_L
1
DS9
C
A
R264
LED GREEN
(12v input, 2.0A Output, 89% Efficient, 11.24w)
GND
C
MCU_5V0_S
D
3V3_SR
27uH
Design requires
B220A-13-F
diode. Use3A
version to
reduce no of
components
A
J27
DNP
5V0_SR
(0603 50V)
FEEDBACK
4
8
10uF
(1210
25V)
5
3
R266
10nF
1
7
C_BOOST
C265
C
6
C34
INPUT
GND
TAB
2
LM2676S-ADJ
4
J19
1
P12V
U17
DC_P12V
0
DNP
DC_5V0_L
3V3_LR
C
J20
1
2
R265
3.3v Switching Regulator
R291
1.0K
R293 1.47K
Rfb2
DC_3V3_L
1V25_LR
Vout = 1.21(1 + Rfb2/Rfb1) = 3.3V
(All Resistors 1% 0603_CC)
Rfb1 R292
0
DNP
MCU_3V3_L
J18
1
0
2
R267
0
DNP
MCU_1V25_L
DC_1V25_L
GND
R297 261.0
P12V
U18
5
J28
DNP
NC
GND
Caution
A
3V3_SR
27uH
2
J24
1
1
0.1UF
(0603
50V)
3V3_SR
L7
1
1
C
10uF
(1210
25V)
Peripheral Power Control
10nF
(0603 50V)
FEEDBACK
ON/OFF SW_OUT
C264
D6
B340A
+ C37
150uF
TP20
R299
270
APXE100ARA151MF80G
J25
PER_HVA
1
2
5V0_SR
PER_HVB
B
2
3
3
DS10
1
B
3
A
C266
2
C35
C_BOOST
GND
TAB
6
7
LM2676S-ADJ
INPUT
4
8
2
C
(12v input, 2A Output, 83% Efficient)
A
These jumpers control the voltage of the
peripherals connected to MCU pads in the
VDD_HV_A / HV_B domains and are required
so the respective jumpers at the MCU can
be used for MCU current measurement.
LED GREEN
The 3.3v regulator design is optimised for an input voltage of 12V. If
the input voltage drops below approx 11V, the 3.3v output voltage
ripple may increase. This can be reduced by increasing the bulk storage
capacitor if required.
The settings on these jumpers must
mirror the setting of the respective
MCU VDD_HV_A / HB_V jumpers
Automotive Microcontroller
Applications
East Kilbride, Scotland
Using Adjustable version of LM2676 rather than fixed 3.3V /
5V regulators to reduce number of components in BOM.
A
Freescale General Business Use
Drawing Title:
Where possible, components have been shared accross the
regulator designs to further reduce component count.
MPC574xx Customer EVB Main Board
Page Title:
Switching Voltage Regulators
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
3
of
16
5
4
3
2
1
Daughter Card Connectors (Sockets)
Notes:
- there was no neat way to fit these connectors onto a B sized sheet so unfortunately the sheet size has been
increased to C so will need to be printed on larger paper.
- The MCU Clock circuitry (apart from external clock) is local to the daughtercard so not pinned out on the
connectors
- Power is supplied to the daughtercard via MCU specific jumpered supplies (left connector) or direct supplies
from the regulators (right connector)
D
D
P12
5
C
EXT-CLK
7
PB2
16
14
14
16
16
14
14
16
11
14
16
8
16
PP11
PE6
PI3
PP10
PP5
PI1
PI2
PP9
PC13
PI0
PK10
PC8
PK13
16
16
11
16
PP2
PK15
PC15
PP7
16
PP6
16
16
16
16
16
PO12
PO7
PO10
PO4
PO9
12,15,16
16
12,16
9
16
PG5
PO14
PO0
PI7
PP0
13
9
16
12
12,15,16
PE1
PI6
PO5
PE11
PG3
12
PE8
13
14
PG9
PA0
16
16
7
PG7
PG8
PC10
7
12,16
PB1
PK2
16
12,16
16
16
16
PF13
PK4
PK6
PK8
PN14
15,16
12,16
16
PF9
PA14
PN13
16
16
16
12,16
16
16
PN11
PJ11
PJ10
PK0
PJ9
PN9
16
16
PJ13
PA4
16
12,16
16
16
PN10
PA15
PN3
PN6
16
12
PN0
PB10
B
3
MCU_5V0_S
3
MCU_1V25_L
P13
(GND)
EXT-CLK
(GND)
PB2
(GND)
PP11
PE6
PI3
PP10
PP5
PI1
PI2
PP9
PC13
PI0
PK10
PC8
PK13
(GND)
PP2
PK15
PC15
PP7
(GND)
PP6
(GND)
PO12
PO7
PO10
PO4
PO9
(GND)
SH1
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH3
SH2
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH4
(GND)
(GND)
PH7
PH6
PB3
PH8
PP8
(GND)
PP3
PE7
PK9
(GND)
PC12
PK11
(GND)
PP4
PK14
PK12
PC9
PL0
(GND)
PP1
(GND)
PC14
PJ4
(GND)
PO11
PO8
(GND)
PH14
PO13
(GND)
(GND)
PG5
PO14
PO0
PI7
PP0
(GND)
PE1
PI6
PO5
PE11
PG3
(GND)
PE8
(GND)
PG9
PA0
(GND)
PG7
PG8
PC10
(GND)
(GND)
PB1
PK2
(GND)
PF13
PK4
PK6
PK8
PN14
(GND)
SH5
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH7
SH6
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH8
(GND)
PO1
PH13
PG4
PH15
PO15
PE10
PE0
PO6
(GND)
PG2
PA2
PE9
PA1
MCU-RSTx
PN15
PO3
(GND)
PG6
PC11
PO2
(GND)
PB0
PK1
PF12
(GND)
(GND)
(GND)
PK3
PK5
PF11
(GND)
(GND)
PF9
PA14
PN13
(GND)
PN11
PJ11
PJ10
PK0
PJ9
PN9
(GND)
PJ13
PA4
(GND)
PN10
PA15
PN3
PN6
(GND)
PN0
PB10
(GND)
(GND)
(GND)
(GND)
SH9
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH11
SH10
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH12
(GND)
PK7
PC6
PF8
(GND)
PC7
PN12
PJ12
(GND)
PJ15
(GND)
PN8
PF10
PN7
PJ14
(GND)
PN4
PA13
(GND)
PN5
PA12
PN2
PF1
PF0
(GND)
(GND)
MCU_3V3_S
MCU_5V0_S
MCU_1V25_L
(GND)
MCU_3V3_L
MCU_5V0_L
(GND)
PH7
PH6
PB3
PH8
PP8
13
13
7
14
16
PP3
PE7
PK9
16
14
16
PC12
PK11
11
16
PP4
PK14
PK12
PC9
PL0
16
16
16
8
16
PP1
16
PC14
PJ4
11
16
PO11
PO8
16
16
PH14
PO13
16
16
PO1
PH13
PG4
PH15
PO15
PE10
PE0
PO6
12,16
16
12,15,16
16
16
12
13
16
PG2
PA2
PE9
PA1
MCU-RSTx
PN15
PO3
12,15,16
15,16
12
15,16
5,6
16
16
PG6
PC11
PO2
16
7
16
PB0
PK1
PF12
7
12,16
16
PK3
PK5
PF11
12,16
16
15,16
PK7
PC6
PF8
16
6
16
11
16
9
9
11
PM11
PH10
PH4
PE5
PM12
PI5
PQ0
PC5
9
9
11
PG14
PH12
PC4
6
9
13
6
9
12
9
9
9
9
9
9
PL9
PC2
PA6
PL3
PH11
PA5
PE14
PQ4
PG15
PQ5
PQ7
PP15
6
6
6
6
PL12
PL11
PL6
PL7
6
6
6
10
10
PL15
PM1
PM2
PE12
PA11
10
10
10
10
10
10
10
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
6
16
12,16
16
16
16
PM8
PH3
PM3
PM6
PM13
PM14
12,13,16
16
10
16
PD13
PD12
PI11
PD10
13
13
13
MLB_DAT
MLB_SIG
MLB_CLK
16
7
16
13
13
MLB_SN
MLB_SP
PC7
PN12
PJ12
7
16
16
12,16
16
12
PD7
PJ5
PJ0
PJ15
16
PN8
PF10
PN7
PJ14
16
16
16
16
12,16
16
16
15,16
12
PD5
PB5
PB11
PD1
PJ1
PN4
PA13
16
12,16
PN5
PA12
PN2
PF1
PF0
16
12,16
16
12
12
12,16
16
12
15
12
12
PD8
PI9
PF5
PB4
PJ2
PJ3
MCU_3V3_S
3
MCU_3V3_L
MCU_5V0_L
3
3
12
16
PF2
PM15
3
DC_5V0_S
3
3
DC_P12V
DC_1V25_L
(GND)
PM11
PH10
PH4
PE5
PM12
PI5
PQ0
PC5
(GND)
PG14
PH12
PC4
(GND)
PL9
PC2
PA6
PL3
PH11
PA5
PE14
PQ4
PG15
PQ5
PQ7
PP15
(GND)
PL12
PL11
PL6
PL7
(GND)
SH1
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH3
SH2
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH4
(GND)
PC1
PE3
PH5
PC0
PQ3
PC3
PE4
PH9
PL10
PE15
PORSTx
PE2
PL4
PG11
PQ1
(GND)
PG10
PQ2
PL8
PQ6
(GND)
PP13
PP12
PI4
PP14
(GND)
PL2
PL5
PL13
PM0
(GND)
(GND)
PL15
PM1
PM2
PE12
PA11
(GND)
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
(GND)
PM8
PH3
PM3
PM6
PM13
PM14
(GND)
PD13
PD12
PI11
PD10
(GND)
MLB_DAT
MLB_SIG
MLB_CLK
(GND)
(GND)
SH5
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH7
SH6
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH8
(GND)
PL14
PM9
PM7
PA10
PA9
PA8
PF14
PG0-R
PH2-R
(GND)
PG12-R
PG13-R
(GND)
(GND)
PM10
PM4
PL1
(GND)
PM5
PI13
PB12
PD9
PI12
PB7
PI15
(GND)
MLB_CN
MLB_CP
(GND)
(GND)
(GND)
SH9
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH11
SH10
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH12
(GND)
MLB_DN
MLB_DP
(GND)
(GND)
PI14
PJ7
PD11
PJ6
PD6
PD2
PD3
PJ8
(GND)
PB6
PD0
PI10
(GND)
PD4
PF6
PN1
(GND)
PF4
PF7
PF3
(GND)
(GND)
DC_3V3_S
(GND)
MLB_SN
MLB_SP
(GND)
(GND)
PD7
PJ5
PJ0
(GND)
PD5
PB5
PB11
PD1
PJ1
(GND)
PD8
PI9
PF5
PB4
PJ2
PJ3
(GND)
(GND)
PF2
PM15
(GND)
(GND)
DC_5V0_S
DC_P12V
DC_1V25_L
CON SKT 180
GND
6
11
16
6
9
9
11
6
6
9
5
11
6
9
9
PG10
PQ2
PL8
PQ6
9
9
6
9
PP13
PP12
PI4
PP14
9
9
9
9
PL2
PL5
PL13
PM0
6
6
6
6
PL14
PM9
PM7
PA10
PA9
PA8
PF14
PG0-R
PH2-R
6
6
6
10
10
10
10
10
10
PG12-R
PG13-R
10
10
PM10
PM4
PL1
6
12,16
16
PM5
PI13
PB12
PD9
PI12
PB7
PI15
16
13,16
16
16
13,16
16
12
MLB_CN
MLB_CP
13
13
MLB_DN
MLB_DP
13
13
PI14
PJ7
PD11
PJ6
PD6
PD2
PD3
PJ8
12
16
16
16
12,16
15,16
15,16
16
PB6
PD0
PI10
16
15,16
16
PD4
PF6
PN1
12,16
12
16
PF4
PF7
PF3
12
12
12
C
B
DC_3V3_S
3
DC_3V3_L
DC_5V0_L
3
3
CON SKT 180
Socket
A
DC_3V3_L
DC_5V0_L
PC1
PE3
PH5
PC0
PQ3
PC3
PE4
PH9
PL10
PE15
PORSTx
PE2
PL4
PG11
PQ1
Socket
GND
A
GND
GND
Not routed through the connectors:
- Crystal signals
- Specific MCU power pins (Power supplies are however taken to daughtercard)
Automotive Microcontroller
Applications
East Kilbride, Scotland
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
Daughter Card Connectors (Sockets)
5
4
3
2
Size
C
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Sheet
1
Rev
D1
PDF: SPF-27897
4
of
16
5
4
3
2
1
Reset and External Clock In
Reset is in the
VDD_HVA domain.
Reset Input / Output
PER_HVA
PORST
PER_HVA
D
Connect an external LVI to pad
when supplying external 1.25V so
that PORST is asserted until
exterbal 1.25V supply is at
threshold and stable
3V3_SR
R31
10.0K
D
TPH1
R217
270
A
C224 (0603
0.1UF 50V)
R16
10.0K
R24
10.0K
GND
JTAG-RSTx
JTAG-RSTx
1
RST-SWITCHx
2
7
SYSTEM-RSTx
VCC
3
MR
RESET
GND
4
Reset Switch
1
1
SW1
C
C3
0.1UF
R4
10.0K
4
2
GND
GND
4
RST-INx
1
2
MCU-RSTx
MCU-RSTx
4,6
Tri-State Buffered
RESET signal to
reset the MCU
Buffered RESET-out
2
B3WN-6002
PORSTx
Bi Directional reset
line to/from MCU
J9
GND
SN74LVC2G08DCT
(1.65 to 5.5v operation)
PORSTx
GND
U3
U4A
VCC
C
6
TARGET
RESET
LED
8
Reset from
Debugger
DS1
YELLOW LED
1
C220 (0603
0.1UF 50V)
ADM6315-26D2ARTZR7
(2.5 to 5v operation)
Active reset drive (high / low)
for any periperhals that need to
be reset when MCU is in reset
TPV5
C
3V3_SR
(0603
50V)
D1
R214 270
Note:
A
C
GND
The Reset pad on the MPC5748G is in the VDD_HV_A domain which can be run from either
3.3V or 5V (selected by the VDD_HV_A and PER_HVA jumpers)
LED RED
(MCU RESET)
U4B
To maintian brightness on the LED's irrespective of the voltage setting, the LED's are
powered from constant 3.3V, grounded via the reset line.
5
3
RST-OUTx
6
RST-OUTx
10,12
EXT-CLK
4
SN74LVC2G08DCT
External Clock In (SMA)
EXT-CLK
B
B
1
R216
100
P7
5
4
2
3
CON 1 SMA
SMA style
Connector
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
Reset Circuitry & External Clock In
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
5
of
16
5
4
3
2
1
Debug Connectors (JTAG and NEXUS)
JTAG Standard 14-pin Connector
(All JTAG reset pullups are on Reset Page)
Voltage Domains:
PER_HVA
D
Note on EVTI:
R44
10.0K
R41
10.0K
R15
10.0K
EVTI is an optional
signal. Although it is
supported on the JTAG
connector, tools vendors
do not normally use EVTI
on non trace hardware.
ONCE Connector
P8
4
4
4
4
5
4,5
PC0
PC1
PH9
PL8
JTAG-RSTx
MCU-RSTx
PC0
PC1
PH9
PL8
TDI
TDO
TCLK
EVTI
JTAG-RSTx
(buffered
reset TO MCU)
MCU-RSTx
(bidirectional
MCU reset)
R19
0 DNP
R3
0
R2
0
(TDI)
(TDO)
(TCLK)
(EVTI)
(RESET)
(VREF)
(RDY)
EVTI
DBUG-RSTx
R30
10.0K
DNP
C17
47PF
C20
47PF
DNP
DNP
Optional
Config
1
3
5
7
9
11
13
2
4
6
8
10
12
14
(GND)
(GND)
(GND)
(N/C)
(TMS)
PH10
(GND)
(JCOMP) JCOMP
CON_2X7
EVTI is powered from
VDD_HV_B whereas the
rest of the JTAG signals
are from VDD_HV_A. In
order to use EVTI on the
JTAG, connector,
VDD_HV_A and HV_B should
be set to the same
voltage. Rather than
impose this limitation
for all customers, a
zero ohm link has been
added to allow EVTI to
be enabled on the JTAG
connector if required.
R1
10.0K
Place One CAP
next to each
connector
C
GND
4
PH10
4
PL12
PH10
TMS
All of the signals used for JTAG (with the
exception of EVTI, see note) are powered from
the VDD_HV_A domain. All of the additional
signals used for Nexus are powered from
VDD_HV_B.
D
If you are using Nexus, you need to ensure that
the VDD_HV_A and VDD_HV_B domains are at the
same voltage as well as ensuring that the
peripheral supplies PER_HVA and PER_HVB match
VDD_HV_A / B. See the MCU power page for
configuration jumpers.
C
NEXUS 50-pin Connector
PL12
PER_HVB
PER_HVB
P10
B
4
4
PL9
PL11
4
4
PL2
PL3
4
4
PL4
PL5
4
4
PL10
PL6
4
4
PL7
PL13
4
4
PL14
PL15
4
4
PM0
PM1
4
4
PM2
PM7
4
PM10
PL9
PL11
PL2
PL3
PL4
PL5
PL10
PL6
PL7
PL13
PL14
PL15
PM0
PM1
PM2
PM7
PM10
(MSEO_0)
(MSEO_1)
(GND)
(MDO0)
(MDO1)
(GND)
(MDO2)
(MDO3)
(GND)
(MCKO)
(MDO4)
(GND)
(MDO5)
(MDO6)
(GND)
(MDO7)
(MDO8)
(GND)
(MDO9)
(MDO10)
(GND)
(MDO11)
(MDO12)
(GND)
(MDO15)
S1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
S2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
(GND)
(VREF)
(TCK)
(TMS)
(TDI)
(TDO)
(JCOMP)
(RDY)
(EVTI)
(EVTO)
(RESET)
(RST OUT)
(GND)
(CLKOUT)
(TD/WT)
(GND)
(DAI1)
(DAI2)
(GND)
(ARBREQ)
(ARBGRT)
(GND)
(MDO13)
(MDO14)
(GND)
(N/C)
(GND)
PH9
PH10
PC0
PC1
JCOMP
PL8
PL12
DBUG-RSTx
MCU-RSTx
TPV11
PM8
PM9
R245
R235
R225
R236
R226
R237
R227
R238
R228
R239
R229
R240
R230
R241
R231
R242
R232
R243
R247
R246
PL12
PL9
PL11
PL2
PL3
PL4
PL5
PL10
PL6
PL7
PL13
PL14
PL15
PM0
PM1
PM2
PM7
PM10
PM9
PM8
B
Neus
Specific
Pullups all
10K 0603
CON 2X25
GND
A
4
4
PM9
PM8
Nexus
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
PM9
PM8
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
Debug Connectors (JTAG & Nexus)
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
6
of
16
5
4
CAN & LIN Physical
3
CAN0 Physical Interface
VDD
2
PER_HVA
5V0_SR
- 5.0V input supply for CAN transceiver (4.5 to 5.5V)
VI/O - determines the signal level on MCU TX and RX pins
and can range from 2.8 to 5.5V
C255
0.1UF
C270
1uF
C254
0.1UF
C271
1uF
(0603
50V)
STB - High for Standby mode, pulled low for normal mode.
(0603
50V)
PB0
PB1
(CAN0_TX)
(CAN0_RX)
1
3
2
4
R59
CAN0_TX
1
CAN0_RX
4
TXD
STB
TPV16
CAN termination resistor
footprint. Place on
underside of PCB
D
R307 120
CANH
CANL
7
CAN0-CANH
6
CAN0-CANL
DNP
P15
1
2
3
HDR_1X3
GND
MC33901WEF
2
GND
All CAN and LIN signals are
in power domain VDD_HV_A.
5
RXD
8
4.70K CAN0-S
GND
VIO
PB0
PB1
VDD
U12
J15
GND
GND
3
D
4
4
1
GND
CAN1 Physical Interface
- 5.0V input supply for CAN transceiver (4.5 to 5.5V)
C257
0.1UF
C273
1uF
VI/O - determines the signal level on MCU TX and RX pins
and can range from 2.8 to 5.5V
4
4
PC10
PC11
1
3
2
4
U11
R58
CAN1_TX
1
CAN1_RX
4
8
4.70K CAN1-S
TPV15
TXD
C
R306 120
RXD
CANH
STB
CANL
7
6
CAN1-CANH
DNP
P14
1
2
3
CAN1-CANL
HDR_1X3
GND
MC33901WEF
2
GND
CAN termination resistor
footprint. Place on
underside of PCB
GND
VIO
GND
J14
(CAN1_TX)
(CAN1_RX)
(0603
50V)
5
STB - High for Standby mode, pulled low for normal mode.
3
(0603
50V)
C
PC10
PC11
C256
0.1UF
C272
1uF
VDD
VDD
PER_HVA
5V0_SR
GND
All interfaces will work at
3.3V or 5.0V (PER_HVA
jumper)
GND
MC33662LEF LIN transceiver is newer version of 33661 offering:
LIN0 Physical Interface
Master Mode Pullup Enable
J11
PER_HVA
B
1
J10
4
4
PB3
PB2
PB3
PB2
(LIN0_RX)
(LIN0_TX)
1
3
2
D200 GF1A
A
C
U6
2
4
LIN0-RX
(Enable)
(Wake)
LIN0-TX
1
2
3
4
RXD
EN
WAKE
TXD
INH
VSUP
LIN
GND
MC33662LEF
(LEF = 20K Baud)
GND
C
D2
8
7
6
5
C231
0.1UF
GND
C234
1000pF
(0402
50V)
(0603
50V)
EN = PER_HVA enables Transceiver and sets I/O for VDD_HV_A
WAKE = GND ensures no spurious wakeups
R25
2.0K
R221
2.0K
A
GF1A
P9
1
2
3
4
LIN0-VSUP
LIN0-LIN
Battery
Reverse
polarity &
Pulse
Protection
Total current
through resistors
(LIN Bus at GND)
= 12mA (0.144W)
-
Full LIN compliance (33661 no longer compliant)
Improved ESD protection on LIN pin up to 15KV
Improved ESD on Wake and VSUP Pins
Other EMC and performance improvements
B
See freescale.com for more details
CON PLUG 4
GND
LIN Molex
Connector
Each resistor spec
= 0.1W (0.2W total)
GND
LIN1 Physical Interface
Master Mode Pullup Enable
J13
PER_HVA
1
J12
4
4
A
PC7
PC6
PC7
PC6
(LIN1_RX)
(LIN1_TX)
1
3
2
D201
A
GF1A
C
U10
2
4
LIN1-RX
(Enable)
(Wake)
LIN1-TX
(TXD_0)
GND
1
2
3
4
RXD
EN
WAKE
TXD
INH
VSUP
LIN
GND
MC33662LEF
(LEF = 20K Baud)
EN = PER_HVA enables Transceiver and sets I/O for VDD_HV_A
WAKE = GND ensures no spurious wakeups
C
D3
8
7
6
5
GND
C248
0.1UF
C249
1000pF
(0402
50V)
(0603
50V)
R248
2.0K
R249
2.0K
A
GF1A
Battery
Reverse
polarity &
Pulse
Protection
P11
1
2
3
4
LIN1-VSUP
LIN1-LIN
Total current
through resistors
(LIN Bus at GND)
= 12mA (0.144W)
Each resistor spec
= 0.1W (0.2W total)
CON PLUG 4
GND
4
3
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
LIN Molex
Connector
GND
5
Automotive Microcontroller
Applications
East Kilbride, Scotland
2
Page Title:
CAN and LIN
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
7
of
16
5
4
3
2
1
USB RS232 (serial) Interface
- Self Powered mode. No power is taken from USB
- Device efaults to Dual serial (RS232) mode ie RS232 on both A and B
- Configurable I/O voltage on CHA / CHB via VDDIOA/B
5V0_SR
PER_HVA
D4
BGX50A
D1
D4
D3
C258 (0603
0.1UF 50V)
R251
470
4
R69 27
USB_RN
USB_RP
C263
0.1UF
(0603
50V)
(0603
50V)
5V0_SR
GND
1.0M
X1
6 MHZ
2
R255
10.0K
CLK_XTIN_6M
43
CLK_XTOUT_6M
44
C259
0.1UF
C260
0.1UF
(0603
50V)
(0603
50V)
GND
48
1
2
GND
R252 10.0K
47
31
USBDP
ADBUS0
ADBUS1
ADBUS2
ADBUS3
ADBUS4
ADBUS5
ADBUS6
ADBUS7
ACBUS0
ACBUS1
ACBUS2
ACBUS3
SI/WUA
RSTOUT#
RESET#
BDBUS0
BDBUS1
BDBUS2
BDBUS3
BDBUS4
BDBUS5
BDBUS6
BDBUS7
XTIN
XTOUT
EECS
EESK
EEDATA
TEST
GND
VCCIOB
42
14
3
USBDM
R66
GND
5
4
1
4
1
R256
4.70K
47PF 47PF
DNP DNP
GND
R67
1.5K
C24
USB_TYPE_B
8
7
R68 27
C23
C262
0.1UF
BCBUS0
BCBUS1
BCBUS2
BCBUS3
SI/WUB
GND1
GND2
GND3
GND4
USB_N
USB_P
3
3
2
S2
2
3
4
1
S1
VCCIOA
P17
3V3OUT
VCC2
6
VCC1
3
2
U13
GND
GND
-D
+D
G
V
+ C22
10UF
C261
0.033UF
46
1
2
D2
L201
470OHM
DNP
GND
C
D
5V0_SR
AVCC
FTDI interface will
work at 3.3V or 5.0V
(PER_HVA jumper)
1
D
FTDI USB <-> Serial Interface
AGND
All Signals are in
power domain
VDD_HV_A.
