US2GB - MDD - Datasheet.World

Document Number: MC33903_4_5

Rev. 14.0, 2/2018

NXP Semiconductors

Data Sheet: Advance Information

* This document contains certain information on a new product.

Specifications and information herein are subject to change without notice.

SBC Gen2 with CAN high speed and

LIN interface

The 33903/4/5 is the second generation family of the System Basis Chip (SBC).

It combines several features and enhances present module designs. The device

works as an advanced power management unit for the MCU with additional

integrated circuits such as sensors and CAN transceivers. It has a built-in

enhanced high-speed CAN interface (ISO11898-2 and -5) with local and bus

failure diagnostics, protection, and fail-safe operation modes. The SBC may

include zero, one or two LIN 2.1 interfaces with LIN output pin switches. It

includes up to four wake-up input pins that can also be configured as output

drivers for flexibility. This device is powered by SMARTMOS technology.

This device implements multiple Low-power (LP) modes, with very low-current

consumption. In addition, the device is part of a family concept where pin

compatibility adds versatility to module design.

The 33903/4/5 also implements an innovative and advanced fail-safe state

machine and concept solution.

Features

• Voltage regulator for MCU, 5.0 or 3.3 V, part number selectable, with

possibility of usage external PNP to extend current capability and share power

dissipation

• Voltage, current, and temperature protection

• Extremely low quiescent current in LP modes

• Fully-protected embedded 5.0 V regulator for the CAN driver

• Multiple undervoltage detections to address various MCU specifications and

system operation modes (i.e. cranking)

• Auxiliary 5.0 or 3.3 V SPI configurable regulator, for additional ICs, with

overcurrent detection and undervoltage protection

• MUX output pin for device internal analog signal monitoring and power supply

monitoring

• Advanced SPI, MCU, ECU power supply, and critical pins diagnostics and

monitoring.

• Multiple wake-up sources in LP modes: CAN or LIN bus, I/O transition,

automatic timer, SPI message, and VDD overcurrent detection.

• ISO11898-5 high-speed CAN interface compatibility for baud rates of 40 kb/s

to 1.0 Mb/s

• Scalable product family of devices ranging from 0 to 2 LINs which are

compatible to J2602-2 and LIN 2.1

33903/

33903/4/5

EK Suffix (Pb-free)

98ASA10556D

32-PIN SOIC

EK Suffix (Pb-free)

98ASA10506D

54-PIN SOIC

Applications

•Aircraft and marine systems

• Automotive and robotic systems

• Farm equipment

• Industrial actuator controls

• Lamp and inductive load controls

• DC motor control applications requiring diagnostics

• Applications where high-side switch control is

required

SYSTEM BASIS CHIP

2NXP Semiconductors

33903/4/5

Table of Contents

1. Simplified application diagrams ..................................................................................................................................................... 3

2. Orderable part ................................................................................................................................................................................ 7

3. Internal block diagrams .................................................................................................................................................................. 9

4. Pin Connections ........................................................................................................................................................................... 11

4.1. Pinout diagram ....................................................................................................................................................................... 11

5. Electrical characteristics .............................................................................................................................................................. 16

5.1. Maximum ratings .................................................................................................................................................................... 16

5.2. Static electrical characteristics ............................................................................................................................................... 18

5.3. Dynamic electrical characteristics .......................................................................................................................................... 26

5.4. Timing diagrams .................................................................................................................................................................... 29

6. Functional description .................................................................................................................................................................. 32

6.1. Introduction ............................................................................................................................................................................ 32

6.2. Functional pin description ...................................................................................................................................................... 32

7. Functional device operation ......................................................................................................................................................... 36

7.1. Mode and state description .................................................................................................................................................... 36

7.2. LP modes ............................................................................................................................................................................... 37

7.3. State diagram ......................................................................................................................................................................... 39

7.4. Mode change ......................................................................................................................................................................... 40

7.5. Watchdog operation ............................................................................................................................................................... 40

7.6. Functional block operation versus mode ............................................................................................................................... 43

7.7. Illustration of device mode transitions .................................................................................................................................... 44

7.8. Cyclic sense operation during LP modes ............................................................................................................................... 45

7.9. Cyclic INT operation during LP VDD on mode ....................................................................................................................... 47

7.10. Behavior at power up and power down ................................................................................................................................ 48

7.11. Fail-safe operation ............................................................................................................................................................... 51

8. CAN interface .............................................................................................................................................................................. 55

8.1. CAN interface description ...................................................................................................................................................... 55

8.2. CAN bus fault diagnostic ........................................................................................................................................................ 58

9. LIN block ...................................................................................................................................................................................... 62

9.1. LIN interface description ........................................................................................................................................................ 62

9.2. LIN operational modes ........................................................................................................................................................... 63

10. Serial peripheral interface .......................................................................................................................................................... 64

10.1. High level overview .............................................................................................................................................................. 64

10.2. Detail operation .................................................................................................................................................................... 64

10.3. Detail of control bits and register mapping ........................................................................................................................... 68

10.4. Flags and device status ....................................................................................................................................................... 84

11. Typical applications ................................................................................................................................................................... 92

12. Packaging ................................................................................................................................................................................ 100

12.1. SOIC 32 package dimensions ........................................................................................................................................... 100

12.2. SOIC 54 package dimensions ........................................................................................................................................... 103

13. Revision history ....................................................................................................................................................................... 106

NXP Semiconductors 3

33903/4/5

SIMPLIFIED APPLICATION DIAGRAMS

1 Simplified application diagrams

Figure 1. 33905D simplified application diagram

Figure 2. 33905S simplified application diagram

SCLK

MOSI

INT

5V-CAN

SUP1

I/O-0

I/O-1

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

SPLIT

BAT

Q1*

BAUX

SAFE

RXD-L1

TXD-L1

LIN-TERM 1

LIN-1

(5.0 V/3.3 V)

SUP2

AUX

CAUX

LIN-TERM 2

LIN-2

RXD-L2

TXD-L2

MUX-OUT

33905D

MCU

SPI

A/D

CAN Bus

LIN Bus

VSENSE

* = Optional

SCLK

MOSI

INT

5V-CAN

SUP1

I/O-0

I/O-1

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

SPLIT

BAT

Q1*

BAUX

SAFE

RXD-L

TXD-L

LIN-T

LIN

(5.0 V/3.3 V)

SUP2

AUX

CAUX

I/O-3

MUX-OUT

33905S

MCU

SPI

A/D

CAN Bus

LIN Bus

VSENSE

BAT

* = Optional

4NXP Semiconductors

33903/4/5

SIMPLIFIED APPLICATION DIAGRAMS

Figure 3. 33904 simplified application diagram

Figure 4. 33903 simplified application diagram

33904

SCLK

MOSI

INT

5V-CAN

SUP1

I/O-0

I/O-1

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

SPLIT

BAT

Q1*

BAUX

SAFE

I/O-3

(5.0 V/3.3 V)

SUP2

AUX

CAUX

I/O-2

MUX-OUT

MCU

SPI

A/D

CAN Bus

VSENSE

BAT

* = Optional

SCLK

MOSI

INT

5V-CAN

VSUP2

I/O-0

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

VDD

SPLIT

BAT

33903

MCU

SPI

CAN Bus

SAFE

VSUP1

NXP Semiconductors 5

33903/4/5

SIMPLIFIED APPLICATION DIAGRAMS

Figure 5. 33903D simplified application diagram

Figure 6. 33903S simplified application diagram

SCLK

MOSI

INT

5V-CAN

SUP

IO-0

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

SPLIT

BAT

Q1*

SAFE

RXD-L1

TXD-L1

LIN-T1/I/O-2

LIN-1

LIN-T2/IO-3

LIN-2 RXD-L2

TXD-L2

MUX-OUT

33903D

MCU

SPI

A/D

CAN Bus

LIN Bus

VSENSE

* = Optional

SCLK

MOSI

INT

5V-CAN

SUP

IO-0

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

SPLIT

BAT

Q1*

SAFE

RXD-L1

TXD-L1

LIN-T1/I/O-2

LIN-1

MUX-OUT

33903S

MCU

SPI

A/D

CAN Bus

LIN Bus

VSENSE

* = Optional

I/O-3

BAT

6NXP Semiconductors

33903/4/5

SIMPLIFIED APPLICATION DIAGRAMS

Figure 7. 33903P simplified application diagram

SCLK

MOSI

INT

5V-CAN

SUP

IO-0

MISO

RXD

TXD

CANL

CANH

GND

RST

DBG

SPLIT

BAT

Q1*

SAFE

MUX-OUT

33903P

MCU

SPI

A/D

CAN Bus

VSENSE

* = Optional

I/O-3

BAT

I/O-2

NXP Semiconductors 7

33903/4/5

ORDERABLE PART

2 Orderable part

Table 1. MC33905 orderable part variations - (all devices rated at TA = -40 °C TO 125 °C)

NXP part number Version

(1), (2), (3)

VDD output

voltage

LIN

interface(s)

Wake-up input / LIN master

termination Package VAUX VSENSE MUX

MC33905D (Dual LIN)

MCZ33905BD3EK/R2 B

3.3 V

2 Wake-up + 2 LIN terms

3 Wake-up + 1 LIN terms

4 Wake-up + no LIN terms

SOIC 54-pin

exposed pad Yes Yes Yes

MCZ33905CD3EK/R2 C

MCZ33905DD3EK/R2 D

MCZ33905D5EK/R2

5.0 V

MCZ33905BD5EK/R2 B

MCZ33905CD5EK/R2 C

MCZ33905DD5EK/R2 D

MC33905S (Single LIN)

MCZ33905BS3EK/R2 B

3.3 V

3 Wake-up + 1 LIN terms

4 Wake-up + no LIN terms

SOIC 32-pin

exposed pad Yes Yes Yes

MCZ33905CS3EK/R2 C

MCZ33905DS3EK/R2 D

MCZ33905S5EK/R2

5.0 V

MCZ33905BS5EK/R2 B

MCZ33905CS5EK/R2 C

MCZ33905DS5EK/R2 D

Notes

1. Design changes in the ‘B’ version resolved VSUP slow ramp up issues, enhanced device current consumption and improved oscillator stability. ‘B’

version has an errata linked to the SPI operation.

2. Design changes in the ‘C’ version resolve the SPI deviation of all prior versions, and does not have the RxD short to ground detection feature.

3. ’C’ versions are no longer recommended for new design.

’D’ versions are recommended for new design, and include quality improvement, and has no electrical parameters specification changes.

Table 2. MC33904 orderable part variations - (all devices rated at TA = -40 °C TO 125 °C)

NXP part number Version

(4), (5), (6)

VDD output

voltage

LIN

interface(s)

Wake-up input / LIN master

termination Package VAUX VSENSE MUX

MC33904

MCZ33904B3EK/R2 B

3.3 V

04 Wake-up SOIC 32 pin

exposed pad Yes Yes Yes

MCZ33904C3EK/R2 C

MCZ33904D3EK/R2 D

MCZ33904A5EK/R2 A

5.0 V

MCZ33904B5EK/R2 B

MCZ33904C5EK/R2 C

MCZ33904D5EK/R2 D

Notes

4. Design changes in the “B” version resolved VSUP slow ramp up issues, enhanced device current consumption and improved oscillator stability.

‘B’ version has an errata linked to the SPI operation.

5. Design changes in the “C” version resolve the SPI deviation of all prior versions, and does not have the RxD short to ground detection feature.

6. ’C’ versions are no longer recommended for new design.

’D’ versions are recommended for new design, and include quality improvement, and has no electrical parameters specification changes.

