NXP MPC560xE Ultra-Reliable 32-bit MCU User Guide

Add to my manuals
22 Pages

advertisement

NXP MPC560xE Ultra-Reliable 32-bit MCU User Guide | Manualzz

Freescale Semiconductor

Document Number:MPC5606EBUG Rev 2, 04/2014

MPC5606E Board User Guide

by: Tomas Kulig

1 Introduction

The MPC5606E Evaluation Board (EVB) is based on the e200z0 Power Architecture core. The MPC5606E 121-pin MAPBGA is assembled on this board to allow the evaluation of the full functionality of this part.

This board was designed as a validation platform with the maximum flexibility. Where possible it is also designed for power and speed but the primary goal of this system is to allow main use cases of this processor.

IMPORTANT

Before the EVB is used or power is applied, read the following sections on how to correctly configure the board.

Failure to correctly configure the board may cause irreparable component, Microcontroller unit (MCU), or video broadcast (VB) damage.

9

10

11

12

1 2

3

4

5

6 7

8

13

Contents

Introduction............................................................1

EVB features...........................................................1

JTAG interface........................................................2

Power configuration................................................3

Reset circuit............................................................6

Clock configuration.................................................9

Audio and video interfaces.....................................9

CAN interface........................................................13

LIN and SCI interface...........................................14

Ethernet interface..................................................15

User buttons and LEDs.........................................16

Summary table with default jumpers setting ...................................................................17

Connectors summary description..........................19

2 EVB features

MPC5606E EVB board has following external interfaces: • Video encoder wrapper connected either to Omnivision connector (J58 - default)

1

or Aptina connector (J57)

1

© 2014 Freescale Semiconductor, Inc.

JTAG interface

• Serial audio interface connected to the Audio connector (J59) 1

• Onboard two wire Ethernet physical interface • JTAG • Either one LIN or one UART (default) interface selectable through jumpers setting • FlexCAN interface • External interrupts

3 JTAG interface

There is a populated standard JTAG 14-pin connector with 0.1-inch walled header footprint on the EVB.

The pin out of the JTAG connector is shown in

Figure 1

.

The JTAG interface is shared between MPC5604E and Broadcom parts of MPC5606E. It means that it is possible to connect via JTAG to the Broadcom part of MPC5606E. Resistors select which part of MPC5606E is connected to the JTAG interface.

The JTAG interface is connected to the MPC5604E as default. Only one part of MPC5606E can be connected to the JTAG

interface in one time, see Table 1 for the resistors setting.

Table 1. The resistors setting for JTAG interface Name of signal

TDI TDO TCK JTAG RESET JCOMP TMS

Figure 1. JTAG connector pin out Resistor name

R14 R721 R13 R718 R719 R12 R48 R738 R15 R53 R732 R11 R16 R724

MPC5604E (default)

Populate DNP Populate

Populate 1

DNP Populate Populate DNP Populate Populate DNP Populate Populate DNP

Broadcom

DNP Populate DNP DNP Populate DNP DNP Populate DNP DNP Populate DNP DNP Populate 1. Only for MPC5606E Ethernet LED activity.

2 1. Only one of these three interfaces can be active. The selection is done via jumpers (I2C communication) and resistors (interface). The omnivision is active as default.

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

CAUTION

It is necessary to populate resistors R712 and R720 for Broadcom JTAG. These two resistors enable JTAG interface in the Broadcom part.

Power configuration

4 Power configuration

The EVB requires an external power supply voltage of 12 V DC, minimum 1 A. This allows the EVB to be easily used in a vehicle if required. The single input voltage is regulated on-board using switching regulators to provide the necessary EVB and MCU operating voltages of 5.0 V, 3.3 V, and 1.2 V.

4.1 Power supply connector

2.1 mm barrel 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 polarization as shown Figure 2

.

Figure 2. 2.1 mm Power connector

4.2 Power switch (SW1) and fuse

Side switch SW1 can be used to isolate power supply input from the EVB voltage regulators if required • EVB OFF - SW1 is in the position 1 (default setting) • EVB ON - SW1 is in the position 3 If there is no power to the MCU, it is possible that either power switch SW1 is in the “OFF” position or that the fuse F1 has blown. The fuse will blow if power is applied to the EVB in reverse-bias, where a protection diode ensures that the main fuse blows rather than causing damage to the EVB circuitry. If the fuse has blown, check the bias of your power supply connection then replace fuse F1 with a 20 mm 2 A fast blow fuse.

