UM11559, SEN-GEN6-SKT user manual - NXP

UM11559SEN-GEN6-SKT user manualRev. 1 — 5 January 2021 User manual

Info Content

Keywords SEN-GEN6-SKT, socket evaluation board

Abstract User manual

Document information

NXP Semiconductors UM11559SEN-GEN6-SKT user manual

1 Introduction

1.1 SEN-GEN6-SKT KitThe SEN-GEN6-SKT board is a socket kit designed to evaluate the FXLS9xxxx, andFXPS7xxxx sensors.

The board supports different communication configurations such as SPI, I²C, DSI3 orPSI5. Before inserting a device into the socket, make sure you have properly configuredthe board to support the desired protocol.

This user manual describes the different options.

1.1.1 Kit contents

Figure 1. Sensor Socket board (SEN-GEN6-SKT)

Content of the Kit:

• One automotive Sensor Socket board (SEN-GEN6-SKT)• Four red jumpers• Two white jumpers• Five blue jumpers• Three green jumpers• Seven purple jumpers

UM11559 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2021. All rights reserved.

User manual Rev. 1 — 5 January 20212 / 18


1.1.2 Schematic

GN

D1

GN

D2

BUSRTN/VSS

IO2

J28HDR 1X3

R330 Ω

DNP

R30 Ω

R320 Ω

DNP

R310 Ω

DNP

R340 Ω

DNP

J7HDR 1X2

jumper = 1

jumper = 2 jumper = 2

jumper = 1

BUSSW_H PCM1/ARM1FXPS7xxxx1 BUS_02 BUSSW_H/TEST03 BUSSW_L/INT4 BUSRTN/VSS5 BUSSW_L/TEST16 NC7 NC8 SPI_NCS9 SPI_CLK/IIC_SCL10 SPI_DIN/TEST411 SPI_DOUT/IIC_SDA12 TEST613 VBUF/VVCIO14 NC15 BUSRTN/VSS16 BUS_I/VCC

VDPL J9CON 2 SKTSILK = PSI5

SILK = VDPLJP11

JP25SILK = VSS

BUSRTN/VSS2

S2

S1

11

1

FXLS9xxxx1 BUS_02 PCM1/ARM13 BUSSW_L/TEST04 TEST15 BUSSW_L/TEST26 TEST37 BUSRTN/VSS8 SPI_NCS9 SPI_CLK/IIC_SCL10 SPI_DIN11 SPI_DOUT/IIC_SDA12 PCM0/ARM013 VBUF/VVCIO14 BUSRTN/VSS15 BUS_I/VCC16 IDATA