8NXP Semiconductors

33903/4/5

ORDERABLE PART

Table 3. MC33903 orderable part variations - (all devices rated at TA = -40 °C TO 125 °C)

NXP part number Version

(8), (9), (10)

VDD output

voltage

LIN

interface(s)

Wake-up input / LIN master

termination Package VAUX VSENSE MUX

MC33903

MCZ33903B3EK/R2 B

3.3 V(7)

01 Wake-up SOIC 32 pin

exposed pad No No No

MCZ33903C3EK/R2 C

MCZ33903D3EK/R2 D

MCZ33903B5EK/R2 B

5.0 V(7)

MCZ33903C5EK/R2 C

MCZ33903D5EK/R2 D

MC33903D (Dual LIN)

MCZ33903BD3EK/R2 B

3.3 V

1 Wake-up + 2 LIN terms

2 Wake-up + 1 LIN terms

3 Wake-up + no LIN terms

SOIC 32 pin

exposed pad No Yes Yes

MCZ33903CD3EK/R2 C

MCZ33903DD3EK/R2 D

MCZ33903BD5EK/R2 B

5.0 VMCZ33903CD5EK/R2 C

MCZ33903DD5EK/R2 D

MC33903S (Single LIN)

MCZ33903BS3EK/R2 B

3.3 V

2 Wake-up + 1 LIN terms

3 Wake-up + no LIN terms

SOIC 32 pin

exposed pad No Yes Yes

MCZ33903CS3EK/R2 C

MCZ33903DS3EK/R2 D

MCZ33903BS5EK/R2 B

5.0 VMCZ33903CS5EK/R2 C

MCZ33903DS5EK/R2 D

MC33903P

MCZ33903CP5EK/R2 C5.0 V

03 Wake-up SOIC 32 pin

exposed pad No Yes Yes

MCZ33903DP5EK/R2 D

MCZ33903CP3EK/R2 C3.3 V

MCZ33903DP3EK/R2 D

Notes

7. VDD does not allow usage of an external PNP on the 33903.

8. Design changes in the ‘B’ version resolved VSUP slow ramp up issues, enhanced device current consumption and improved oscillator stability. ‘B’

version has an errata linked to the SPI operation.

9. Design changes in the “C” version resolve the SPI deviation of all prior versions, and does not have the RxD short to ground detection feature.

10. ’C’ versions are no longer recommended for new design.

’D’ versions are recommended for new design, and include quality improvement, and has no electrical parameters specification changes.

NXP Semiconductors 9

33903/4/5

INTERNAL BLOCK DIAGRAMS

3 Internal block diagrams

Figure 8. 33905 internal block diagram

Figure 9. 33904 internal block diagram

SCLK

MOSI

INT

5 V-CAN

VSUP1

I/O-1

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Analog Monitoring

VBAUX

5 V Auxiliary

SAFE

Signals Condition & Analog MUX

Input-Output

VSENSE

Regulator

S2-INT

Oscillator

Regulator

State Machine

Fail-safe

Power Management

VSUP2

S2-INT

VAUX

VCAUX

MUX-OUT

I/O-0

RXD

TXD

Enhanced High Speed CAN

Physical Interface

CANL

CANH

SPLIT

LIN Term #1

LIN-T1

LIN1 RXD-L1

TXD-L1

LIN 2.1 Interface - #1

S2-INT

LIN Term #2

LIN-T2

LIN2 RXD-L2

TXD-L2

LIN 2.1 Interface - #2

S2-INT

I/O-3

LIN Term #1

SCLK

MOSI

INT

5 V-CAN

VSUP1

I/O-1

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Analog Monitoring

VBAUX

5V Auxiliary

SAFE

Signals Condition & Analog MUX

Input-Output

VSENSE

Regulator

S2-INT

Oscillator

Regulator

State Machine

Fail-safe

Power Management

VSUP2

S2-INT

VAUX

VCAUX

MUX-OUT

I/O-0

LIN-T

LIN RXD-L

TXD-L

LIN 2.1 Interface - #1

RXD

TXD

Enhanced High Speed CAN

Physical Interface

CANL

CANH

SPLIT

S2-INT

33905D

33905S

SCLK

MOSI

INT

5V-CAN

VSUP1

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Analog Monitoring

VBAUX

5V Auxiliary

SAFE

Signals Condition & Analog MUX

Input-Output

VSENSE

Regulator

S2-INT

Oscillator

Regulator

State Machine

Fail-safe

Power Management

VSUP2

S2-INT

VAUX

VCAUX

MUX-OUT

RXD

TXD

Enhanced High Speed CAN

Physical Interface

CANL

CANH

SPLIT

I/O-1

I/O-2

I/O-3

I/O-0

10 NXP Semiconductors

33903/4/5

INTERNAL BLOCK DIAGRAMS

Figure 10. 33903 internal block diagram

SCLK

MOSI

INT

5 V-CAN

VSUP2

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Input-Output Regulator

S2-INT

Oscillator

State Machine

Power Management

S2-INT

I/O-0

RXD

TXD

Enhanced High Speed CAN

Physical Interface

CANL

CANH

SPLIT

SAFE

VSUP1

SCLK

MOSI

INT

5 V-CAN

VSUP

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Analog Monitoring

SAFE

Signals Condition & Analog MUX

Input-Output

VSENSE

Regulator

S-INT

Oscillator

State Machine

Fail-safe

Power Management

S-INT

MUX-OUT

IO-0

RXD

TXD

Enhanced High-speed CAN

Physical Interface

CANL

CANH

SPLIT

LIN Term #1

LIN-T1

LIN1 RXD-L1

TXD-L1

LIN 2.1 Interface - #1

S-INT

LIN Term #2

LIN-T2

LIN2 RXD-L2

TXD-L2

LIN 2.1 Interface - #2

S-INT

33903

33903D

I/O-3

LIN Term #1

SCLK

MOSI

INT

5 V-CAN

VSUP

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Analog Monitoring

SAFE

Signals Condition & Analog MUX

Input-Output

VSENSE

Regulator

S-INT

Oscillator

State Machine

Fail-safe

Power Management

MUX-OUT

I/O-0

LIN-T

LIN RXD-L

TXD-L

LIN 2.1 Interface - #1

RXD

TXD

Enhanced High Speed CAN

Physical Interface

CANL

CANH

SPLIT

S-INT

I/O-3

SCLK

MOSI

INT

5 V-CAN

VSUP

MISO

GND

SPI

RST

Regulator

DBG

5V-CAN

Configurable

VDD

Analog Monitoring

SAFE

Signals Condition & Analog MUX

Input-Output

VSENSE

Regulator

S-INT

Oscillator

State Machine

Fail-safe

Power Management

MUX-OUT

I/O-0

RXD

TXD

Enhanced High Speed CAN

Physical Interface

CANL

CANH

SPLIT

S-INT

I/O-2

33903S

33903P

NXP Semiconductors 11

33903/4/5

PIN CONNECTIONS

4 Pin Connections

4.1 Pinout diagram

Figure 11. 33905D, MC33905S, MC33904 and MC33903 pin connections

MC33905D

TXD-L2

GND

RXD-L2

LIN-2

MISO

SCLK

MOSI

VSENSE

VDD

TXD

I/O-1

RXD-L1

TXD-L1

LIN-1

INT

RST

RXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

VSUP2

MUX-OUT

V-AUX

V-CAUX

V-BAUX

VSUP1

LIN-T1/I/O-2

GND CAN

LIN-T2/I/O-3

I/O-0

GND

MC33904

MISO

SCLK

MOSI

VSENSE

VDD

TXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

VSUP2 VE

I/O-1

MUX-OUT

V-AUX

V-CAUX

V-BAUX

VSUP1

I/O-2

GND CAN

INT

RST

I/O-3 RXD

I/O-0

MC33905S

MISO

SCLK

MOSI

VSENSE

VDD

TXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

VSUP2 VE

I/O-1

RXD-L

TXD-L

LIN

MUX-OUT

V-AUX

V-CAUX

V-BAUX

VSUP1

LIN-T/I/O-2

GND CAN

INT

RST

I/O-3 RXD

I/O-0

GROUND

MC33903

MISO

SCLK

MOSI

VDD

TXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

VSUP1

GND CAN

INT

RST

RXD

I/O-0

GROUND

VSUP2

Note: MC33905D, MC33905S, MC33904 and MC33903 are footprint compatible,

GROUND

32 pin exposed package

GND - LEAD FRAME

32 pin exposed package

GND - LEAD FRAME

32 pin exposed package

GND - LEAD FRAME

54 pin exposed package

GND - LEAD FRAME

12 NXP Semiconductors

33903/4/5

PIN CONNECTIONS

Figure 12. 33905D, MC33905S, MC33904 and MC33903 pin connections

MC33903D

MISO

SCLK

MOSI

VSENSE

VDD

TXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

LIN1

GND

LIN2

MUX-OUT

VSUP

GND CAN INT

RST

RXD

IO-0

32 pin exposed package

GROUND

RXD-L1

TXD-L1

LIN-T2 / I/O-3

LIN-T1 / I/O-2

TXD-L2

GND

RXD-L2

MC33903S

MISO

SCLK

MOSI

VSENSE

VDD

TXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

LIN

GND

MUX-OUT

VSUP

GND CAN INT

RST

RXD

I/O-0

32 pin exposed package

GROUND

RXD-L

TXD-L

I/O-3

LIN-T / I/O-2

GND

Note: MC33903D, MC33903S, and MC33903P are footprint compatible.

GND - LEAD FRAMEGND - LEAD FRAME

MC33903P

MISO

SCLK

MOSI

VSENSE

VDD

TXD

SAFE

5V-CAN

CANL

SPLIT

DBG

CANH

N/C

GND

MUX-OUT

VSUP

GND CAN INT

RST

RXD

I/O-0

32 pin exposed package

GROUND

N/C

I/O-3

I/O-2

GND

GND - LEAD FRAME

NXP Semiconductors 13

33903/4/5

PIN CONNECTIONS

4.2 Pin definitions

A functional description of each pin can be found in the Functional pin description section beginning on page 32.

Table 4. 33903/4/5 pin definitions

54 Pin

33905D

32 Pin

33905S

32 Pin

33904

32 Pin

33903

32 Pin

33903D

32 Pin

33903S

32 Pin

33903P Pin Name Pin

Function

Formal

Name Definition

1-3, 20-

22, 27-

30, 32-

35, 52-

N/A 17, 18,

3-4,11-

14, 17-

21, 31,

N/A N/A N/A N/C No

Connect -Connect to GND.

N/A N/A N/A N/A N/A 14, 16,

14, 16,

17, 19-

N/C No

Connect

Do NOT connect the N/C pins to GND. Leave

these pins Open.

4111222VSUP/1 Power

Battery

Voltage

Supply 1

Supply input for the device internal supplies,

power on reset circuitry and the VDD regulator.

VSUP and VSUP1 supplies are internally

connected on part number MC33903BDEK and

MC33903BSEK

5 2 2 2 N/A N/A N/A VSUP2 Power

Battery

Voltage

Supply 2

Supply input for 5 V-CAN regulator, VAUX

regulator, I/O and LIN pins. VSUP1 and VSUP2

supplies are internally connected on part

number MC33903BDEK and MC33903BSEK

6 3 3 N/A 3 3 3

LIN-T2

I/O-3

Output

Input/

Output

LIN

Termination 2

Input/Output

33903D and 33905D - Output pin for the LIN2

master node termination resistor.

33903P, 33903S, 33903D, 33904, 33905S and

33905D - Configurable pin as an input or HS

output, for connection to external circuitry

(switched or small load). The input can be used

as a programmable Wake-up input in (LP)

mode. When used as a HS, no

overtemperature protection is implemented. A

basic short to GND protection function, based

on switch drain-source overvoltage detection, is

available.

7 4 4 N/A 4 4 4

LIN-T1

LIN-T

I/O-2

Output

Input/

Output

LIN

Termination

Input/Output

33905D - Output pin for the LIN1 master node

termination resistor.

33903P, 33903S, 33903D, 33904, 33905S and

33905D - Configurable pin as an input or HS

output, for connection to external circuitry

(switched or small load). The input can be used

as a programmable Wake-up input in (LP)

mode. When used as a HS, no

overtemperature protection is implemented. A

basic short to GND protection function, based

on switch drain-source overvoltage detection, is

available.

8555555SAFE Output Safe Output

(Active LOW)

Output of the safe circuitry. The pin is asserted

LOW if a fault event occurs (e.g.: software

watchdog is not triggered, VDD low, issue on the

RST pin, etc.). Open drain structure.

96666665 V-CAN Output 5V-CAN

Output voltage for the embedded CAN

interface. A capacitor must be connected to this

pin.

10 777777CANH Output CAN High CAN high output.

11 888888CANL Output CAN Low CAN low output.

12 999999GND-CAN Ground GND-CAN Power GND of the embedded CAN interface

13 10 10 10 10 10 10 SPLIT Output SPLIT Output Output pin for connection to the middle point of

the split CAN termination

14 NXP Semiconductors

33903/4/5

PIN CONNECTIONS

14 11 11 N/A N/A N/A N/A VBAUX Output VB Auxiliary Output pin for external path PNP transistor

base

15 12 12 N/A N/A N/A N/A VCAUX Output VCOLLECT

OR Auxiliary

Output pin for external path PNP transistor

collector

16 13 13 N/A N/A N/A N/A VAUX Output VOUT

Auxiliary Output pin for the auxiliary voltage.