4.3 Power status LEDs

When Power is applied to the EVB, a green power LEDs adjacent to 5.0 V, 3.3 V, and 1.2 V of the voltage regulators show the presence of the supply voltages. Following are connection between LED's labels and supply voltages: • 5.0 V voltage supply is connected to LED D16 Freescale Semiconductor, Inc.

MPC5606E Board User Guide, Rev 2, 04/2014

3

4

Power configuration

• 3.3 V voltage supply is connected to LED D17 • 1.2 V voltage supply is connected to LED D1

4.4 Power jumpers settings

There are three main areas of these jumpers: 1.2 V regulator, Broadcom part of MPC5606E, and MPC5604E part of MPC5606E.

Table 2

shows setting of jumper J9 which select input voltage for 1.2 V regulator.

Table 2. Select input voltage for 1.2 V regulator Position of jumper J9

1-2 2-3 (default)

Input voltage for 1.2 V regulator

5.0 V 12.0 V • Broadcom part needs to populate jumpers in the

Table 3

for its supply voltages:

Table 3. Broadcom part voltage jumpers Jumper

J17 J18 J22 J24 J25 J32 J49 J51

Voltage name

OVDD_3V3 OVDD_RGMI_3V3 AVDD_3V3 AVDDL_1V2 DVDD_1V2 PLLVDD_1V2 XTALVDD_3V3 BIASVDD_3V3 • MC5604E part needs to populate jumpers in the

Table 4

for its supply voltages:

Table 4. MPC5604E part voltage jumpers Jumper

J23 J31 J50

Voltage name

VDD_LV_COR0_1, VDD_LV_COR0_2, VDD_LV_PLL0 VDD_HV_ADR0 VDD_HV_FLA0 ,VDD_HV_FLA1 ,VDD_HV_OSC0_REG0 The MCU can run at two regulation modes: • Internal regulation mode:

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Power configuration

In this mode I/O supply, ballast supply, and ADC supply are at the same potential of typical 3.3 V (+/- 10 %). To reduce power dissipation on the chip there are exploring possibilities of connecting the I/O supply with the ballast supply via a small resistor R731 with value 2.55 Ohms. This will lead to the ballast supply being lower than the I/O

supply, see Figure 3 and the Table 5

for the jumpers setting.

Jumper

J8 J23 J34 J35

Table 5. Jumpers setting for internal regulation mode Position of jumper

Connect pin 2 to 3.3 V DNP 1-2 1-2 or 2-3 (default)

Description

POR_B signal is not used in internal regulation mode Used internal generated 1.2 V supply Select internal regulation mode Unused (1-2) or used (2-3) ballast resistor R731

Figure 3. Internal regulation mode - simplified connection

External regulation mode (default setting): In this mode the Ballast supply is shorted to 1.2 V (+/-10%) generated by an external regulator. The I/O supply and the MCU ADC supply continues to be at 3.3 V (+/-10%), see

Figure 4 and the Table 6 for jumper setting.

Freescale Semiconductor, Inc.

MPC5606E Board User Guide, Rev 2, 04/2014

5

Reset circuit Jumper

J8 J23 J34 J35

Table 6. Jumpers setting for external regulation mode Position of jumper

1-2 1-2 2-3 DNP

Description

POR_B signal is connected to the external voltage watchdog Used external 1.2 V supply Select external regulation mode external 1.2 V supply -

Figure 4. External regulation mode - simplified connection

6

5 Reset circuit

The external reset circuits are consisted from three different resets. Power on Reset (MPC5604E), JTAG Reset (MPC5604E), and Reset_BR (Broadcom). All MPC5604E resets can be activate by buttons manually (SW2 - JTAG Reset, SW3 - Power on Reset).

The Power on Reset circuit uses device STM6904TGEDS6F. This device deactivates the Power on Reset after voltages 1.2

V, 3.3 V, and 5.5 V are in valid ranges. If any of these voltages falls down under allowed range, the device activates the Power on Reset signal. The device also filters the glitches from the button (SW3).

The JTAG Reset uses device STM6315RDW13F. This device deactivates the JTAG Reset after voltage 3.3 V is in valid range. If the voltage falls down under allowed range the device activate the JTAG Reset signal. The device also filters the glitches from the button (SW2).