FXPS7xxxx FXLS9xxxx

IO15IO16

IO14IO13IO12

IO11IO10IO9

21

J2

345

678

3 2

jumper = 1-2

1

1516

141312

1110

9

IO15IO16

1

1

1

1

MH_100 milMH2 J3

HDR 1X2jumper = 1

1

1

2

2

BUS_I/VCC

BUS_I/VCC

BUS_0

VBUF/VCCIOJ1

HDR 1X2jumper = 1

IO14

NP583-016-009

VBUF/VCCIOPCM0/ARM0

SPI_DOUT/IIC_SDASPI_DINSPI_CLK/IIC_SCL

IO2IO1

IO3IO4IO5

IO6IO7IO8

IO2BUS_0

BUSSW/L/TEST0TEST1

BUSSW/L/TEST2

TEST3BUSRTN/VSS

SPI_NCS

GN

D3

GN

D4

MH_100 milMH4

1MH_100 milMH1

MH_100 milMH3

IO14PCM1/ARM1 BUSRTN/VSS

3 2

jumper = 1-2

1

IO15

J37HDR 1X3

J30HDR 1X3

BUSRTN/VSS BUS_I/VCC3 2

jumper = 1-21

J42HDR 1X3

J33HDR 1X3

C16220 pF

12VDPL BUS_I/VCC

- PSI5: Populate if FXLS9xxxxAES- Other: DNP

BUSRTN/VSS

PI-Filter option

IDATA

BUS_I/VCC

BUSRTN/VSS

3

1

12

23

IO16

J47HDR 1X3

BUS_I/VCC IDATA

3 2

jumper = 1-2

1

TEST1

J55HDR 1X3

BUSRTN/VSS3 2

jumper = 1-2

1

VDPL J10CON 2 SKTSILK = PSI5_Chain

JP20SILK = VSSOUT

SILK = TEST0JP21

BUSSW_L/TEST0

VSSOUT2

S2

S1

1

1

VDPL

BUSR

TN/V

SS

VDPL

MM

BZ27

VCLT

1

MM

BZ27

VCLT

1

VSSO

UT

VDPL

J45CON 2 SKTSILK = PSI5

J49HDR 1X3

jumper = 1-2 R1120 kΩ

R10100 kΩ

2

S1

S2

3

1

BUSRTN/VSS

BUSSW_L/TEST0 BUSRTN/VSS

VSSOUT

NTR4501NT1GQ2

BUSSW_L/TEST2

2

3

2 1 2 1

3

S2

OPTIONAL

D1 D2S1

1

12

PSI5

DAISY CHAIN

BUSR

TN/V

SS

BUSO

UT

BUSR

TN/V

SS

BUS_

0

MM

BZ27

VCLT

1

MM

BZ27

VCLT

1

BUSR

TN/V

SS

3

1 2 1 2 21

3 3

BUSSW_L/TEST0

D3 D5 D4

POWER SUPPLIES

OPTIONAL

SENSOR

DSI3

BUS_

I/VC

CM

MBZ

27VC

LT1

SILK = TEST1JP22

TEST1

SILK = PCM1/ARM1JP16

PCM1/ARM1

SILK = PCM0/ARM0JP18

PCM0/ARM0

SILK = PCM1_OUTJP17

PCM1_OUT

SILK = PCM0_OUTJP19

PCM0_OUT

SILK = TEST2JP23

J17CON 8 SKT

BUSSW_L/TEST2

BUSSW_L/TEST0

TEST1

BUSSW_L/TEST2

TEST3

SILK = TEST3JP26

TEST3

1

1

2345678

TESTMODE

S1

S2

J19

PCM1_OUT

PCM1/ARM1

PCM0/ARM0

PCM0_OUT

1

2345678

S1

S2

J16CON 8 SKT

SPI_DOUT/IIC_SDA

SPI_DIN

SPI_CLK/IIC_SCL

SPI_NCS

12345678

5103310-3

J48

J54

SILK = MDI

5103310-1SILK = BEAGLE

MDI

BEAGLE

SPI_NCS

Standard connectors SPI ARM/PCM

3SPI_CLK/IIC_SCL5SPI_DIN

BUS_I/VCC

VBUF/VCCIO

SPI/CLK/IIC_SCLSPI_DOUT/IIC_SDASPI_DOUT/IIC_SDASPI_CLK/IIC_SCLSPI_NCS

7SPI_DOUT/IIC_SDA9TEST3

VBUF/VCCIO

SPI/DIN

11BUSSW_L/TEST013PCM0/ARM015

246810

13579

2468

10

121416

SILK = NCSJP9

R30

27.4 Ω

R24

82 Ω

R25

27.4 Ω

SPI_NCSSPI_CLK/IIC_SCL

SILK = CLK/SCLJP6

SILK = MOSIJP5

SPI_DINSPI_DOUT/IIC_SDA

SILK = MISO/SDAJP4

C132200 pF

TEST1 BUSSW_L/TEST2

R11 kΩ

R21 kΩ

R51 kΩ

TEST3

SPI_NCS

VBUF/VCCIO

SPI_DOUT/IIC_SDA

SPI_CLK/IIC_SCL

SPI_DIN

DIN- SPI: Do Not Populate- DSI3/PSI5/I2C: Optional (but recommended to be left unterminated)

CLK/SCL- SPI/I2C: Do Not Populate- DSI3/PSI5/I2C: Optional (but recommended to be left unterminated)

R40 Ω

J8HDR 1X2

jumper = 1

12

HDR 1X2jumper = 1

12

HDR 1X2jumper = 1

12

HDR 1X2jumper = 1

JP32SILK = SDAJP33SILK = SCL

J6J5J41

1

1

2

J50HDR 1X2jumper = 1

12

SCL/SDA- I2C: Populate- Others: Do Not Populate

SS_B- I2C: Populate- SPI: Do Not Populate- DSI3/PSI5: Optional (but recommended to be left unterminated)