17 14 14 N/A 11 11 11 MUX-OUT Output Multiplex

Output

Multiplexed output to be connected to an MCU

A/D input. Selection of the analog parameter

available at MUX-OUT is done via the SPI. A

switchable internal pull-down resistor is

integrated for VDD current sense

measurements.

18 15 15 15 12 12 12 I/O-0 Input/

Output

Input/Output

Configurable pin as an input or output, for

connection to external circuitry (switched or

small load). The voltage level can be read by

the SPI and via the MUX output pin. The input

can be used as a programmable Wake-up input

in LP mode. In LP, when used as an output, the

High-side (HS) or Low-side (LS) can be

activated for a cyclic sense function.

19 16 16 16 13 13 13 DBG Input Debug

Input to activate the Debug mode. In Debug

mode, no watchdog refresh is necessary.

Outside of Debug mode, connection of a

resistor between DBG and GND allows the

selection of Safe mode functionality.

23 N/A N/A N/A 14 N/A N/A TXD-L2 Input LIN Transmit

Data 2

LIN bus transmit data input. Includes an internal

pull-up resistor to VDD.

24,31 N/A N/A N/A 15, 18 15, 18 15, 18 GND Ground Ground Ground of the IC.

25 N/A N/A N/A 16 N/A N/A RXD-L2 Output LIN Receive

Data LIN bus receive data output.

26 N/A N/A N/A 17 N/A N/A LIN2 Input/

Output LIN bus LIN bus input output connected to the LIN bus.

36 17 N/A N/A 19 19 N/A

33903D/5D

LIN-1

33903S/5S

LIN

Input/

Output LIN bus LIN bus input output connected to the LIN bus.

37 18 N/A N/A 20 20 N/A

33903D/5D

TXD-L11

33903S/5S

TXD-L

Input LIN Transmit

Data

LIN bus transmit data input. Includes an internal

pull-up resistor to VDD.

38 19 N/A N/A 21 21 N/A

33903D/5D

RXD-L1

33903S/5S

RXD-L

Output LIN Receive

Data LIN bus receive data output.

39 20 20 N/A 22 22 22 VSENSE Input Sense input

Direct battery voltage input sense. A serial

resistor is required to limit the input current

during high voltage transients.

40 21 21 N/A N/A N/A N/A I/O-1 Input/

Output

Input Output

Configurable pin as an input or output, for

connection to external circuitry (switched or

small load). The voltage level can be read by

the SPI and the MUX output pin. The input can

be used as a programmable Wake-up input in

(LP) mode. It can be used in association with

I/O-0 for a cyclic sense function in (LP) mode.

Table 4. 33903/4/5 pin definitions (continued)

54 Pin

33905D

32 Pin

33905S

32 Pin

33904

32 Pin

33903

32 Pin

33903D

32 Pin

33903S

32 Pin

33903P Pin Name Pin

Function

Formal

Name Definition

NXP Semiconductors 15

33903/4/5

PIN CONNECTIONS

41 22 22 22 23 23 23 RST Output Reset Output

(Active LOW)

This is the device reset output whose main

function is to reset the MCU. This pin has an

internal pull-up to VDD. The reset input voltage

is also monitored in order to detect external

reset and safe conditions.

42 23 23 23 24 24 24 INT Output

Interrupt

Output

(Active LOW)

This output is asserted low when an enabled

interrupt condition occurs. This pin is an open

drain structure with an internal pull up resistor

to VDD.

43 24 24 24 25 25 25 CS Input Chip Select

(Active LOW)

Chip select pin for the SPI. When the CS is low,

the device is selected. In (LP) mode with VDD

ON, a transition on CS is a Wake-up condition

44 25 25 25 26 26 26 SCLK Input Serial Data

Clock

Clock input for the Serial Peripheral Interface

(SPI) of the device

45 26 26 26 27 27 27 MOSI Input Master Out /

Slave In SPI data received by the device

46 27 27 27 28 28 28 MISO Output Master In /

Slave Out

SPI data sent to the MCU. When the CS is high,

MISO is high-impedance

47 28 28 28 29 29 29 VDD Output Voltage

Digital Drain

5.0 or 3.3 V output pin of the main regulator for

the Microcontroller supply.

48 29 29 29 30 30 30 TXD Input Transmit

Data

CAN bus transmit data input. Internal pull-up to

VDD

49 30 30 30 31 31 31 RXD Output Receive Data CAN bus receive data output

50 31 31 N/A 32 32 32 VE Voltage

Emitter

Connection to the external PNP path transistor.

This is an intermediate current supply source

for the VDD regulator

51 32 32 N/A 1 1 1 VB Output Voltage Base Base output pin for connection to the external

PNP pass transistor

EX PAD EX PAD EX PAD EX PAD EX PAD EX PAD EX PAD GND Ground Ground Ground

Table 4. 33903/4/5 pin definitions (continued)

54 Pin

33905D

32 Pin

33905S

32 Pin

33904

32 Pin

33903

32 Pin

33903D

32 Pin

33903S

32 Pin

33903P Pin Name Pin

Function

Formal

Name Definition

16 NXP Semiconductors

33903/4/5

ELECTRICAL CHARACTERISTICS

5 Electrical characteristics

5.1 Maximum ratings

Table 5. Maximum ratings

All voltages are referenced to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or permanent damage

to the device.

Symbol Ratings Value Unit Notes

Electrical ratings(11)

VSUP1/2

VSUP1/2TR

Supply Voltage at VSUP/1 and VSUP2

Normal Operation (DC)

Transient Conditions (Load Dump)

-0.3 to 28

-0.3 to 40

VBUSLIN

VBUSLINTR

DC voltage on LIN/1 and LIN2

Normal Operation (DC)

Transient Conditions (Load Dump)

-28 to 28

-28 to 40

VBUS

VBUSTR

DC voltage on CANL, CANH, SPLIT

Normal Operation (DC)

Transient Conditions (Load Dump)

-28 to 28

-32 to 40

VSAFE

VSAFETR

DC Voltage at SAFE

Normal Operation (DC)

Transient Conditions (Load Dump)

-0.3 to 28

-0.3 to 40

VI/O

VI/OTR

DC Voltage at I/O-0, I/O-1, I/O-2, I/O-3 (LIN-T Pins)

Normal Operation (DC)

Transient Conditions (Load Dump)

-0.3 to 28

-0.3 to 40

VDIGLIN DC voltage on TXD-L, TXD-L1 TXD-L2, RXD-L, RXD-L1, RXD-L2 -0.3 to VDD +0.3 V

VDIG DC voltage on TXD, RXD -0.3 to VDD +0.3 V(13)

VINT DC Voltage at INT -0.3 to 10 V

VRST DC Voltage at RST -0.3 to VDD +0.3 V

VRST DC Voltage at MOSI, MSIO, SCLK and CS -0.3 to VDD +0.3 V

VMUX DC Voltage at MUX-OUT -0.3 to VDD +0.3 V

VDBG DC Voltage at DBG -0.3 to 10 V

ILH Continuous current on CANH and CANL 200 mA

VREG DC voltage at VDD, 5V-CAN, VAUX, VCAUX -0.3 to 5.5 V

VREG DC voltage at VBASE and VBAUX -0.3 to 40 V(12)

VE DC voltage at VE -0.3 to 40 V(13)

VSENSE DC voltage at VSENSE -28 to 40 V

Notes

11. The voltage on non-VSUP pins should never exceed the VSUP voltage at any time or permanent damage to the device may occur.

12. If the voltage delta between VSUP/1/2 and VBASE is greater than 6.0 V, the external VDD ballast current sharing functionality may be damaged.

13. Potential Electrical Over Stress (EOS) damage may occur if RXD is in contact with VE while the device is ON.

NXP Semiconductors 17

33903/4/5

ELECTRICAL CHARACTERISTICS

Figure 13. PCB with top and bottom layer dissipation area (dual layer)

VESD1-1

VESD1-2

VESD2-1

VESD2-2

VESD3-1

VESD3-2

VESD3-3

VESD4-1

VESD4-2

VESD4-3

ESD Capability

AECQ100(14)

Human Body Model - JESD22/A114 (CZAP = 100 pF, RZAP = 1500 Ω)

CANH and CANL. LIN1 and LIN2, Pins versus all GND pins

all other Pins including CANH and CANL

Charge Device Model - JESD22/C101 (CZAP = 4.0 pF)

Corner Pins (Pins 1, 16, 17, and 32)

All other Pins (Pins 2-15, 18-31)

Tested per IEC 61000-4-2 (CZAP = 150 pF, RZAP = 330 Ω)

Device unpowered, CANH and CANL pin without capacitor, versus GND

Device unpowered, LIN, LIN1 and LIN2 pin, versus GND

Device unpowered, VS1/VS2 (100 nF to GND), versus GND

Tested per specific OEM EMC requirements for CAN and LIN with

additional capacitor on VSUP/1/2 pins (See Typical applications on page

92)

CANH, CANL without bus filter

LIN, LIN1 and LIN2 with and without bus filter

I/O with external components (22 k - 10 nF)

±8000

±2000

±750

±500

±15000

±9000

±12000

±7000

Thermal ratings

TJJunction temperature 150 °C

TAAmbient temperature -40 to 125 °C

TST Storage temperature -50 to 150 °C

Thermal resistance

RθJA Thermal resistance junction to ambient 50 °C/W (17)

TPPRT Peak package reflow temperature during reflow Note 16 °C (15), (16)

Notes

14. ESD testing is performed in accordance with the Human Body Model (HBM) (CZAP = 100 pF, RZAP = 1500 Ω), the Charge Device Model (CDM),

and Robotic (CZAP = 4.0 pF).

15. Pin soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may cause

malfunction or permanent damage to the device.

16. NXP’s Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow Temperature and

Moisture Sensitivity Levels (MSL), go to www.nxp.com, search by part number (remove prefixes/suffixes) and enter the core ID to view all

orderable parts, and review parametrics.

17. This parameter was measured according to Figure 13:

Table 5. Maximum ratings (continued)

All voltages are referenced to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or permanent damage

to the device.

Symbol Ratings Value Unit Notes

PCB 100mm x 100mm

Bottom side

20mm x 40mm

Top side, 300 sq. mm

(20mmx15mm)

Bottom view

18 NXP Semiconductors

33903/4/5

ELECTRICAL CHARACTERISTICS

5.2 Static electrical characteristics

Table 6. Static electrical characteristics

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

Power input

VSUP1/VSUP2 Nominal DC Voltage Range 5.5 -28 V(18)

VSUP1/VSUP2 Extended DC Low Voltage Range 4.0 -5.5 V(19)

VS1_LOW

Undervoltage Detector Thresholds, at the VSUP/1 pin,

Low threshold (VSUP/1 ramp down)

High threshold (VSUP/1 ramp up)

Hysteresis

Note: function not active in LP mode

5.5

0.22

6.0

0.35

6.5

6.6

0.5

VS2_LOW

Undervoltage Detector Thresholds, at the VSUP2 pin:

Low threshold (VSUP2 ramp down)

High threshold (VSUP2 ramp up)

Hysteresis

Note: function not active in LP modes

5.5

0.22

6.0

0.35

6.5

6.6

0.5

VS_HIGH

VSUP Overvoltage Detector Thresholds, at the VSUP/1 pin:

Not active in LP modes 16.5 17 18.5 V

BATFAIL Battery loss detection threshold, at the VSUP/1 pin. 2.0 2.8 4.0 V

VSUP-TH1 VSUP/1 to turn VDD ON, VSUP/1 rising -4.1 4.5 V

VSUP-TH1HYST VSUP/1 to turn VDD ON, hysteresis (Guaranteed by design) 150 180 mV

ISUP1

Supply current

- from VSUP/1

- from VSUP2, (5V-CAN VAUX, I/O OFF)

2.0

0.05

4.0

0.85

mA (20), (21)

ISUP1+2

Supply current, ISUP1 + ISUP2, Normal mode, VDD ON

- 5 V-CAN OFF, VAUX OFF

- 5 V-CAN ON, CAN interface in Sleep mode, VAUX OFF

- 5 V-CAN OFF, Vaux ON

- 5 V-CAN ON, CAN interface in TXD/RXD mode, VAUX OFF, I/O-x

disabled

2.8

4.5

5.0

5.5

8.0

ILPM_OFF

LP mode VDD OFF. Wake-up from CAN, I/O-x inputs

VSUP ≤ 18 V, -40 to 25 °C

VSUP ≤ 18 V, 125 °C

μA

ILPM_ON

LP mode VDD ON (5.0 V) with VDD undervoltage and VDD

overcurrent monitoring, Wake-up from CAN, I/O-x inputs

VSUP ≤ 18 V, -40 to 25 °C, IDD = 1.0 μA

VSUP ≤ 18 V, -40 to 25 °C, IDD = 100 μA

VSUP ≤ 18 V, 125 °C, IDD = 100 μA

-20

μA

IOSC

LP mode, additional current for oscillator (used for: cyclic sense,

forced Wake-up, and in LP VDD ON mode cyclic interruption and

watchdog)

VSUP ≤ 18 V, -40 to 125 °C -5.0 9.0

μA

VDBG Debug mode DBG voltage range 8.0 -10 V

Notes

18. All parameters in spec (ex: VDD regulator tolerance).

19. Device functional, some parameters could be out of spec. VDD is active, device is not in Reset mode if the lowest VDD undervoltage reset threshold

is selected (approx. 3.4 V). CAN and I/Os are not operational.