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Reset circuit

The last one Reset_BR uses GPIO pin from MPC5604E. The reason is that Broadcom parts has different (more complex)

reset sequence, see Figure 5 . The timing parameters are in the Table 7 .

Symbol

RESET_PU RESET_WAIT RESET_LEN -

Figure 5. Broadcom reset sequence waveforms NOTE

CLK_OUT_25 MHz is generated by MPC5604E part of MPC5606E via CLK_OUT pin.

Table 7. Reset Timing parameters Parameter

Power up to RESET deassertion RESET deassertion to normal PHY operation RESET pulse length RESET rise/fall time

Minimum

10 20 2 -

Maximum

25

Unit

ms µs µs ns The jumper J61, resistors R71, and R65 are for the selection between two MPC5604E GPIO pins. The selection depends on the connected daughter card, if there is connected video daughter cards (Omnivision, Aptina), Port C2 is used for generating

the reset and if there is connected sound daughter card, Port A12 is used for generating the reset, see Figure 6 . The setting of J61 and resistors are in the Table 8 .

Freescale Semiconductor, Inc.

MPC5606E Board User Guide, Rev 2, 04/2014

7

Reset circuit Used daughter card

video (Aptina, Omnivision) sound

Figure 6. Broadcom reset circuitry Table 8. The setting of J61 position of J61

2-3 (default) 1-2

R71

Populate DNP filter the glitches from reset buttons.

NOTE

Both devices only monitor the decrease of the supply voltages under set threshold and

R65

DNP Populate 8

5.1 Reset boot configuration

The MPC5606E has three jumpers for boot configuration (BOOTCFG) that determines the boot location of the MCU based

at POR (Power On Reset), Table 9 shows the boot configuration possibility.

The fourth row configuration (Boot-ID in boot sector) is set as default.

Table 9. Boot configuration FAB (J36)

1 (1-2) 1 (1-2) 1 (1-2) 0 (2-3) 0 (2-3)

ABS0 (J48)

0 (2-3) 1 (1-2) 0 (2-3) -

ABS2 (J37)

0 (2-3) 0 (2-3) 1 (1-2) -

Boot ID

Boot-ID in boot sector no Boot-ID

1

description

Serial boot (SBL) UART (LINFlex) without autobaud Serial boot (SBL) FlexCAN without autobaud Scan of both serial interfaces (FlexCAN and LINFlex) for Serial Boot with autobaud Boot from internal code Flash - single chip (SC) Static mode 1. Flash boot ID was not be find in any boot sector.

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Clock configuration

6 Clock configuration

EVB supports following MCU clock sources: • 25 MHz crystal oscillator (Y2) • 8 MHz external oscillator module (Y1) - driving the MCU EXTAL signal • An external clock input to the EVB via the SMA connector (J53), driving the MCU EXTAL signal The clock circuitry is shown in the diagram on the

Figure 7

- the default positions of jumpers have red color. The 25 MHz crystal circuit is used as default.

Figure 7. EVB clock circuit

Table 10 shows the jumper setting for the clock circuit:

Table 10. Jumper setting for different source of clock Jumper

J26 J33 J43 J52

Crystal (default)

DNP DNP 2-3 1-2

External oscillator

populate 2-3 1-2 2-3

SMA connector

DNP 1-2 1-2 2-3

CAUTION

The MPC5606E clock circuitry are all 3.3 V based. Any external clock signal driven into the SMA connector must have a maximum voltage of 3.3 V.

7 Audio and video interfaces

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

9

Audio and video interfaces

The EVB support two video interfaces (Omnivision and Aptina) and one audio interface, but only one of these interface can be active.

All interfaces have two main part: • The first part of the interface is for managing the device (daughter card) connected on the interface and it uses I2C interface. I2C interface is muxing via jumpers, see

Table 11 and the connection among jumpers is on Figure 8 . The

default setting has done by red symbols (jumpers).

• The second part of the interface is the interface itself and is muxing via resistors and inductors, see Table 12

.

The Omnivision video interface is selected as default. There are other peripherals available in this setting, see

the Serial Audio Interface module of MPC5606E.

Table 12

.