PWREN#
FT2232D
9
18
25
34
45
B
P18
1
3
5
2
4
6
24
23
22
21
20
19
17
16
BUS0
BUS1
BUS2
BUS3
BUS4
BUS5
15
13
12
11
10
Send Immediate / Wakeup
Disabled for CHA
PER_HVA
40
39
38
37
36
35
33
32
FTDI_TXD
FTDI_RXD
30
29
28
27
26
Send Immediate / Wakeup
Disabled for CHB
PER_HVA
HDR 2X3
DNP
FTDI Pin 40 (TXD)
is Output from
FTDI Device,
connect to MCU RXD
C
FTDI Pin 39 (RXD)
is Input to FTDI
device, connect to
MCU TXD
R254 10.0K
J16
1
3
2
4
(MCU_LIN2RX)
(MCU_LIN2TX)
PC9
PC8
PC9
PC8
4
4
5V0_SR
R253 10.0K
41
R250 10.0K
DNP
Disable Receiver when
in USB suspend mode
B
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
USB RS232 Interface
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
8
of
16
5
4
3
2
1
USB (Type A Host and Type AB OTG)
3V3_SR
(0603
50V)
GND
4
4
4
4
4
4
4
4
PG14
PG15
PE14
PE15
PG10
PG11
PH11
PH12
4
4
4
4
PC3
PI4
PI5
PC2
4
PI7
(USB1_DO)
(USB1_D1)
(USB1_D2)
(USB1_D3)
(USB1_D4)
(USB1_D5)
(USB1_D6)
(USB1_D7)
PC3
PI4
PI5
PC2
R49
(USB1_DIR)
31
(USB1_STP)
29
(USB1_NXT)
2
USB1_CLK 1
30
PI7
(USB1_RST Active Low)
R46
10.0K
C14
R33
10
2
33PF Y3
24MHZ
C
3
4
5
6
7
9
10
13
PG14
PG15
PE14
PE15
PG10
PG11
PH11
PH12
27
A_XO 25
A_XI 26
16
15
33PF
1
3V3_SR
R26
1.0M
C13
DATA0
DATA1
DATA2
DATA3
DATA4
DATA5
DATA6
DATA7
DM
DP
ID
VDD3V3_20
RESET
VDD1V8_28
VDD1V8_30
SPK_R
SPK_L
Crystals are
FOXSDLF/240F-20
(20pF Load
Capacitance)
USB Host, Type A
D
(Available on all packages)
GND
REFSEL0
REFSEL1
REFSEL2
VBUS
XO
REFCLK/XI
Adobe Acrobat
Document
(35V
TANT)
3V3_SR
CPEN
DIR
STP
NXT
CLKOUT
General Layout Note. Recommendation is to keep all
tracks between MCU and USB PHI less than 3" See
additional SMSC Layout guidelines PDF to the right
C230
+ 10UF
(0603
50V)
VBAT_5V
U7
21
32
(Layout Note: Place Series
Termination resistor close
to USB IC)
C236
0.1UF
C243
0.1UF
VDDIO
The USB
interface
only supports
3.3V
operation.
All I/O
signals must
be 3.3V. If
VDD_HVA is
set to 5V,
USB MCU pads
must be left
as tri-state
with no
pullups.
C239
10UF +
(35V
TANT)
RBIAS
8
11
14
17
USB_A_EN
22
USB_A_VBUS
19
18
23
(1/10W 0603)
USB_A_DM
USB_A_DP
(ID=GND for HOST mode)
20
USB_A_VDD3.3
28
30
USB_TYPE_A_FEMALE
(Layout Note: Route DP and DM with
90 Ohm Differential Pair. Keep
tracks as short as possible)
(Select 60MHz CLKOUT
with 24MHz XTAL)
P5
S1
R36
20K
L4
C8
C9
100UF 1.0UF
1
(16V (16V (0402
TANT) TANT) 50v)
+
+
C10
1000pF
(20K for HOST)
26OHM
2
C216
10UF
(35V
TANT)
C214
1000pF
USB_A_5V
USB_A_DM
USB_A_DP
V
D-
D+
G
S2
A1
A2
A3
A4
+
C206
1000pf
(1210
2KV)
R213
100
GND
GND
(50V
0402)
USB_A_VDD1.8
GND
GND
GND
24
C
NC
R38
8.06K
1%
12
C238
1uF
(10V
0603
low
ESR)
USB83340
33
D
5V0_SR
PAD_GND
USB Signals
are in
power
domain
VDD_HV_A
GND
GND
GND
Layout Note:
Place caps &
resistor as
close to
device as
possible
C19
1uF
(10V
0603
low
ESR)
GND
GND
USB OTG Micro AB
(Only available on BGA packages)
5V0_SR
U9
(0603
50V)
(0603
50V)
GND
PP15
PP14
PP13
PP12
PQ7
PQ6
PQ5
PQ4
4
4
4
4
PQ2
PQ0
PQ3
PQ1
4
PI6
PP15
PP14
PP13
PP12
PQ7
PQ6
PQ5
PQ4
(USB0_DO)
(USB0_D1)
(USB0_D2)
(USB0_D3)
(USB0_D4)
(USB0_D5)
(USB0_D6)
(USB0_D7)
3
4
5
6
7
9
10
13
PQ2
PQ0
PQ3
PQ1
R48
(USB0_DIR)
(USB0_STP)
(USB0_NXT)
30 USB0_CLK
31
29
2
1
PI6
(USB0_RST Active Low)
C16
2
33PF Y4
24MHZ
R47
10.0K
B_XO 25
B_XI 26
16
15
33PF
C15
1
3V3_SR
A
R32
10
27
R27
1.0M
DATA0
DATA1
DATA2
DATA3
DATA4
DATA5
DATA6
DATA7
REFSEL0
REFSEL1
REFSEL2
DM
DP
ID
VDD3V3_20
RESET
VDD1V8_28
VDD1V8_30
XO
REFCLK/XI
SPK_R
SPK_L
Crystals are
FOXSDLF/240F-20
(20pF Load
Capacitance)
GND
(35V
TANT)
USB_A_EN
1
USB_B_EN
4
(0603
50V)
GND
VBUS
DIR
STP
NXT
CLKOUT
C246
0.1UF
C247
+ 10UF
(35V
TANT)
7
3V3_SR
CPEN
33
4
4
4
4
4
4
4
4
C244
+ 10UF
6
VBAT_5V
U8
21
32
C235
0.1UF
VDDIO
B
C242
0.1UF
PAD_GND
(Layout Note: Place Series
Termination resistor close
to USB IC)
C245
10UF +
(35V
TANT)
RBIAS
NC
GND
8
11
14
USB Power Switch
17
USB_B_EN
22
USB_B_VBUS
R37
USB_B_DM
USB_B_DP
USB_B_ID
(1/10W 0603)
20
USB_B_VDD3.3
1.0K
C237
1uF
(10V
0603
low
ESR)
USB83340
GND
GND
GND
OUTA
OUTB
FLG_A
TPV12
3
FLG_B
TPV13
8
USB_A_PWR
5
USB_B_PWR
6
MIC2026-1YM
4
SHELL2
SHELL1
SHELL3
SHELL4
C2
1000pf
(1210
2KV)
8
9
R202
100
B
GND
USB AB 5
C18
1uF
(10V
0603
low
ESR)
GND
Layout Note:
Place caps &
resistor as
close to
device as
possible
L3
C212 C5
100UF 1.0UF
1
(16V (16V (0402
TANT) TANT) 50v)
+
+
C4
1000pF
GND
26OHM
2
C205
10UF
(35V
TANT)
+
3
Automotive Microcontroller
Applications
East Kilbride, Scotland
C1
1000pF
(50V
0402)
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
GND
GND
Page Title:
USB Type A / Type AB
GND
5
P1
7
GND
USB_B_ID
USB_B_DP
USB_B_DM
USB_B_5V
USB_B_VDD1.8
R39
8.06K
1%
IN
FLGB
2
(1K for OTG)
24
12
ENB
FLGA
(Layout Note: Route DP and DM with
90 Ohm Differential Pair. Keep
tracks as short as possible)
19
18
23
28
30
ENA
GND
ID
D+
DVBUS
5V0_SR
5
4
3
2
1
3V3_SR
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
9
of
16
5
4
3
2
1
Ethernet
1
Layout Note - Place Caps
and Resistors close to PHI
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
PG1
4
4
4
4
4
4
4
4
4
PE13
PA7
PA8
PA9
PF15
PA11
PA10
PE12
PA3
PE13
PA7
PA8
PA9
PF15
PA11
PA10
PE12
PA3
C
4
4
PG0-R
PF14
(Termination
(Termination
(Termination
(Termination
(Termination
on
on
on
on
on
DC)
DC)
DC)
DC)
DC)
** See Layout Note
(bottom right)
R45
R80
R43
R42
R40
R35
R17
R28
R34
R20
R5
50
50
50
50
50
50
50
50
50
50
50
MCU Output
Resistors Next
to MCU on
daughtercard
CLKIN_X1 34
33
X2
(+MII)
(+MII)
(RMII)
(RMII)
(RMII)
(RMII)
(TXD3)
(TXD2)
(TXD1)
(TXD0)
(TXEN)
TXCLK
6
5
4
3
2
1
(+MII)
(+MII)
(RMII)
(RMII)
(RMII)
(RMII)
(+MII)
(RMII)
(+MII)
RXD3
RXD2
RXD1
RXD0
RXDV
RXER
COL
CRS
RXCLK
46
45
44
43
39
41
42
40
38
(RMII)
(RMII)
(MDC)
(MDIO)
31
30
DNP
(Termination on DC)
PG0-R
PF14
(RMII)
(+MII)
PHI Output
Place Next to
PHI
29
7
X1
X2
10/100 single phy
GND
25MHZ_OUT
TXD3_SNIMODE
TXD2
TXD1
TXD0
TXEN
TXCLK
dp83848c
TDP
TDN
RDP
RDN
RXD3_PHYAD3
RXD2_PHYAD2
RXD1_PHYAD1 LEDACTCOL_ANEN
RXD0_PHYAD1
LEDLINK_AN0
RXDV_MIIMODE LEDSPEED_AN1
RXER_MDIXEN
COL_PHYAD0
PFBOUT
CRS_LEDCFG
RXCLK
PFBIN1
PFBIN2
MDC
MDIO
RESET
PWRDN_INT
RBIAS
19
15
36
35
47
Series Termination Resistors:
50 Ohms as per TI spec. Place
resistors as close to driving
source as possible. Termination
recommended for ALL MII signals
25
TDP
TDN
14
13
RDP
RDN
28
26
27
LED_Y
LED_G
23
PFBOUT
RST-OUTx
4
PI11
3
3V3_SR
1
2
3
4
5
6
7
8
3V3_SR
R234
49.9
1%
18
37
C233
0.1UF
C11
0.1UF
C6
0.1UF
(0603
50V)
(0603
50V)
(0603
50V)
TD+
TDGND1
CT_3
GND_4
GND_5
CT_6
RD+
GND2
RD-
CG1
CG2
C
GND
R222
270
R223
270
3V3_SR
GND
3V3_SR
GND
24
Place Caps close
to connector
RBIAS
R18
4.87K
GND
GND
PI11
Pulse J1011F21PNL
(Includes built in
transformer)
P6
RJ45-8
GND
R244
49.9
1%
2
B
3V3_SR
(0603
50V)
GND
1
RST-OUTx
C228
0.1UF
R233
49.9
1%
TPV10
17
16
J8
5,12
3V3_SR
R224
49.9
1%
GC
GA
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
PG1
U5
2
(0603
50V)
11
12
1
(0603
50V)
D
YA
YC
R215 0
20
21
GND
J6
C223
0.1UF
9
10
GND
J7
Y2
25MHZ
1
33PF
(0603
50V)
RSVDPU1
RSVDPU2
33PF
GND
10UF
(TANT)
R21
2.2K
5%
RSVD1
RSVD2
RSVD3
RSVD4
RSVD5
PHY_25MHz 1
(MII Clock)
50MHZ
R29
2.2K
5%
C232
0.1UF
8
9
10
11
12
2
C211
GND
+
22
C241
32
48
CLK
OUT
C227
0.1UF
AVDD33
1 OE
3
(RMII Clock)
GND
PHY_50MHz
3
IOVDD33_1
IOVDD33_2
VDD
C210
4
4
4
4
4
4
3V3_SR
L200
120OHM
2
AGND_1
AGND_2
DGND
IOGND_1
IOGND_2
Y1
3V3_SR
(0603
50V)
2
The Ethernet
interface only
supports 3.3V
operation. All I/O
signals must be 3.3V.
If VDD_HVA is set to
5V, Ethernet MCU pads
must be left as
tri-state with no
pullups.
2
D
50MHz Osc for RMII and 25MHz XTAL for MII
C200
RMII_50MHZ 0.1UF
4
All Ethernet Signals
are in power domain
VDD_HV_B
Reset Control:
- Reset from MCU Reset Out (will reset with MCU)
- Reset from GPIO. Allows MCU to reset PHY as well as hold PHY in reset
while reset config data can be driven onto pins to change mode etc.
C229
0.1UF
C226
0.1UF
C240
+
(0603
50V)
(0603
50V)
10UF
(TANT)
PFBIN1
PFBIN2
Layout Note:
Place 0.1uF cap close
to each pin. 10uF
(0603 TANT as close to pin
50V)
23 as possible
C225
0.1UF
B
PFBOUT
GND
R218
10.0K
Boot Configuration (using PHY internal Pulls)
R308 0
3V3_SR
RMII_50MHZ
(50MHz OSC
Power)
J5
- Auto Negotiation Enable (All speeds / duplex supported)
(AN_EN, AN0 and AN1 all Internal PullUP)
1
R219
2
- Operating Mode (MII or RMII)
(SNI_Mode Internal PullDown, MII_Mode control via jumper)
- LED Configuraiton (Mode1)
(LED_CFG Internal PullUp)
PF15
(MII_MODE)
2.2K 5%
3
Posn 1-2 for MII (default)
Posn 2-3 for RMII
GND
3V3_SR
- MDIX Enable (Auto MDIX Enabled)
(MDIX_EN Internal PullUP)
R220
** Layout Note - Place
resistors as shown
with shared pad on PG1
side of resistors
For RMII mode,
remove resistor
between PG1 and
TXCLK and place
between PG1 and
PHY_50MHz
PHY_50MHz
PG1
TXCLK
MDIO Pullup
1.5K
Automotive Microcontroller
Applications
East Kilbride, Scotland
PF14
- Physical Address (set to 0b00001)
(PHYAD[0] Internal PullUp, PHYAD[1..4] Internal PullDown)
A
A
Freescale General Business Use
Drawing Title:
Layout Note:
MPC574xx Customer EVB Main Board
MII Mode resistor (MII / RMII mode) and the MDIP ullup resistor should be placed as close as
possible to the PF15 / PF14 tracks to reduce the effect of a stub on the transmission line.
Page Title:
Ethernet
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
10
of
16
5
4
3
2
1
FlexRAY Physical Interface
Decoupling Caps for BOTH IC's. Place next to power pins.
All Signals are in
power domain VDD_HV_A.
P12V
D
FlexRAY interface will
work at 3.3V or 5.0V
(PER_HVA jumper)
4
4
PC12
PC14
(FR_DBG0)
(FR_DBG2)
PC12
PC14
D
PER_HVA
DNP
4
4
PC15
PC13
PER_HVA
5V0_SR
FlexRAY
debug
connector
P4
1
2 (FR_DBG1)
3
4 (FR_DBG3)
5V0_SR
P12V
C209
+
C221
+
C222
+
C217
+
C213
0.1UF
C215
0.1UF
C218
0.1UF
C219
0.1UF
10UF
10UF
10UF
10UF
(0603
50V)
(0603
50V)
(0603
50V)
(0603
50V)
PC15
PC13
VBAT
VBUF
VCC
VIO
1
3
5
(FR_A_TX)
(FR_A_TX_EN)
(FR_A_RX)
PC5
PE2
PE3
2
4
6
FRA-JTXD
FRA-JTXEN
FRA-JRXD
HDR 2X3
PER_HVA
U2
GND
11
10
J2
R200
R203
R205
R212
C
10.0K
10.0K
10.0K
10.0K
1
3
5
7
2
4
6
8
FRA-BGE
FRA-STBN
FRA-EN
5
6
8
9
3
FRA-WAKE 15
TRXD0
TRXD1
TXD
TXEN
BGE
STBN
EN
WAKE
16
GND
FlexRAY A
PER_HVA
FRA-INH2
FRA-INH1
18
17
FRA-BP
1
FRA-BM
4
7
13
12
FRA-ERRN
FRA-RXEN
R210
47.0
C208
1%
4700PF
(50V 0805)
TPV9
TPV7
L2
2
FRA-DATA-A
3
FRA-DATA-B
DLW43SH
TPV1
TPV4
R209
47.0
1%
C204
10PF
P3
1
2
(0603)
C203 GND
10PF
Crimped lead - 279-9522
Receptacle housing - 279-9156
C
(0603)
TJA1080TS/N
Bus voltage +/- 12V (VBAT = 12v)
Components spec'd for 12V operation
FRB-JTXD
FRB-JTXEN
FRB-JRXD
B
HDR 2X3
U1
GND
11
10
PER_HVA
J1
R201
R204
R206
R211
10.0K
10.0K
10.0K
10.0K
1
3
5
7
2
4
6
8
FRB-BGE
FRB-STBN
FRB-EN
5
6
8
9
3
FRB-WAKE 15
TRXD0
TRXD1
TXD
TXEN
BGE
STBN
EN
WAKE
16
GND
INH2
INH1
BP
BM
GND
2
4
6
P12V
4
19
20
14
1
3
5
(FR_B_TX)
(FR_B_TX_EN)
(FR_B_RX)
PE4
PC4
PE5
5V0_SR
VIO
VCC
VBUF
VBAT
J4
PE4
PC4
PE5
RXD
ERRN
RXEN
1
2
GND
FlexRAY B
4
4
4
INH2
INH1
BP
BM
GND
PC5
PE2
PE3
VIO
VCC
VBUF
VBAT
4
4
4
4
19
20
14
GND
J3
RXD
ERRN
RXEN
1
2
18
17
7
13
12
FRB-INH2
FRB-INH1
FRB-BP
1
FRB-BM
4
FRB-ERRN
FRB-RXEN
R208
47.0
C207
1%
4700PF
(50V 0805)
TPV8
TPV6
L1
2
FRB-DATA-A
3
FRB-DATA-B
DLW43SH
TPV2
TPV3
R207
47.0
1%
C202
10PF
B
P2
(0603)
1
2
C201 GND
10PF
Crimped lead - 279-9522
Receptacle housing - 279-9156
(0603)
TJA1080TS/N
Bus voltage +/- 12V (VBAT = 12v)
Components spec'd for 12V operation
GND
MODE
Normal
Rec Only
Go to Sleep
Sleep
EN
1
0
1
0
STBN
1
1
0
0
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
FlexRAY Physical Interface
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
11
of
16
5
4
3
2
1
SAI Audio, AVB & TWRPI Connectors
General Purpose TWRPI
3V3_SR 5V0_SR
3V3_SR
D
3V3_LR 3V3_SR
1
3
5
7
9
11
13
15
17
19
R315
10.0K
Note: Ports
PD[4..8] are
shared with the
GPIO Matrix
4,16
PD6
PD6
(ADC1_P[10])
TWRPI-ADC1
4,16
PD7
PD7
(ADC1_P[11])
TWRPI-ID0
5,10
RST-OUTx
GND
4,16
4,16
4,16
2
4
6
8
10
12
14
16
18
20
CON_2X10
R316
10.0K
R314
R317 10.0K
0
TWRPI-ADC2
TWRPI-ID1
RESET
I2C0_SCL
PO0
TWRPI-ADC0
PD5
PD4
PK3
PK1
PK4
PD8
RST-OUTx
GND
PA12
PA15
(DSPI0_SIN)
(DSPI0_SS0)
(EIRQ31)
(GPIO0/IRQ)
(GPIO2)
(GPIO4)
GND
1
3
5
7
9
11
13
15
17
19
3V3_SR
2
4
6
8
10
12
14
16
18
20
CON_2X10
D
R318 10.0K
I2C0_SDA
(DSPI0_SOUT)
(DSPI0_SCK)
PO1
PO1
4,16
PK0
PK2
4,16
4,16
PK4
PK1
PK3
4,16
4,16
4,16
PO0
4,16
PA13
PA14
(GPIO1)
(GPIO3)
PK0
PK2
Note: Ports
PK[0..5] are
shared with the
GPIO Matrix
GND
RST-OUTx
PD8
PD4
PD5
PD8
PD4
PD5
P27
3V3_SR
P26
PK4
PK1
PK3
(ADC1_P[12])
(ADC1_P[8])
(ADC1_P[9])
PO0
C
C
SAI Audio and AVB
P25
4,16
4,16
4,16
4,16
4,15,16
4,15,16
4,15,16
4,15,16
PA12
PA13
PA14
PA15
PG2
PG3
PG4
PG5
PA12
PA13
PA14
PA15
PG2
PG3
PG4
PG5
(DSPI0_SIN)
(DSPI0_SOUT)
(DSPI0_SCK)
(DSPI0_SS0)
(DSPI3_SOUT)
(DSPI3_SS3)
(DSPI3_SCK)
(DSPI3_SIN)
1
3
5
7
9
11
13
15
17
19
2
4
6
8
10
12
14
16
18
20
HDR_10X2
DNP
Pins used on this header are also at GPIO Matrix
PA12
PA13
PA14
PA15
PG2
PG3
PG4
PG5
-
DSPI0_SIN
DSPI0_SOUT
DSPI0_SCK
DSPI0_SS0
DSPI3_SOUT
DSPI3_SS3
DSPI3_SCLK
DSPI3_SIN
(Also
(Also
(Also
(Also
shared
shared
shared
shared
with
with
with
with
TWRPI)
TWRPI)
TWRPI)
TWRPI)
(Also
(Also
(Also
(Also
shared
shared
shared
shared
with
with
with
with
User
User
User
User
LED)
LED)
LED)
LED)
GND
B
B
3V3_SR
A
4
4
4
4
4
4
4
4,13,16
4
4
4
4
4,16
4
4
4
4
4
4
4
4
4,16
4
PF2
PF3
PF4
PF5
PF1
PB10
PF0
PD13
PE11
PE10
PJ2
PJ3
PM4
PF6
PF7
PE9
PE8
PI14
PJ1
PJ0
PI15
PM3
PA5
PF2
PF3
PF4
PF5
PF1
PB10
PF0
PD13
PE11
PE10
PJ2
PJ3
PM4
PF6
PF7
PE9
PE8
PI14
PJ1
PJ0
PI15
PM3
PA5
(SAI0_DATA3)
(SAI0_DATA2)
(SAI0_DATA1)
(SAI0_DATA0)
(SAI0_BCLK)
(SAI0_SYNC)
(SAI0_MCLK)
(ENET0_TMR0)
(I2C_SCL3)
(I2C_SDA3)
(SAI1_DATA0)
(SAI1_BCLK)
(ENET1_TMR2)
(SAI1_SYNC)
(SAI1_MCLK)
(I2C_SCL2)
(I2C_SDA2)
(SAI2_DATA0)
(SAI2_BCLK)
(SAI2_SYNC)
(SAI2_MCLK)
(ENET0_TMR2)
(GPIO Control)
P24
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
Differences to RevC
Pin 17 was PH5, now PD13** (PH5 now routed to GPIO Matrix)
Pin 27 was PH4, now PM4
(PH4 now routed to GPIO Matrix)
Pin 45 was PH3, now PM3
(PH3 now routed to GPIO Matrix)
** Note PD13 is also routed to MLB header via DNP link
Black - SAI Channels
Green - I2C Channels
Orange - ENET TMRx channels
Automotive Microcontroller
Applications
East Kilbride, Scotland
MPC574xx Customer EVB Main Board
Page Title:
5V0_SR
HDR_2X25
5
A
Freescale General Business Use
Drawing Title:
4
SAI Audio, AVB & TWRPI Headers
GND
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
12
of
16
5
4
3
2
1
MLB (SMSC) Daughtercard Connector
3V3_SR
Layout Note: MLB track lengths should be < 80mm
(from MCU through daughter card to connector)
D
3V3_LR
P16
44
43
40
38
39
37
(3.3v)
(3.3v)
(RSVD)
(INT)
36
34
35
33
(SDA)
(SCLK)
(TDI/DSDA)
(TMS)
32
30
31
29
(TDO/DINT)
(TCK/DSCL)
MLB_MCKIN
MLB_RSTOUT
(MCK_IN)
(RSOUT)
28
26
27
25
(ERR/BOOT)
(RST)
MLB_PS1
(PWROFF)
(PS1)
24
22
23
21
(STATUS)
(PS0)
MLB_STATUS
MLB_PS0
(RSVD)
(SR0)
20
18
19
17
(MLBCP)
(MLBCN)
MLB_CP
MLB_CN
(RMCK)
(SX0)
16
14
15
13
(RSVD)
(RSVD)
All MLB Signals are in
power domain VDD_HV_C.