20. In Run mode, CAN interface in Sleep mode, 5 V-CAN and VAUX turned OFF. IOUT at VDD < 50 mA. Ballast: turned OFF or not connected.

21. VSUP1 and VSUP2 supplies are internally connected on part number MC33903BDEK and MC33903BSEK. Therefore, ISUP1 and ISUP2 cannot

be measured individually.

NXP Semiconductors 19

33903/4/5

ELECTRICAL CHARACTERISTICS

VDD Voltage regulator, VDD pin

VOUT-5.0

VOUT-5.0-EMC

VOUT-3.3

Output Voltage

VDD = 5.0 V, VSUP 5.5 to 28 V, IOUT 0 to 150 mA

VDD = 5.0 V, under EMC immunity test condition

VDD = 3.3 V, VSUP 5.5 to 28 V, IOUT 0 to 150 mA

4.9

3.234

5.0

3.3

5.1

5.15

3.4

V(22)

VDROP

Drop voltage without external PNP pass transistor

VDD = 5.0 V, IOUT = 100 mA

VDD = 5.0 V, IOUT = 150 mA

330

450

500

mV (23)

VDROP-B

Drop voltage with external transistor

IOUT = 200 mA (I_BALLAST + I_INTERNAL)-350 500 mV (23)

VSUP1-3.3

VSUP/1 to maintain VDD within VOUT-3.3 specified voltage range

VDD = 3.3 V, IOUT = 150 mA

VDD = 3.3 V, IOUT = 200 mA, external transistor implemented

4.0

KExternal ballast versus internal current ratio (I_BALLAST = K x Internal

current) 1.5 2.0 2.5

ILIM Output Current limitation, without external transistor 150 350 550 mA

TPW Temperature pre-warning (Guaranteed by design) -140 -°C

TSD Thermal shutdown (Guaranteed by design) 160 - - °C

CEXT Range of decoupling capacitor (Guaranteed by design) 4.7 -100 μF(24)

VDDLP

LP mode VDD ON, IOUT ≤ 50 mA (time limited)

VDD = 5.0 V, 5.6 V ≤ VSUP ≤ 28 V

VDD = 3.3 V, 5.6 V ≤ VSUP ≤ 28 V

4.75

3.135

5.0

3.3

5.25

3.465

LP-IOUTDC

LP mode VDD ON, dynamic output current capability (Limited duration.

Ref. to device description). - - 50 mA

LP-ITH

LP VDD ON mode:

Overcurrent Wake-up threshold.

Hysteresis

1.0

0.1

3.0

1.0

LP-VDROP

LP mode VDD ON, drop voltage, at IOUT = 30 mA (Limited duration.

Ref. to device description) -200 400 mV (23)

LP-MINVS

LP mode VDD ON, min VSUP operation (Below this value, a VDD,

undervoltage reset may occur) 5.5 - - V

VDD_OFF VDD when VSUP < VSUP-TH1, at I_VDD ≤ 10 μA (Guaranteed by design) - - 0.3 V

VDD_START UP

VDD when VSUP ≥ VSUP-TH1, at I_VDD ≤ 40 mA (Guaranteed with

parameter VSUP-TH1

3.0 - - V

Notes

22. Guaranteed by design. During immunity tests, according to IEC62132-4, with RF injection applied to CAN or LIN pins. No filter components on

CAN or LIN pins. When immunity tests are performed with a CAN filter component (common mode choke) or LIN filter component (capacitor), the

VDD specification is 5.0 V ±2%.

23. For 3.3 V VDD devices, the drop-out voltage test condition leads to a VSUP below the min VSUP threshold (4.0 V). As a result, the dropout voltage

parameter cannot be specified.

24. The regulator is stable without an external capacitor. Usage of an external capacitor is recommended for AC performance.

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

20 NXP Semiconductors

33903/4/5

ELECTRICAL CHARACTERISTICS

Voltage regulator for CAN interface supply, 5.0 V-CAN pin

5V-C OUT

Output voltage, VSUP/2 = 5.5 to 40 V

IOUT 0 to 160 mA 4.75 5.0 5.25 V

5V-C ILIM Output Current limitation 160 280 -mA (25)

5V-C UV Undervoltage threshold 4.1 4.5 4.7 V

5V-CTS Thermal shutdown (Guaranteed by design) 160 - - °C

CEXT-CAN External capacitance (Guaranteed by design) 1.0 -100 μF

V auxiliary output, 5.0 and 3.3 V selectable pin VB-Aux, VC-Aux, Vaux

VAUX

VAUX output voltage

VAUX = 5.0 V, VSUP = VSUP2 5.5 to 40 V, IOUT 0 to 150 mA

VAUX = 3.3 V, VSUP = VSUP2 5.5 to 40 V, IOUT 0 to 150 mA

4.75

3.135

5.0

3.3

5.25

3.465

VAUX-UVTH

VAUX undervoltage detector (VAUX configured to 5.0 V)

Low Threshold

Hysteresis

VAUX undervoltage detector (VAUX configured to 3.3 V, default

value)

4.2

0.06

2.75

4.5

3.0

4.70

0.12

3.135

VAUX-ILIM

VAUX overcurrent threshold detector

VAUX set to 3.3 V

VAUX set to 5.0 V

250

230

360

330

450

430

VAUX CAP External capacitance (Guaranteed by design) 2.2 -100 μF

Undervoltage reset and reset function, RST pin

VRST-TH1

VDD undervoltage threshold down - 90% VDD (VDD 5.0 V)

VDD undervoltage threshold up - 90% VDD (VDD 5.0 V)

VDD undervoltage threshold down - 90% VDD (VDD 3.3 V)

VDD undervoltage threshold up - 90% VDD (VDD 3.3 V)

4.5

2.75

4.65

3.0

4.85

4.90

3.135

(26), (28)

VRST-TH2-5 VDD undervoltage reset threshold down - 70% VDD (VDD 5.0 V) 2.95 3.2 3.45 V(27), (28)

VRST-HYST

Hysteresis

for threshold 90% VDD, 5.0 V device

for threshold 70% VDD, 5.0 V device

Hysteresis 3.3 V VDD

for threshold 90% VDD, 3.3 V device

150

VRST-LP

VDD undervoltage reset threshold down - LP VDD ON mode

(Note: device change to Normal Request mode). VDD 5.0 V

(Note: device change to Normal Request mode). VDD 3.3 V

4.0

2.75

4.5

3.0

4.85

3.135

VOL Reset VOL @ 1.5 mA, VSUP 5.5 to 28 V - 300 500 mV

IRESET LOW Current limitation, Reset activated, VRESET = 0.9 x VDD 2.5 7.0 10 mA

RPULL-UP Pull-up resistor (to VDD pin) 8.0 11 15 kΩ

Notes

25. Current limitation will be reported by setting a flag.

26. Generate a Reset or an INT. SPI programmable

27. Generate a Reset

28. In Non-LP modes

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

NXP Semiconductors 21

33903/4/5

ELECTRICAL CHARACTERISTICS

Undervoltage reset and reset function, RST PIN (continued)

VSUP-RSTL VSUP to guaranteed reset low level 2.5 - - V (29)

VRST-VTH

Reset input threshold

Low threshold, VDD = 5.0 V

High threshold, VDD = 5.0 V

Low threshold, VDD = 3.3 V

High threshold, VDD = 3.3 V

1.5

0.99

3.5

2.31

VHYST Reset input hysteresis 0.5 1.0 1.5 V

I/O pins when function selected is output

VI/O-0 HSDRP I/O-0 HS switch drop @ I = -12 mA, VSUP = 10.5 V - 0.5 1.4 V

VI/O-2-3 HSDRP I/O-2 and I/O-3 HS switch drop @ I = -20 mA, VSUP = 10.5 V - 0.5 1.4 V

VI/O-1 HSDRP I/O-1, HS switch drop @ I = -400 μA, VSUP = 10.5 V - 0.4 1.4 V

VI/O-01 LSDRP I/O-0, I/O-1 LS switch drop @ I = 400 μA, VSUP = 10.5 V - 0.4 1.4 V

II/O_LEAK Leakage current, I/O-x ≤ VSUP -0.1 3.0 μA

I/O pins when function selected is input

VI/O_NTH Negative threshold 1.4 2.0 2.9 V

VI/O_PTH Positive threshold 2.1 3.0 3.8 V

VI/O_HYST Hysteresis 0.2 1.0 1.4 V

II/O_IN Input current, I/O ≤ VSUP/2 -5.0 1.0 5.0 μA

RI/O-X

I/O-0 and I/O-1 input resistor. I/O-0 (or I/O-1) selected in

VSENSE input

VSENSE_TH

VSENSE undervoltage threshold (Not active in LP modes)

Low Threshold

High threshold

Hysteresis

8.1

0.1

8.6

0.25

9.0

9.1

0.5

RVSENSE

Input resistor to GND. In all modes except in LP modes. (Guaranteed

by design). -125 - kΩ

Notes

29. Reset must be kept low

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

22 NXP Semiconductors

33903/4/5

ELECTRICAL CHARACTERISTICS

Analog MUX output

VOUT_MAX Output Voltage Range, with external resistor to GND >2.0 kΩ0.0 - VDD - 0.5 V

RMI Internal pull-down resistor for regulator output current sense 0.8 1.9 2.8 kΩ

CMUX External capacitor at MUX OUTPUT (Guaranteed by design) - - 1.0 nF (30)

TEMP-COEFF

Chip temperature sensor coefficient (Guaranteed by design and

device characterization)

VDD = 5.0 V

VDD = 3.3 V

13.2

13.9

14.6

mv/°C

VTEMP

Chip temperature: MUX-OUT voltage

VDD = 5.0 V, TA = 125 °C

VDD = 3.3 V, TA = 125 °C

3.6

2.45

3.75

2.58

3.9

2.65

VTEMP(GD)

Chip temperature: MUX-OUT voltage (guaranteed by design and

characterization)

TA = -40 °C, VDD = 5.0 V

TA = 25 °C, VDD = 5.0 V

TA = -40 °C, VDD = 3.3 V

TA = 25 °C, VDD = 3.3 V

0.12

1.5

0.07

1.08

0.30

1.65

0.19

1.14

0.48

1.8

0.3

1.2

VSENSE GAIN

Gain for VSENSE, with external 1.0 k 1% resistor

VDD = 5.0 V

VDD = 3.3 V

5.42

8.1

5.48

8.2

5.54

8.3

VSENSE OFFSET Offset for VSENSE, with external 1.0 k 1% resistor -20 -20 mV

VSUP/1 RATIO

Divider ratio for VSUP/1

VDD = 5.0 V

VDD = 3.3 V

5.335

7.95

5.5

8.18

5.665

8.45

VI/O RATIO

Attenuation/Gain ratio for I/O-0 and I/O-1 actual voltage:

VDD = 5.0 V, I/O = 16 V (Attenuation, MUX-OUT register bit 3 set to

VDD = 5.0 V, (Gain, MUX-OUT register bit 3 set to 0)

VDD = 3.3 V, I/O = 16 V (Attenuation, MUX-OUT register bit 3 set to

VDD = 3.3 V, (Gain, MUX-OUT register bit 3 set to 0)