Video interface signals are routed to the Video Encoder wrapper module of MPC5606E. Audio interface signals are routed to

Omnivision video interface

EVB is possible to connect Omnivision camera evaluation boards to Ominivision video connector J58. This interface

supports up to 10-bit parallel data (camera). For the pin description of J58, see Connectors summary description

.

Aptina video interface

EVB is possible to connect Aptina camera evaluation boards to Aptina video connector J57. This interface supports up to 10-

bit parallel data (camera). For the pin description of J57, see Connectors summary description .

Audio interface

The audio interface uses connector J59, for the pin description, see Connectors summary description .

10

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Audio and video interfaces Jumper

J19

Figure 8. I2C jumpers interconnection Table 11. I2C setting of jumper for each interface Omnivision interface (default)

1-2

Aptina interface

1-2

Table continues on the next page...

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Audio interface

2-3 11

Audio and video interfaces Table 11. I2C setting of jumper for each interface (continued) Jumper

J20 J28 J29 J38

1

J39 J40 J41

1

J55 J56

Omnivision interface (default)

1-2 1-2 1-2 1-2 DNP DNP 1-2 1-2 1-2

Aptina interface

1-2 1-2 1-2 1-2 DNP DNP 1-2 2-3 2-3

Audio interface

DNP 2-3 DNP 2-3 2-3 2-3 2-3 DNP DNP 1. This jumper is also used for boot selection during reset.

• When the Omnivision video interface is selected CAN, LIN interfaces, and one measure point (JP18) is available.

• When the Aptina video interface is selected CAN interface and one measure point (JP18) is available.

• When the Audio interface is selected one measure point (JP21) is available.

Device Port Pin

A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 A15 B0

Table 12. Audio and Video resistors and inductors muxing Omnivision video interface (default) Part Name

R101 Data[11] R104 R98 R95 R92 L9 R112 R109 R89 R86 R82 R118 R116 R107 Data[10] Data[9] Data[8] Data[7] PIX_CLK V_Sync H_Sync Data[6] Data[5] Data[4] Data[3] Data[2] PWDN -

Aptina video interface Part

R102 R105 R99 R96 R93 L10 R113 R110 R90 R87 R84 R119 R117

Name

Data[11] Data[10] Data[9] Data[8] Data[7] PIX_CLK V_Sync H_Sync Data[6] Data[5] Data[4] Data[3] Data[2]

Audio interface Part

R100 R103 R97 R94 R91 R114 R111 R108 R88 R85 R83 R65 R106 R77

Table continues on the next page...

Name

SAI0_Data[0 ] SAI0_Data[1 ] SAI0_Data[2 ] SAI0_Data[3 ] SAI0_Sync SAI1_Sync SAI2_Sync SAI0_Bclk SAI2_Data[0 ] SAI2_Bclk SAI2_Mclk Broadcom Reset SAI1_Mclk SAI1_Bclk

Other peripheral Part

R66 R69

Name

JP21 CAN0_TXD 12

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Device Port Pin

B1 B2 B3 C2 C3 C4

1

CAN interface Table 12. Audio and Video resistors and inductors muxing (continued) Omnivision video interface (default) Part Name

R71 L11 Broadcom Reset Clk_in

Aptina video interface Part

R81 R75 R71 L12

Name

Frame_Sync RST Broadcom Reset Clk_in

Audio interface Part

R76 R80 R74 R79 R78 R115

Name

SAI1_Data[0 ] AN13 ETC2_AN14 ETC0 ETC1 SAI0_Mclk

Other peripheral Part

R68 R72 R67 R70 -

Name

CAN0_RXD LIN0_TXD LIN0_RXD JP18 1. This port pin is used for generation of the 25 MHz signal for Audio and Video interfaces. It is necessary to set the functionality of this pin as CLKOUT, the source of CLKOUT is 25 MHz oscillator without divider. The name of this signal in the schematics is CLK_OUT_25_MHz signal.

CAUTION

There is only one functionality available for each port pin Omnivision video interface, Aptina video interface, or other peripheral.

8 CAN interface

The EVB has one NXP TJA1041T high speed CAN transceiver on the MCU CAN channel. This can operate with 3.3 V I/O from the MCU. For flexibility, the CAN transceiver I/O is connected to a standard 0.1-inch connector (P5) and DB9 connector (P3) at the top edge of the PCB. Connectors P5 and P3 provides the CAN bus level signal interface for CAN-A.