C172200 pF

C1415 nF

C100.01 µF

C15470 pF C5

100 pF

BUS_0

J51HDR 1X2

jumper = 112

C200.1 µF

C10.47 µF

C6100 pF

BUSOUT BUS_I/VCC

BUS_I/VCC

BUSRTN/VCC

IDATA

J36HDR 1X2

jumper = 1J52

HDR 1X2jumper = 1

jumper = 1

12

C1815 nF

R18

0 Ω

R15

510 Ω

R16

510 Ω

R17

510 Ω

J46HDR 1X3jumper = 2-3

VBUF/VCCIO

3 2 1

- DSI3: Populate- Other protocol: DNP

- DSI3: Populate if FXLS9xxxx- Other protocol: DNP

- DSI3: Optional (if daisy-chain)- Other protocol: Populate

- DSI3: Optional- Other protocol: DNP

- PSI5: Populate as below-> FXLS9xxxx: 1-2-> FXPS7xxxx: 2-3

- Other protocol : DNP

BUS_I/VCC J11CON 2 SKTSILK = DSI3

SILK = BUS_IJP12

JP34SILK = BUSRTN/VSS

Optional filtering PCM

PCM1/ARM1 PCM1_OUT

2S2

S1

11

1

BUSOUT J13CON 2 SKT

SILK = BUSOUTJP14

HDR 1X2JP14

R6100 kΩ

Q1NTR4502PT1Q

SILK = BUSSW_H

JP15

BUSRTN/VSS2

S2

S1

11

R920 kΩ

VBUF/VCCIO J53CON 2 SKTSILK = VBUF

2S2

S1

1

BUS_0 J12CON 2 SKTSILK = PSI3_Chain

R35330 Ω

C212200 pF

SILK = BUS_0JP13

BUSRTN/VSS2

S2

S1

11

2

3

1 BUSSW_H

BUS_I/VCC

BUSOUT

1

SILK = GNDJP27

1

SILK = GNDJP29

1

SILK = GNDJP28

1

SILK = GNDJP30

1

SILK = BUS_IJP31

BUS_I/VCC1

SILK = VBUFJP3

VBUF/VCCIO

HDR = 1X2J34

- SPI/I2C: Populate- DSI3/PSI5: Do Not Populate

- SPI/I2C: Populate- DSI3: Do Not Populate- PSI5: Optional

- DSI3/PSI5: 1-2- SPI/I2C: 2-3

C110.01 µF

C120.01 µF

C70.01 µF

R22

0 Ω

R19

510 Ω

R20

510 Ω

R21

510 Ω

PCM0/ARM0

Legend:The jumper color is related to its use. Please refer to the text below for details:- Sensor: Black- PSI5: Red- DSI3: Blue- I2C: Green- Optional: Grey

Manufacturing:- Add 4x self-adhesive rubber bumper SJ5076 (3M), in the pcb corners (bottom side)

aaa-039727

- Place the jumper as detailed in the schematic. Use reference below for jumper/shunt: Black (M7582-05) Red (M7581-05) Blue (M7583-05) Green (142270-5) Grey (AKSPT/G GREY)