3.8

5.6

4.0

2.0

5.8

1.3

4.2

6.2

VREF

Internal reference voltage

VDD = 5.0 V

VDD = 3.3 V

2.45

1.64

2.5

1.67

2.55

1.7

IDD_RATIO

Current ratio between VDD output & IOUT at MUX-OUT

(IOUT at MUX-OUT = IDD out / IDD_RATIO)

At IOUT = 50 mA

I_OUT from 25 to 150 mA

62.5

115

117

SAFE output

VOL SAFE low level, at I = 500 μA0.0 0.2 1.0 V

ISAFE-IN

Safe leakage current (VDD low, or device unpowered). VSAFE 0 to

28 V. -0.0 1.0 μA

Notes

30. When C is higher than CMUX, a serial resistor must be inserted

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

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ELECTRICAL CHARACTERISTICS

Interrupt

VOL Output low voltage, IOUT = 1.5 mA -0.2 1.0 V

RPU Pull-up resistor 6.5 10 14 kΩ

VOH-LPVDDON Output high level in LP VDD ON mode (Guaranteed by design) 3.9 4.3 V

VMAX

Leakage current INT voltage = 10 V (to allow high-voltage on MCU

INT pin) -35 100 μA

I SINK Sink current, VINT > 5.0 V, INT low state 2.5 6.0 10 mA

MISO, MOSI, SCLK, CS pins

VOL Output low voltage, IOUT = 1.5 mA (MISO) - - 1.0 V

VOH Output high voltage, IOUT = -0.25 mA (MISO) VDD -0.9 - V

VIL Input low voltage (MOSI, SCLK,CS) - - 0.3 x VDD V

VIH Input high voltage (MOSI, SCLK,CS)0.7 x VDD - - V

IHZ Tri-state leakage current (MISO) -2.0 -2.0 μA

IPU Pull-up current (CS)200 370 500 μA

CAN logic input pins (TXD)

VIH High Level Input Voltage 0.7 x VDD - VDD + 0.3 V

VIL Low Level Input Voltage -0.3 -0.3 x VDD V

IPDWN

Pull-up Current, TXD, VIN = 0 V

VDD = 5.0 V

VDD = 3.3 V

-850

-500

-650

-250

-200

-175

µA

CAN data output pins (RXD)

VOUTLOW

Low Level Output Voltage

IRXD = 5.0 mA 0.0 -0.3 x VDD

VOUTHIGH

High Level Output Voltage

IRX = -3.0 mA 0.7 x VDD - VDD

IOUTHIGH

High Level Output Current

VRXD = VDD - 0.4 V 2.5 5.0 9.0 mA

IOUTLOW

Low Level Input Current

VRXD = 0.4 V 2.5 5.0 9.0 mA

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

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ELECTRICAL CHARACTERISTICS

CAN output pins (CANH, CANL)

VCOM Bus pins common mode voltage for full functionality -12 -12 V

VCANH-VCANL Differential input voltage threshold 500 -900 mV

VDIFF-HYST Differential input hysteresis 50 - - mV

RIN Input resistance 5.0 -50 kΩ

RIN-DIFF Differential input resistance 10 -100 kΩ

RIN-MATCH Input resistance matching -3.0 0.0 3.0 %

VCANH

CANH output voltage (45 Ω < RBUS < 65 Ω)

TXD dominant state

TXD recessive state

2.75

2.0

3.5

2.5

4.5

3.0

VCANL

CANL output voltage (45 Ω < RBUS < 65 Ω)

TXD dominant state

TXD recessive state

0.5

2.0

1.5

2.5

2.25

3.0

VOH-VOL

Differential output voltage (45 Ω < RBUS < 65 Ω)

TXD dominant state

TXD recessive state

1.5

-0.5

2.0

0.0

3.0

0.05

ICANH CAN H output current capability - Dominant state - - -30 mA

ICANL CAN L output current capability - Dominant state 30 - - mA

ICANL-OC CANL overcurrent detection - Error reported in register 75 120 195 mA

ICANH-OC CANH overcurrent detection - Error reported in register -195 -120 -75 mA

RINSLEEP

CANH, CANL input resistance to GND, device supplied, CAN in Sleep

mode, V_CANH, V_CANL from 0 to 5.0 V 5.0 -50 kΩ

VCANLP CANL, CANH output voltage in LP VDD OFF and LP VDD ON modes -0.1 0.0 0.1 V

ICAN-UN_SUP1

CANH, CANL input current, VCANH, VCANL = 0 to 5.0 V, device

unpowered (VSUP, VDD, 5V-CAN: open). -3.0 10 µA (31)

ICAN-UN_SUP2

CANH, CANL input current, VCANH, VCANL = -2.0 to 7.0 V, device

unpowered (VSUP, VDD, 5V-CAN: open). - - 250 µA (31)

VDIFF-R-LP Differential voltage for recessive bit detection in LP mode - - 0.4 V(32)

VDIFF-D-LP Differential voltage for dominant bit detection in LP mode 1.15 - - V (32)

CANH and CANL diagnostic information

VLG CANL to GND detection threshold 1.6 1.75 2.0 V

VHG CANH to GND detection threshold 1.6 1.75 2.0 V

VLVB CANL to VBAT detection threshold, VSUP/1 and VSUP2 > 8.0 V - VSUP -2.0 - V

VHVB CANH to VBAT detection threshold, VSUP/1 and VSUP2 > 8.0 V - VSUP -2.0 - V

VL5 CANL to VDD detection threshold 4.0 VDD -0.43 - V

VH5 CANH to VDD detection threshold 4.0 VDD -0.43 - V

Notes

31. VSUP, VDD, 5V-CAN: shorted to GND, or connected to GND via a 47 k resistor instances are guaranteed by design and device characterization.

32. Guaranteed by design and device characterization.

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

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ELECTRICAL CHARACTERISTICS

SPLIT

VSPLIT

Output voltage

Loaded condition ISPLIT = ±500 µA

Unloaded condition Rmeasure > 1.0 MΩ

0.3 x VDD

0.45 x VDD

0.5 x VDD

0.7 x VDD

0.55 x VDD

ILSPLIT

Leakage current

-12 V < VSPLIT < +12 V

-22 to -12 V < VSPLIT < +12 to +35 V

0.0

5.0

200

µA

LIN terminals (LIN-T/1, LIN-T2)

VLT_HSDRP LIN-T1, LIN-T2, HS switch drop @ I = -20 mA, VSUP > 10.5 V - 1.0 1.4 V

LIN1 & LIN2 33903D/5D pin - LIN 33903S/5S pin (parameters guaranteed for VSUP/1, VSUP2 7.0 V ≤ VSUP ≤ 18 V)

VBAT Operating Voltage Range 8.0 -18 V

VSUP Supply Voltage Range 7.0 -18 V

IBUS_LIM

Current Limitation for Driver Dominant State

Driver ON, VBUS = 18 V 40 90 200 mA

IBUS_PAS_DOM

Input Leakage Current at the receiver

Driver off; VBUS = 0 V; VBAT = 12 V -1.0 - - mA

IBUS_PAS_REC

Leakage Output Current to GND

Driver Off; 8.0 V < VBAT < 18 V; 8.0 V < VBUS < 18 V; VBUS ≥ VBAT - - 20 µA

IBUS_NO_GND

Control unit disconnected from ground (Loss of local ground must not

affect communication in the residual network)

GNDDEVICE = VSUP; VBAT = 12 V; 0 < VBUS < 18 V (Guaranteed by

design)

-1.0 -1.0 mA

IBUSNO_BAT

VBAT Disconnected; VSUP_DEVICE = GND; 0 < VBUS < 18 V (Node has

to sustain the current that can flow under this condition. Bus must

remain operational under this condition). (Guaranteed by design)

- - 100 µA

VBUSDOM Receiver Dominant State - - 0.4 VSUP

VBUSREC Receiver Recessive State 0.6 - - VSUP

VBUS_CNT

Receiver Threshold Center

(VTH_DOM + VTH_REC)/2 0.475 0.5 0.525 VSUP

VHYS

Receiver Threshold Hysteresis

(VTH_REC - VTH_DOM) - - 0.175 VSUP

VBUSWU LIN Wake-up threshold from LP VDD ON or LP VDD OFF mode -5.3 5.8 V

RSLAVE LIN Pull-up Resistor to VSUP 20 30 60 kΩ

TLINSD Overtemperature Shutdown (Guaranteed by design) 140 160 180 °C

TLINSD_HYS Overtemperature Shutdown Hysteresis (Guaranteed by design) -10 -°C

Table 6. Static electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, unless otherwise noted. Typical values noted reflect

the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

26 NXP Semiconductors

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ELECTRICAL CHARACTERISTICS

5.3 Dynamic electrical characteristics

Table 7. Dynamic electrical characteristics

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, GND = 0 V, unless otherwise noted. Typical values

noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

SPI timing

FREQ SPI Operation Frequency (MISO cap = 50 pF) 0.25 -4.0 MHz

tPCLK SCLK Clock Period 250 - N/A ns

tWSCLKH SCLK Clock High Time 125 - N/A ns

tWSCLKL SCLK Clock Low Time 125 - N/A ns

tLEAD

Falling Edge of CS to Rising Edge of SCLK

‘C’ and ‘D’ versions

All others

550

N/A

tLEAD

Falling Edge of CS to Rising Edge of SCLK when CS_low flag is set to

‘1’

‘C’ and ‘D’ versions

All others

0.030

0.55

2.5

μs

tLAG Falling Edge of SCLK to Rising Edge of CS 30 - N/A ns

tSISU MOSI to Falling Edge of SCLK 30 - N/A ns

tSIH Falling Edge of SCLK to MOSI 30 - N/A ns

tRSO MISO Rise Time (CL = 50 pF) - - 30 ns

tFSO MISO Fall Time (CL = 50 pF) - - 30 ns

tSOEN

tSODIS

Time from Falling to MISO Low-impedance

Time from Rising to MISO High-impedance

30 ns

tVALID Time from Rising Edge of SCLK to MISO Data Valid - - 30 ns

tCSLOW

Delay between falling and rising edge on CS

‘C’ and ‘D’ versions

All others

1.0

5.5

N/A

μs

tCS-TO CS Chip Select Low Timeout Detection 2.0 - - ms

Supply, voltage regulator, reset

tVS_LOW1/2_DGLT VSUP undervoltage detector threshold deglitcher 30 50 100 μs

tRISE-ON Rise time at turn ON. VDD from 1.0 to 4.5 V. 2.2 μF at the VDD pin. 50 250 800 μs

tRST-DGLT Deglitcher time to set RST pin low 20 30 40 μs

Reset pulse duration

tRST-PULSE

VDD undervoltage (SPI selectable)

short, default at power on when BATFAIL bit set

medium

medium long

long

0.9

4.0

8.5

1.0

5.0

1.4

6.0

tRST-WD Watchdog reset 0.9 1.0 1.4 ms

I/O input

tIODT Deglitcher time (Guaranteed by design) 19 30 41 μs

VSENSE input

tBFT Undervoltage deglitcher time 30 -100 μs

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ELECTRICAL CHARACTERISTICS

Interrupt

tINT-PULSE

INT pulse duration (refer to SPI for selection. Guaranteed by design)

short (25 to 125 °C)

short (-40 °C)

long (25 to 125 °C)

long (-40 °C)

100

130

140

μs

State diagram timings

tD_NM

Delay for SPI Timer A, Timer B or Timer C write command after

entering Normal mode

(No command should occur within tD_NM.

tD_NM delay definition: from CS rising edge of “Go to Normal mode (i.e.