The MLB interface only
supports 3.3V operation.
All I/O signals must be
3.3V. If VDD_HVC is set
to 5V, MLB MCU pads must
be left as tri-state
with no pullups.
P12V
(12v)
(3.3v Linear)
4
PG9
PG9
CARD INTERRUPTING MCU (WKPU21)
TPV17
TPV14
4
4,16
PH7
PI13
4
MLB_DAT
4
MLB_SIG
4
MLB_CLK
C
PH7
PI13
(MLB_PWROFF)
R60
0 DNP
MLB_DAT
MLB_DAT
(ID2)
(MLBDAT)
12
10
11
9
(MLBDP)
(MLBDN)
MLB_SIG
MLB_SIG
(ID1)
(MLBSIG)
8
6
7
5
(ID3)
(ID4)
MLB_CLK
(ID0)
(MLBCLK)
4
2
3
1
(MLBSP)
(MLBSN)
MLB_CLK
Series
termination
on MCU
daughtercard
R56
47K
R54
47K
R52
47K
R50
100
DNP
C21
27PF
DNP
GND
4
MLB_SN
4
MLB_SP
4
MLB_DN
4
MLB_DP
4
MLB_CN
4
MLB_CP
B
47 Ohm series
termination
already on
SMSC
daughtercard
42
R63
10.0K
R65
10.0K
R64
10.0K
D
(I2C1_SDA)
(I2C1_SCL)
PE1
PE0
PE1
PE0
4
4
PA6
PH6
4
4
PD13
PI12
4,12,16
4,16
Debug - Not RQD
Controls INIC Mode
R62
R61
PA6
PH6
0 DNP
0 DNP
PD13
PI12
MLB_DP
MLB_DN
C
MLB_SP
MLB_SN
Parallel 100 ohm LVDS
termination and Pullups
/ Pulldopwns (DNP'd)
are already on MLB
daughtercard.
41
QSH-020-01-L-D-DP-A
Place resistors as
3V3_SR close as possible to
GND
MLB tracks to
minimise stub lengths
R51
1.0K
R55
1.0K
MLB_SN
MLB_SP
B
(PD[15] Shared with MLB_DAT for 3-pin mode)
MLB_DN
MLB_DP
MLB_CN
(PB[15] Shared with MLB_SIG for 3-pin mode)
MLB_CP
(PI[8] Shared with MLB_CLK for 3-pin mode)
Parallel
termination
on MCU
daughtercard
R53
619.0
1%
R57
619.0
1%
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
MLB SMSC Daughtercard Connector
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
13
of
16
5
4
3
2
1
SD Connector
Caution
D
The SD card specification details an operating voltage of
between 2.7 and 3.6V. If using the SD card, it can ONLY be
used when VDD_HV_A (and PER_HVA) jumpers are set to 3.3V.
Inserting an SD card with VDD_HV_A / PER_HVA set to 5V will
result in card damage.
D
3V3_SR
R9
10.0K
DNP
R8
10.0K
DNP
R12
10.0K
DNP
R11
10.0K
DNP
R6
10.0K
R7
10.0K
C7
+ 10UF
(35V
TANT)
R10
10.0K
DNP
C12
0.1UF
(0603
50V)
GND
P200
4
4
4
4
PI3
PI2
PI1
PI0
4
4
4
4
C
PH8
PA0
PE7
PE6
PI3
PI2
PI1
PI0
PH8
PA0
PE7
PE6
4
3
15
14
13
11
7
5
(SDHC_DATA0)
(SDHC_DATA1)
(SDHC_DATA2)
(SDHC_DATA3)
(SDHC_WP)
(SDHC_CD) WKPU19
(SDHC_CLK)
(SDHC_CMD)
R22
R23
R14
0 SD_WP
0 SD_Detect
22 SDHC1_CLK
1
2
8
12
R13
10.0K
DNP
DAT0
DAT1
DAT2
DAT3
DAT4
DAT5
DAT6
DAT7
VCC/VDD
VSS1
GND/VSS2
WP_SW
CD_SW
CLK
CMD
GND1
GND2
GND3
GND4
9
10
6
S1
S2
S3
S4
C
MMC_SD_CARD
GND
Amphenol 101-00565-64 SD
/ MMC socket with card
detection switch.
GND
B
B
Card Detect:
Write Protect:
Grounded when Card Inserted, Pulled high when card removed
Grounded when NOT protected, Pulled high when protected (or card removed)
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
SD Card
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
14
of
16
5
4
User Peripherals,
3
2
1
Audio Controls and GPIO
Switches are hard wired to 3.3V rather than 5V so it's not possible to drive 5V into a 3.3V pad (which would cause damage)
Similarly, the LED's are active low with 3.3v supply so can be safely coupled to pads on either 3.3V or 5V domains
The ADC input is limited to 3.3V, again to prevent driving 5V into a 3.3V pad which would cause damage
User LED's (Active Low)
PG[2..5] share eMIOS1
UC[11..14] with PWM
functionality
D
ADC Input Pot and Test Point
DS2
C
R257
A
USR_LED1
USR_LED2
USR_LED3
USR_LED4
0
0
0
0
C
Note that LED2 and LED4 (PG3
and PG5) can be controlled in
LPU_RUN mode (and also have pad
keepers in LPU_STANDBY)
R259
A
3
270
1
DS7
C
A
R261
TP18
DS8
C
GND
270
R269
A
2
270
1
PB4
(ADC1_P[0])
C25
P19
HDR 1X4
DNP
J17
1
R258
R260
R262
R270
(Note - This is run from linear 3.3v regulator to
provide a stable input voltage)
2
PG2
PG3
PG4
PG5
1
2
3
4
PG2
PG3
PG4
PG5
3V3_LR
270
RV1 2K
DS3
4,12,16
4,12,16
4,12,16
4,12,16
D
3V3_SR
LED's are SMD (1206) Yellow
4
PB4
0.1UF
DNP
(0603 50V)
GND
Hex Encoded Switch (Active High)
J26
2
1
C
100
The LED's, Hex switches and push-button switches are
connected to MCU pads vvia zero ohm links. If desired
these can be removed and direct connection made to the
LED or switch. All of the ports used for LED's /
Switches are also bonded out to the GPIO matrix
C
SW2
R286
B C D
E
A
F
9
8
1
7
6 5 3 2
4
1
HEX_SW1
R275
0
PD0
2
HEX_SW2
R277
0
PD1
4
HEX_SW3
R280
0
PD2
8
HEX_SW4
R282
0
PD3
DRS4016
R281
R279
R278
R276
Since the Hex switch always
has an active output, the
jumper is to allow the switch
to be powered off
PD0
4,16
PD1
4,16
PD2
4,16
PD3
4,16
1
2
3
4
3V3_SR
0
C
10.0K
10.0K
10.0K
10.0K
P20
HDR 1X4
DNP
GND
User Pushbutton Switches (Active High)
B
Note - PA1 is also the NMI pin!
3V3_SR
SW3
1 SW4
2
1
2
SW6
1
2
SW7
1
PB_SW1
PB_SW2
PB_SW3
PB_SW4
(eMIOS
(eMIOS
(eMIOS
(eMIOS
R303
R301
R288
R290
10.0K
10.0K
10.0K
10.0K
H / X)
G / X)
G / Y)
G)
PA1
PA2
PF9
PF11
0
0
0
0
PA1
PA2
PF9
PF11
4,16
4,16
4,16
4,16
P22
HDR 1X4
DNP
2
OMRON B3WN-6002 Pushbutton Switch
R289
R287
R302
R304
1
2
3
4
B
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Page Title:
User Peripherals, Audio Controls and GPIO
5
4
3
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
15
of
16
5
4
GPIO Pin Matrix
PORTA
A
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
4
4
PL0
PL1
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
PORTI
PORTJ
1
PJ4
IOM31
1
PJ5
IOM40
1
PJ6
IOM49
1
PJ7
IOM58
1
PJ8
IOM66
1
PJ9
IOM74
1
PJ10
IOM82
1
PJ11
IOM90
1
PJ12
IOM101
1
PJ13
IOM111
1
PJ14
IOM118
1
PJ15
IOM125
1
PI9
IOM73
1
PI10
IOM81
1
PI12
IOM100
1
PI13
IOM110
PL0
PL1
Busses are not used
on ports as it makes
it harder to see
which pins are shared
with other functions
TPH2
14 GND Pads
(one at
bottom of
each colum)
PORTK
TPH3
PORTL
1
PK0
IOM2
1
PK1
IOM9
1
PK2
IOM17
1
PK3
IOM23
1
PK4
IOM32
1
PK5
IOM41
1
PK6
IOM50
1
PK7
IOM59
1
PK8
IOM67
1
PK9
IOM75
1
PK10
IOM83
1
PK11
IOM91
1
PK12
IOM102
1
PK13
IOM112
1
PK14
IOM119
1
PK15
IOM126
TPH4
TPH5
TPH6
PORTM
1
PG2
IOM16
1
PG3
IOM22
1
PG4
IOM30
1
PG5
IOM39
1
PG6
IOM48
1
PG7
IOM57
1
PG8
IOM65
PG2
PG3
PG4
PG5
PG6
PG7
PG8
1
PH3
IOM132
1
PH4
IOM131
1
PH5
IOM130
PH3
PH4
PH5
PH13
PH14
PH15
PM3
PM4
PM5
PM6
PM11
PM12
PM13
PM14
PM15
1
PN0
IOM4
1
PN1
IOM11
1
PN2
IOM18
1
PN3
IOM25
1
PN4
IOM34
1
PN5
IOM43
1
PN6
IOM52
1
PN7
IOM60
1
PN8
IOM68
1
PN9
IOM76
1
PN10
IOM84
1
PN11
IOM93
1
PN12
IOM104
1
PN13
IOM114
1
PN14
IOM121
1
PN15
IOM128
1
PM3
IOM24
1
PM4
IOM33
1
PM5
IOM42
1
PM6
IOM51
PM11 1
IOM92
PM12 1
IOM103
PM13 1
IOM113
PM14 1
IOM120
PM15 1
IOM127
TPH7
TPH8
TPH9
TPH10
TPH11
TPH12
TPH13
TPH14
PORTO
1
PO0
IOM5
1
PO1
IOM12
1
PO2
IOM19
1
PO3
IOM26
1
PO4
IOM35
1
PO5
IOM44
1
PO6
IOM53
1
PO7
IOM61
1
PO8
IOM69
1
PO9
IOM77
PO10 1
IOM85
PO11 1
IOM94
PO12 1
IOM105
PO13 1
IOM115
PO14 1
IOM122
PO15 1
IOM129
PN0
PN1
PN2
PN3
PN4
PN5
PN6
PN7
PN8
PN9
PN10
PN11
PN12
PN13
PN14
PN15
PORTP
1
PP0
IOM6
1
PP1
IOM13
1
PP2
IOM20
1
PP3
IOM27
1
PP4
IOM36
1
PP5
IOM45
1
PP6
IOM54
1
PP7
IOM62
1
PP8
IOM70
1
PP9
IOM78
1
PP10
IOM86
1
PP11
IOM95
PO0
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
PO12
PO13
PO14
PO15
PP0
PP1
PP2
PP3
PP4
PP5
PP6
PP7
PP8
PP9
PP10
PP11
PORTQ
No spare pins
on PortQ
TPH15
PF8
PF9
PF10
PF11
PF12
PF13
4
4,15
4
4,15
4
4
PG2
PG3
PG4
PG5
PG6
PG7
PG8
4,12,15
4,12,15
4,12,15
4,12,15
4
4
4
PH3
PH4
PH5
PH13
PH14
PH15
4
4
4
4
4
4
PM3
PM4
PM5
PM6
PM11
PM12
PM13
PM14
PM15
4,12
4,12
4
4
4
4
4
4
4
PN0
PN1
PN2
PN3
PN4
PN5
PN6
PN7
PN8
PN9
PN10
PN11
PN12
PN13
PN14
PN15
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
4
PO0
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
PO12
PO13
PO14
PO15
4,12
4,12
4
4
4
4
4
4
4
4
4
4
4
4
4
4
PP0
PP1
PP2
PP3
PP4
PP5
PP6
PP7
PP8
PP9
PP10
PP11
4
4
4
4
4
4
4
4
4
4
4
4
PF[9,11] shared with
user switches
PG[2..5] shared with
user LED's, SAI and
TWRPI headers
D
PM[3..4] shared with
SAI Audio header
C
PO[0..1] shared with
TWRPI header
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
GND
A
Freescale General Business Use
Drawing Title:
MPC574xx Customer EVB Main Board
Layout Notes:
Pads must be placed in a 13 x 16 matrix pattern, 2.54 mm pitch
- 13 wide (one column for each port EXCLUDING those with no available pads ie C, E, H, Q)
- 16 tall (1 row for each port number from 0 to 15).
- GND pad at bottom of each colum
- After production, pads should be through hole (not solder filled)
5
PORTH
1
PH13
IOM109
1
PH14
IOM117
1
PH15
IOM124
PORTN
1
PL0
IOM3
1
PL1
IOM10
1
4,12
4,12
4,12
4,12
4,12
4
4
4
4
4
4
4
4
4
4
4
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
1
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
1
4
4
4
4
4
4
4
4
4
4
4
4
1
PF8
PF9
PF10
PF11
PF12
PF13
PI12
PI13
1
PI12
PI13
PORTG
No spare pins
on PortE
No spare pins
on PortE
1
B
4,13
4,13
PORTF
1
PF8
IOM64
1
PF9
IOM72
1
PF10
IOM80
1
PF11
IOM89
1
PF12
IOM99
1
PF13
IOM108
1
PK[0..4] shared with
TWRPI header
PI9
PI10
PI9
PI10
1
PB11
IOM87
1
PB12
IOM97
1
PA12
IOM96
1
PA13
IOM106
1
PA14
IOM116
1
PA15
IOM123
1
PI[12,13] shared with
MLB header
4
4
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
1
PB5
IOM37
1
PB6
IOM46
1
PB7
IOM55
1
C
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
1
PA4
IOM28
1
PD[13] shared with
SAI Audio and MLB
headers
4,15
4,15
4,15
4,15
4,12
4,12
4,12
4,12
4,12
4
4
4
4
4,12,13
PORTE
1
PD0
IOM1
1
PD1
IOM8
1
PD2
IOM15
1
PD3
IOM21
1
PD4
IOM29
1
PD5
IOM38
1
PD6
IOM47
1
PD7
IOM56
1
PD8
IOM63
1
PD9
IOM71
1
PD10
IOM79
1
PD11
IOM88
1
PD12
IOM98
1
PD13
IOM107
1
PD[4..8] shared with
TWRPI connector with
pullup on PD[7], PD[8]
PB5
PB6
PB7
PB11
PB12
PB5
PB6
PB7
PB11
PB12
2
PORTD
1
PA1
IOM7
1
PA2
IOM14
1
PD[0..3] shared with
Hex Switch
4
4
4
4
4
PA1
PA2
PA4
PA12
PA13
PA14
PA15
PORTC
1
D
PA1
PA2
PA4
PA12
PA13
PA14
PA15
1
PA[12..15] shared with
SAI Audio and TWRPI
4,15
4,15
4
4,12
4,12
4,12
4,12
PORTB
1
PA[1,2] shared with
user switches
3
All pads are DNP (Do Not Populate) 0.1" pitch headers placed on a 0.1" grid
4
3
Page Title:
GPIO Pin Matrix
2
Size
B
Document Number
Date:
Friday, August 14, 2015
SCH-27897
Rev
D1
PDF: SPF-27897
Sheet
1
16
of
16
324 BGA DC
5
4
3
2
1
MPC5748G Customer EVB 324 BGA Daughter Card (MPC574XG-324DS)
Table Of Contents:
D
Sheet 2
Sheet 3
Sheet 4
Sheet 5
Sheet 6
Sheet 7
Sheet 8
Power - MPC5748G power pins footprint
Power - MPC5748G Decoupling Capacitors
GPIO - MPC5748G GPIO pins 1 of 2
GPIO - MPC5748G GPIO pins 2 of 2
Clocks
Bus Termination
Daughtercard Connectors
Revision Information
Rev Date
X1 28 Feb 2013
X2 11 Mar 2013
X3 13 Mar 2013
X4 15 Mar 2013
X5 29 Mar 2013
X6 15 Apr 2013
A
15 Apr 2015
A1 18 Aug 2015
Designer
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Comments
Initial release sent for review
Final Review
Version sent to Pre Layout, incorporating fixes from review
Component consolodation, Few minor changes. Sent to Layout
Changes made during layout to Daughtercard Connectors
CIS CAD Database update & SCH Back-Annotate
Post Layout (Back Annotated). Matches PCB RevA
Tidy up Schematics for UM (RevA PCB)
D
C
C
Caution:
These schematics are provided for reference purposes only. As such,
Freescale does not make any warranty, implied or otherwise, as to the
suitability of circuit design or component selection (type or value) used in
these schematics for hardware design using the Freescale MPC5748G family
of Microprocessors. Customers using any part of these schematics as a
basis for hardware design, do so at their own risk and Freescale does not
assume any liability for such a hardware design.
B
3 Different test points used in design:
B
TPVx - Through Hole Pad small
TPHx - Through Hile Pad Large (for standard 0.1" header).
TPX
- Surface Mount Wire Loop
Notes:
-
A
All components and board processes are to be ROHS compliant
All small capacitors are 0402 unless otherwise stated
All resistors are 0603 5% 0.1w unless otherwise stated. All zero ohm links are 0603
All connectors and headers are denoted Px and are 2.54mm pitch unless otherwise stated
All jumpers are denoted Jx. Jumpers are 2mm pitch
Jumper default positions are shown in the schematics. For 3 way jumpers, default is always posn 1-2.
2 Pin jumpers generally have the "source" on pin 1.
- All switches are denoted SWx
- All test points are denoted TPx
- Test point Vias are denoted TPVx
User notes are given throughtout the schematics.