The connectors pin out are shown on the Figure 9 .

CAUTION

This interface is not available when the audio daughter card is used.

Figure 9. CAN connectors pin out

Table 13 shows the jumpers setting which controls the external CAN transceiver (interface).

Table 13. CAN jumper setting Jumper

J1 J4

Description

device setting Enable RX

Table continues on the next page...

Default position

short 1-2, 3-4, and 5-6

1

Populate

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

13

LIN and SCI interface Jumper

J5 J6 J7

Table 13. CAN jumper setting (continued) Description

Connect supply voltage 5.0 V Check battery voltage Enable TX .

1. 1-2 disable local wake up, 3-4 disable standby, 5-6 enable the driver.

There is one more connector J3 with following (CAN transceiver) functionality: • pin 1 - error and power indication output • pin 2 - switching the external regulator

Default position

Populate Populate Populate

9 LIN and SCI interface

The EVB provides one LIN interface or one SCI interface. SCI interface is set as default and it is one mode of LIN module which is on MPC5606E. It means only one of this interface can be active in one time. But the selection is given by jumper also because each of the interface uses different external hardware. The jumper setting is in the

Table 14

.

Table 14. Jumper setting for LIN interface (SCI default) Name of jumper

J2 J10 J11 J13 J14 P6

LIN setting

DNP 1-2 Depends on the setting

2

Populate

3

1-2 Short 1-2

4

SCI setting (default)

Populate

1

2-3 DNP DNP 2-3 DNP 1. Enable the SCI driver power supply.

2. This jumper enables master mode pull-up on the LIN interface.

3. Enable the LIN driver.

4. Enable the LIN driver power supply.

9.1 LIN interface

The EVB has one MC33661PEF LIN enhanced physical interface on the MCU LIN channel. This can operate with 3.3 V I/O from the MCU. The LIN transceiver I/O is connected to the standard 0.1-inch connector (P6) and one Molex connector (J12) at the left edge of the PCB. Connectors P6 and J12 provide the LIN bus level signal interface for LIN0. The connectors pin out are shown on the

Figure 10 .

14

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Ethernet interface Figure 10. LIN physical interface connectors

1-2 of P6 for powering the driver.

CAUTION

The LIN VSUP is power supply of LIN driver. You need to populate jumper on position

9.2 SCI interface

The EVB has one MAX3223 RS232 line driver on the MCU SCI (LIN) channel. This can operate with 3.3 V I/O from the MCU. The line driver I/O are connected to a standard DB9 connector (P2) at the top edge of the PCB. Connector P2 provides the RS232 bus level signal interface for SCI (LIN0). The connector pin out is shown on the

Figure 11 .

Figure 11. SCI physical interface connector

10 Ethernet interface

The ethernet physical interface uses two wire ethernet standard and it is a part of MPC5606E, but the interconnection between ethernet and processor is done outside the chip, see the

Table 15

.

Table 15. Connection between ethernet and microcontroller Name of signal Connection

FEC_RXD3 FEC_RXD2 FEC_RXD1 FEC_RXD0 FEC_RX_DV FEC_RX_CLK FEC_TXD3 FEC_TXD2

MPC5604E PADs of MPC5606E

C6 D8 C7 B8 G8 A7 F11 E9

Broadcom PADs of MPC5606E

D7 D9 C9 B9 H8 B7 F10 E8

Table continues on the next page...

directly directly directly directly directly directly directly directly

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

15

User buttons and LEDs Table 15. Connection between ethernet and microcontroller (continued) Name of signal

FEC_TXD1 FEC_TXD0 FEC_TX_EN FEC_TX_CLK CLK_OUT_25 MHz MDC MDIO

MPC5604E PADs of MPC5606E

G11 G10 E11 A10 G6 D11 C10

Broadcom PADs of MPC5606E

H10 H9 E10 A9 H7 C11 B10

Connection

directly directly directly directly R713 = 150 Ohm R20 = 33 Ohm

1 directly 2

1. MDC: Connect Capacitor 100 pF against ground.

2. MDIO: Connect pull up 4k7 and Capacitor 100 pF against ground.

There is populated molex connector Molex 34793-0040, see its pin out on the

Figure 12 .

CAUTION

It is necessary to populate jumpers on J15 (short 3-4 and 5-6), without these MII interface (MDIO and MDC) will not be connected.