0x5A00)” command to CS falling edge of “Timer write” command)

60 - - μs

tTIMING-ACC

Tolerance for: watchdog period in all modes, FWU delay, Cyclic sense

period and active time, Cyclic Interrupt period, LP mode overcurrent

(unless otherwise noted)

-10 -10 %(36)

CAN dynamic characteristics

tDOUT TXD Dominant State Timeout 300 600 1000 µs

tDOM Bus dominant clamping detection 300 600 1000 µs

tLRD

Propagation loop delay TXD to RXD, recessive to dominant (Fast slew

rate) 60 120 210 ns

tTRD Propagation delay TXD to CAN, recessive to dominant -70 110 ns

tRRD Propagation delay CAN to RXD, recessive to dominant -45 140 ns

tLDR

Propagation loop delay TXD to RXD, dominant to recessive (Fast slew

rate) 100 120 200 ns

tTDR Propagation delay TXD to CAN, dominant to recessive -75 150 ns

tRDR Propagation delay CAN to RXD, dominant to recessive -50 140 ns

tLOOP-MSL

Loop time TXD to RXD, Medium Slew Rate (Selected by SPI)

Recessive to Dominant

Dominant to Recessive

200

tLOOP-SSL

Loop time TXD to RXD, Slow Slew Rate (Selected by SPI)

Recessive to Dominant

Dominant to Recessive

300

tCAN-WU1-F

CAN Wake-up filter time, single dominant pulse detection (See

Figure 35)0.5 2.0 5.0 μs(33)

tCAN-WU3-F CAN Wake-up filter time, 3 dominant pulses detection 300 - - ns (34)

tCAN-WU3-TO

CAN Wake-up filter time, 3 dominant pulses detection timeout (See

Figure 36)- - 120 μs(35)

Notes

33. No Wake-up for single pulse shorter than tCAN-WU1 min. Wake-up for single pulse longer than tCAN-WU1 max.

34. Each pulse should be greater than tCAN-WU3-F min. Guaranteed by design, and device characterization.

35. The 3 pulses should occur within tCAN-WU3-TO. Guaranteed by design, and device characterization.

36. Guaranteed by design.

Table 7. Dynamic electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, GND = 0 V, unless otherwise noted. Typical values

noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

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ELECTRICAL CHARACTERISTICS

LIN physical layer: driver characteristics for normal slew rate - 20.0 kBit/sec according to lin physical layer specification

Bus load RBUS and CBUS 1.0 nF / 1.0 kΩ, 6.8 nF / 660 Ω, 10 nF / 500 Ω. See Figure 18, page 30.

Duty Cycle 1:

THREC(MAX) = 0.744 * VSUP

THDOM(MAX) = 0.581 * VSUP

D1 = tBUS_REC(MIN)/(2 x tBIT), tBIT = 50 µs, 7.0 V ≤ VSUP ≤ 18 V 0.396 - -

Duty Cycle 2:

THREC(MIN) = 0.422 * VSUP

THDOM(MIN) = 0.284 * VSUP

D2 = tBUS_REC(MAX)/(2 x tBIT), tBIT = 50 µs, 7.6 V ≤ VSUP ≤ 18 V - - 0.581

LIN physical layer: driver characteristics for slow slew rate - 10.4 kBit/sec according to lin physical layer specification

Bus load RBUS and CBUS 1.0 nF / 1.0 kΩ, 6.8 nF / 660 Ω, 10 nF / 500 Ω. Measurement thresholds. See Figure 19, page 31.

Duty Cycle 3:

THREC(MAX) = 0.778 * VSUP

THDOM(MAX) = 0.616 * VSUP

D3 = tBUS_REC(MIN)/(2 x tBIT), tBIT = 96 µs, 7.0 V ≤ VSUP ≤ 18 V 0.417 - -

Duty Cycle 4:

THREC(MIN) = 0.389 * VSUP

THDOM(MIN) = 0.251 * VSUP

D4 = tBUS_REC(MAX)/(2 x tBIT), tBIT = 96 µs, 7.6 V ≤ VSUP ≤ 18 V - - 0.590

LIN physical layer: driver characteristics for fast slew rate

SRFAST LIN Fast Slew Rate (Programming Mode) -20 - V / μs

LIN physical layer: characteristics and wake-up timings. VSUP from 7.0 to 18 V, bus load RBUS and CBUS 1.0 nF / 1.0 kΩ, 6.8 nF / 660 Ω,

10 nF / 500 Ω. See Figure 18, page 30.

REC_PD

REC_SYM

Propagation Delay and Symmetry (See Figure 18, page 30 and

Figure 19, page 31)

Propagation Delay of Receiver, tREC_PD = MAX (tREC_PDR,

tREC_PDF)

Symmetry of Receiver Propagation Delay, tREC_PDF - tREC_PDR

- 2.0

4.2

6.0

2.0

μs

t PROPWL

Bus Wake-up Deglitcher (LP VDD OFF and LP VDD ON modes) (See

Figure 20, page 30 for LP VDD OFF mode and Figure 21, page 31 for

LP mode)

42 70 95 μs

WAKE_LPVDDOFF

WAKE_LPVDDON

Bus Wake-up Event Reported

From LP VDD OFF mode

From LP VDD ON mode

1.0

1500

μs

t TXDDOM TXD Permanent Dominant State Delay (Guaranteed by design) 0.65 1.0 1.35 s

Table 7. Dynamic electrical characteristics (continued)

Characteristics noted under conditions 5.5 V ≤ VSUP ≤ 28 V, - 40 °C ≤ TA ≤ 125 °C, GND = 0 V, unless otherwise noted. Typical values

noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.

Symbol Characteristic Min. Typ. Max. Unit Notes

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ELECTRICAL CHARACTERISTICS

5.4 Timing diagrams

Figure 14. SPI timing

Figure 15. CAN signal propagation loop delay TXD to RXD

Figure 16. CAN signal propagation delays TXD to CAN and CAN to RXD

Di 0

Do 0

Undefined Don’t Care Di n Don’t Care

tLEAD

tSIH

tSISU

tLAG

tPCLK

tWCLKH

tWCLKL

tVALID

Do n

tSODIS

SCLK

MOSI

MISO

tSOEN

tCSLOW

TXD

RXD

0.3 x V

LRD

0.7 x V

LDR

0.3 x V

0.7 x V

TXD

VDIFF

0.9 V

TRD

0.5 V

TDR

RXD

RRD

RDR

0.3 x VDD

0.7 x V

0.3 x V

0.7 x V

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ELECTRICAL CHARACTERISTICS

Figure 17. Test circuit for CAN timing characteristics

Figure 18. LIN timing measurements for normal slew rate

VSUP

12 V

CANL

22 μF

10 μF

SPLIT

GND

TXD

RXD

Signal generator

All pins are not shown

RBUS

15 pF

CBus

100 pF

60 Ω

100 nF

5 V_CAN

CANH

TXD

LIN

RXD

tBIT tBIT

tBUS_DOM(MAX) tBUS_REC(MIN)

tREC_PDF(1)

74.4% V

SUP

42.2% VSUP

58.1% VSUP

28.4% VSUP

tBUS_REC(MAX)

VLIN_REC

tBUS_DOM(MIN)

RXD

Output of receiving Node 1

Output of receiving Node 2

THREC(MAX)

THDOM(MAX)

THREC(MIN)

THDOM(MIN)

Thresholds of

receiving node 1

Thresholds of

receiving node 2

tREC_PDR(1)

tREC_PDF(2)

tREC_PDR(2)

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ELECTRICAL CHARACTERISTICS

Figure 19. LIN timing measurements for slow slew rate

Figure 20. LIN wake-up LP VDD off mode timing

Figure 21. LIN Wake-up LP VDD ON Mode Timing

TXD

LIN

RXD

tBIT tBIT

tBUS_DOM(MAX) tBUS_REC(MIN)

tREC_PDF(1)

77.8% V

SUP

38.9% VSUP

61.6% VSUP

25.1% VSUP

tBUS_REC(MAX)

VLIN_REC

tBUS_DOM(MIN)

RXD

Output of receiving Node 1

Output of receiving Node 2

THREC(MAX)

THDOM(MAX)

THREC(MIN)

THDOM(MIN)

Thresholds of

receiving node 1

Thresholds of

receiving node 2

tREC_PDR(1)

tREC_PDF(2)

tREC_PDR(2)

VDD

LIN

Dominant level

0.4 V

SUP

PROPWL WAKE

BUSWU

REC

IRQ

LIN

LIN_REC

Dominant level

0.4 V V

IRQ stays low until SPI reading command

PROPWL

WAKE

BUSWU

SUP

32 NXP Semiconductors

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FUNCTIONAL DESCRIPTION

6 Functional description

6.1 Introduction

The MC33903_4_5 is the second generation of System Basis Chip, combining:

- Advanced power management unit for the MCU, the integrated CAN interface and for the additional ICs such as sensors, CAN

transceiver.

- Built in enhanced high speed CAN interface (ISO11898-2 and -5), with local and bus failure diagnostic, protection, and fail-safe operation

mode.

- Built in LIN interface, compliant to LIN 2.1 and J2602-2 specification, with local and bus failure diagnostic and protection.

- Innovative hardware configurable fail-safe state machine solution.

- Multiple LP modes, with low current consumption.

- Family concept with pin compatibility; with and without LIN interface devices.

6.2 Functional pin description

6.2.1 Power supply (VSUP/1 and VSUP2)

Note: VSUP1 and VSUP2 supplies are externally available on all devices except the 33903D, 33903S, and 33903P, where these are

connected internally.

VSUP1 is the input pin for the internal supply and the VDD regulator. VSUP2 is the input pin for the 5 V-CAN regulator, LIN’s interfaces

and I/O functions. The VSUP block includes over and undervoltage detections which can generate interrupt. The device includes a loss

of battery detector connected to VSUP/1.

Loss of battery is reported through a bit (called BATFAIL). This generates a POR (Power On Reset).

6.2.2 VDD voltage regulator (VDD)

The regulator has two main modes of operation (Normal mode and LP mode). It can operate with or without an external PNP transistor.

In Normal mode, without external PNP, the max DC capability is 150 mA. Current limitation, temperature pre-warning flag and

overtemperature shutdown features are included. When VDD is turned ON, rise time from 0 to 5.0 V is controlled. Output voltage is 5.0 V.

A 3.3 V option is available via dedicated part number.

If current higher than 150 mA is required, an external PNP transistor must be connected to VE (PNP emitter) and VB (PNP base) pins, in

order to increase total current capability and share the power dissipation between internal VDD transistor and the external transistor. See

External transistor Q1 (VE and VB). The PNP can be used even if current is less than 150 mA, depending upon ambient temperature,

maximum supply and thermal resistance. Typically, above 100-200 mA, an external ballast transistor is recommended.

6.2.3 VDD regulator in LP mode

When the device is set in LP VDD ON mode, the VDD regulator is able to supply the MCU with a DC current below typically 1.5 mA (LP-

ITH). Transient current can also be supplied up to a tenth of a mA. Current in excess of 1.5 mA is detected, and this event is managed by

the device logic (Wake-up detection, timer start for overcurrent duration monitoring or watchdog refresh).

6.2.4 External transistor Q1 (VE and VB)

The device has a dedicated circuit to allow usage of an external “P” type transistor, with the objective to share the power dissipation

between the internal transistor of the VDD regulator and the external transistor. The recommended bipolar PNP transistor is MJD42C or

BCP52-16.

When the external PNP is connected, the current is shared between the internal path transistor and the external PNP, with the following

typical ratio: 1/3 in the internal transistor and 2/3 in the external PNP. The PNP activation and control is done by SPI.

The device is able to operate without an external transistor. In this case, the VE and VB pins must remain open.

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FUNCTIONAL DESCRIPTION

6.2.5 5 V-CAN voltage regulator for CAN and analog MUX

This regulator is supplied from the VSUP/2 pin. A capacitor is required at 5 V-CAN pin. Analog MUX and part of the LIN interfaces are

supplied from 5 V-CAN. Consequently, the 5 V-CAN must be ON in order to have Analog MUX operating and to have the LIN interface

operating in TXD/RXD mode.

The 5 V-CAN regulator is OFF by default and must be turned ON by SPI. In Debug mode, the 5 V-CAN is ON by default.

6.2.6 V auxiliary output, 5.0 and 3.3 V selectable

(VB-Aux, VC-Aux, and VCaux) - Q2

The VAUX block is used to provide an auxiliary voltage output, 5.0 or 3.3 V, selectable by the SPI. It uses an external PNP pass transistor

for flexibility and power dissipation constraints. The external recommended bipolar transistors are MJD42C or BCP52-16.

An overcurrent and undervoltage detectors are provided.

VAUX is controlled via the SPI, and can be turned ON or OFF. VAUX low threshold detection and overcurrent information will disable VAUX,

and are reported in the SPI and can generate INT. VAUX is OFF by default and must be turned ON by the SPI.

6.2.7 Undervoltage reset and reset function (RST)

The RST pin is an open drain structure with an internal pull-up resistor. The LS driver has limited current capability when asserted low, in

order to tolerate a short to 5.0 V. The RST pin voltage is monitored in order to detect failure (e.g. RST pin shorted to 5.0 V or GND).

The RST pin reports an undervoltage condition to the MCU at the VDD pin, as a RST failure in the watchdog refresh operation. VDD

undervoltage reset also operates in LP VDD ON mode.