Specific PCB LAYOUT notes are detailed in ITALICS
Automotive Microcontroller Applications
East Kilbride, Scotland
Freescale General Business Use
This document contains information proprietary to Freescale and shall not be used for engineering design,
procurement or manufacture in whole or in part without the express written permission of Freescale
A
Freescale AISG Applications, East Kilbride
Designer:
Drawing Title:
A. Robertson
MPC5748G 324 BGA Daughter Card
Drawn by:
Page Title:
A. Robertson
Index and Title Page
Approved:
Size
B
Document Number
Date:
Tuesday, August 18, 2015
A. Robertson
5
4
3
2
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
1
of
8
5
4
3
MPC5748G MCU Power Connections
2
Caution:
Default Configuraiton:
- ALL MCU supply voltages are set to 3.3V (ADC0, ADC1, VDD_HV_A,
VDD_HV_B, VDD_HV_C, VBallast)
- VDD_HV_FLA = External 3.3V supplied (jumper fitted)
- VDD_LV Supplied from ballast transistor
- If VDD_HV_A is driven from 5V, the VDD_HV_FLA pin
must not be supplied from 3.3V (remove the HVA_FLA
jumper)
- Don't attempt to over drive an analogue pad to 5V
when the digital VDD_HV_x supply is set to 3.3V. This
will trigger the ESD protectrion on that pad. For
example if VDD_HV_A is set to 3.3V and the analogue
supplies are set to 5V, you cannot drive 5V into a
pad in the VDD_HV_A domain
D
From MCU
supply
jumpers on
main board
HVA_CAP
3v3
5v0
J8
Individual MCU
supply control
jumpers
E_CAP
2
C
LVDEC_CAP
R35
0
DAC External
Ref Voltage
Select
J11
Q20
MJD31CT4
1
3
1
2
HVFLA_CAP
HVC_CAP
HVB_CAP
HVA_CAP
5v0
J9
2
2
J7
3v3
TPH3
1
3v3
1
3
1
3
5v0
0
ADC1REF_CAP
(Current Limit Resistor to
protecxt against case when
other MCU supplies are
disconnected and external
reference supply is live)
R36
1.0K
J10
2
ADC1_CAP
3v3
J6
2
J5
R7
ADC0_CAP
5v0
1
2
J4
3v3
1
5v0
3
1
3v3
2
J3
C
3
5v0
1
3
1
3v3
3
MCU_3V3_L
3 1
MCU_5V0_L
1
8 MCU_3V3_L
MCU_3V3_S
4 2
8 MCU_5V0_L
D
MCU_5V0_S
3
8 MCU_3V3_S
LV_CAP
8 MCU_5V0_S
This is not necessarily the same as the default shown in the RM. All
VDD_HV_x domains have at least one peripheral that only functions at
3.3V. Therefore the default is to run these from 3.3V. The analogue pins
can only be driven to the same voltage as the VDD_HV_x domain they are
situated in (ie max 3.3V) so makes sense for the analogue supply and
reference to be 3.3V
MCU_1V25_L
B_CAP
8 MCU_1V25_L
1
DAC Ref
J3
VIN1_CMP_REF
L2
D8
F5
K3
K11
K12
L11
L12
M11
M12
VDD_LP_DEC
VRC_CTRL
VDD_LV_D8
VDD_LV_F5
VDD_LV_K3
VDD_LV_K11
VDD_LV_K12
VDD_LV_L11
VDD_LV_L12
VDD_LV_M11
VDD_LV_M12
K2
J2
VDD_HV_FLA
1.25v Core & External Ballast
VSS_LV_F6
VSS_LV_J7
VSS_LV_J8
VSS_LV_J9
VSS_LV_K7
VSS_LV_K8
VSS_LV_K9
VSS_LV_K10
VSS_LV_L7
VSS_LV_L8
VSS_LV_L9
VSS_LV_L10
VSS_LV_M7
VSS_LV_M8
VSS_LV_M9
VSS_LV_M10
VSS_HV_VPP
MPC5748G + OTB-324R-1.0-019-00
F6
J7
J8
J9
K7
K8
K9
K10
L7
L8
L9
L10
M7
M8
M9
M10
K1
H7
H8
H9
H10
H11
H12
J10
J11
J12
K14
K16
V8
V17
Flash
B
Power Pins
VSS_HV_H7
VSS_HV_H8
VSS_HV_H9
VSS_HV_H10
VSS_HV_H11
VSS_HV_H12
VSS_HV_J10
VSS_HV_J11
VSS_HV_J12
VSS_HV_K14
VSS_HV_K16
VSS_HV_V8
VSS_HV_ADC1
Package 2of3
VSS_HV_ADC0
VDD_HV_C
MPC5748G 6M 324BGA
Analogue
U14
L14
J15
K13
VDD_HV_B_J15
VDD_HV_B_K13
C2
C9
E18
K17
R7
U8
VDD_HV_A_C2
VDD_HV_A_C9
VDD_HV_A_E18
VDD_HV_A_K17
VDD_HV_A_R7
VDD_HV_A_U8
V15
V16
VDD_HV_ADC1_REF
B
VDD_HV_ADC1
U1B
VDD_HV_ADC0
V14
TPH2
0
1
R24
ADC0_GND
ADC1_GND
GND
TPH1
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
GND
A
A
Freescale General Business Use
Drawing Title:
Ground Links
(0 Ohm
Resistors)
5
4
R9
0
R10
MPC5748G 324 BGA Daughter Card
0
Page Title:
ADC0_GND
GND
ADC1_GND
3
MPC5748G MCU Power
GND
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
2
of
8
5
4
3
2
1
MPC5748G MCU Decoupling and bulk storage
Capacitor Types:
470pF - Ceramic COG, 50v 5% 0402
1000pF - Ceramic COG, 50V 5% 0402
4700pF - Ceramic X7R, 50V 10% 0402
Flash
ADC
ADC0_CAP
ADC1_CAP
C49
1000pF
ADC1REF_CAP
C47
1000pF
HVFLA_CAP
D
C2
10UF
DNP
+
C3
10UF
DNP
C60
1.0 UF
C57
0.1UF
ADC0_GND
+
C48
C59
1.0 UF
1000pF
C56
0.1UF
ADC1_GND
C36
C58
1.0 UF
C34
2.2UF
LMK107B7225KA-T
(low ESR)
1000pF
ADC1_GND
0.01uF
0.1uF
0.68uF
1.0uF
2.2uF
-
- Ceramic X7R, 50V 10% 0402
Ceramic X7R, 16V 10% 0402
Ceramic X7R 16V 10% 0805 (Murata GCM219R71C684KA37 )
Ceraminc X7R, 10V 10% 0603 (Taiyo Yuden LMK107B7105KA-T)
Ceraminc X7R, 10V, 10%, 0603 (Taiyo Yuden LMK107B7225KA-TR)
4.7uF
10uF
- TANT, 12.5V 20% ESR=0.08R 7343
- TANT, 35V 10% ESR=0.125R CC7343-31
D
4.7uF Alternative (150-78844)- Polymer ALU, 16V 20% ESR=0.08R
7343-18
GND
Place small Caps as close as possible to MCU pins
VDD_HVA
VDD_HVB
HVA_CAP
C27
470pF
C52
1000pF
C22
470pF
C55
1000pF
C28
470pF
C37
1000pF
+ C1
10UF
C
VDD_HVC
HVB_CAP
C40
470pF
HVC_CAP
C33
1000pF
+ C4
10UF
DNP
C26
0.1UF
GND
C53
0.1UF
C23
0.1UF
C54
0.1UF
C30
0.1UF
C38
0.1UF
C42
1000pF
+ C5
10UF
DNP
C41
0.1UF
GND
C35
0.1UF
C
C44
0.1UF
GND
Place 10uF cap to west side of package
Place small caps close to each MCU pin
Ballast Transistor
VDD_LV
LV_CAP
C24
0.1UF
C51
0.1UF
DNP
C50
0.1UF
C46
0.1UF
DNP
B_CAP
C8
B
C32
0.1UF
GND
C39
0.1UF
C45
0.1UF
DNP
C21
0.1UF
DNP
C25
0.1UF
DNP
E_CAP
LP Internal Reg Cap
E_CAP
LV_CAP
LVDEC_CAP
4700pF
C9
2.2UF
DNP
(low
ESR)
Place
close to
transistor
C10
2.2UF
DNP
(low
ESR)
C29
0.68uF
(low
ESR)
C61
0.68uF
(low
ESR)
C31
0.68uF
(low
ESR)
C20
0.68uF
DNP
(low
ESR)
C43
1uF
LMK107B7105KA-T
(low ESR)
B
(Murata GCM219R71C684KA37)
GND
VDD_LV (1.25V) Decoupling. Place one of the non DNP caps each side of the device
as close as possible to pin. Distribute other (DNP) caps around rest of pins
GND
2.2uF caps
are DNP.
Place close
to emitter
See caps below for Bypass Transistor bulk storage (some on VDD1V2 rail)
GND
Place one 0.68uF cap footprint
each side of package
One of these is DNP. May replace 2 caps with
0.47uF to keep overall capacitance within limits
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 324 BGA Daughter Card
Page Title:
MPC5748G MCU Decoupling
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
3
of
8
5
4
3
2
1
MPC5748G GPIO 1 of 2
U1A
** PA1 is also NMI. Routed
to I/O Matrix
(WKPU2 / NMI0)
(WKPU3)
D
Key to text colours:
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
C
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
(SD_CD - WKPU19)
(SW1 & GPIO**)
(SW2 & GPIO)
(MII_RXCLK)
(CMP1_13 / IO)
(SAI_GPIO)
(MLB_GPIO)
(MII_RXD2)
(RMII_RXD1)
(RMII_RXD0)
(MII_COL)
(RMII_RXER)
(CMP1_15 / IO)
(CMP1_14 / IO)
(CMP1_12 / IO)
(CMP1_10 / IO)
8
8
8
8
8
8
8
8
6
6
8
8
8
7
7
7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
(CAN0_TX)
(CAN0_RX)
(LIN0_TX)
(LIN0_RX)
(ADC_POT)
(GPIO)
(GPIO)
(GPIO)
(XTAL32)
(EXTAL32)
(SAI0_SYNC)
(GPIO)
(GPIO)
(MLB_DN)
(MLB_SN)
(MLB_CN / SIG)
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
N1
N2
G9
G8
N11
R14
N12
P14
V10
V9
P9
P13
N13
T18
R17
R18
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
(TDI)
(TDO)
(USB1_CLK)
(USB1_DIR)
(FR_B_TX_EN)
(FR_A_TX)
(LIN1_TX)
(LIN1_RX)
(RS232_TX)
(RS232_RX)
(CAN1_TX)
(CAN1_RX)
(FR_DBG0)
(FR_DBG1)
(FR_DBG2)
(FR_DBG3)
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
F9
F10
C13
D11
B12
A11
R3
U2
D5
D4
M5
M4
D6
E6
B2
C3
8
8
8
8
8
8
8
8
8
8
8
8
8
8
7
7
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
PD14
PD15
(HEX1 & GPIO)
(HEX2 & GPIO)
(HEX3 & GPIO)
(HEX4 & GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO & MLB_ST)
(MLB_DP)
(MLB_SP / DAT)
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
PD14
PD15
R12
T13
T14
R13
P11
T15
U15
R15
P12
N15
P15
V18
N16
N14
T17
P17
8
8
MCU-RSTx
PORSTx
MCU-RSTx
PORSTx
6
6
MCU-XTAL
MCU-EXTAL
MCU-XTAL
MCU-EXTAL
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
L5
K6
J6
M17
P6
A14
A13
F17
F18
E17
D18
D17
N8
P7
T3
N7
B
A
L1
C12
V6
V7
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
MPC5748G 324 BGA
Package 1of3 GPIO Pins1
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8/XTAL32
PB9/EXTAL32
PB10
PB11
PB12
PB13
PB14
PB15
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
PD14
PD15
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
H3
H2
A12
D10
B11
A10
F8
D7
K5
K4
H1
J1
C18
G17
C15
E12
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
(MLB_I2C1_SCL)
(MLB_I2C1_SDA)
(FR_A_TX_EN)
(FR_A_RX)
(FR_B_TX)
(FR_B_RX)
(SD_CMD)
(SD_CLK)
(SAI_I2C2_SDA)
(SAI_I2C2_SCL)
(SAI_I2C3_SDA)
(SAI_I2C3_SCL)
(MII_CRS)
(MII_RXD3)
(USB1_D2)
(USB1_D3)
N9
R9
P10
U10
N10
V12
T11
R10
T2
T1
R5
P5
N5
N6
G18
H17
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
(SAI0_MCLK)
(SAI0_BCLK)
(SAI0_D3)
(SAI0_D2)
(SAI0_D1)
(SAI0_D0)
(SAI1_SYNC)
(SAI1_MCLK)
(GPIO)
(SW3 & GPIO) WKPU22
(CMP1_8 / IO)
(SW4 & GPIO) WKPU15
(GPIO)
(CMP1_11 /IO)
(RMII_MDIO)
(RMII_RXDV)
H18
J16
J4
J5
G2
F2
M2
M1
M3
L3
D14
D13
L18
M18
F12
C16
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
(RMII_MDC)
(RMII_TXCLK)
(LED1 & GPIO)
(LED2 & GPIO)
(LED3 & GPIO)
(LED4 & GPIO)
(CLKOUT1 GPIO)
(CLKOUT0 GPIO)
(GPIO)
(MLB_IRQ - WKPU21)
(USB1_D4)
(USB1_D5)
(MII_TXD2)
(MII_TXD3)
(USB1_D0)
(USB1_D1)
L17
K18
J18
J17
C10
B10
A9
D9
E8
E9
E10
C14
D12
F3
E2
G4
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
(RMII_TXD1)
(RMII_TXD0)
(RMII_TXEN)
(eMIOS1_UC_5H)
(eMIOS1_UC_6H)
(eMIOS1_UC_7H)
(MLB_RST)
(MLB_PWR)
(SD_WP)
(TCK)
(TMS)
(USB1_D6)
(USB1_D7)
(GPIO)
(GPIO)
(GPIO)
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
7
8
8
8
8
8
8
8
8
8
8
8
7
7
8
8
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
7
7
7
8
8
8
8
8
8
8
8
8
8
8
8
8
D
C
(eMIOS
(eMIOS
(eMIOS
(eMIOS
E1UC_11_H)
E1UC_12_H)
E1UC_13_H)
E1UC_14_H)
B
RESET
PORST
Automotive Microcontroller
Applications
East Kilbride, Scotland
XTAL
EXTAL
A
Freescale General Business Use
Drawing Title:
MPC5748G + OTB-324R-1.0-019-00
MPC5748G 324 BGA Daughter Card
Page Title:
MPC5748G GPIO 1of2
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
4
of
8
5
4
3
2
1
MPC5748G GPIO 2 of 2
U1C
Key to text colours:
Purple
Orange
Blue
Black
RED
Green
- Comms Physical Interfaces
- Other Peripherals and I/O
- Debug (JTAG & Nexus)
- Clock, Reset and Control
I/O Matrix and other functions (eg LED)
- I/O Matrix (dedicated)
D
C
C6
E7
C7
C8
A18
E11
H4
G3
P18
T12
U12
N18
N17
M16
R16
P16
8
8
8
8
8
8
8
8
7
8
8
8
8
8
8
8
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
PI9
PI10
PI11
PI12
PI13
PI14
PI15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PJ0
PJ1
PJ2
PJ3
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
(SAI2_SYNC)
(SAI2_BCLK)
(SAI1_D0)
(SAI1_BCLK)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
PJ0
PJ1
PJ2
PJ3
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
U18
V13
R11
U11
A1
T16
U16
U17
U13
V5
V4
U3
V3
T6
R6
U4
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
T4
N3
N4
P1
P2
P3
P4
R1
R2
B7
A6
B6
A5
B5
C5
A4
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PL0
PL1
PL2
PL3
PL4
PL5
PL6
PL7
PL8
PL9
PL10
PL11
PL12
PL13
PL14
PL15
(GPIO)
(GPIO)
(MDO0)
(MDO1)
(MDO2)
(MDO3)
(MDO4)
(MDO5)
(EVTI)
(MSEO0)
(MCKO)
(MSEO1)
(EVTO)
(MDO6)
(MDO7)
(MDO8)
PL0
PL1
PL2
PL3
PL4
PL5
PL6
PL7
PL8
PL9
PL10
PL11
PL12
PL13
PL14
PL15
B4
L15
E15
E14
F13
F14
F15
G13
D15
E13
G12
E16
D16
F16
G16
G15
8
8
8
8
8
8
8
8
PQ0
PQ1
PQ2
PQ3
PQ4
PQ5
PQ6
PQ7
(USB0_STP)
(USB0_CLK)
(USB0_DIR)
(USB0_NXT)
(USB0_D7)
(USB0_D6)
(USB0_D5)
(USB0_D4)
PQ0
PQ1
PQ2
PQ3
PQ4
PQ5
PQ6
PQ7
C11
B13
B14
F11
A15
A16
B15
A17
B
A
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
PI9
PI10
PI11
PI12
PI13
PI14
PI15
(SD_D3)
(SD_D2)
(SD_D1)
(SD_D0)
(USB1_STP)
(USB1_NXT)
(USB0_RST)
(USB1_RST)
(MLB_CP / CLK)
(GPIO)
(GPIO)
(ENET_RST)
(GPIO & MLB_PS0)
(GPIO & MLB_PS1)
(SAI2_D0)
(SAI2_MCLK)
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
PI9
PI10
PI11
PI12
PI13
PI14
PI15
MPC5748G 324 BGA
Package 3of3 GPIO Pins2
PM0
PM1
PM2
PM3
PM4
PM5
PM6
PM7
PM8
PM9
PM10
PM11
PM12
PM13
PM14
PM15
PJ0
PJ1
PJ2
PJ3
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
PN0
PN1
PN2
PN3
PN4
PN5
PN6
PN7
PN8
PN9
PN10
PN11
PN12
PN13
PN14
PN15
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
PO0
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
PO12
PO13
PO14
PO15
PL0
PL1
PL2
PL3
PL4
PL5
PL6
PL7
PL8
PL9
PL10
PL11
PL12
PL13
PL14
PL15
PP0
PP1
PP2
PP3
PP4
PP5
PP6
PP7
PP8
PP9
PP10
PP11
PP12
PP13
PP14
PP15
G14
H13
H15
L13
K15
M14
L16
H16
J13
H14
J14
G10
G11
M13
M15
T10
PM0
PM1
PM2
PM3
PM4
PM5
PM6
PM7
PM8
PM9
PM10
PM11
PM12
PM13
PM14
PM15
(MDO9)
(MDO10)
(MDO11)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(MDO12)
(MDO13)
(MDO14)
(MDO15)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
T9
V11
U9
T8
U7
R8
P8
U6
U5
T5
T7
V2
V1
U1
R4
L4
PN0
PN1
PN2
PN3
PN4
PN5
PN6
PN7
PN8
PN9
PN10
PN11
PN12
PN13
PN14
PN15
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
G1
F1
M6
L6
E1
H6
H5
D1
D2
E3
D3
C1
B1
E4
F4
G6
PO0
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
PO12
PO13
PO14
PO15
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
G5
B3
C4
F7
E5
G7
A2
A3
B8
A7
A8
B9
B17
B16
C17
B18
PP0
PP1
PP2
PP3
PP4
PP5
PP6
PP7
PP8
PP9
PP10
PP11
PP12
PP13
PP14
PP15
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(USB0_D3)
(USB0_D2)
(USB0_D1)
(USB0_D0)
PM0
PM1
PM2
PM3
PM4
PM5
PM6
PM7
PM8
PM9
PM10
PM11
PM12
PM13
PM14
PM15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PN0
PN1
PN2
PN3
PN4
PN5
PN6
PN7
PN8
PN9
PN10
PN11
PN12
PN13
PN14
PN15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PO0
PO1
PO2
PO3
PO4
PO5
PO6
PO7
PO8
PO9
PO10
PO11
PO12
PO13
PO14
PO15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PP0
PP1
PP2
PP3
PP4
PP5
PP6
PP7
PP8
PP9
PP10
PP11
PP12
PP13
PP14
PP15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
D
C
B
PQ0
PQ1
PQ2
PQ3
PQ4
PQ5
PQ6
PQ7
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
Freescale General Business Use
Drawing Title:
MPC5748G 324 BGA Daughter Card
Page Title:
MPC5748G + OTB-324R-1.0-019-00
MPC5748G GPIO 2of2
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
5
of
8
5
4
3
2
1
Clocks
D
D
Oscillators and External Clock
4
PB9
EXT-CLK
(From SMA connector on main board)
C63
PB9
(EXTAL32)
R33
1.0M
DNP
C
12PF
3
Y20
32.768KHZ
C
2
PB8
C62
12PF
FC-255 32.7680K-A3
(Load Capacitance 7pF)
4
MCU-EXTAL
4
MCU-XTAL
J2
R8
1.0M
DNP
GND
Y1
40.0MHZ
J1
MCU-EXTAL
1
MCU-XTAL
EXTAL
12PF
1
PB8
(XTAL32)
1
1
4
C7
2
EXT-CLK
2
8
XTAL
C6
12PF
2
R34
3
GND
0
NX8045GB-40.000M-STD-CSJ-1 XTAL
(Optimised for Automotive, 8pF Load capacitance)
DNP
GND
B
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 324 BGA Daughter Card
Page Title:
Clocks
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
6
of
8
5
4
3
2
1
High Speed Signal Termination
D
D
Ethernet Termination
4
4
4
4
4
PG13
PG12
PH0
PH1
PH2
4
PG0
PG13
PG12
PH0
PH1
PH2
PG0
R6
R5
R4
R3
R2
50
50
50
50
50
R1
50
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
PG0-R
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
8
8
8
8
8
PG0-R
8
MLB_DAT
MLB_SIG
MLB_CLK
8
8
8
MLB_SN
8
MLB_SP
8
MLB_DN
8
MLB_DP
8
MLB_CN
8
MLB_CP
8
Place resistors as close as possible to MCU
MLB Termination
MLB_DAT
MLB_SIG
MLB_CLK
C
R20
100
DNP
4
4
PB14
PD15
4
PB13
4
PD14
4
PB15
5
PI8
R25
100
DNP
C
R29
100
DNP
PB14
R23
0
MLB_SN
PD15
R21
0
MLB_SP
PB13
R30
0
MLB_DN
PD14
R32
0
MLB_DP
PB15
R26
0
MLB_CN
PI8
R28
0
MLB_CP
R22
105.0 1%
(PD[15] Shared with MLB_DAT for 3-pin mode)
R31
105.0 1%
(PB[15] Shared with MLB_SIG for 3-pin mode)
R27
100 1%
(PI[8] Shared with MLB_CLK for 3-pin mode)
Place resistors as close as possible to MCU
From MCU
B
To Daughtercard
Layout Note - Place resistors as shown with
shared pad (as close to MCU as possible)
B
Remove R1 and
fit R2 to
enable 3-pin
signals
R1 Fitted by default
for LVDS 6-pin signals
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 324 BGA Daughter Card
Page Title:
High Speed Signal Termination
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Rev
A1
PDF: SPF-27900
Sheet
1
7
of
8
5
4
3
2
1
Daughter Card Connectors (Plugs)
Notes:
Connectors on Main board (Shown for reference)
- there was no neat way to fit these connectors onto a B sized sheet so unfortunately the sheet size
has been increased to C so will need to be printed on larger paper.
- The Crystal Signals are NOT routed via the daughtercard connectors
- The Specific MCU power pins are not routed via the daughter card however the jumpered MCU supply
lines are brought up from the main board (see the top pins of the connector on the left)
D
- The connector schematic symbols have been horizontally mirrored so they match the main EVB connector.
This has no bearing on the PCB placement or footprint. Pin1 on the recepticle mates with pin 1 on the
plug.