Figure 12. Ethernet connector pin out

11 User buttons and LEDs

There are two buttons and four LEDs for the user on the EVB. LEDs and buttons are not primarily connected to the MCU.

The connection can be done via cables, because each LED and button has own test point.

The LED is active (light) if the connected signal is in low level. The LEDs numbers and their tests pins are in the Table 16

.

Table 16. User LEDs and their test pins LED name

D10 D11 D12 D13

Test pin

JP13 JP14 JP15 JP12 The buttons are more flexible because it is possible to configure their active level via jumpers. The setting is valid for both

and is not possible to separate settings for each button. The configuration of jumpers is in the Table 17

.

16

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Position J45

1-2 (GND) 2-3 (3.3 V)

Summary table with default jumpers setting Table 17. Buttons setting Position J46

1-2 (GND) 2-3 (3.3 V) 1-2 (GND) 2-3 (3.3V)

Description

nonsense 1

When the button is pressed there is high voltage level on the test pin. Idle level of voltage is low.

When the button is pressed there is low voltage level on the test pin. Idle level of voltage is high.

nonsense 1

1. If the button is touched it does not influence on the test pin voltage level (buttons are between the same voltage levels).

The buttons number and their tests pins are in the

Table 18 .

Table 18. User Buttons and their test pins Button name

SW4 SW5

Test pin

JP16 JP17

12 Summary table with default jumpers setting

Name

J1 J2 J3 J4 J5 J6 J7 J8 J9 J10 J11 J13 J14

Table 19. Default jumpers summary table Position of jumper

1-2 3-4 5-6 populate DNP populate populate populate populate 1-2 2-3 2-3 DNP DNP 2-3

Table continues on the next page...

Description

Disable CAN driver wake up signal Disable CAN driver standby mode Enable CAN driver Supply voltage for RS232 driver Unconnect CAN information signals Connect CAN RX to driver Connect supply voltage for CAN driver Connect battery voltage to the CAN driver Connect CAN TX to driver Part MPC5604E reset 12 V source voltage for 1V2 DC/DC convertor Select LIN TX signal for SCI Disable LIN Master mode pull-up Disable LIN driver Select LIN RX signal for SCI

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

17

Summary table with default jumpers setting Table 19. Default jumpers summary table (continued) Name

J15 J34 J35 J36 J37 J38 J39 J40 J41 J43 J24 J25 J26 J28 J29 J30 J31 J32 J33 J17 J18 J19 J20 J21 J22 J23 J45 J46 J48 J49 J50 J51 J52 J55 J56 J61

Position of jumper

3-4 5-6 populate populate 1-2 1-2 1-2 populate Populate Populate Populate DNP 1-2 1-2 DNP populate Populate DNP 2-3 2-3 2-3 2-3 1-2 DNP DNP 1-2 2-3 DNP DNP 2-3 populate populate populate 1-2 1-2 1-2 2-3

Description

Short MDIO signal Short MDC signal OVDD_3V3 OVDD_RGMI_3V3 I2C setting for omnivision I2C setting for omnivision VPP_Test connect to GND AVDD_3V3 VDD_LV_COR0_1, VDD_LV_COR0_2, VDD_LV_COR0_3, VDD_LV_PLL0 AVDDL_1V2 DVDD_1V2 Disable external oscillator I2C setting for omnivision I2C setting for omnivision Not select voltage for NMI VDD_HV_ADR PLLVDD_1V2 Disable external oscillator as clock source VDD_HV_S_BALLAST0 = 1.2 V Select ballast resistor Bootconfig FAB = 0 Bootconfig ABS2 = 0 I2C setting and bootconfig I2C setting I2C setting I2C setting Select external crystal as a source of clock Disable buttons Disable buttons Bootconfig ABS0 = 0 XTALVDD_3V3 VDD_HV_FLA0 , VDD_HV_FLA1, VDD_HV_OSC0_REG0 BIASVDD_3V3 Select external crystal I2C setting for omnivision I2C setting for omnivision Broadcom reset 18

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

Connectors summary description

13 Connectors summary description

This section describes the pinout of the EVB user connectors. Each connector has own table with pinout description.