PCM0_OUT

C80.01 µF

C90.01 µF

1

1

1

17 18 19 20

I2C

BUSRTN/VSS

12

1 2

Daisy Chain

Figure 2. Schematic




1.1.3 Component mapping

Figure 3. Component mapping




2 Getting started with the SEN-GEN6-SKT board

2.1 Order an FXLSxxxx sensorOrder any FXLSxxxxx sensors from www.nxp.com or through our distributors.

Device Variation Protocol

FXLS90322 XY – MM SPI, DSI3

FXLS90422 XZ – MM SPI, DSI3

FXLS90333 XY – HH SPI, DSI3

FXLS90433 XZ – HH SPI, DSI3

FXLS93322 XY – MM PSI5

FXLS93422 XZ – MM PSI5

FXLS93333 XY – HH PSI5

FXLS93433 XZ – HH PSI5

FXLS90220 X – M SPI, DSI3

FXLS90230 X – H SPI, DSI3

FXLS90120 Z – M SPI, DSI3

FXLS90130 Z – H SPI, DSI3

FXLS93220 X – M PSI5

FXLS93230 X – H PSI5

FXLS93120 Z – M PSI5

FXLS93130 Z – H PSI5

FXPS7115D4 40 – 115 kPa SPI

FSPS7115DS4T1 40 – 115 kPa SPI

FSPS7115DI4T1 40 – 115 kPa I2C

FXPS7140D4 40 – 140 kPa DSI3

FXPS7140P4 50 – 126 kPa PSI5

FXPS7165DS4T1 60 – 165 kPa SPI

FXPS7165DI4T1 60 – 165 kPa I2C







Table 1. FXLSxxxxx parts list




2.2 Order a kitTo order a socket board, visit http://www.nxp.com/SEN-GEN6-SKT.

Figure 4. SEN-GEN6-SKT board

2.3 Configure the boardThe board supports the FXLS9xxxx, and FXPS7xxxx sensor families.

For easier board configuration, the jumpers have been colored per category/protocol.They are listed below:

• Sensor compatibility or power supply related: black• I²C: green• DSI3: blue• PSI5: red• SPI: N/A

By default, the board is configured for FXLS9xxxx devices in SPI mode. However, theconfiguration can easily be modified using the jumpers.

By default, most jumpers are floating. Floating means they are attached to their properconnector but remain unconnected. The reference to "DNP" means “Do not populate”,meaning it can be removed or unshorted.

2.3.1 FXLS9xxxx (default) or FXPS7xxxx

Table 2 identifies the proper jumper settings for family compatibility.



http://www.nxp.com/SEN-GEN6-SKT


Jumper positionJumper reference

FXLS9xxxx compatibility FXPS7xxxx compatibility

J28 1-2 2-3

J30 1-2 2-3

J37 1-2 2-3

J47 1-2 2-3

J55 1-2 2-3

Table 2. Family compatibility

There are four possible configurations depending on the bus communication protocolneeds of the user.

2.3.2 SPI (default)

By default, the board is configured to support SPI communication. NXP recommendsconfiguring J1, J3, and J36 as non-floating potentials on the sensor supply pins. Refer tothe product data sheet.

Ensure that J4, J5, and J6 are not populated (pull-up resistors). J7 and J8 must remainfloating for SPI mode.

Jumperreference

Jumperposition

Description

J3 1-2 Connect BUS_I/VCC to VBUF_VCCIO

J1 (1-2) Connect BUS_I/VCC to BUS_O (optional)

J36 (1-2) Connect BUS_I/VCC to IDATA (Optional)

J46 2-3 VCC with 1 μF capacitor

J4 1 or DNP Floating





Table 3. SPI mode jumper configuration

2.3.3 I²C

In order to configure I²C mode, begin with the SPI mode configuration and add pull-upresistors on SDA, SCL, and the CS pins.

If the I²C lines are already driven by the MCU (shared pull-up), NXP recommends leavingJ4 and J6 unpopulated.

Jumperreference

Jumperposition

Description

J3 1-2 Connect BUS_I/VCC to VBUF_VCCIO

J1 (1-2) Connect BUS_I/VCC to BUS_O (optional)

Table 4. I²C mode jumper configuration




Jumperreference

Jumperposition

Description

J36 (1-2) Connect BUS_I/VCC to IDATA (Optional)

J46 2-3 VCC with 1 μF capacitor

J4 1-2 Add pull-up resistor on I²C SLC signal

J5 1-2 Add pull-up resistor on I²C SDA signal

J6 1-2 Add pull-up resistor on SS_B signal



Table 4. I²C mode jumper configuration...continued

2.3.4 DSI3

The communication interface between an ECU device (such as MC33SA0528AC) andthe sensor device in DSI3 mode is established via a DSI3 compatible two-wire interface,with parallel or serial (daisy-chain) connections to the satellite modules.