Two VDD undervoltage thresholds are included. The upper (typically 4.65 V, RST-TH1-5) can lead to a Reset or an Interrupt. This is selected

by the SPI. When “RST-TH2-5“is selected, in Normal mode, an INT is asserted when VDD falls below “RST-TH1-5“, then, when VDD falls

below “RST-TH2-5” a Reset will occur. This will allow the MCU to operate in a degraded mode (i.e., with 4.0 V VDD).

6.2.8 I/O pins (I/O-0: I/O-3)

I/Os are configurable input/output pins. They can be used for small loads or to drive external transistors. When used as output drivers, the

I/Os are either a HS or LS type. They can also be set to high-impedance. I/Os are controlled by the SPI and at power on, the I/Os are set

as inputs. They include overload protection by temperature or excess of a voltage drop.

When I/O-0/-1/-2/-3 voltage is greater than VSUP/2 voltage, the leakage current (II/O_LEAK) parameter is not applicable

• I/O-0 and I/O-1 will have current flowing into the device through three diodes limited by an 80 kOhm resistor (in series).

• I/O-2 and I/O-3 will have unlimited current flowing into the device through one diode.

In LP mode, the state of the I/O can be turned ON or OFF, with extremely low power consumption (except when there is a load). Protection

is disabled in LP mode. When cyclic sense is used, I/O-0 is the HS/LS switch, I/O-1, -2 and -3 are the wake inputs. I/O-2 and I/O-3 pins

share the LIN Master pin function.

6.2.9 VSENSE input (VSENSE)

This pin can be connected to the battery line (before the reverse battery protection diode), via a serial resistor and a capacitor to GND. It

incorporates a threshold detector to sense the battery voltage and provide a battery early warning. It also includes a resistor divider to

measure the VSENSE voltage via the MUX-OUT pin.

6.2.10 MUX-output (MUXOUT)

The MUX-OUT pin (Figure 22) delivers an analog voltage to the MCU A/D input. The voltage to be delivered to MUX-OUT is selected via

the SPI, from one of the following functions: VSUP/1, VSENSE, I/O-0, I/O-1, Internal 2.5 V reference, die temperature sensor, VDD current

copy.

Voltage divider or amplifier is inserted in the chain, as shown in Figure 22.

For the VDD current copy, a resistor must be added to the MUX-OUT pin, to convert current into voltage. Device includes an internal 2.0 k

resistor selectable by the SPI.

Voltage range at MUX-OUT is from GND to VDD. It is automatically limited to VDD (max 3.3 V for 3.3 V part numbers).

The MUX-OUT buffer is supplied from 5 V-CAN regulator, so the 5 V-CAN regulator must be ON in order to have:

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FUNCTIONAL DESCRIPTION

1) MUX-OUT functionality and

2) SPI selection of the analog function.

If the 5 V-CAN is OFF, the MUX-OUT voltage is near GND and the SPI command that selects one of the analog inputs is ignored.

Delay must be respected between SPI commands for 5 V-CAN turned ON and SPI to select MUX-OUT function. The delay depends

mainly upon the 5 V-CAN capacitor and load on 5 V-CAN.

The delay can be estimated using the following formula: delay = C(5 V-CAN) x U (5.0 V) / I_lim 5 V-CAN.

C = cap at 5 V-CAN regulator, U = 5.0 V,

I_LIM 5 V-CAN = min current limit of 5 V-CAN regulator (parameter 5 V-C ILIM).

Note:

As there is no link between 5VCAN and VDD, the 5VCAN can starts after both the VDD and RSTB are released. To ensure the MCU can

use MUXOUT output information, it must verify the presence of the 5VCAN. This can be done for instance by checking the 5VCAN

undervoltage flag (bit4 of the 0xDF00 SPI command).

Figure 22. Analog multiplexer block diagram

6.2.11 DGB (DGB) and debug mode

6.2.11.1 Primary function

It is an input used to set the device in Debug mode. This is achieved by applying a voltage between 8.0 and 10 V at the DEBUG pin and

then, powering up the device (See State diagram). When the device leaves the INIT Reset mode and enters into INIT mode, it detects the

voltage at the DEBUG pin to be between a range of 8.0 to 10 V, and activates the Debug mode.

When Debug mode is detected, no Watchdog SPI refresh commands are necessary. This allows an easy debug of the hardware and

software routines (i.e. SPI commands).

When the device is in Debug mode it is reported by the SPI flag. While in Debug mode, and the voltage at DBG pin falls below the 8.0 to

10 V range, the Debug mode is left, and the device starts the watchdog operation, and expects the proper watchdog refresh. The Debug

mode can be left by SPI. This is recommended to avoid staying in Debug mode when an unwanted Debug mode selection (FMEA pin) is

present. The SPI command has a higher priority than providing 8.0 to 10 V at the DEBUG pin.

BAT

VSUP/1

S_in

I/O-1

I/O-0

ultiplexer

DD-I_COPY

M(*)

(*)Optional

A/D in

MCU

S_iddc

MUX-OUT

S_g3.3

Tem p

VSENSE

S_g5

SENSE

1.0 k

S_ir

S_in

REF

: 2.5 V

5V-CAN

S_I/O_att

All swicthes and resistor are configured and controlled via the SPI

RM: internal resistor connected when VREG current monitor is used

S_g3.3 and S_g5 for 5.0 V or 3.3 V VDD versions

S_iddc to select VDD regulator current copy

S_in1 for LP mode resistor bridge disconnection

S_ir to switch on/off of the internal RMI resistor

S_I/O_att for I/O-0 and I/O-1 attenuation selection

buffer

5V-CAN

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FUNCTIONAL DESCRIPTION

6.2.11.2 Secondary function

The resistor connected between the DBG pin and the GND selects the Fail-Safe mode operation. DBG pin can also be connected directly

to GND (this prevents the usage of Debug mode).

Flexibility is provided to select SAFE output operation via a resistor at the DBG pin or via a SPI command. The SPI command has higher

priority than the hardware selection via Debug resistor. When the Debug mode is selected, the SAFE modes cannot be configured via the

resistor connected at DBG pin.

6.2.12 SAFE

6.2.12.1 Safe output pin

This pin is an output and is asserted low when a fault event occurs. The objective is to drive electrical safe circuitry and set the ECU in a

known state, independent of the MCU and SBC, once a failure has been detected. The SAFE output structure is an open drain, without

a pull-up.

6.2.13 Interrupt (INT)

The INT output pin is asserted low or generates a low pulse when an interrupt condition occurs. The INT condition is enabled in the INT

No current will flow inside the INT structure when VDD is low, and the device is in LP VDD OFF mode. This allows the connection of an

external pull-up resistor and connection of an INT pin from other ICs without extra consumption in unpowered mode.

INT has an internal pull-up structure to VDD. In LP VDD ON mode, a diode is inserted in series with the pull-up, so the high level is slightly

lower than in other modes.

6.2.14 CANH, CANL, SPLIT, RXD, TXD

These are the pins of the high speed CAN physical interface, between the CAN bus and the micro controller. A detail description is

provided in the document.

6.2.15 LIN, LIN-T, TXDL and RXDL

These are the pins of the LIN physical interface. Device contains zero, one or two LIN interfaces.

The MC33903, MC33903P, and MC33904 do not have a LIN interface. However, the MC33903S/5S (S = Single) and MC33903D/5D

(D=Dual) contain 1 and 2 LIN interfaces, respectively.

LIN, LIN1 and LIN2 pins are the connection to the LIN sub buses. LIN interfaces are connected to the MCU via the TXD, TXD-L1 and

TXD-L2 and RXD, RXD-L1 and RXD-L2 pins.

The device also includes one or two HS switches to VSUP/2 pin which can be used as a LIN master termination switch. Pins LINT, LINT-

1 and LINT-2 pins are the same as I/O-2 and I/O-3.

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FUNCTIONAL DEVICE OPERATION

7 Functional device operation

7.1 Mode and state description

The device has several operation modes. The transitions and conditions to enter or leave each mode are illustrated in the state diagram.

7.1.1 INIT reset

This mode is automatically entered after the device is “powered on”. In this mode, the RST pin is asserted low, for a duration of typically

1.0 ms. Control bits and flags are ‘set’ to their default reset condition. The BATFAIL is set to indicate the device is coming from an

unpowered condition, and all previous device configurations are lost and “reset” the default value. The duration of the INIT reset is typically

1.0 ms.

INIT reset mode is also entered from INIT mode if the expected SPI command does not occur in due time (Ref. INIT mode), and if the

device is not in the debug mode.

7.1.2 INIT

This mode is automatically entered from the INIT Reset mode. In this mode, the device must be configured via SPI within a time of 256 ms

max. Four registers called INIT Wdog, INIT REG, INIT LIN I/O and INIT MISC must be, and can only be configured during INIT mode.

Other registers can be written in this and other modes.

Once the INIT register configuration is done, a SPI Watchdog Refresh command must be sent in order to set the device into Normal mode.

If the SPI watchdog refresh does not occur within the 256 ms period, the device will return into INIT Reset mode for typically 1.0 ms, and

then re enter into INIT mode.

Register read operation is allowed in INIT mode to collect device status or to read back the INIT register configuration.

When INIT mode is left by a SPI watchdog refresh command, it is only possible to re-enter the INIT mode using a secured SPI command.

In INIT mode, the CAN, LIN1, LIN2, VAUX, I/O_x and Analog MUX functions are not operating. The 5 V-CAN is also not operating, except

if the Debug mode is detected.

7.1.3 Reset

In this mode, the RST pin is asserted low. Reset mode is entered from Normal mode, Normal Request mode, LP VDD on mode and from

the Flash mode when the watchdog is not triggered, or if a VDD low condition is detected.

The duration of reset is typically 1.0 ms by default. You can define a longer Reset pulse activation only when the Reset mode is entered

following a VDD low condition. Reset pulse is always 1.0 ms, when reset mode is entered due to wrong watchdog refresh command.

Reset mode can be entered via the secured SPI command.

7.1.4 Normal request

This mode is automatically entered after RESET mode, or after a Wake-up from LP VDD ON mode.

A watchdog refresh SPI command is necessary to transition to NORMAL mode. The duration of the Normal request mode is 256 ms when

Normal Request mode is entered after RESET mode. Different durations can be selected by SPI when normal request is entered from LP

VDD ON mode.

If the watchdog refresh SPI command does not occur within the 256 ms (or the shorter user defined time out), then the device will enter

into RESET mode for a duration of typically 1.0 ms.

Note: in init reset, init, reset and normal request modes as well as in LP modes, the VDD external PNP is disabled.

7.1.5 Normal

In this mode, all device functions are available. This mode is entered by a SPI watchdog refresh command from Normal Request mode,

or from INIT mode.

During Normal mode, the device watchdog function is operating, and a periodic watchdog refresh must occur. When an incorrect or

missing watchdog refresh command is initiated, the device will enter into Reset mode.

While in Normal mode, the device can be set to LP modes (LP VDD ON or LP VDD OFF) using the SPI command. Dedicated, secured SPI

commands must be used to enter from Normal mode to Reset mode, INIT mode or Flash mode.

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FUNCTIONAL DEVICE OPERATION

7.1.6 Flash

In this mode, the software watchdog period is extended up to typically 32 seconds. This allow programming of the MCU flash memory

while minimizing the software over head to refresh the watchdog. The flash mode is entered by Secured SPI command and is left by SPI

command. Device will enter into Reset mode. When an incorrect or missing watchdog refresh command device will enter into Reset mode.

An interrupt can be generated at 50% of the watchdog period.

CAN interface operates in Flash mode to allow flash via CAN bus, inside the vehicle.

7.1.7 Debug

Debug is a special operation mode of the device which allows for easy software and hardware debugging. The debug operation is detected

after power up if the DBG pin is set to 8.0 to 10 V range.

When debug is detected, all the software watchdog operations are disabled: 256 ms of INIT mode, watchdog refresh of Normal mode and

Flash mode, Normal Request time out (256 ms or user defined value) are not operating and will not lead to transition into INIT reset or

Reset mode.

When the device is in Debug mode, the SPI command can be sent without any time constraints with respect to the watchdog operation

and the MCU program can be “halted” or “paused” to verify proper operation.

Debug can be left by removing 8 to 10 V from the DEBUG pin, or by the SPI command (Ref. to MODE register).

The 5 V-CAN regulator is ON by default in Debug mode.

7.2 LP modes

The device has two main LP modes: LP mode with VDD OFF, and LP mode with VDD ON.