D
P21
6
C
EXT-CLK
4
PB2
5
4
5
5
5
5
5
5
4
5
5
4
5
PP11
PE6
PI3
PP10
PP5
PI1
PI2
PP9
PC13
PI0
PK10
PC8
PK13
5
5
4
5
PP2
PK15
PC15
PP7
5
PP6
5
5
5
5
5
PO12
PO7
PO10
PO4
PO9
4
5
5
5
5
PG5
PO14
PO0
PI7
PP0
4
5
5
4
4
PE1
PI6
PO5
PE11
PG3
4
PE8
4
4
PG9
PA0
4
4
4
PG7
PG8
PC10
4
5
PB1
PK2
4
5
5
5
5
PF13
PK4
PK6
PK8
PN14
4
4
5
PF9
PA14
PN13
5
5
5
5
5
5
PN11
PJ11
PJ10
PK0
PJ9
PN9
5
4
PJ13
PA4
5
4
5
5
PN10
PA15
PN3
PN6
5
4
PN0
PB10
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
(GND)
PH7
PH6
PB3
PH8
PP8
(GND)
PP3
PE7
PK9
(GND)
PC12
PK11
(GND)
PP4
PK14
PK12
PC9
PL0
(GND)
PP1
(GND)
PC14
PJ4
(GND)
PO11
PO8
(GND)
PH14
PO13
(GND)
(GND)
PG5
PO14
PO0
PI7
PP0
(GND)
PE1
PI6
PO5
PE11
PG3
(GND)
PE8
(GND)
PG9
PA0
(GND)
PG7
PG8
PC10
(GND)
(GND)
PB1
PK2
(GND)
PF13
PK4
PK6
PK8
PN14
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
PO1
PH13
PG4
PH15
PO15
PE10
PE0
PO6
(GND)
PG2
PA2
PE9
PA1
MCU-RSTx
PN15
PO3
(GND)
PG6
PC11
PO2
(GND)
PB0
PK1
PF12
(GND)
(GND)
(GND)
PK3
PK5
PF11
(GND)
(GND)
PF9
PA14
PN13
(GND)
PN11
PJ11
PJ10
PK0
PJ9
PN9
(GND)
PJ13
PA4
(GND)
PN10
PA15
PN3
PN6
(GND)
PN0
PB10
(GND)
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
PK7
PC6
PF8
(GND)
PC7
PN12
PJ12
(GND)
PJ15
(GND)
PN8
PF10
PN7
PJ14
(GND)
PN4
PA13
(GND)
PN5
PA12
PN2
PF1
PF0
(GND)
(GND)
MCU_3V3_S
B
2
MCU_5V0_S
2
MCU_1V25_L
P20
(GND)
EXT-CLK
(GND)
PB2
(GND)
PP11
PE6
PI3
PP10
PP5
PI1
PI2
PP9
PC13
PI0
PK10
PC8
PK13
(GND)
PP2
PK15
PC15
PP7
(GND)
PP6
(GND)
PO12
PO7
PO10
PO4
PO9
(GND)
MCU_5V0_S
MCU_1V25_L
(GND)
PH7
PH6
PB3
PH8
PP8
4
4
4
4
5
PP3
PE7
PK9
5
4
5
PC12
PK11
4
5
5
4
4
4
5
5
5
4
PM11
PH10
PH4
PE5
PM12
PI5
PQ0
PC5
4
4
4
PG14
PH12
PC4
5
4
4
5
4
4
4
5
4
5
5
5
PL9
PC2
PA6
PL3
PH11
PA5
PE14
PQ4
PG15
PQ5
PQ7
PP15
5
5
5
5
PL12
PL11
PL6
PL7
5
5
5
4
4
PL15
PM1
PM2
PE12
PA11
4
4
4
4
7
7
4
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
5
4
5
5
5
5
PM8
PH3
PM3
PM6
PM13
PM14
4
4
5
4
PD13
PD12
PI11
PD10
7
7
7
MLB_DAT
MLB_SIG
MLB_CLK
PP4
PK14
PK12
PC9
PL0
5
5
5
4
5
PP1
5
PC14
PJ4
4
5
PO11
PO8
5
5
PH14
PO13
4
5
PO1
PH13
PG4
PH15
PO15
PE10
PE0
PO6
5
4
4
4
5
4
4
5
PG2
PA2
PE9
PA1
MCU-RSTx
PN15
PO3
4
4
4
4
4
5
5
PG6
PC11
PO2
4
4
5
PB0
PK1
PF12
4
5
4
PK3
PK5
PF11
5
5
4
PK7
PC6
PF8
5
4
4
7
7
MLB_SN
MLB_SP
PC7
PN12
PJ12
4
5
5
4
5
5
PD7
PJ5
PJ0
PJ15
5
PN8
PF10
PN7
PJ14
5
4
5
5
4
4
4
4
5
PD5
PB5
PB11
PD1
PJ1
PN4
PA13
5
4
PN5
PA12
PN2
PF1
PF0
5
4
5
4
4
4
5
4
4
5
5
PD8
PI9
PF5
PB4
PJ2
PJ3
4
5
PF2
PM15
MCU_3V3_S
2
MCU_3V3_L
MCU_5V0_L
2
2
TPV1
MCU_3V3_L
MCU_5V0_L
(GND)
TPV3
TPV2
(GND)
PM11
PH10
PH4
PE5
PM12
PI5
PQ0
PC5
(GND)
PG14
PH12
PC4
(GND)
PL9
PC2
PA6
PL3
PH11
PA5
PE14
PQ4
PG15
PQ5
PQ7
PP15
(GND)
PL12
PL11
PL6
PL7
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
PC1
PE3
PH5
PC0
PQ3
PC3
PE4
PH9
PL10
PE15
PORSTx
PE2
PL4
PG11
PQ1
(GND)
PG10
PQ2
PL8
PQ6
(GND)
PP13
PP12
PI4
PP14
(GND)
PL2
PL5
PL13
PM0
(GND)
(GND)
PL15
PM1
PM2
PE12
PA11
(GND)
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
(GND)
PM8
PH3
PM3
PM6
PM13
PM14
(GND)
PD13
PD12
PI11
PD10
(GND)
MLB_DAT
MLB_SIG
MLB_CLK
(GND)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
PL14
PM9
PM7
PA10
PA9
PA8
PF14
PG0-R
PH2-R
(GND)
PG12-R
PG13-R
(GND)
(GND)
PM10
PM4
PL1
(GND)
PM5
PI13
PB12
PD9
PI12
PB7
PI15
(GND)
MLB_CN
MLB_CP
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
MLB_DN
MLB_DP
(GND)
(GND)
PI14
PJ7
PD11
PJ6
PD6
PD2
PD3
PJ8
(GND)
PB6
PD0
PI10
(GND)
PD4
PF6
PN1
(GND)
PF4
PF7
PF3
(GND)
(GND)
DC_3V3_S
(GND)
MLB_SN
MLB_SP
(GND)
(GND)
PD7
PJ5
PJ0
(GND)
PD5
PB5
PB11
PD1
PJ1
(GND)
PD8
PI9
PF5
PB4
PJ2
PJ3
(GND)
(GND)
PF2
PM15
(GND)
(GND)
DC_5V0_S
DC_P12V
DC_1V25_L
PLUG 180
GND
4
4
4
4
5
4
4
4
5
4
4
4
5
4
5
PG10
PQ2
PL8
PQ6
4
5
5
5
PP13
PP12
PI4
PP14
5
5
5
5
PL2
PL5
PL13
PM0
5
5
5
5
PL14
PM9
PM7
PA10
PA9
PA8
PF14
PG0-R
PH2-R
5
5
5
4
4
4
4
7
7
PG12-R
PG13-R
7
7
PM10
PM4
PL1
5
5
5
PM5
PI13
PB12
PD9
PI12
PB7
PI15
5
5
4
4
5
4
5
MLB_CN
MLB_CP
7
7
MLB_DN
MLB_DP
7
7
PI14
PJ7
PD11
PJ6
PD6
PD2
PD3
PJ8
5
5
4
5
4
4
4
5
PB6
PD0
PI10
4
4
5
PD4
PF6
PN1
4
4
5
PF4
PF7
PF3
4
4
4
C
B
TPV4
DC_3V3_L
DC_5V0_L
TPV5
TPV6
PLUG 180
Plug
A
PC1
PE3
PH5
PC0
PQ3
PC3
PE4
PH9
PL10
PE15
PORSTx
PE2
PL4
PG11
PQ1
Plug
A
GND
GND
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
Freescale General Business Use
Drawing Title:
MPC5748G 324 BGA Daughter Card
Page Title:
Daughter Card Connectors (Plugs)
5
4
3
2
Size
C
Document Number
Date:
Tuesday, August 18, 2015
SCH-27900
Sheet
1
Rev
A1
PDF: SPF-27900
8
of
8
256 BGA DC
5
4
3
2
1
MPC5748G Customer EVB 256BGA [6M/3M] Daughter Card (X-MPC574XG-256DS)
Table Of Contents:
D
Sheet 2
Sheet 3
Sheet 4
Sheet 5
Sheet 6
Sheet 7
Sheet 8
Power - MPC5748G power pins footprint
Power - MPC5748G Decoupling Capacitors
GPIO - MPC5748G GPIO pins 1 of 2
GPIO - MPC5748G GPIO pins 2 of 2
Clocks
Bus Termination
Daughtercard Connectors
Revision Information
Rev Date
X1 11 Mar 2013
X2 13 Mar 2013
X3 15 Mar 2013
X4 29 Mar 2013
X5 15 Apr 2013
15 Apr 2013
A
X1 16 Mar 2014
A
A1
18 Apr 2014
18 Aug 2015
Designer
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Jesus Sanchez
Jesus Sanchez
Alasdair Robertson
Comments
Initial release sent for review based on X-MPC574XG-324DS X2
Version sent to Pre Layout, incorporating fixes from review
Component consolodation, Few minor changes. Sent to Layout
Changes made during layout to Daughtercard Connectors
LAY RefDes Re-Sequence & SCH Back-Annotate
Post Layout (Back Annotated). Matches PCB RevA
Changes on MCU Power to validate MPC5746
SCH-27899 change to SCH-28341
Post Layout. RevA.
Tidy up Schematics for UM (RevA PCB)
D
C
C
Caution:
These schematics are provided for reference purposes only. As such,
Freescale does not make any warranty, implied or otherwise, as to the
suitability of circuit design or component selection (type or value) used in
these schematics for hardware design using the Freescale MPC5748G family
of Microprocessors. Customers using any part of these schematics as a
basis for hardware design, do so at their own risk and Freescale does not
assume any liability for such a hardware design.
B
B
Notes:
-
A
All components and board processes are to be ROHS compliant
All small capacitors are 0402 unless otherwise stated
All resistors are 0603 5% 0.1w unless otherwise stated. All zero ohm links are 0603
All connectors and headers are denoted Px and are 2.54mm pitch unless otherwise stated
All jumpers are denoted Jx. Jumpers are 2mm pitch
Jumper default positions are shown in the schematics. For 3 way jumpers, default is always posn 1-2.
2 Pin jumpers generally have the "source" on pin 1.
- All switches are denoted SWx
- All test points are denoted TPx
- Test point Vias are denoted TPVx
User notes are given throughtout the schematics.
Specific PCB LAYOUT notes are detailed in ITALICS
Automotive Microcontroller Applications
East Kilbride, Scotland
Freescale General Business Use
This document contains information proprietary to Freescale and shall not be used for engineering design,
procurement or manufacture in whole or in part without the express written permission of Freescale
A
Freescale AISG Applications, East Kilbride
Designer:
Drawing Title:
A. Robertson / J. Sanchez
MPC5748G 256 BGA Daughter Card
Drawn by:
Page Title:
A. Robertson
Index and Title Page
Approved:
Size
B
Document Number
Date:
Tuesday, August 18, 2015
A. Robertson / J. Sanchez
5
4
3
2
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
1
of
8
5
4
3
MPC5748G MCU Power Connections
2
Caution:
Default Configuraiton:
- ALL MCU supply voltages are set to 3.3V (ADC0, ADC1, VDD_HV_A,
VDD_HV_B, VDD_HV_C, VBallast)
- VDD_HV_FLA = External 3.3V supplied (jumper fitted)
- VDD_LV Supplied from ballast transistor
- If VDD_HV_A is driven from 5V, the VDD_HV_FLA pin
must not be supplied from 3.3V (remove the HVA_FLA
jumper)
- Don't attempt to over drive an analogue pad to 5V
when the digital VDD_HV_x supply is set to 3.3V. This
will trigger the ESD protectrion on that pad. For
example if VDD_HV_A is set to 3.3V and the analogue
supplies are set to 5V, you cannot drive 5V into a
pad in the VDD_HV_A domain
D
From MCU
supply
jumpers on
main board
MCU_1V25_L
8 MCU_1V25_L
1
HVA_CAP
2
MCU_5V0_L
3v3 1
J12
MCU_3V3_L
3v3
5v0
J8
2
3
M9
U1B
DAC Ref
VIN1_CMP_REF
VDD_LP_DEC
K2
D8
E5
H14
J3
K10
K11
L10
L11
2
J10
VDD_LV_D8
VDD_LV_E5
VDD_LV_H14
VDD_LV_J3
VDD_LV_K10
VDD_LV_K11
VDD_LV_L10
VDD_LV_L11
J2
VRC_CTRL
VDD_HV_FLA_H2
VDD_HV_C_M10
Flash
(Current Limit Resistor to
protecxt against case when
other MCU supplies are
disconnected and external
reference supply is live)
R36
1.0K
Differences to 324BGA
-
1.25v Core & External Ballast
B
more VDD_HV_A on 256BGA
fewer VDD_HV_B
fewer VDD_LV
more VSS_HV
fewer VSS_LV
VSS_LV_E6
VSS_LV_H6
VSS_LV_H7
VSS_LV_H15
VSS_LV_J6
VSS_LV_J7
VSS_LV_J8
VSS_LV_K6
VSS_LV_K7
VSS_LV_K8
VSS_LV_K9
VSS_LV_L7
VSS_LV_L8
VSS_LV_L9
1
1
1
2
1
L6
TP3
PPC5748GSK0MMJ6 + OTB-256(324R)-1.0-006-00
2
HVA_CAP
E6
H6
H7
H15
J6
J7
J8
K6
K7
K8
K9
L7
L8
L9
VSS_LV_L6
VSS_HV_VPP
J1
VSS_HV_G6
VSS_HV_G7
VSS_HV_G8
VSS_HV_G9
VSS_HV_G10
VSS_HV_G11
VSS_HV_H8
VSS_HV_H9
VSS_HV_H10
VSS_HV_H11
VSS_HV_J9
VSS_HV_J10
VSS_HV_J11
VSS_HV_T9
Power Pins
G6
G7
G8
G9
G10
G11
H8
H9
H10
H11
J9
J10
J11
T9
M16
T15
1
TP11 TP12 TP13 TP14
VSS_HV_ADC1
VSS_HV_ADC0
Package 2of3
TP10
H2
M10
G13
VDD_HV_B_G13
VDD_HV_A_C2
VDD_HV_A_C9
VDD_HV_A_E16
VDD_HV_A_H13
VDD_HV_A_N6
VDD_HV_A_N9
VDD_HV_A_R9
C2
C9
E16
H13
N6
N9
R9
M11
VDD_HV_ADC1_REF
VDD_HV_ADC0
L16
R15
VDD_HV_ADC1
MPC5748G 256 BGA
Analogue
LV_CAP
R35
0
LVDEC_CAP
4
3
1
C
E_CAP
2
HVFLA_CAP
HVC_CAP
HVB_CAP
HVA_CAP
MJD31CT4
Q20
TP1
B
DAC External
Ref Voltage
Select
J11
TP2
1
ADC1REF_CAP
ADC1_CAP
ADC0_CAP
Individual MCU
supply control
jumpers
J7
0
TPH2
TPH3
1
3v3
2
J6
3
1
5v0
2
J5
R7
3v3
3
5v0
2
2
J4
3v3
1
5v0
3
1
3v3
2
J3
C
3
5v0
1
3
1
3v3
R37
1.0
DNP
3 1
MCU_3V3_S
1
8 MCU_3V3_L
5v0 3
1
8 MCU_5V0_L
D
J9
MCU_5V0_S
2
8 MCU_3V3_S
This is not necessarily the same as the default shown in the RM. All
VDD_HV_x domains have at least one peripheral that only functions at
3.3V. Therefore the default is to run these from 3.3V. The analogue pins
can only be driven to the same voltage as the VDD_HV_x domain they are
situated in (ie max 3.3V) so makes sense for the analogue supply and
reference to be 3.3V
B_CAP
8 MCU_5V0_S
1
GND
0
J13
R38
10K
R24
Automotive Microcontroller
Applications
East Kilbride, Scotland
GND
1
GND
A
GND
TPH1
1
ADC1_GND
3
ADC0_GND
A
Freescale General Business Use
Drawing Title:
Ground Links
(0 Ohm
Resistors)
R9
ADC0_GND
0
R10
GND
ADC1_GND
0
MPC5748G 256 BGA Daughter Card
Page Title:
MPC5748G MCU Power
GND
GND
5
GND
C63
1.0 UF
DNP
R39
10K
DNP
4
3
GND
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
2
of
8
5
4
3
2
1
MPC5748G MCU Decoupling and bulk storage
Capacitor Types:
470pF - Ceramic COG, 50v 5% 0402
1000pF - Ceramic COG, 50V 5% 0402
4700pF - Ceramic X7R, 50V 10% 0402
Flash
ADC
ADC0_CAP
ADC1_CAP
C48
1000pF
ADC1REF_CAP
C46
1000pF
HVFLA_CAP
D
C2
10UF
DNP
+
C3
10UF
DNP
C59
1.0 UF
C56
0.1UF
ADC0_GND
+
C47
C58
1.0 UF
1000pF
C55
0.1UF
ADC1_GND
C36
C57
1.0 UF
C34
2.2UF
LMK107B7225KA-T
(low ESR)
1000pF
ADC1_GND
0.01uF
0.1uF
0.68uF
1.0uF
2.2uF
-
- Ceramic X7R, 50V 10% 0402
Ceramic X7R, 16V 10% 0402
Ceramic X7R 16V 10% 0805 (Murata GCM219R71C684KA37 )
Ceraminc X7R, 10V 10% 0603 (Taiyo Yuden LMK107B7105KA-T)
Ceraminc X7R, 10V, 10%, 0603 (Taiyo Yuden LMK107B7225KA-TR)
4.7uF
10uF
- TANT, 12.5V 20% ESR=0.08R 7343
- TANT, 35V 10% ESR=0.125R CC7343-31
D
4.7uF Alternative (150-78844)- Polymer ALU, 16V 20% ESR=0.08R
7343-18
GND
Place small Caps as close as possible to MCU pins
VDD_HVA
VDD_HVB
HVA_CAP
C27
470pF
C51
1000pF
C22
470pF
C54
1000pF
C28
470pF
C37
1000pF
C40
470pF
+ C1
10UF
C
VDD_HVC
HVB_CAP
HVC_CAP
C33
470pF
+ C4
10UF
DNP
C26
0.1UF
GND
C52
0.1UF
C23
0.1UF
C53
0.1UF
C30
0.1UF
C38
0.1UF
C41
0.1UF
C42
1000pF
+ C5
10UF
DNP
C35
0.1UF
GND
C
C44
0.1UF
GND
Place 10uF cap to west side of package
Place small caps close to each MCU pin
Ballast Transistor
VDD_LV
LV_CAP
C24
0.1UF
C50
0.1UF
DNP
C49
0.1UF
C25
0.1UF
DNP
B_CAP
C8
C32
0.1UF
C39
0.1UF
C45
0.1UF
DNP
LP Internal Reg Cap
E_CAP
C21
0.1UF
DNP
LV_CAP
LVDEC_CAP
4700pF
C9
2.2UF
DNP
(low
ESR)
Place
close to
transistor
B
GND
E_CAP
C10
2.2UF
DNP
(low
ESR)
C29
0.68uF
(low
ESR)
C60
0.68uF
(low
ESR)
C31
0.68uF
(low
ESR)
C20
0.68uF
DNP
(low
ESR)
C43
1uF
LMK107B7105KA-T
(low ESR)
B
(Murata GCM219R71C684KA37)
GND
VDD_LV (1.25V) Decoupling. Place one of the non DNP caps each side of the device
as close as possible to pin. Distribute other (DNP) caps around rest of pins
GND
2.2uF caps
are DNP.