Jumperreference

Jumperposition

Description



J46 2-3 BUS_I/VCC with 0.47 μF capacitor

J36 1-2 Connect BUS_I/VCC to IDATA

J50 1-2 Add 100 pF cap between BUS_O and BUSRTN

J51 1-2 Add 200 pF cap between BUS_I/VSS and BUSRTN

J52 (1-2) Optional EMC filter


Table 5. DSI3 mode jumper configuration

2.3.5 PSI5

The communication interface between an ECU device and this sensor device in PSI5mode is established via a PSI5 compatible two-wire interface, with universal or daisy-chain connections to the satellite modules.

Jumperreference

Jumperposition

Description



J46 2-3 BUS_I/VCC with 0.47 μF capacitor

1-2 Filtering (FXLS9xxxx)J42

2-3 Filtering (FXPS7xxxx)

J34 1-2 Connect the filter to IDATA

Table 6. PSI5 mode jumper configuration




Jumperreference

Jumperposition

Description

1-2 Connect the filter to BUS_I/VCC (FXLS9xxxx only)J33

2-3 Connect the filter to BUS_I/VCC (FXLS9xxxx only)

J49 1-2 or2-3

If using PSI5 daisy chain

Table 6. PSI5 mode jumper configuration...continued

2.4 Insert the sensor into the socketFigure 5 illustrates the proper way to insert the sensor into the socket. For properconnection, align the circle on the IC to the arrowhead (identified in yellow in Figure 5) onthe mounting socket.

Figure 5. Insert sensor in to SEN-GEN6-SKT socket

2.5 Connect the board to a compatible ECUThe SEN-SPI-BOX has two dedicated interfaces suitable for SPI and I²Ccommunications, an MDI connector and a Beagle connector. The NXP MDI connectorsupports the SEN-SPI-BOX kit. The Beagle connector is an industrial standard and maybe coupled to any Beagle compatible analyzer.




Figure 6. SEN-SPI-BOX coupled with a SEN-GEN6-SKT board (SPI protocol)

For DSI3 and PSI5 support, the SEN-SPI-BOX can be used with a dedicated NXPadapter (SEN-DSI3-ADAPTER and SEN-PSI5-ADAPTER).

Refer to Section 2.5.1 for board connections.

2.5.1 NXP MDI and Beagle

Figure 7 illustrates the MDI and Beagle connectors while Figure 8 identifies the individualconnectors.

Figure 7. NXP MDI and Beagle




aaa-039732

NXP MDI

NC PCM0/AM0

MISOSDA

SCKSCLTEST0 TEST3 MOSI /CS VBUF/

VCCIOVBUF/VCCIO

BUSRTN/VSS

BUSRTN/VSS

BUSRTN/VSS

SCL SDA MISO SCK /CSNC NC BUSRTN/VSS

BUSRTN/VSS

BUSRTN/VSS

BUSRTN/VSS

BUS_I/VCC

VBUF/VCCIO

Beagle

Figure 8. NXP MDI and Beagle connections

2.5.2 SPI

Connect the SEN-GEN6-SKT board to any MCU with SPI compatibility using the 4-pinSPI signals and a power supply.

VCC must not exceed 5.25 V.

aaa-039733

MCU(S32K1)

VCC/CS

CLK

MISOMOSI

GND

FXLSxxxxxAES

Figure 9. SPI application diagram

Table 7 identifies the various accessible interfaces that can connect to the MCU board.

Signal name Connectorreference

Description

VCC JP31 Power supply

GND JP29 Ground

SS_B JP9 Chip select

SCLK JP6 Serial Clock

MISO JP4 MCU In Sensor out

MOSI JP5 MCU out Sensor in

SPI J16 4-pin SPI connector

NXP MDI J48 General-purpose connector

Beagle J54 General-purpose connector

Table 7. SPI connector reference

2.5.3 I²C

Connect the SEN-GEN6-SKT board to any I²C MCU board using the two-pin I²C signalsand a power supply.

VCC must not exceed 5.25 V.




aaa-039734

MCU(S32K1)

VCC

SDA

SCL

GND

FXLSxxxxxAES

Figure 10. I²C application diagram


Description

VCC JP31 Power supply

GND JP29 Ground

SDA JP32 I²C Serial Data

SCL JP33 I²C Serial Clock

I²C J16 two-pin I²C connector

NXP MDI J48 General-purpose connector

Beagle J54 General-purpose connector

Table 8. I²C connector reference

The board is equipped with two dedicated interfaces suitable for SPI and I²Ccommunications. The NXP MDI connector supports the SEN-SPI-BOX board. TheBeagle connector, an industrial standard, can be interfaced with any Beagle compatibleanalyzer.