Table 20. NMI connector (J30) Pin

1 2 3

Description

GND NMI 3.3 V

Pin

1 3 5

Table 21. GPIO connector (J54) Description

PORT_B0 GND PORT_B1

Pin

2 4 6

Description

GND GND GND

Pin

1 3 5 7 9 11 13 15 17 19 21 23 25

Table 22. Aptina video interface connector (J57) Description

DATA [4] DATA [6] DATA [8] DATA [10] DATA [2] GND HSYNC NC VSYNC IIC_CLK 5.0 V PIX_CLK GND

Pin

2 4 6 8 10 12 14 16 18 20 22 24 26

Description

DATA [5] DATA [7] DATA [9] DATA [11] DATA [3] GND FRAME_SYNCH RST IIC_DATA NC 5.0 V GND CLK OUT 25 MHz

Pin

1 3

Table 23. Omnivision video interface connector (J58) Description

DATA [4] DATA [6]

Pin

2 4

Table continues on the next page...

Description

DATA [5] DATA [7]

MPC5606E Board User Guide, Rev 2, 04/2014

Freescale Semiconductor, Inc.

19

Connectors summary description Table 23. Omnivision video interface connector (J58) (continued) Pin

5 7 25 27 29 31 9 11 13 15 17 19 21 23

Description

DATA [8] DATA [10] PWDN IIC_DATA IIC_CLK GND GND CLK OUT 25 MHz GND DATA [2] NC NC NC GND

Pin

6 8 26 28 30 32 10 12 14 16 18 20 22 24

Description

DATA [9] DATA [11] NC NC HSYNC VSYNC PIX_CLK 5.0 V 5.0 V DATA [3] NC NC NC GND 20

Pin

1 3 5 7 9 11 13 15 17 35 37 39 41 19 21 23 25 27 29 31 33

Table 24. Audio interface connector (J59) Description

3.3 V SAI0_DATA [3] SAI0_DATA [2] SAI0_DATA [1] SAI0_DATA [0] SAI0_BCLK SAI0_SYNC SAI0_MCLK ETC2_AN14 IIC1_CLK IIC1_DATA SAI1_DATA [0] SAI1_BCLK ETC1 SAI1_SYNC SAI1_MCLK IIC0_CLK IIC0_DATA SAI2_DATA [0] SAI2_BCLK SAI2_SYNC

Table continues on the next page...

Pin

2 4 6 8 10 12 14 16 18 36 38 40 42 20 22 24 26 28 30 32 34

MPC5606E Board User Guide, Rev 2, 04/2014 Description

GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND GND Freescale Semiconductor, Inc.

Pin

43 45 47 49

Connectors summary description Table 24. Audio interface connector (J59) (continued) Description

SAI2_MCLK ETC0 AN13 5.0 V

Pin

44 46 48 50

Description

GND GND GND GND

Pin

1 2 3

Table 25. FlexCAN connector (P5) Description

CANH CANL GND

Pin

1 2 3 4

Table 26. LINFlex connector (P6) Description

12 V Supply LIN driver LIN GND

NOTE

The description of J12 and P2 connectors are in the

LIN interface and

SCI interface .

Freescale Semiconductor, Inc.

MPC5606E Board User Guide, Rev 2, 04/2014

21

How to Reach Us:

Home Page:

freescale.com

Web Support:

freescale.com/support Information in this document is provided solely to enable system and software implementers to use Freescale products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits based on the information in this document.

Freescale reserves the right to make changes without further notice to any products herein.

Freescale makes no warranty, representation, or guarantee regarding the suitability of its products for any particular purpose, nor does Freescale assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages.

“Typical” parameters that may be provided in Freescale data sheets and/or specifications can and do vary in different applications, and actual performance may vary over time. All operating parameters, including “typicals,” must be validated for each customer application by customer's technical experts. Freescale does not convey any license under its patent rights nor the rights of others. Freescale sells products pursuant to standard terms and conditions of sale, which can be found at the following address: freescale.com/SalesTermsandConditions .

Freescale and the Freescale logo are trademarks of Freescale Semiconductor, Inc., Reg. U.S. Pat. & Tm. Off. All other product or service names are the property of their respective owners. The Power Architecture and Power.org word marks and the Power and Power.org

logos and related marks are trademarks and service marks licensed by Power.org.

© 2014 Freescale Semiconductor, Inc.

Document Number MPC5606EBUG Revision 2, 04/2014

advertisement

Was this manual useful for you? Yes No
Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Related manuals