Place close
to emitter
See caps below for Bypass Transistor bulk storage (some on VDD1V2 rail)
GND
Place one 0.68uF cap footprint
each side of package
One of these is DNP. May replace 2 caps with
0.47uF to keep overall capacitance within limits
Differences to 324BGA
A
Automotive Microcontroller
Applications
East Kilbride, Scotland
- 1 more VDD_HV_A capacitor pair
- 1 fewer VDD_HV_B capacitor pair
- 1 fewer VDD_LV capacitor (one of DNP caps)
A
Freescale General Business Use
Drawing Title:
MPC5748G 256 BGA Daughter Card
Page Title:
MPC5748G MCU Decoupling
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
3
of
8
5
4
3
2
1
MPC5748G GPIO 1 of 2
U1A
** PA1 is also NMI. Routed to I/O Matrix
D
(WKPU2 / NMI0)
(WKPU3)
Key to text colours:
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
C
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
(SD_CD - WKPU19)
(SW1 & GPIO**)
(SW2 & GPIO)
(MII_RXCLK)
(CMP1_13 / IO)
(SAI_GPIO)
(MLB_GPIO)
(MII_RXD2)
(RMII_RXD1)
(RMII_RXD0)
(MII_COL)
(RMII_RXER)
(CMP1_15 / IO)
(CMP1_14 / IO)
(CMP1_12 / IO)
(CMP1_10 / IO)
8
8
8
8
8
8
8
8
6
6
8
8
8
7
7
7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
(CAN0_TX)
(CAN0_RX)
(LIN0_TX)
(LIN0_RX)
(ADC_POT)
(GPIO)
(GPIO)
(GPIO)
(XTAL32)
(EXTAL32)
(SAI0_SYNC)
(GPIO)
(GPIO)
(MLB_DN)
(MLB_SN)
(MLB_CN / SIG)
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
L3
M2
A2
D4
T16
N13
N14
R16
T11
T10
N7
M13
L14
L15
K15
K16
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
(TDI)
(TDO)
(USB1_CLK)
(USB1_DIR)
(FR_B_TX_EN)
(FR_A_TX)
(LIN1_TX)
(LIN1_RX)
(RS232_TX)
(RS232_RX)
(CAN1_TX)
(CAN1_RX)
(FR_DBG0)
(FR_DBG1)
(FR_DBG2)
(FR_DBG3)
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
B10
D9
B11
C11
A9
B9
N3
N4
B3
C3
L1
K4
B4
A3
B2
A1
8
8
8
8
8
8
8
8
8
8
8
8
8
8
7
7
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
PD14
PD15
(HEX1 & GPIO)
(HEX2 & GPIO)
(HEX3 & GPIO)
(HEX4 & GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO & MLB_ST)
(MLB_DP)
(MLB_SP / DAT)
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
PD14
PD15
R12
T13
N11
R13
P12
T14
R14
P13
P14
N16
M14
M15
L13
K14
K13
J13
8
8
MCU-RSTx
PORSTx
MCU-RSTx
PORSTx
K1
C8
6
6
MCU-XTAL
MCU-EXTAL
MCU-XTAL
MCU-EXTAL
T7
T8
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
G4
F3
F1
G16
T2
C10
D11
C15
B16
B15
A15
B14
P6
R5
P4
R2
B
A
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
MPC5748G 256 BGA
Package 1of3 GPIO Pins1
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PD11
PD12
PD13
PD14
PD15
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
G2
F4
A7
A10
A8
B8
B6
A5
G1
H1
G3
H3
C14
C16
A14
C12
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
(MLB_I2C1_SCL)
(MLB_I2C1_SDA)
(FR_A_TX_EN)
(FR_A_RX)
(FR_B_TX)
(FR_B_RX)
(SD_CMD)
(SD_CLK)
(SAI_I2C2_SDA)
(SAI_I2C2_SCL)
(SAI_I2C3_SDA)
(SAI_I2C3_SCL)
(MII_CRS)
(MII_RXD3)
(USB1_D2)
(USB1_D3)
P7
T6
R6
R7
R8
P8
N8
P9
N2
M4
P2
R1
P1
P3
D14
D15
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
(SAI0_MCLK)
(SAI0_BCLK)
(SAI0_D3)
(SAI0_D2)
(SAI0_D1)
(SAI0_D0)
(SAI1_SYNC)
(SAI1_MCLK)
(GPIO)
(SW3 & GPIO) WKPU22
(CMP1_8 / IO)
(SW4 & GPIO) WKPU15
(GPIO)
(CMP1_11 /IO)
(RMII_MDIO)
(RMII_RXDV)
E13
E14
E4
E1
F2
D1
M1
L2
K3
J4
B13
A16
F15
F16
C13
D13
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
(RMII_MDC)
(RMII_TXCLK)
(LED1 & GPIO)
(LED2 & GPIO)
(LED3 & GPIO)
(LED4 & GPIO)
(CLKOUT1 GPIO)
(CLKOUT0 GPIO)
(GPIO)
(MLB_IRQ - WKPU21)
(USB1_D4)
(USB1_D5)
(MII_TXD2)
(MII_TXD3)
(USB1_D0)
(USB1_D1)
E15
F13
D16
F14
D7
B7
C7
C6
A6
A11
D10
A13
B12
B1
C1
E3
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
(RMII_TXD1)
(RMII_TXD0)
(RMII_TXEN)
(eMIOS1_UC_5H)
(eMIOS1_UC_6H)
(eMIOS1_UC_7H)
(MLB_RST)
(MLB_PWR)
(SD_WP)
(TCK)
(TMS)
(USB1_D6)
(USB1_D7)
(GPIO)
(GPIO)
(GPIO)
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
7
8
8
8
8
8
8
8
8
8
8
8
7
7
8
8
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
7
7
7
8
8
8
8
8
8
8
8
8
8
8
8
8
D
C
(eMIOS
(eMIOS
(eMIOS
(eMIOS
E1UC_11_H)
E1UC_12_H)
E1UC_13_H)
E1UC_14_H)
B
Differences to 324BGA
(none on this page)
RESET
PORST
Automotive Microcontroller
Applications
East Kilbride, Scotland
XTAL
EXTAL
A
Freescale General Business Use
Drawing Title:
PPC5748GSK0MMJ6 + OTB-256(324R)-1.0-006-00
MPC5748G 256 BGA Daughter Card
Page Title:
MPC5748G GPIO 1of2
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
4
of
8
5
4
3
2
1
MPC5748G GPIO 2 of 2
U1C
Key to text colours:
D
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
C
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
PI9
PI10
PI11
PI12
PI13
PI14
PI15
C5
A4
D6
B5
A12
D12
D2
E2
J14
J15
J16
H16
G15
G14
T12
P11
8
8
8
8
8
8
8
8
7
8
8
8
8
8
8
8
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
PI9
PI10
PI11
PI12
PI13
PI14
PI15
(SD_D3)
(SD_D2)
(SD_D1)
(SD_D0)
(USB1_STP)
(USB1_NXT)
(USB0_RST)
(USB1_RST)
(MLB_CP / CLK)
(GPIO)
(GPIO)
(ENET_RST)
(GPIO & MLB_PS0)
(GPIO & MLB_PS1)
(SAI2_D0)
(SAI2_MCLK)
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PJ0
PJ1
PJ2
PJ3
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
(SAI2_SYNC)
(SAI2_BCLK)
(SAI1_D0)
(SAI1_BCLK)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
PJ0
PJ1
PJ2
PJ3
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
R11
N10
R10
P10
D3
N12
N15
P16
P15
P5
T5
R3
T1
N5
T4
R4
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
T3
H4
L4
N1
M3
M5
M6
M7
M8
E8
E7
F8
G12
H12
J12
D5
8
8
PL0
PL1
(GPIO)
(GPIO)
PL0
PL1
B
C4
F7
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
PI9
PI10
PI11
PI12
PI13
PI14
PI15
MPC5748G 256 BGA
Package 3of3 GPIO Pins2
PM3
PM4
PM5
PM14
K12
L12
F9
PM3
PM4
PM5
M12 PM14
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
PM3
PM4
PM5
8
8
8
PM14
8
D
PJ0
PJ1
PJ2
PJ3
PJ4
PJ5
PJ6
PJ7
PJ8
PJ9
PJ10
PJ11
PJ12
PJ13
PJ14
PJ15
C
PK0
PK1
PK2
PK3
PK4
PK5
PK6
PK7
PK8
PK9
PK10
PK11
PK12
PK13
PK14
PK15
PO0
PO1
K5
L5
PO0
PO1
(GPIO)
(GPIO)
PO0
PO1
8
8
B
PL0
PL1
Differences to 324BGA
PP12
PP13
PP14
PP15
8
8
8
8
8
8
8
8
A
PQ0
PQ1
PQ2
PQ3
PQ4
PQ5
PQ6
PQ7
(USB0_STP)
(USB0_CLK)
(USB0_DIR)
(USB0_NXT)
(USB0_D7)
(USB0_D6)
(USB0_D5)
(USB0_D4)
PQ0
PQ1
PQ2
PQ3
PQ4
PQ5
PQ6
PQ7
J5
H5
G5
F5
F6
E9
F10
E10
E12
F12
E11
F11
PP12
PP13
PP14
PP15
(USB0_D3)
(USB0_D2)
(USB0_D1)
(USB0_D0)
PP12
PP13
PP14
PP15
PQ0
PQ1
PQ2
PQ3
PQ4
PQ5
PQ6
PQ7
8
8
8
8
14
12
16
14
12
fewer
fewer
fewer
fewer
fewer
pins
pins
pins
pins
pins
on
on
on
on
on
Port
Port
Port
Port
Port
L
M
N
O
P
(And corresponding changes
to daughtercard connectors)
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
Freescale General Business Use
Drawing Title:
MPC5748G 256 BGA Daughter Card
Page Title:
PPC5748GSK0MMJ6 + OTB-256(324R)-1.0-006-00
5
4
3
MPC5748G GPIO 2of2
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
5
of
8
5
4
3
2
1
Clocks
D
D
Oscillators and External Clock
4
PB9
EXT-CLK
(From SMA connector on main board)
C62
PB9
(EXTAL32)
R33
1.0M
DNP
C
12PF
3
Y20
32.768KHZ
C
2
PB8
C61
12PF
FC-255 32.7680K-A3
(Load Capacitance 7pF)
4
MCU-EXTAL
4
MCU-XTAL
J2
R8
1.0M
DNP
GND
Y1
40.0MHZ
J1
MCU-EXTAL
1
MCU-XTAL
EXTAL
12PF
1
PB8
(XTAL32)
1
1
4
C7
2
EXT-CLK
2
8
XTAL
C6
12PF
2
R34
3
GND
0
NX8045GB-40.000M-STD-CSJ-1 XTAL
(Optimised for Automotive, 8pF Load capacitance)
DNP
GND
B
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 256 BGA Daughter Card
Page Title:
Clocks
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
6
of
8
5
4
3
2
1
High Speed Signal Termination
D
D
Ethernet Termination
4
4
4
4
4
PG13
PG12
PH0
PH1
PH2
4
PG0
PG13
PG12
PH0
PH1
PH2
PG0
R4
R6
R5
R3
R1
50
50
50
50
50
R2
50
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
PG0-R
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
8
8
8
8
8
PG0-R
8
MLB_DAT
MLB_SIG
MLB_CLK
8
8
8
MLB_SN
8
MLB_SP
8
MLB_DN
8
MLB_DP
8
MLB_CN
8
MLB_CP
8
Place resistors as close as possible to MCU
MLB Termination
MLB_DAT
MLB_SIG
MLB_CLK
C
R20
100
DNP
4
4
PB14
PD15
4
PB13
4
PD14
4
PB15
5
PI8
R25
100
DNP
C
R29
100
DNP
PB14
R23
0
MLB_SN
PD15
R21
0
MLB_SP
PB13
R30
0
MLB_DN
PD14
R32
0
MLB_DP
PB15
R26
0
MLB_CN
PI8
R28
0
MLB_CP
R22
105.0 1%
(PD[15] Shared with MLB_DAT for 3-pin mode)
R31
105.0 1%
(PB[15] Shared with MLB_SIG for 3-pin mode)
R27
100 1%
(PI[8] Shared with MLB_CLK for 3-pin mode)
Place resistors as close as possible to MCU
From MCU
B
To Daughtercard
Layout Note - Place resistors as shown with
shared pad (as close to MCU as possible)
B
Remove R1 and
fit R2 to
enable 3-pin
signals
R1 Fitted by default
for LVDS 6-pin signals
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 256 BGA Daughter Card
Page Title:
High Speed Signal Termination
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Rev
A
PDF: SPF-28341
Sheet
1
7
of
8
5
4
3
2
1
Daughter Card Connectors (Plugs)
Notes:
Connectors on Main board (Shown for reference)
- there was no neat way to fit these connectors onto a B sized sheet so unfortunately the sheet
size has been increased to C so will need to be printed on larger paper.
- The Crystal Signals are NOT routed via the daughtercard connectors
- The Specific MCU power pins are not routed via the daughter card however the jumpered MCU
supply lines are brought up from the main board (see the top pins of the connector on the left)
D
- The connector schematic symbols have been horizontally mirrored so they match the main EVB
connector. This has no bearing on the PCB placement or footprint. Pin1 on the recepticle mates
with pin 1 on the plug.
D
P21
6
EXT-CLK
4
PB2
4
5
PE6
PI3
5
5
PI1
PI2
4
5
5
4
5
PC13
PI0
PK10
PC8
PK13
5
4
PK15
PC15
C
4
PG5
5
5
PO0
PI7
4
5
PE1
PI6
4
4
PE11
PG3
4
PE8
4
4
PG9
PA0
4
4
4
PG7
PG8
PC10
4
5
PB1
PK2
4
5
5
5
PF13
PK4
PK6
PK8
B
4
4
PF9
PA14
5
5
5
5
PJ11
PJ10
PK0
PJ9
5
4
PJ13
PA4
4
PA15
4
PB10
2
MCU_5V0_S
2
MCU_1V25_L
P20
(GND)
EXT-CLK
(GND)
PB2
(GND)
(PP11)
PE6
PI3
(PP10)
(PP5)
PI1
PI2
(PP9)
PC13
PI0
PK10
PC8
PK13
(GND)
(PP2)
PK15
PC15
(PP7)
(GND)
(PP6)
(GND)
(PO12)
(PO7)
(PO10)
(PO4)
(PO9)
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
(GND)
PH7
PH6
PB3
PH8
(PP8)
(GND)
(PP3)
PE7
PK9
(GND)
PC12
PK11
(GND)
(PP4)
PK14
PK12
PC9
PL0
(GND)
(PP1)
(GND)
PC14
PJ4
(GND)
(PO11)
(PO8)
(GND)
PH14
(PO13)
(GND)
(GND)
PG5
(PO14)
PO0
PI7
(PP0)
(GND)
PE1
PI6
(PO5)
PE11
PG3
(GND)
PE8
(GND)
PG9
PA0
(GND)
PG7
PG8
PC10
(GND)
(GND)
PB1
PK2
(GND)
PF13
PK4
PK6
PK8
(PN14)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
PO1
PH13
PG4
PH15
(PO15)
PE10
PE0
(PO6)
(GND)
PG2
PA2
PE9
PA1
MCU-RSTx
(PN15)
(PO3)
(GND)
PG6
PC11
(PO2)
(GND)
PB0
PK1
PF12
(GND)
(GND)
(GND)
PK3
PK5
PF11
(GND)
(GND)
PF9
PA14
(PN13)
(GND)
(PN11)
PJ11
PJ10
PK0
PJ9
(PN9)
(GND)
PJ13
PA4
(GND)
(PN10)
PA15
(PN3)
(PN6)
(GND)
(PN0)
PB10
(GND)
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
PK7
PC6
PF8
(GND)
PC7
(PN12)
PJ12
(GND)
PJ15
(GND)
(PN8)
PF10
(PN7)
PJ14
(GND)
(PN4)
PA13
(GND)
(PN5)
PA12
(PN2)
PF1
PF0
(GND)
(GND)
MCU_3V3_S
MCU_5V0_S
MCU_1V25_L
(GND)
PH7
PH6
PB3
PH8
4
4
4
4
PE7
PK9
4
5
PC12
PK11
4
5
PK14
PK12
PC9
PL0
5
5
4
5
PC14
PJ4
4
5
PH14
4
PO1
PH13
PG4
PH15
5
4
4
4
PE10
PE0
4
4
PG2
PA2
PE9
PA1
MCU-RSTx
4
4
4
4
4
PG6
PC11
4
4
PB0
PK1
PF12
4
5
4
PK3
PK5
PF11
5
5
4
4
4
4
PH10
PH4
PE5
5
5
4
PI5
PQ0
PC5
4
4
4
PG14
PH12
PC4
4
4
PC2
PA6
4
4
4
5
4
5
5
5
PH11
PA5
PE14
PQ4
PG15
PQ5
PQ7
PP15
4
4
PE12
PA11
4
4
4
4
7
7
4
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
4
5
PH3
PM3
5
PM14
4
4
5
4
PD13
PD12
PI11
PD10
7
7
7
MLB_DAT
MLB_SIG
MLB_CLK
PK7
PC6
PF8
5
4
4
7
7
MLB_SN
MLB_SP
PC7
4
PJ12
5
4
5
5
PD7
PJ5
PJ0
PJ15
5
PF10
4
PD5
PB5
PB11
PD1
PJ1
PJ14
5
4
4
4
4
5
PA13
4
PA12
4
4
5
4
4
5
5
PD8
PI9
PF5
PB4
PJ2
PJ3
PF1
PF0
4
4
4
PF2
MCU_3V3_S
2
MCU_3V3_L
MCU_5V0_L
2
2
TPV1
MCU_3V3_L
MCU_5V0_L
(GND)
TPV3
TPV2
(GND)
(PM11)
PH10
PH4
PE5
(PM12)
PI5
PQ0
PC5
(GND)
PG14
PH12
PC4
(GND)
(PL9)
PC2
PA6
(PL3)
PH11
PA5
PE14
PQ4
PG15
PQ5
PQ7
PP15
(GND)
(PL12)
(PL11)
(PL6)
(PL7)
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
PC1
PE3
PH5
PC0
PQ3
PC3
PE4
PH9
(PL10)
PE15
PORSTx
PE2
(PL4)
PG11
PQ1
(GND)
PG10
PQ2
(PL8)
PQ6
(GND)
PP13
PP12
PI4
PP14
(GND)
(PL2)
(PL5)
(PL13)
(PM0)
(GND)
(GND)
(PL15)
(PM1)
(PM2)
PE12
PA11
(GND)
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
(GND)
(PM8)
PH3
PM3
(PM6)
(PM13)
PM14
(GND)
PD13
PD12
PI11
PD10
(GND)
MLB_DAT
MLB_SIG
MLB_CLK
(GND)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
(PL14)
(PM9)
(PM7)
PA10
PA9
PA8
PF14
PG0-R
PH2-R
(GND)
PG12-R
PG13-R
(GND)
(GND)
(PM10)
PM4
PL1
(GND)
PM5
PI13
PB12
PD9
PI12
PB7
PI15
(GND)
MLB_CN
MLB_CP
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
MLB_DN
MLB_DP
(GND)
(GND)
PI14
PJ7
PD11
PJ6
PD6
PD2
PD3
PJ8
(GND)
PB6
PD0
PI10
(GND)
PD4
PF6
(PN1)
(GND)
PF4
PF7
PF3
(GND)
(GND)
DC_3V3_S
(GND)
MLB_SN
MLB_SP
(GND)
(GND)
PD7
PJ5
PJ0
(GND)
PD5
PB5
PB11
PD1
PJ1
(GND)
PD8
PI9
PF5
PB4
PJ2
PJ3
(GND)
(GND)
PF2
(PM15)
(GND)
(GND)
DC_5V0_S
DC_P12V
DC_1V25_L
PLUG 180
GND
4
4
4
4
5
4
4
4
PE15
PORSTx
PE2
4
4
4
PG11
PQ1
4
5
PG10
PQ2
4
5
PQ6
5
PP13
PP12
PI4
PP14
5
5
5
5
PA10
PA9
PA8
PF14
PG0-R
PH2-R
4
4
4
4
7
7
PG12-R
PG13-R
7
7
PM4
PL1
5
5
PM5
PI13
PB12
PD9
PI12
PB7
PI15
5
5
4
4
5
4
5
MLB_CN
MLB_CP
7
7
C
B
MLB_DN
MLB_DP
7
7
PI14
PJ7
PD11
PJ6
PD6
PD2
PD3
PJ8
5
5
4
5
4
4
4
5
PB6
PD0
PI10
4
4
5
PD4
PF6
4
4
PF4
PF7
PF3
4
4
4
TPV4
DC_3V3_L
DC_5V0_L
TPV5
TPV6
PLUG 180
Plug
Plug
A
PC1
PE3
PH5
PC0
PQ3
PC3
PE4
PH9
A
GND
GND
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
Freescale General Business Use
Drawing Title:
MPC5748G 256 BGA Daughter Card
Page Title:
Daughter Card Connectors (Plugs)
5
4
3
2
Size
C
Document Number
Date:
Tuesday, August 18, 2015
SCH-28341
Sheet
1
Rev
A
PDF: SPF-28341
8
of
8
176 QFP DC
5
4
3
2
1
MPC5748G Customer EVB 176QFP Daughter Card (MPC574XG-176DS)
Table Of Contents:
D
Sheet 2
Sheet 3
Sheet 4
Sheet 5
Sheet 6
Sheet 7
Sheet 8
Power - MPC5748G power pins footprint
Power - MPC5748G Decoupling Capacitors
GPIO - MPC5748G GPIO pins 1 of 2
GPIO - MPC5748G GPIO pins 2 of 2
Clocks
Bus Termination
Daughtercard Connectors
Revision Information
Rev Date
X1 11 Mar 2013
X2 13 Mar 2013
X3 15 Mar 2013
X4 29 Mar 2013
X5 15 Apr 2013
15 Apr 2013
A
B
22 Jul 2013
C
19 Nov 2013
D
19 Dec 2013
D1 17 Aug 2015
Designer
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Jesus Sanchez
Jesus Sanchez
Alasdair Robertson
Comments
Initial release sent for review based on X-MPC574XG-324DS X2
Version sent to Pre Layout, incorporating fixes from review
Component consolodation, Added MCU GND tab. Sent to Layout
Changes made during layout to Daughtercard Connectors
LAY RefDes Re-Sequence & SCH Back-Annotate
Post Layout (Back Annotated). Matches PCB RevA
Update to accomodate extra socket pins on MCU
The socket was updated, exposed center PAD is grounded.
Changes on MCU Power to validate MPC5746
Tidy up Schematics for UM (RevD PCB)
D
C
C
Caution:
These schematics are provided for reference purposes only. As such,
Freescale does not make any warranty, implied or otherwise, as to the
suitability of circuit design or component selection (type or value) used in
these schematics for hardware design using the Freescale MPC5748G family
of Microprocessors. Customers using any part of these schematics as a
basis for hardware design, do so at their own risk and Freescale does not
assume any liability for such a hardware design.
B
B
Notes:
-
A
All components and board processes are to be ROHS compliant
All small capacitors are 0402 unless otherwise stated
All resistors are 0603 5% 0.1w unless otherwise stated. All zero ohm links are 0603
All connectors and headers are denoted Px and are 2.54mm pitch unless otherwise stated
All jumpers are denoted Jx. Jumpers are 2mm pitch
Jumper default positions are shown in the schematics. For 3 way jumpers, default is always posn 1-2.
2 Pin jumpers generally have the "source" on pin 1.
- All switches are denoted SWx
- All test points are denoted TPx
- Test point Vias are denoted TPVx
User notes are given throughtout the schematics.
Specific PCB LAYOUT notes are detailed in ITALICS
Automotive Microcontroller Applications
East Kilbride, Scotland
Freescale General Business Use
This document contains information proprietary to Freescale and shall not be used for engineering design,
procurement or manufacture in whole or in part without the express written permission of Freescale
A
Freescale AISG Applications, East Kilbride
Designer:
Drawing Title:
A. Robertson
MPC5748G 176 QFP Daughter Card
Drawn by:
Page Title:
A. Robertson
Index and Title Page
Approved:
Size
B
Document Number
Date:
Tuesday, August 18, 2015
A. Robertson
5
4
3
2
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
1
of
8
5
4
3
2
1
MPC5748G MCU Power Connections
Caution:
Default Configuraiton:
- ALL MCU supply voltages are set to 3.3V (ADC0, ADC1, VDD_HV_A,
VDD_HV_B, VDD_HV_C, VBallast)
- VDD_HV_FLA = External 3.3V supplied (jumper fitted)
- VDD_LV Supplied from ballast transistor
- If VDD_HV_A is driven from 5V, the VDD_HV_FLA pin
must not be supplied from 3.3V (remove the HVA_FLA
jumper)
- Don't attempt to over drive an analogue pad to 5V
when the digital VDD_HV_x supply is set to 3.3V. This
will trigger the ESD protectrion on that pad. For
example if VDD_HV_A is set to 3.3V and the analogue
supplies are set to 5V, you cannot drive 5V into a
pad in the VDD_HV_A domain
D
From MCU
supply
jumpers on
main board
3v3
1
2
MCU_5V0_L
J10
J14
J9
R39
1.0
DNP
MCU_3V3_L
3v3
3
2
5v0
J8
B_CAP
4
3v3
3
31
54
110
152
109
HVA_CAP
TP107
TPAD_030
2
GND
TPH1
R37
10K
J11
3
R9
ADC0_GND
0
R8
GND
ADC1_GND
Drawing Title:
R38
10K
DNP
4
MPC5748G 176 QFP Daughter Card
GND
C51
1.0 UF
DNP
Page Title:
MPC5748G MCU Power
GND
GND
5
3
A
Freescale General Business Use
MPC5746
INT_BAL_SELECT enable
0
Automotive Microcontroller
Applications
East Kilbride, Scotland
GND
A
Ground Links
(0 Ohm
Resistors)
PPC5748GSK0MKU6 + OTQ-176SG-0.5-004-00
1
GND
B
2 fewer VDD_HV_A on 176QFP
1 fewer VDD_HV_B
No VDD_HV_C
5 Fewer VDD_LV
No VIN1_CMP_REF
15 Fewer VSS_LV
5 Fewer VSS_HV
Heat Dissipation GND TAB
EX_PAD1
EX_PAD2
EX_PAD3
EX_PAD4
EX_PAD5
VSS_LV_109
Central Pad for heat
dissipation & GND
R20
1
ADC1_GND
-
1.25v Core & External Ballast
VSS_HV_VPP
26
7
28
55
57
86
123
150
0
ADC0_GND
VDD_LP_DEC
VRC_CTRL
VDD_LV_31
VDD_LV_54
VDD_LV_110
VDD_LV_152
32
27
VDD_HV_FLA
Flash
Differences to 324BGA
Power Pins
VSS_HV_7
VSS_HV_28
VSS_HV_55
VSS_HV_57
VSS_HV_86
VSS_HV_123
VSS_HV_150
VSS_HV_ADC1
97
89
VSS_HV_ADC0
Package 2of3
LVDEC_CAP
HVB_CAP
VDD_HV_B_124
6
59
85
151
VDD_HV_A_6
VDD_HV_A_59
VDD_HV_A_85
VDD_HV_A_151
98
VDD_HV_ADC1_REF
MPC5748G 176QFP
Analogue
C
Individual MCU
supply control
jumpers
R36
0
124
HVA_CAP
ADC1REF_CAP
ADC1_CAP
VDD_HV_ADC1
VDD_HV_ADC0
99
ADC0_CAP
90
U1B
TPH2
Q20
MJD31CT4
HVFLA_CAP
2
0
1
R27
1
J6
2
J5
2
2
J4
2
J3
C
B
1
2
5v0
3
3v3
1
5v0
3
3v3
1
5v0
3
3v3
1
3
1
Individual MCU
supply control
jumpers
LV_CAP
3
1
8 MCU_3V3_L
5v0
MCU_3V3_S
30
8 MCU_5V0_L
MCU_5V0_S
177
178
179
180
181
8 MCU_3V3_S
E_CAP
8 MCU_5V0_S
D
MCU_1V25_L
1
8 MCU_1V25_L
This is not necessarily the same as the default shown in the RM. All
VDD_HV_x domains have at least one peripheral that only functions at
3.3V. Therefore the default is to run these from 3.3V. The analogue pins
can only be driven to the same voltage as the VDD_HV_x domain they are
situated in (ie max 3.3V) so makes sense for the analogue supply and
reference to be 3.3V
GND
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
2
of
8
5
4
3
2
1
MPC5748G MCU Decoupling and bulk storage
Capacitor Types:
470pF - Ceramic COG, 50v 5% 0402
1000pF - Ceramic COG, 50V 5% 0402
4700pF - Ceramic X7R, 50V 10% 0402
Flash
ADC
ADC0_CAP
ADC1_CAP
C43
1000pF
C34
1000pF
ADC1REF_CAP
HVFLA_CAP
D
C4
10UF
DNP
+
C3
10UF
DNP
C44
1.0 UF
C42
0.1UF
ADC0_GND
+
C41
C33
1.0 UF
1000pF
C35
0.1UF
ADC1_GND
C32
C40
1.0 UF
C31
2.2UF
LMK107B7225KA-T
(low ESR)
1000pF
ADC1_GND
0.01uF
0.1uF
0.68uF
1.0uF
2.2uF
-
- Ceramic X7R, 50V 10% 0402
Ceramic X7R, 16V 10% 0402
Ceramic X7R 16V 10% 0805 (Murata GCM219R71C684KA37 )
Ceraminc X7R, 10V 10% 0603 (Taiyo Yuden LMK107B7105KA-T)
Ceraminc X7R, 10V, 10%, 0603 (Taiyo Yuden LMK107B7225KA-TR)
4.7uF
10uF
- TANT, 12.5V 20% ESR=0.08R 7343
- TANT, 35V 10% ESR=0.125R CC7343-31
D
4.7uF Alternative (150-78844)- Polymer ALU, 16V 20% ESR=0.08R
7343-18
GND
Place small Caps as close as possible to MCU pins
VDD_HVA
VDD_HVB
HVA_CAP
C27
470pF
C24
1000pF
C48
470pF
HVB_CAP
C46
1000pF
+ C2
10UF
C
C23
470pF
+ C1
10UF
DNP
C26
0.1UF
GND
C25
0.1UF
C47
0.1UF
C45
0.1UF
C
C22
0.1UF
GND
Place 10uF cap to west side of package
Place small caps close to each MCU pin
Ballast Transistor
VDD_LV
LV_CAP
C50
0.1UF
C20
0.1UF
B_CAP
C7
E_CAP
LP Internal Reg Cap
E_CAP
C37
0.1UF
GND
LVDEC_CAP
4700pF
C8
2.2UF
DNP
(low
ESR)
Place
close to
transistor
B
LV_CAP
C9
2.2UF
DNP
(low
ESR)
C49
0.68uF
(low
ESR)
C29
0.1UF
C30
0.68uF
(low
ESR)
C21
0.68uF
(low
ESR)
C28
0.68uF
DNP
(low
ESR)
C36
1uF
LMK107B7105KA-T
(low ESR)
B
(Murata GCM219R71C684KA37)
GND
VDD_LV (1.25V) Decoupling. Place
as close as possible to pin.