2.5.4 DSI3

The DSI3 protocol, an automotive protocol, provides power supply and bidirectionalcommunication using only two wires. This protocol is suitable for all satellite-basedapplications (such as airbag) requiring safety and EMC robustness.


Description Mode

BUSIN JP12 DSI3 Bus In

BUSRTN JP34 DSI3 bus return

DSI3 J11 two-pin DSI3 connector

Discovery mode /Parallel mode

BUS_O JP13 Daisy chain out


DSI3_Chain J12 two-pin DSI3 daisy chain connector

Daisy chain mode

BUSOUT JP14 Daisy chain out


DSI3_Chain J13 two-pin DSI3 daisy chain connector

Daisy chain mode(FXPS7xxxx only)

Table 9. DSI3 connector reference




2.5.4.1 DSI3 parallel or discovery mode

aaa-039735

DSI3 ECU(MC33SA058)

BUS_I

BUSRTNFXLSxxxxxAES

Figure 11. DSI3 parallel application diagram

2.5.4.2 DSI3 daisy chain

aaa-039736

DSI3 ECU(MC33SA058)

BUS_I

BUSRTNFXLSxxxxxAES

BUS_IBUS_O

BUSRTNFXLSxxxxxAES

Figure 12. DSI3 daisy chain application diagram

2.5.4.3 DSI3 daisy chain mode (FXPS7xxxx only)

aaa-039737

DSI3 ECU(MC33SA058)

BUS_I

BUSRTNFXLSxxxxxAES

BUS_IBUS_OUT

BUSRTNFXLSxxxxxAES

Figure 13. DSI3 daisy chain mode application diagram (FXPS7xxxx only)

2.5.5 PSI5

The PSI protocol, an automotive protocol, provides power supply and bidirectionalcommunication using only two wires. This protocol is suitable for all satellite-basedapplications.


Description Mode

VDPL JP11 PSI5 BUS IN

VSS JP25 PSI5 VSS

PSI5 J9, J45 two-pin PSI5 connector

Universal mode /Parallel mode

VDPL JP11 PSI5 BUS IN

VSSOUT JP20 PSI5 VSS daisy chain

PSI5_Chain J10 two-pin PSI5 daisy chain out

Daisy chain mode

Table 10. PSI5 connector reference




2.5.5.1 PSI5 parallel or universal mode

aaa-039738

PSI5 ECU(MC33789)

VDPL

VSSFXLSxxxxxAES

Figure 14. PSI5 parallel application diagram

2.5.5.2 PSI5 daisy chain mode

aaa-039739

PSI5 ECU(MC33789)

VDPL

VSSFXLSxxxxxAES

VDPL

VSSVSSOUT FXLSxxxxxAES

Figure 15. PSI5 daisy chain mode application diagram




3 Revision history

Rev Date Description

v.1 20210105 Initial release

Table 11. Revision history




4 Legal information

4.1 DefinitionsDraft — A draft status on a document indicates that the content is stillunder internal review and subject to formal approval, which may resultin modifications or additions. NXP Semiconductors does not give anyrepresentations or warranties as to the accuracy or completeness ofinformation included in a draft version of a document and shall have noliability for the consequences of use of such information.

4.2 DisclaimersLimited warranty and liability — Information in this document is believedto be accurate and reliable. However, NXP Semiconductors does notgive any representations or warranties, expressed or implied, as to theaccuracy or completeness of such information and shall have no liabilityfor the consequences of use of such information. NXP Semiconductorstakes no responsibility for the content in this document if provided by aninformation source outside of NXP Semiconductors. In no event shall NXPSemiconductors be liable for any indirect, incidental, punitive, special orconsequential damages (including - without limitation - lost profits, lostsavings, business interruption, costs related to the removal or replacementof any products or rework charges) whether or not such damages are basedon tort (including negligence), warranty, breach of contract or any otherlegal theory. Notwithstanding any damages that customer might incur forany reason whatsoever, NXP Semiconductors’ aggregate and cumulativeliability towards customer for the products described herein shall be limitedin accordance with the Terms and conditions of commercial sale of NXPSemiconductors.

Right to make changes — NXP Semiconductors reserves the right tomake changes to information published in this document, including withoutlimitation specifications and product descriptions, at any time and withoutnotice. This document supersedes and replaces all information supplied priorto the publication hereof.

Applications — Applications that are described herein for any of theseproducts are for illustrative purposes only. NXP Semiconductors makesno representation or warranty that such applications will be suitablefor the specified use without further testing or modification. Customersare responsible for the design and operation of their applications andproducts using NXP Semiconductors products, and NXP Semiconductorsaccepts no liability for any assistance with applications or customer productdesign. It is customer’s sole responsibility to determine whether the NXPSemiconductors product is suitable and fit for the customer’s applicationsand products planned, as well as for the planned application and use ofcustomer’s third party customer(s). Customers should provide appropriatedesign and operating safeguards to minimize the risks associated withtheir applications and products. NXP Semiconductors does not accept anyliability related to any default, damage, costs or problem which is basedon any weakness or default in the customer’s applications or products, orthe application or use by customer’s third party customer(s). Customer isresponsible for doing all necessary testing for the customer’s applicationsand products using NXP Semiconductors products in order to avoid adefault of the applications and the products or of the application or use bycustomer’s third party customer(s). NXP does not accept any liability in thisrespect.

Export control — This document as well as the item(s) described hereinmay be subject to export control regulations. Export might require a priorauthorization from competent authorities.

Evaluation products — This product is provided on an “as is” and “with allfaults” basis for evaluation purposes only. NXP Semiconductors, its affiliatesand their suppliers expressly disclaim all warranties, whether express,

implied or statutory, including but not limited to the implied warranties ofnon-infringement, merchantability and fitness for a particular purpose. Theentire risk as to the quality, or arising out of the use or performance, of thisproduct remains with customer. In no event shall NXP Semiconductors, itsaffiliates or their suppliers be liable to customer for any special, indirect,consequential, punitive or incidental damages (including without limitationdamages for loss of business, business interruption, loss of use, loss ofdata or information, and the like) arising out the use of or inability to usethe product, whether or not based on tort (including negligence), strictliability, breach of contract, breach of warranty or any other theory, even ifadvised of the possibility of such damages. Notwithstanding any damagesthat customer might incur for any reason whatsoever (including withoutlimitation, all damages referenced above and all direct or general damages),the entire liability of NXP Semiconductors, its affiliates and their suppliersand customer’s exclusive remedy for all of the foregoing shall be limited toactual damages incurred by customer based on reasonable reliance up tothe greater of the amount actually paid by customer for the product or fivedollars (US$5.00). The foregoing limitations, exclusions and disclaimers shallapply to the maximum extent permitted by applicable law, even if any remedyfails of its essential purpose.

Translations — A non-English (translated) version of a document is forreference only. The English version shall prevail in case of any discrepancybetween the translated and English versions.

Security — Customer understands that all NXP products may be subjectto unidentified or documented vulnerabilities. Customer is responsiblefor the design and operation of its applications and products throughouttheir lifecycles to reduce the effect of these vulnerabilities on customer’sapplications and products. Customer’s responsibility also extends to otheropen and/or proprietary technologies supported by NXP products for usein customer’s applications. NXP accepts no liability for any vulnerability.Customer should regularly check security updates from NXP and follow upappropriately. Customer shall select products with security features that bestmeet rules, regulations, and standards of the intended application and makethe ultimate design decisions regarding its products and is solely responsiblefor compliance with all legal, regulatory, and security related requirementsconcerning its products, regardless of any information or support that maybe provided by NXP. NXP has a Product Security Incident Response Team(PSIRT) (reachable at [email protected]) that manages the investigation,reporting, and solution release to security vulnerabilities of NXP products.