GND
2.2uF caps
are DNP.
Place close
to emitter
See caps below for Bypass Transistor bulk storage (some on VDD1V2 rail)
GND
Place one 0.68uF cap footprint
each side of package
One of these is DNP. May replace 2 caps with
0.47uF to keep overall capacitance within limits
Differences to 324BGA
A
-
Automotive Microcontroller
Applications
East Kilbride, Scotland
2 Fewer VDD_HV_A capacitor pairs
1 fewer VDD_HV_B capacitor pair
No VDD_HV_C capacitor pairs
5 fewer VDD_LV capacitor pairs
A
Freescale General Business Use
Drawing Title:
MPC5748G 176 QFP Daughter Card
Page Title:
MPC5748G MCU Decoupling
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
3
of
8
5
4
3
2
1
MPC5748G GPIO 1 of 2
U1A
** PA1 is also NMI. Routed to I/O Matrix
D
(WKPU2 / NMI0)
(WKPU3)
Key to text colours:
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
C
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
(SD_CD - WKPU19)
(SW1 & GPIO**)
(SW2 & GPIO)
(MII_RXCLK)
(CMP1_13 / IO)
(SAI_GPIO)
(MLB_GPIO)
(MII_RXD2)
(RMII_RXD1)
(RMII_RXD0)
(MII_COL)
(RMII_RXER)
(CMP1_15 / IO)
(CMP1_14 / IO)
(CMP1_12 / IO)
(CMP1_10 / IO)
8
8
8
8
8
8
8
8
6
6
8
8
8
7
7
7
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
(CAN0_TX)
(CAN0_RX)
(LIN0_TX)
(LIN0_RX)
(ADC_POT)
(GPIO)
(GPIO)
(GPIO)
(XTAL32)
(EXTAL32)
(SAI0_SYNC)
(GPIO)
(GPIO)
(MLB_DN)
(MLB_SN)
(MLB_CN / SIG)
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
39
40
176
1
88
91
92
93
61
60
62
96
101
103
105
107
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
(TDI)
(TDO)
(USB1_CLK)
(USB1_DIR)
(FR_B_TX_EN)
(FR_A_TX)
(LIN1_TX)
(LIN1_RX)
(RS232_TX)
(RS232_RX)
(CAN1_TX)
(CAN1_RX)
(FR_DBG0)
(FR_DBG1)
(FR_DBG2)
(FR_DBG3)
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
154
149
145
144
159
158
44
45
175
2
36
35
173
174
3
4
8
8
8
8
8
8
8
8
8
8
8
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
(HEX1 &
(HEX2 &
(HEX3 &
(HEX4 &
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
(GPIO)
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
77
78
79
80
81
82
83
84
87
94
95
8
8
7
7
PD12
PD13
PD14
PD15
(GPIO)
(GPIO & MLB_ST)
(MLB_DP)
(MLB_SP / DAT)
PD12
PD13
PD14
PD15
100
102
104
106
8
8
MCU-RSTx
PORSTx
MCU-RSTx
PORSTx
6
6
MCU-XTAL
MCU-EXTAL
MCU-XTAL
MCU-EXTAL
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
24
19
17
114
51
146
147
128
129
130
131
132
53
52
50
48
B
A
GPIO)
GPIO)
GPIO)
GPIO)
29
153
56
58
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
MPC5748G 176QFP
Package 1of3 GPIO Pins1
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
PB0
PB1
PB2
PB3
PB4
PB5
PB6
PB7
PB8
PB9
PB10
PB11
PB12
PB13
PB14
PB15
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
PC0
PC1
PC2
PC3
PC4
PC5
PC6
PC7
PC8
PC9
PC10
PC11
PC12
PC13
PC14
PC15
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
PD0
PD1
PD2
PD3
PD4
PD5
PD6
PD7
PD8
PD9
PD10
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
PD12
PD13
PD14
PD15
18
20
156
157
160
161
167
168
21
22
23
25
133
127
136
137
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
(MLB_I2C1_SCL)
(MLB_I2C1_SDA)
(FR_A_TX_EN)
(FR_A_RX)
(FR_B_TX)
(FR_B_RX)
(SD_CMD)
(SD_CLK)
(SAI_I2C2_SDA)
(SAI_I2C2_SCL)
(SAI_I2C3_SDA)
(SAI_I2C3_SCL)
(MII_CRS)
(MII_RXD3)
(USB1_D2)
(USB1_D3)
63
64
65
66
67
68
69
70
42
41
46
47
43
49
126
125
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
(SAI0_MCLK)
(SAI0_BCLK)
(SAI0_D3)
(SAI0_D2)
(SAI0_D1)
(SAI0_D0)
(SAI1_SYNC)
(SAI1_MCLK)
(GPIO)
(SW3 & GPIO) WKPU22
(CMP1_8 / IO)
(SW4 & GPIO) WKPU15
(GPIO)
(CMP1_11 /IO)
(RMII_MDIO)
(RMII_RXDV)
122
121
16
15
14
13
38
37
34
33
138
139
116
115
134
135
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
(RMII_MDC)
(RMII_TXCLK)
(LED1 & GPIO)
(LED2 & GPIO)
(LED3 & GPIO)
(LED4 & GPIO)
(CLKOUT1 GPIO)
(CLKOUT0 GPIO)
(GPIO)
(MLB_IRQ - WKPU21)
(USB1_D4)
(USB1_D5)
(MII_TXD2)
(MII_TXD3)
(USB1_D0)
(USB1_D1)
117
118
119
120
162
163
164
165
166
155
148
140
141
9
10
8
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
(RMII_TXD1)
(RMII_TXD0)
(RMII_TXEN)
(eMIOS1_UC_5H)
(eMIOS1_UC_6H)
(eMIOS1_UC_7H)
(MLB_RST)
(MLB_PWR)
(SD_WP)
(TCK)
(TMS)
(USB1_D6)
(USB1_D7)
(GPIO)
(GPIO)
(GPIO)
PE0
PE1
PE2
PE3
PE4
PE5
PE6
PE7
PE8
PE9
PE10
PE11
PE12
PE13
PE14
PE15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PF0
PF1
PF2
PF3
PF4
PF5
PF6
PF7
PF8
PF9
PF10
PF11
PF12
PF13
PF14
PF15
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PG0
PG1
PG2
PG3
PG4
PG5
PG6
PG7
PG8
PG9
PG10
PG11
PG12
PG13
PG14
PG15
7
8
8
8
8
8
8
8
8
8
8
8
7
7
8
8
PH0
PH1
PH2
PH3
PH4
PH5
PH6
PH7
PH8
PH9
PH10
PH11
PH12
PH13
PH14
PH15
7
7
7
8
8
8
8
8
8
8
8
8
8
8
8
8
D
C
(eMIOS
(eMIOS
(eMIOS
(eMIOS
E1UC_11_H)
E1UC_12_H)
E1UC_13_H)
E1UC_14_H)
B
Differences to 324BGA
- Port D 11 Not on 176QFP
RESET
PORST
Automotive Microcontroller
Applications
East Kilbride, Scotland
XTAL
EXTAL
A
Freescale General Business Use
Drawing Title:
PPC5748GSK0MKU6 + OTQ-176SG-0.5-004-00
MPC5748G 176 QFP Daughter Card
Page Title:
MPC5748G GPIO 1of2
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
4
of
8
5
4
3
2
1
MPC5748G GPIO 2 of 2
U1C
Key to text colours:
D
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
172
171
170
169
143
142
11
12
108
8
8
8
8
8
8
8
8
7
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
(SD_D3)
(SD_D2)
(SD_D1)
(SD_D0)
(USB1_STP)
(USB1_NXT)
(USB0_RST)
(USB1_RST)
(MLB_CP / CLK)
(GPIO)
8
8
8
8
8
PI11
PI12
PI13
PI14
PI15
(ENET_RST)
(GPIO & MLB_PS0)
(GPIO & MLB_PS1)
(SAI2_D0)
(SAI2_MCLK)
PI11
PI12
PI13
PI14
PI15
111
112
113
76
75
8
8
8
8
8
PJ0
PJ1
PJ2
PJ3
PJ4
(SAI2_SYNC)
(SAI2_BCLK)
(SAI1_D0)
(SAI1_BCLK)
(GPIO)
PJ0
PJ1
PJ2
PJ3
PJ4
74
73
72
71
5
PI0
PI1
PI2
PI3
PI4
PI5
PI6
PI7
PI8
MPC5748G 176QFP
Package 3of3 GPIO Pins2
D
PI11
PI12
PI13
PI14
PI15
PJ0
PJ1
PJ2
PJ3
PJ4
C
C
B
B
Differences to 324BGA
- 2 fewer pins on Port I
- 12 fewer pins on Port J
- No Ports K to Q
(And corresponding changes
to daughtercard connectors)
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 176 QFP Daughter Card
Page Title:
PPC5748GSK0MKU6 + OTQ-176SG-0.5-004-00
5
4
3
2
MPC5748G GPIO 2of2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
5
of
8
5
4
3
2
1
Clocks
D
D
Oscillators and External Clock
4
PB9
EXT-CLK
(From SMA connector on main board)
C39
PB9
(EXTAL32)
R30
1.0M
DNP
C
12PF
3
Y20
32.768KHZ
C
2
PB8
C38
12PF
FC-255 32.7680K-A3
(Load Capacitance 7pF)
4
MCU-EXTAL
4
MCU-XTAL
J2
R7
1.0M
DNP
GND
Y1
40.0MHZ
J1
MCU-EXTAL
1
MCU-XTAL
EXTAL
12PF
1
PB8
(XTAL32)
1
1
4
C6
2
EXT-CLK
2
8
XTAL
C5
12PF
2
R35
3
GND
0
NX8045GB-40.000M-STD-CSJ-1 XTAL
(Optimised for Automotive, 8pF Load capacitance)
DNP
GND
B
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 176 QFP Daughter Card
Page Title:
Clocks
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
6
of
8
5
4
3
2
1
High Speed Signal Termination
D
D
Ethernet Termination
4
4
4
4
4
PG13
PG12
PH0
PH1
PH2
4
PG0
PG13
PG12
PH0
PH1
PH2
PG0
R5
R4
R6
R3
R2
50
50
50
50
50
R1
50
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
PG0-R
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
8
8
8
8
8
PG0-R
8
MLB_DAT
MLB_SIG
MLB_CLK
8
8
8
MLB_SN
8
MLB_SP
8
MLB_DN
8
MLB_DP
8
MLB_CN
8
MLB_CP
8
Place resistors as close as possible to MCU
MLB Termination
MLB_DAT
MLB_SIG
MLB_CLK
C
R34
100
DNP
4
4
PB14
PD15
4
PB13
4
PD14
4
PB15
5
PI8
R21
100
DNP
C
R25
100
DNP
PB14
R31
0
MLB_SN
PD15
R33
0
MLB_SP
PB13
R26
0
MLB_DN
PD14
R29
0
MLB_DP
PB15
R22
0
MLB_CN
PI8
R24
0
MLB_CP
R32
105.0 1%
(PD[15] Shared with MLB_DAT for 3-pin mode)
R28
105.0 1%
(PB[15] Shared with MLB_SIG for 3-pin mode)
R23
100 1%
(PI[8] Shared with MLB_CLK for 3-pin mode)
Place resistors as close as possible to MCU
From MCU
B
To Daughtercard
Layout Note - Place resistors as shown with
shared pad (as close to MCU as possible)
B
Remove R1 and
fit R2 to
enable 3-pin
signals
R1 Fitted by default
for LVDS 6-pin signals
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5748G 176 QFP Daughter Card
Page Title:
High Speed Signal Termination
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Rev
D1
PDF: SPF-27898
Sheet
1
7
of
8
5
4
3
2
1
Daughter Card Connectors (Plugs)
Notes:
Connectors on Main board (Shown for reference)
- there was no neat way to fit these connectors onto a B sized sheet so unfortunately the
sheet size has been increased to C so will need to be printed on larger paper.
- The Crystal Signals are NOT routed via the daughtercard connectors
- The Specific MCU power pins are not routed via the daughter card however the jumpered MCU
supply lines are brought up from the main board (see the top pins of the connector on the
left)
D
- The connector schematic symbols have been horizontally mirrored so they match the main EVB
connector. This has no bearing on the PCB placement or footprint. Pin1 on the recepticle
mates with pin 1 on the plug.
D
P21
6
EXT-CLK
4
PB2
4
5
PE6
PI3
5
5
PI1
PI2
4
5
PC13
PI0
4
PC8
4
PC15
C
4
PG5
5
PI7
4
5
PE1
PI6
4
4
PE11
PG3
4
PE8
4
4
PG9
PA0
4
4
4
PG7
PG8
PC10
4
PB1
4
PF13
B
4
4
PF9
PA14
4
PA4
4
PA15
4
PB10
2
MCU_5V0_S
2
MCU_1V25_L
P20
(GND)
EXT-CLK
(GND)
PB2
(GND)
(PP11)
PE6
PI3
(PP10)
(PP5)
PI1
PI2
(PP9)
PC13
PI0
(PK10)
PC8
(PK13)
(GND)
(PP2)
(PK15)
PC15
(PP7)
(GND)
(PP6)
(GND)
(PO12)
(PO7)
(PO10)
(PO4)
(PO9)
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
(GND)
PH7
PH6
PB3
PH8
(PP8)
(GND)
(PP3)
PE7
(PK9)
(GND)
PC12
(PK11)
(GND)
(PP4)
(PK14)
(PK12)
PC9
(PL0)
(GND)
(PP1)
(GND)
PC14
PJ4
(GND)
(PO11)
(PO8)
(GND)
PH14
(PO13)
(GND)
(GND)
PG5
(PO14)
(PO0)
PI7
(PP0)
(GND)
PE1
PI6
(PO5)
PE11
PG3
(GND)
PE8
(GND)
PG9
PA0
(GND)
PG7
PG8
PC10
(GND)
(GND)
PB1
(PK2)
(GND)
PF13
(PK4)
(PK6)
(PK8)
(PN14)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
(PO1)
PH13
PG4
PH15
(PO15)
PE10
PE0
(PO6)
(GND)
PG2
PA2
PE9
PA1
MCU-RSTx
(PN15)
(PO3)
(GND)
PG6
PC11
(PO2)
(GND)
PB0
(PK1)
PF12
(GND)
(GND)
(GND)
(PK3)
(PK5)
PF11
(GND)
(GND)
PF9
PA14
(PN13)
(GND)
(PN11)
(PJ11)
(PJ10)
(PK0)
(PJ9)
(PN9)
(GND)
(PJ13)
PA4
(GND)
(PN10)
PA15
(PN3)
(PN6)
(GND)
(PN0)
PB10
(GND)
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
(PK7)
PC6
PF8
(GND)
PC7
(PN12)
(PJ12)
(GND)
(PJ15)
(GND)
(PN8)
PF10
(PN7)
(PJ14)
(GND)
(PN4)
PA13
(GND)
(PN5)
PA12
(PN2)
PF1
PF0
(GND)
(GND)
MCU_3V3_S
MCU_5V0_S
MCU_1V25_L
(GND)
PH7
PH6
PB3
PH8
4
4
4
4
PE7
4
PC12
4
4
4
4
PH10
PH4
PE5
5
PI5
4
PC5
4
4
4
PG14
PH12
PC4
4
4
PC9
4
PC14
PJ4
4
5
PH14
4
PH13
PG4
PH15
4
4
4
PE10
PE0
4
4
PG2
PA2
PE9
PA1
MCU-RSTx
4
4
4
4
4
PG6
PC11
4
4
PB0
4
PF12
4
PF11
4
PC6
PF8
4
4
PC7
4
4
4
4
PH11
PA5
PE14
4
PG15
4
4
PE12
PA11
4
4
4
4
7
7
4
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
4
PH3
4
4
5
4
PD13
PD12
PI11
PD10
7
7
7
MLB_DAT
MLB_SIG
MLB_CLK
7
7
MLB_SN
MLB_SP
4
PD7
5
PJ0
4
4
4
4
5
PD5
PB5
PB11
PD1
PJ1
4
PD8
PF5
PB4
PJ2
PJ3
PF2
PF10
4
PA13
4
PA12
4
4
4
5
5
PF1
PF0
4
4
4
MCU_3V3_S
2
MCU_3V3_L
MCU_5V0_L
2
2
PC2
PA6
TPV1
MCU_3V3_L
MCU_5V0_L
(GND)
TPV3
TPV2
(GND)
(PM11)
PH10
PH4
PE5
(PM12)
PI5
(PQ0)
PC5
(GND)
PG14
PH12
PC4
(GND)
(PL9)
PC2
PA6
(PL3)
PH11
PA5
PE14
(PQ4)
PG15
(PQ5)
(PQ7)
(PP15)
(GND)
(PL12)
(PL11)
(PL6)
(PL7)
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
PC1
PE3
PH5
PC0
(PQ3)
PC3
PE4
PH9
(PL10)
PE15
PORSTx
PE2
(PL4)
PG11
(PQ1)
(GND)
PG10
(PQ2)
(PL8)
(PQ6)
(GND)
(PP13)
(PP12)
PI4
(PP14)
(GND)
(PL2)
(PL5)
(PL13)
(PM0)
(GND)
(GND)
(PL15)
(PM1)
(PM2)
PE12
PA11
(GND)
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
(GND)
(PM8)
PH3
(PM3)
(PM6)
(PM13)
(PM14)
(GND)
PD13
PD12
PI11
PD10
(GND)
MLB_DAT
MLB_SIG
MLB_CLK
(GND)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
(PL14)
(PM9)
(PM7)
PA10
PA9
PA8
PF14
PG0-R
PH2-R
(GND)
PG12-R
PG13-R
(GND)
(GND)
(PM10)
(PM4)
(PL1)
(GND)
(PM5)
PI13
PB12
PD9
PI12
PB7
PI15
(GND)
MLB_CN
MLB_CP
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
MLB_DN
MLB_DP
(GND)
(GND)
PI14
(PJ7)
(PD11)
(PJ6)
PD6
PD2
PD3
(PJ8)
(GND)
PB6
PD0
(PI10)
(GND)
PD4
PF6
(PN1)
(GND)
PF4
PF7
PF3
(GND)
(GND)
DC_3V3_S
(GND)
MLB_SN
MLB_SP
(GND)
(GND)
PD7
(PJ5)
PJ0
(GND)
PD5
PB5
PB11
PD1
PJ1
(GND)
PD8
(PI9)
PF5
PB4
PJ2
PJ3
(GND)
(GND)
PF2
(PM15)
(GND)
(GND)
DC_5V0_S
DC_P12V
DC_1V25_L
PLUG 180
DC_3V3_L
DC_5V0_L
PC1
PE3
PH5
PC0
4
4
4
4
PC3
PE4
PH9
4
4
4
PE15
PORSTx
PE2
4
4
4
PG11
4
PG10
4
PI4
5
PA10
PA9
PA8
PF14
PG0-R
PH2-R
4
4
4
4
7
7
PG12-R
PG13-R
7
7
PI13
PB12
PD9
PI12
PB7
PI15
5
4
4
5
4
5
MLB_CN
MLB_CP
7
7
C
B
MLB_DN
MLB_DP
7
7
PI14
5
PD6
PD2
PD3
4
4
4
PB6
PD0
4
4
PD4
PF6
4
4
PF4
PF7
PF3
4
4
4
TPV4
TPV5
TPV6
PLUG 180
A
A
Plug
GND
Plug
GND
GND
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
Freescale General Business Use
Drawing Title:
MPC5748G 176 QFP Daughter Card
Page Title:
Daughter Card Connectors (Plugs)
5
4
3
2
Size
C
Document Number
Date:
Tuesday, August 18, 2015
SCH-27898
Sheet
1
Rev
D1
PDF: SPF-27898
8
of
8
100 QFP DC
5
4
3
2
1
MPC5746C Customer EVB 100 BGA Daughter Card (MPC574XG-100DS)
Table Of Contents:
D
Sheet 2
Sheet 3
Sheet 4
Sheet 5
Sheet 6
Sheet 7
Sheet 8
Power - MPC5746C power pins footprint
Power - MPC5746C Decoupling Capacitors
GPIO - MPC5746C GPIO pins 1 of 2
GPIO - MPC5746C GPIO pins 2 of 2
Clocks
Bus Termination
Daughtercard Connectors
Revision Information
Rev Date
X1 05 Jan 2014
X2 07 Jan 2014
A
30 Jan 2014
A1 18 Aug 2015
Designer
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Alasdair Robertson
Comments
Initial release sent for review based on X-MPC574XG-256DS RevA
Post review corrections incl MCU Orcad Footprint
Prototype build release
Tidy up Schematics for UM (RevA PCB)
D
C
C
Caution:
These schematics are provided for reference purposes only. As such,
Freescale does not make any warranty, implied or otherwise, as to the
suitability of circuit design or component selection (type or value) used in
these schematics for hardware design using the Freescale MPC5746C family
of Microprocessors. Customers using any part of these schematics as a
basis for hardware design, do so at their own risk and Freescale does not
assume any liability for such a hardware design.
B
B
Notes:
-
A
All components and board processes are to be ROHS compliant
All small capacitors are 0402 unless otherwise stated
All resistors are 0603 5% 0.1w unless otherwise stated. All zero ohm links are 0603
All connectors and headers are denoted Px and are 2.54mm pitch unless otherwise stated
All jumpers are denoted Jx. Jumpers are 2mm pitch
Jumper default positions are shown in the schematics. For 3 way jumpers, default is always posn 1-2.
2 Pin jumpers generally have the "source" on pin 1.
- All switches are denoted SWx
- All test points are denoted TPx
- Test point Vias are denoted TPVx
User notes are given throughtout the schematics.