Suitability for use in automotive applications — This NXP product hasbeen qualified for use in automotive applications. It has been developed inaccordance with ISO 26262, and has been ASIL-classified accordingly. Ifthis product is used by customer in the development of, or for incorporationinto, products or services (a) used in safety critical applications or (b) inwhich failure could lead to death, personal injury, or severe physical orenvironmental damage (such products and services hereinafter referredto as “Critical Applications”), then customer makes the ultimate designdecisions regarding its products and is solely responsible for compliance withall legal, regulatory, safety, and security related requirements concerningits products, regardless of any information or support that may be providedby NXP. As such, customer assumes all risk related to use of any productsin Critical Applications and NXP and its suppliers shall not be liable forany such use by customer. Accordingly, customer will indemnify and holdNXP harmless from any claims, liabilities, damages and associated costsand expenses (including attorneys’ fees) that NXP may incur related tocustomer’s incorporation of any product in a Critical Application.

4.3 TrademarksNotice: All referenced brands, product names, service names andtrademarks are the property of their respective owners.

NXP — wordmark and logo are trademarks of NXP B.V.




TablesTab. 1. FXLSxxxxx parts list ..........................................5Tab. 2. Family compatibility ...........................................7Tab. 3. SPI mode jumper configuration .........................7Tab. 4. I²C mode jumper configuration ..........................7Tab. 5. DSI3 mode jumper configuration .......................8Tab. 6. PSI5 mode jumper configuration .......................8

Tab. 7. SPI connector reference ................................. 11Tab. 8. I²C connector reference .................................. 12Tab. 9. DSI3 connector reference ............................... 12Tab. 10. PSI5 connector reference ............................... 13Tab. 11. Revision history ...............................................15

FiguresFig. 1. Sensor Socket board (SEN-GEN6-SKT) ........... 2Fig. 2. Schematic ..........................................................3Fig. 3. Component mapping .........................................4Fig. 4. SEN-GEN6-SKT board ......................................6Fig. 5. Insert sensor in to SEN-GEN6-SKT socket ....... 9Fig. 6. SEN-SPI-BOX coupled with a SEN-GEN6-

SKT board (SPI protocol) ................................10Fig. 7. NXP MDI and Beagle ......................................10Fig. 8. NXP MDI and Beagle connections ..................11

Fig. 9. SPI application diagram .................................. 11Fig. 10. I²C application diagram ................................... 12Fig. 11. DSI3 parallel application diagram ....................13Fig. 12. DSI3 daisy chain application diagram ............. 13Fig. 13. DSI3 daisy chain mode application diagram

(FXPS7xxxx only) ............................................13Fig. 14. PSI5 parallel application diagram ....................14Fig. 15. PSI5 daisy chain mode application diagram ....14




Contents1 Introduction ......................................................... 21.1 SEN-GEN6-SKT Kit ........................................... 21.1.1 Kit contents ........................................................21.1.2 Schematic .......................................................... 31.1.3 Component mapping ......................................... 42 Getting started with the SEN-GEN6-SKT

board .................................................................... 52.1 Order an FXLSxxxx sensor ............................... 52.2 Order a kit ......................................................... 62.3 Configure the board ...........................................62.3.1 FXLS9xxxx (default) or FXPS7xxxx ...................62.3.2 SPI (default) .......................................................72.3.3 I²C ...................................................................... 72.3.4 DSI3 ...................................................................82.3.5 PSI5 ................................................................... 82.4 Insert the sensor into the socket ....................... 92.5 Connect the board to a compatible ECU ........... 92.5.1 NXP MDI and Beagle ...................................... 102.5.2 SPI ................................................................... 112.5.3 I²C .................................................................... 112.5.4 DSI3 .................................................................122.5.4.1 DSI3 parallel or discovery mode ......................132.5.4.2 DSI3 daisy chain ............................................. 132.5.4.3 DSI3 daisy chain mode (FXPS7xxxx only) .......132.5.5 PSI5 ................................................................. 132.5.5.1 PSI5 parallel or universal mode .......................142.5.5.2 PSI5 daisy chain mode ....................................143 Revision history ................................................ 154 Legal information ..............................................16

Please be aware that important notices concerning this document and the product(s)described herein, have been included in section 'Legal information'.

© NXP B.V. 2021. All rights reserved.For more information, please visit: http://www.nxp.comFor sales office addresses, please send an email to: [email protected]

Date of release: 5 January 2021Document identifier: UM11559

Documents

UM11559, SEN-GEN6-SKT user manual - NXP