Specific PCB LAYOUT notes are detailed in ITALICS
Automotive Microcontroller Applications
East Kilbride, Scotland
Freescale General Business Use
This document contains information proprietary to Freescale and shall not be used for engineering design,
procurement or manufacture in whole or in part without the express written permission of Freescale
A
Freescale AISG Applications, East Kilbride
Designer:
Drawing Title:
A. Robertson
MPC5746C 100 BGA Daughter Card
Drawn by:
Page Title:
A. Robertson
Index and Title Page
Approved:
Size
B
Document Number
Date:
Tuesday, August 18, 2015
A. Robertson
5
4
3
2
SCH-28701
Rev
A1
PDF: SPF-28701
Sheet
1
1
of
8
5
4
3
MPC5746C MCU Power Connections
2
Caution:
Default Configuraiton:
- ALL MCU supply voltages are set to 3.3V (ADC0, ADC1, VDD_HV_A,
VDD_HV_B, VDD_HV_C, VBallast)
- VDD_HV_FLA = External 3.3V supplied (jumper fitted)
- VDD_LV Supplied from ballast transistor
- If VDD_HV_A is driven from 5V, the VDD_HV_FLA pin
must not be supplied from 3.3V (remove the HVA_FLA
jumper)
- Don't attempt to over drive an analogue pad to 5V
when the digital VDD_HV_x supply is set to 3.3V. This
will trigger the ESD protectrion on that pad. For
example if VDD_HV_A is set to 3.3V and the analogue
supplies are set to 5V, you cannot drive 5V into a
pad in the VDD_HV_A domain
D
From MCU
supply
jumpers on
main board
MCU_5V0_L
MCU_3V3_L
1
J8
HDR 1X2
3v3
5v0
Individual MCU
supply control
jumpers
J9
E_CAP
LVDEC_CAP
R35
0
3
HVFLA_CAP
HVB_CAP
HVA_CAP
C
Q20
MJD31CT4
1
1
2
2
2
J6
3
3v3
5v0
0
ADC1REF_CAP
J10
2
ADC1_CAP
3v3
3
1
5v0
J5
R7
ADC0_CAP
3v3
1
2
J4
3
5v0
2
J3
C
3v3
1
5v0
3
3v3
1
3
1
1
8 MCU_3V3_L
MCU_3V3_S
4 2
8 MCU_5V0_L
D
MCU_5V0_S
3
8 MCU_3V3_S
LV_CAP
8 MCU_5V0_S
This is not necessarily the same as the default shown in the RM. All
VDD_HV_x domains have at least one peripheral that only functions at
3.3V. Therefore the default is to run these from 3.3V. The analogue pins
can only be driven to the same voltage as the VDD_HV_x domain they are
situated in (ie max 3.3V) so makes sense for the analogue supply and
reference to be 3.3V
MCU_1V25_L
B_CAP
8 MCU_1V25_L
1
Flash
F2
D5
D6
G5
G6
VDD_LP_DEC
VDD_LV_D5
VDD_LV_D6
VDD_LV_G5
VDD_LV_G6
E1
VRC_CTRL
U1B
B
1.25v Core & External Ballast
VSS_D1
VSS_E4
VSS_E5
VSS_E6
VSS_E7
VSS_F4
VSS_F5
VSS_F6
VSS_F7
VSS_K4
VSS_K7
SKT BGA 100 TH + MPC574XG-100
0
1
R24
D1
E4
E5
E6
E7
F4
F5
F6
F7
K4
K7
H10
D2
E2
VSS_VPP
INT_BAL_SEL
Power Pins
VSS_HV_ADC1
Package 2of3
VSS_HV_ADC0
H3
VDD_HV_B_E8
MPC5746C 100 BGA
Analogue
K9
VDD_HV_FLA_H3
E8
D4
D7
G4
G7
VDD_HV_A_D4
VDD_HV_A_D7
VDD_HV_A_G4
VDD_HV_A_G7
H9
G10
VDD_HV_ADC1_REF
B
VDD_HV_ADC1
VDD_HV_ADC0
K10
TPH2
ADC0_GND
ADC1_GND
TPH1
Automotive Microcontroller
Applications
East Kilbride, Scotland
GND
GND
A
Ground Links
(0 Ohm
Resistors)
R9
0
R10
HVA_CAP J12
3
0
Drawing Title:
MPC5746C 100 BGA Daughter Card
2
ADC0_GND
GND
ADC1_GND
Page Title:
MPC5746C MCU Power
1
GND
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Rev
A1
PDF: SPF-28701
GND
5
4
3
A
Freescale General Business Use
R37
1.0K
2
Sheet
1
2
of
8
5
4
3
2
1
MPC5746C MCU Decoupling and bulk storage
Capacitor Types:
470pF - Ceramic COG, 50v 5% 0402
1000pF - Ceramic COG, 50V 5% 0402
4700pF - Ceramic X7R, 50V 10% 0402
Flash
ADC
ADC0_CAP
ADC1_CAP
C48
1000pF
C46
1000pF
ADC1REF_CAP
HVFLA_CAP
D
C2
10UF
DNP
+
C3
10UF
DNP
C59
1.0 UF
C56
0.1UF
ADC0_GND
+
C47
C58
1.0 UF
1000pF
C55
0.1UF
ADC1_GND
C36
C57
1.0 UF
C34
2.2UF
LMK107B7225KA-T
(low ESR)
1000pF
ADC1_GND
0.01uF
0.1uF
0.68uF
1.0uF
2.2uF
-
- Ceramic X7R, 50V 10% 0402
Ceramic X7R, 16V 10% 0402
Ceramic X7R 16V 10% 0805 (Murata GCM219R71C684KA37 )
Ceraminc X7R, 10V 10% 0603 (Taiyo Yuden LMK107B7105KA-T)
Ceraminc X7R, 10V, 10%, 0603 (Taiyo Yuden LMK107B7225KA-TR)
4.7uF
10uF
- TANT, 12.5V 20% ESR=0.08R 7343
- TANT, 35V 10% ESR=0.125R CC7343-31
D
4.7uF Alternative (150-78844)- Polymer ALU, 16V 20% ESR=0.08R
7343-18
GND
Place small Caps as close as possible to MCU pins
VDD_HVA
VDD_HVB
HVA_CAP
C27
470pF
C51
1000pF
C22
470pF
HVB_CAP
C54
1000pF
+ C1
10UF
C
C33
470pF
+ C4
10UF
DNP
C26
0.1UF
GND
C52
0.1UF
C23
0.1UF
C53
0.1UF
C
C35
0.1UF
GND
Place small caps close to each MCU pin
Ballast Transistor
VDD_LV
LV_CAP
C24
0.1UF
C49
0.1UF
B_CAP
C8
E_CAP
LP Internal Reg Cap
E_CAP
C32
0.1UF
GND
LVDEC_CAP
4700pF
C9
2.2UF
DNP
(low
ESR)
Place close
to transistor
B
LV_CAP
C10
2.2UF
DNP
(low
ESR)
C29
0.68uF
(low
ESR)
C39
0.1UF
C60
0.68uF
(low
ESR)
C31
0.68uF
(low
ESR)
C20
0.68uF
DNP
(low
ESR)
C43
1uF
LMK107B7105KA-T
(low ESR)
B
(Murata GCM219R71C684KA37)
VDD_LV (1.25V) Decoupling. Place -.1uF
caps as close as possible to respective
VDD_LV pins
GND
GND
2.2uF caps are
DNP. Place close
to emitter
Place one 0.68uF cap footprint
each side of package
GND
One of these is DNP to keep overall capacitance less
than max spec of 3uF. If necessary, these can be
replaced with 0.47uF caps as long as combined ESR of all
caps is less than 0.03 Ohms
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5746C 100 BGA Daughter Card
Page Title:
MPC5746C MCU Decoupling
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Rev
A1
PDF: SPF-28701
Sheet
1
3
of
8
5
4
3
2
1
MPC5746C GPIO 1 of 2
U1A
** PA1 is also NMI. Routed to I/O Matrix
D
(WKPU2 / NMI0)
(WKPU3)
Key to text colours:
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
8
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
(SD_CD - WKPU19)
(SW1 & GPIO**)
(SW2 & GPIO)
(MII_RXCLK)
(CMP1_13 / IO)
(SAI_GPIO)
(MLB_GPIO)
(MII_RXD2)
(RMII_RXD1)
(RMII_RXD0)
(MII_COL)
(RMII_RXER)
(CMP1_15 / IO)
(CMP1_14 / IO)
(CMP1_12 / IO)
(CMP1_10 / IO)
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
H4
G3
F3
C10
J3
A5
B4
A10
B10
B9
B8
C8
J7
J6
J5
J4
PB0
PB1
(CAN0_TX)
(CAN0_RX)
PB0
PB1
H2
H1
PA0
PA1
PA2
PA3
PA4
PA5
PA6
PA7
PA8
PA9
PA10
PA11
PA12
PA13
PA14
PA15
MPC5746C 100 BGA
Package 1of3 GPIO Pins1
PE2
PE3
PE13
PE15
PF0
PF5
8
C
PB10
(SAI0_SYNC)
PB10
K8
PF8
PF9
PF10
PB10
PF14
PF15
8
8
PC0
PC1
(TDI)
(TDO)
8
PC5
(FR_A_TX)
PC0
PC1
PC5
C5
C6
E3
PC0/TDI
PC1/TDO
PG0
PG1
PG2
PG3
PC5
PG6
PG7
8
8
PC10
PC11
(CAN1_TX)
(CAN1_RX)
PC10
PC11
G2
G1
PC10
PC11
PG11
PG12
PG13
PG14
PG15
B
8
PD1
(HEX2 & GPIO)
PD1
J10
PH0
PH1
PH2
PD1
TCK/PH9
TMS/PH10
A
(GPIO & MLB_ST) PD13
G9
8
PD13
8
8
MCU-RSTx
PORSTx
MCU-RSTx
PORSTx
F1
A4
6
6
MCU-XTAL
MCU-EXTAL
MCU-XTAL
MCU-EXTAL
K5
K6
PE2
PE3
(FR_A_TX_EN)
(FR_A_RX)
8
8
PE2
PE3
D
PE8
PE9
PB0
PB1
C3
D3
PH12
C2
C1
PE8
PE9
(SAI_I2C2_SDA)
(SAI_I2C2_SCL)
A9
PE13
(MII_RXD3)
A6
PE15
(USB1_D3)
J8
PF0
(SAI0_MCLK)
G8
PF5
(SAI0_D0)
J2
J1
K1
PF8
PF9
PF10
(GPIO)
(SW3 & GPIO) WKPU22
(CMP1_8 / IO)
D9
A8
PF14
PF15
(RMII_MDIO)
(RMII_RXDV)
F9
F10
B1
B2
PG0
PG1
PG2
PG3
(RMII_MDC)
(RMII_TXCLK)
(LED1 & GPIO)
(LED2 & GPIO)
H6
H5
PG6
PG7
(CLKOUT1 GPIO)
(CLKOUT0 GPIO)
B6
D10
D8
A7
B7
PG11
PG12
PG13
PG14
PG15
(USB1_D5)
(MII_TXD2)
(MII_TXD3)
(USB1_D0)
(USB1_D1)
E10
E9
C9
PH0
PH1
PH2
(RMII_TXD1)
(RMII_TXD0)
(RMII_TXEN)
C4
C7
PH9
PH10
(TCK)
(TMS)
B5
PH12
(USB1_D7)
PE8
PE9
8
8
PE13
8
PE15
8
PF0
8
PF5
8
PF8
PF9
PF10
8
8
8
PF14
PF15
8
8
PG0
PG1
PG2
PG3
7
8
8
8
PG6
PG7
8
8
PG11
PG12
PG13
PG14
PG15
8
7
7
8
8
PH0
PH1
PH2
7
7
7
PH9
PH10
8
8
PH12
8
C
(eMIOS E1UC_11_H)
(eMIOS E1UC_12_H)
B
PD13
RESET
PORST
Automotive Microcontroller
Applications
East Kilbride, Scotland
XTAL
EXTAL
A
Freescale General Business Use
Drawing Title:
SKT BGA 100 TH + MPC574XG-100
MPC5746C 100 BGA Daughter Card
Page Title:
MPC5746C GPIO 1of2
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Rev
A1
PDF: SPF-28701
Sheet
1
4
of
8
5
4
3
2
1
MPC5746C GPIO 2 of 2
U1C
Key to text colours:
D
Purple
Orange
Blue
Black
RED
Green
-
Comms Physical Interfaces
Other Peripherals and I/O
Debug (JTAG & Nexus)
Clock, Reset and Control
I/O Matrix and other functions (eg LED)
I/O Matrix (dedicated)
8
8
8
8
PI0
PI1
PI2
PI3
(SD_D3)
(SD_D2)
(SD_D1)
(SD_D0)
PI0
PI1
PI2
PI3
A1
A2
B3
A3
PI0
PI1
PI2
PI3
MPC5746C 100 BGA
Package 3of3 GPIO Pins2
D
8
PI14
(SAI2_D0)
PI14
J9
8
8
8
PJ0
PJ1
PJ2
(SAI2_SYNC)
(SAI2_BCLK)
(SAI1_D0)
PJ0
PJ1
PJ2
F8
H8
H7
8
8
PJ13
PJ14
(GPIO)
(GPIO)
PJ13
PJ14
K3
K2
PI14
PJ0
PJ1
PJ2
C
C
PJ13
PJ14
B
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5746C 100 BGA Daughter Card
Page Title:
SKT BGA 100 TH + MPC574XG-100
5
4
MPC5746C GPIO 2of2
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Rev
A1
PDF: SPF-28701
Sheet
1
5
of
8
5
4
3
2
1
Clocks
D
D
Oscillators and External Clock
8
EXT-CLK
EXT-CLK
(From SMA connector on main board)
3
C
C
2
1
C7
EXTAL
12PF
1
(Note the 32KHz osc
pins are not bonded
out on the 100 pin
package)
J2
MCU-EXTAL
4
MCU-XTAL
J1
MCU-EXTAL
1
MCU-XTAL
Y1
40.0MHZ
2
4
R8
1.0M
DNP
XTAL
C6
12PF
2
R34
3
GND
0
NX8045GB-40.000M-STD-CSJ-1 XTAL
(Optimised for Automotive, 8pF Load capacitance)
DNP
GND
B
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5746C 100 BGA Daughter Card
Page Title:
Clocks
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Rev
A1
PDF: SPF-28701
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High Speed Signal Termination
D
D
Ethernet Termination
4
4
4
4
4
PG13
PG12
PH0
PH1
PH2
4
PG0
PG13
PG12
PH0
PH1
PH2
PG0
R4
R6
R5
R3
R1
50
50
50
50
50
R2
50
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
PG0-R
PG13-R
PG12-R
PH0-R
PH1-R
PH2-R
8
8
8
8
8
PG0-R
8
Place resistors as close as possible to MCU
C
C
B
B
Automotive Microcontroller
Applications
East Kilbride, Scotland
A
A
Freescale General Business Use
Drawing Title:
MPC5746C 100 BGA Daughter Card
Page Title:
High Speed Signal Termination
5
4
3
2
Size
B
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Rev
A1
PDF: SPF-28701
Sheet
1
7
of
8
5
4
3
2
1
Daughter Card Connectors (Plugs)
Notes:
Connectors on Main board (Shown for reference)
- there was no neat way to fit these connectors onto a B sized sheet so unfortunately the sheet
size has been increased to C so will need to be printed on larger paper.
- The Crystal Signals are NOT routed via the daughtercard connectors
- The Specific MCU power pins are not routed via the daughter card however the jumpered MCU
supply lines are brought up from the main board (see the top pins of the connector on the left)
D
- The connector schematic symbols have been horizontally mirrored so they match the main EVB
connector. This has no bearing on the PCB placement or footprint. Pin1 on the recepticle mates
with pin 1 on the plug.
D
P21
6
EXT-CLK
5
PI3
5
5
PI1
PI2
5
PI0
C
4
PG3
4
PE8
4
PA0
4
PG7
4
PC10
4
PB1
B
P20
(GND)
EXT-CLK
(GND)
(PB2)
(GND)
(PP11)
(PE6)
PI3
(PP10)
(PP5)
PI1
PI2
(PP9)
(PC13)
PI0
(PK10)
(PC8)
(PK13)
(GND)
(PP2)
(PK15)
(PC15)
(PP7)
(GND)
(PP6)
(GND)
(PO12)
(PO7)
(PO10)
(PO4)
(PO9)
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
(GND)
(PH7)
(PH6)
(PB3)
(PH8)
(PP8)
(GND)
(PP3)
(PE7)
(PK9)
(GND)
(PC12)
(PK11)
(GND)
(PP4)
(PK14)
(PK12)
(PC9)
(PL0)
(GND)
(PP1)
(GND)
(PC14)
(PJ4)
(GND)
(PO11)
(PO8)
(GND)
(PH14)
(PO13)
(GND)
(GND)
(PG5)
(PO14)
(PD0)
(PI7)
(PP0)
(GND)
(PE1)
(PI6)
(PO5)
(PE11)
PG3
(GND)
PE8
(GND)
(PG9)
PA0
(GND)
PG7
(PG8)
PC10
(GND)
(GND)
PB1
(PK2)
(GND)
(PF13)
(PK4)
(PK6)
(PK8)
(PN14)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
(PO1)
(PH13)
(PG4)
(PH15)
(PO15)
(PE10)
(PE0)
(PO6)
(GND)
PG2
PA2
PE9
PA1
MCU-RSTx
(PN15)
(PO3)
(GND)
PG6
PC11
(PO2)
(GND)
PB0
(PK1)
(PF12)
(GND)
(GND)
(GND)
(PK3)
(PK5)
(PF11)
(GND)
(GND)
PF9
PA14
(PN13)
(GND)
(PN11)
(PJ11)
(PJ10)
(PK0)
(PJ9)
(PN9)
(GND)
PJ13
PA4
(GND)
(PN10)
PA15
(PN3)
(PN6)
(GND)
(PN0)
PB10
(GND)
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
(PK7)
(PC6)
PF8
(GND)
(PC7)
(PN12)
(PJ12)
(GND)
(PJ15)
(GND)
(PN8)
PF10
(PN7)
PJ14
(GND)
(PN4)
PA13
(GND)
(PN5)
PA12
(PN2)
(PF1)
PF0
(GND)
(GND)
MCU_3V3_S
4
PG2
PA2
PE9
PA1
MCU-RSTx
4
4
4
4
4
PG6
PC11
4
4
PB0
4
PH10
4
PC5
4
4
PG14
PH12
4
PA6
4
PA5
4
PG15
4
PA11
4
4
4
4
7
7
4
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
4
PD13
(GND)
(PM11)
PH10
(PH4)
(PE5)
(PM12)
(PI5)
(PQ0)
PC5
(GND)
PG14
PH12
(PC4)
(GND)
(PL9)
(PC2)
PA6
(PL3)
(PH11)
PA5
(PE14)
(PQ4)
PG15
(PQ5)
(PQ7)
(PP15)
(GND)
(PL12)
(PL11)
(PL6)
(PL7)
(GND)
SH2
1
3
5
7
9
11
13
15
17
19
21
23
25
27
29
31
33
35
37
39
41
43
45
47
49
51
53
55
57
59
SH4
SH1
2
4
6
8
10
12
14
16
18
20
22
24
26
28
30
32
34
36
38
40
42
44
46
48
50
52
54
56
58
60
SH3
(GND)
PC1
PE3
(PH5)
PC0
(PQ3)
(PC3)
(PE4)
PH9
(PL10)
PE15
PORSTx
PE2
(PL4)
PG11
(PQ1)
(GND)
(PG10)
(PQ2)
(PL8)
(PQ6)
(GND)
(PP13)
(PP12)
(PI4)
(PP14)
(GND)
(PL2)
(PL5)
(PL13)
(PM0)
(GND)
(GND)
(PL15)
(PM1)
(PM2)
(PE12)
PA11
(GND)
PA7
PE13
PF15
PG1
PH1-R
PH0-R
PA3
(GND)
(PM8)
(PH3)
(PM3)
(PM6)
(PM13)
(PM14)
(GND)
PD13
(PD12)
(PI11)
(PD10)
(GND)
(MLB_DAT)
(MLB_SIG)
(MLB_CLK)
(GND)
(GND)
SH6
61
63
65
67
69
71
73
75
77
79
81
83
85
87
89
91
93
95
97
99
101
103
105
107
109
111
113
115
117
119
SH8
SH5
62
64
66
68
70
72
74
76
78
80
82
84
86
88
90
92
94
96
98
100
102
104
106
108
110
112
114
116
118
120
SH7
(GND)
(PL14)
(PM9)
(PM7)
PA10
PA9
PA8
PF14
PG0-R
PH2-R
(GND)
PG12-R
PG13-R
(GND)
(GND)
(PM10)
(PM4)
(PL1)
(GND)
(PM5)
(PI13)
(PB12)
(PD9)
(PI12)
(PB7)
(PI15)
(GND)
(MLB_CN)
(MLB_CP)
(GND)
(GND)
(GND)
SH10
121
123
125
127
129
131
133
135
137
139
141
143
145
147
149
151
153
155
157
159
161
163
165
167
169
171
173
175
177
179
SH12
SH9
122
124
126
128
130
132
134
136
138
140
142
144
146
148
150
152
154
156
158
160
162
164
166
168
170
172
174
176
178
180
SH11
(GND)
(MLB_DN)
(MLB_DP)
(GND)
(GND)
PI14
(PJ7)
(PD11)
(PJ6)
(PD6)
(PD2)
(PD3)
(PJ8)
(GND)
(PB6)
(PD0)
(PI10)
(GND)
(PD4)
(PF6)
(PN1)
(GND)
(PF4)
(PF7)
(PF3)
(GND)
(GND)
DC_3V3_S
PC1
PE3
4
4
PC0
4
PH9
4
PE15
PORSTx
PE2
4
4
4
PG11
4
C
PA10
PA9
PA8
PF14
PG0-R
PH2-R
4
4
4
4
7
7
PG12-R
PG13-R
7
7
B
(MLB_SP_
4
4
5
4
4
4
PF9
PA14
PJ13
PA4
PA15
PB10
2
MCU_5V0_S
2
MCU_1V25_L
MCU_5V0_S
MCU_1V25_L
(GND)
PF8
4
PF10
4
PJ14
5
PA13
4
PA12
4
PF0
4
MCU_3V3_S
2
MCU_3V3_L
MCU_5V0_L
2
2
5
PJ0
4
5
PD1
PJ1
4
PF5
5
PJ2
TPV1
MCU_3V3_L
MCU_5V0_L
(GND)
TPV3
TPV2
(GND)
(MLB_SN)
(MLB_SP)
(GND)
(GND)
(PD7)
(PJ5)
PJ0
(GND)
(PD5)
(PB5)
(PB11)
PD1
PJ1
(GND)
(PD8)
(PI9)
PF5
(PB4)
PJ2
(PJ3)
(GND)
(GND)
(PF2)
(PM15)
(GND)
(GND)
DC_5V0_S
DC_P12V
DC_1V25_L
PLUG 180
GND
5
TPV4
DC_3V3_L
DC_5V0_L
TPV5
TPV6
PLUG 180
Plug
Plug
A
PI14
A
GND
GND
GND
Automotive Microcontroller
Applications
East Kilbride, Scotland
Freescale General Business Use
Drawing Title:
MPC5746C 100 BGA Daughter Card
Page Title:
Daughter Card Connectors (Plugs)
5
4
3
2
Size
C
Document Number
Date:
Tuesday, August 18, 2015
SCH-28701
Sheet
1
Rev
A1
PDF: SPF-28701
8
of
8
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Document Number: MPC5748GEVBUG
Rev. 0
08/2015