Prior to entering into LP mode, I/O and CAN Wake-up flags must be cleared (Ref. to mode register). If the Wake-up flags are not cleared,

the device will not enter into LP mode. In addition, the CAN failure flags (i.e. CAN_F and CAN_UF) must be cleared, in order to meet the

LP current consumption specification.

7.2.1 LP - VDD off

In this mode, VDD is turned OFF and the MCU connected to VDD is unsupplied. This mode is entered using SPI. It can also be entered

by an automatic transition due to fail-safe management. 5 V-CAN and VAUX regulators are also turned OFF.

When the device is in LP VDD OFF mode, it monitors external events to Wake-up and leave the LP mode. The Wake-up events can occur

from:

•CAN

• LIN interface, depending upon device part number

• Expiration of an internal timer

• I/O-0, and I/O-1 inputs, and depending upon device part number and configuration, I/O-2 and/or -3 input

• Cyclic sense of I/O-1 input, associated by I/O-0 activation, and depending upon device part number and configuration, cyclic sense

of I/O-2 and -3 input, associated by I/O-0 activation

When a Wake-up event is detected, the device enters into Reset mode and then into Normal Request mode. The Wake-up sources are

reported to the device SPI registers. In summary, a Wake-up event from LP VDD OFF leads to the VDD regulator turned ON, and the MCU

operation restart.

7.2.2 LP - VDD ON

In this mode, the voltage at the VDD pin remains at 5.0 V (or 3.3 V, depending upon device part number). The objective is to maintain the

MCU powered, with reduced consumption. In such mode, the DC output current is expected to be limited to 100 μA or a few mA, as the

ECU is in reduced power operation mode.

During this mode, the 5 V-CAN and VAUX regulators are OFF. The optional external PNP at VDD will also be automatically disabled when

entering this mode.

The same Wake-up events as in LP VDD OFF mode (CAN, LIN, I/O, timer, cyclic sense) are available in LP VDD on mode. In addition, two

additional Wake-up conditions are available.

• Dedicated SPI command. When device is in LP VDD ON mode, the Wake-up by SPI command uses a write to “Normal Request

mode”, 0x5C10.

• Output current from VDD exceeding LP-ITH threshold.

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FUNCTIONAL DEVICE OPERATION

In LP VDD ON mode, the device is able to source several tenths of mA DC. The current source capability can be time limited, by a

selectable internal timer. Timer duration is up to 32 ms, and is triggered when the output current exceed the output current threshold

typically 1.5 mA.

This allows for instance, a periodic activation of the MCU, while the device remains in LP VDD on mode. If the duration exceed the selected

time (ex 32 ms), the device will detect a Wake-up.

Wake-up events are reported to the MCU via a low level pulse at INT pulse. The MCU will detect the INT pulse and resume operation.

7.2.2.1 Watchdog function in LP VDD on mode

It is possible to enable the watchdog function in LP VDD ON mode. In this case, the principle is timeout.

Refresh of the watchdog is done either by:

• a dedicated SPI command (different from any other SPI command or simple CS activation which would Wake-up - Ref. to the

previous paragraph)

• or by a temporary (less than 32 ms max) VDD over current Wake-up (IDD > 1.5 mA typically).

As long as the watchdog refresh occurs, the device remains in LP VDD on mode.

7.2.2.2 Mode transitions

Mode transitions are either done automatically (i.e. after a timeout expired or voltage conditions), or via a SPI command, or by an external

event such as a Wake-up. Some mode changes are performed using the Secured SPI commands.

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FUNCTIONAL DEVICE OPERATION

7.3 State diagram

Figure 23. State diagram

INIT Reset

start T_IR

INIT

start T_INIT

T_IR expired

T_INIT expired

or VDD<VDD_UVTH

NORMAL (4)

start T_WDN

SPI write (0x5A00)

SPI secured (3)

watchdog refresh

FLASH

start T_WDF

SPI secured (3)

watchdog refresh

RESET

(config)

start T_R

(1.0 ms or config) VDD<VDD_UVTH or T_WD expired

POWER DOWN

SPI secured

VSUP fall

VSUP/1 rise > VSUP-TH1

NORMAL

start T_NR

REQUEST

(256 ms or config)

(1) watchdog refresh in closed window or enhanced watchdog refresh failure

T_R expired

SPI write (0x5A00)

T_NR expired

start T_WDL (2)

VDD ON

VDD OFF

Wake-up

if enable

Wake-up (5)

(2) If enable by SPI, prior to enter LP VDD ON mode

LP VDDON

start T_OC time

IDD > 1.5 mA

I-DD>IOC

I-DD<IOC

T_OC expired

SPI

& VDD>VDD_UVTH

watchdog refresh

SPI

or T_WDF expired

or VDD<VDD_UVTH

VSUP fall

Debug

FAIL-SAFE DETECTED

detection

(watchdog refresh)

(1.5 mA)

by SPI

mode

(T_IR =1.0ms)

(T_INIT =256ms)

(T_WDN = config)

T_WDL expired or VDD<VDD_UVTHLP

or Wake-up

or watchdog failure (1) or SPI secured

(watchdog refresh)

VDD<VDD_UVTHLP

by SPI

& VDD > VDD_UVTH

Ext reset

(3) Ref. to “SPI secure” description

(4) VDD external PNP is disable in all mode except Normal and Flash modes.

(5) Wake-up from LP VDD ON mode by SPI command is done by a SPI mode change: 0X5C10

or VDD TSD

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FUNCTIONAL DEVICE OPERATION

7.4 Mode change

7.4.1 ‘Secured SPI’ description

A request is done by a SPI command, the device provide on MISO an unpredictable ‘random code’. Software must perform a logical

change on the code and return it to the device with the new SPI command to perform the desired action.

The ‘random code’ is different at every exercise of the secured procedure and can be read back at any time.

The secured SPI uses the Special MODE register for the following transitions:

- from Normal mode to INT mode

- from Normal mode to Flash mode

- from Normal mode to Reset mode (reset request).

“Random code” is also used when the ‘advance watchdog’ is selected.

7.4.2 Changing of device critical parameters

Some critical parameters are configured one time at device power on only, while the batfail flag is set in the INIT mode. If a change is

required while device is no longer in INIT mode, device must be set back in INIT mode using the “SPI secure” procedure.

7.5 Watchdog operation

7.5.1 In normal request mode

In Normal Request mode, the device expects to receive a watchdog configuration before the end of the normal request time out period.

This period is reset to a long (256 ms) after power on and when BATFAIL is set.

The device can be configured to a different (shorter) time out period which can be used after Wake-up from LP VDD on mode.

After a software watchdog reset, the value is restored to 256 ms, in order to allow for a complete software initialization, similar to a device

power up. In Normal Request mode the watchdog operation is “timeout” only and can be triggered/observed any time within the period.

7.5.2 Watchdog type selection

Three types of watchdog operation can be used:

- Window watchdog (default)

- Timeout operation

- Advanced

The selection of watchdog is performed in INIT mode. This is done after device power up and when the BATFAIL flag is set. The Watchdog

configuration is done via the SPI, then the Watchdog mode selection content is locked and can be changed only via a secured SPI

procedure.

7.5.2.1 Window watchdog operation

The window watchdog is available in Normal mode only. The watchdog period selection can be kept (SPI is selectable in INIT mode),

while the device enters into LP VDD ON mode. The watchdog period is reset to the default long period after BATFAIL.

The period and the refresh of watchdog are done by the SPI. A refresh must be done in the open window of the period, which starts at

50% of the selected period and ends at the end of the period.

If the watchdog is triggered before 50%, or not triggered before end of period, a reset has occurred. The device enters into Reset mode.

7.5.2.2 Watchdog in debug mode

When the device is in Debug mode (entered via the DBG pin), the watchdog continues to operate but does not affect the device operation

by asserting a reset. For the user, operation appears without the watchdog.

When Debug mode is left by software (SPI mode reg), the watchdog period starts at the end of the SPI command.

When Debug mode is left by hardware (DBG pin below 8-10 V), the device enters into Reset mode.

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FUNCTIONAL DEVICE OPERATION

7.5.2.3 Watchdog in flash mode

During Flash mode, watchdog can be set to a long timeout period. Watchdog is timeout only and an INT pulse can be generated at 50%

of the time window.

7.5.2.4 Advance watchdog operation

When the Advance watchdog is selected (at INIT mode), the refresh of the watchdog must be done using a random number and with 1,

2, or 4 SPI commands. The number for the SPI command is selected in INIT mode.

The software must read a random byte from the device, and then must return the random byte inverted to clear the watchdog. The random

byte write can be performed in 1, 2, or 4 different SPI commands.

If one command is selected, all eight bits are written at once.

If two commands are selected, the first write command must include four of the eight bits of the inverted random byte. The second

command must include the next four bits. This completes the watchdog refresh.

If four commands are selected, the first write command must include two of the eight bits of the inverted random byte. The second

command must include the next two bits, the 3rd command must include the next two, and the last command, must include the last two.

This completes the watchdog refresh. When multiple writes are used, the most significant bits are sent first. The latest SPI command

needs to be done inside the open window time frame, if window watchdog is selected.

7.5.3 Detail SPI operation and SPI commands for all watchdog types.

All SPI commands and examples do not use parity functions.

In INIT mode, the watchdog type (window, timeout, advance and number of SPI commands) is selected using the register Init watchdog,

bits 1, 2 and 3. The watchdog period is selected using the TIM_A register. The watchdog period selection can also be done in Normal

mode or in Normal Request mode.

Transition from INIT mode to Normal mode or from Normal Request mode to Normal mode is done using a single watchdog refresh

command (SPI 0x 5A00).

While in Normal mode, the Watchdog Refresh Command depends upon the watchdog type selected in INIT mode. They are detailed in

the paragraph below:

7.5.3.1 Simple watchdog

The Refresh command is 0x5A00. It can be send any time within the watchdog period, if the timeout watchdog operation is selected (INIT-

watchdog register, bit 1 WD N/Win = 0). It must be send in the open window (second half of the period) if the Window Watchdog operation

was selected (INIT-watchdog register, bit 1 WD N/Win = 1).

7.5.3.2 Advance watchdog

The first time the device enters into Normal mode (entry on Normal mode using the 0x5A00 command), Random (RNDM) code must be

read using the SPI command, 0x1B00. The device returns on MISO second byte the RNDM code. The full 16 bits MISO is called 0x XXRD.

RD is the complement of the RD byte.

7.5.3.3 Advance watchdog, refresh by 1 SPI command

The refresh command is 0x5ARD. During each refresh command, the device will return on MISO, a new Random Code. This new Random

Code must be inverted and send along with the next refresh command. It must be done in an open window, if the Window operation was

selected.

7.5.3.4 Advance watchdog, refresh by two SPI commands

The refresh command is split in two SPI commands.

The first partial refresh command is 0x5Aw1, and the second is 0x5Aw2. Byte w1 contains the first four inverted bits of the RD byte plus

the last four bits equal to zero. Byte w2 contains four bits equal to zero plus the last four inverted bits of the RD byte.

During this second refresh command the device returns on MISO a new Random Code. This new random code must be inverted and send

along with the next two refresh commands and so on. The second command must be done in an open window if the Window operation

was selected.

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FUNCTIONAL DEVICE OPERATION

7.5.3.5 Advance watchdog, refresh by four SPI commands

The refresh command is split into four SPI commands.

The first partial refresh command is 0x5Aw1, the second is 0x5Aw2, the third is 0x5Aw3, and the last is 0x5Aw4.

Byte w1 contains the first two inverted bits of the RD byte, plus the last six bits equal to zero.

Byte w2 contains two bits equal to zero, plus the next two inverted bits of the RD byte, plus four bits equal to zero.

Byte w3 contains four bits equal to zero, plus the next two inverted bits of the RD byte, plus two bits equal to zero.

Byte w4 contains six bits equal to zero, plus the next two inverted bits of the RD byte.

During this fourth refresh command, the device will return, on MISO, a new Random Code. This new Random Code must be inverted and

send along with the next four refresh commands.

The fourth command must be done in an open window if the Window operation was selected.

7.5.4 Proper response to INT

During a device detect upon an INT, the software handles the INT in a timely manner: Access of the INT register is done within two

watchdog periods. This feature must be enabled by SPI using the INIT watchdog register bit 7.

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FUNCTIONAL DEVICE OPERATION

7.6 Functional block operation versus mode

The 5 V-CAN default is ON when the device is powered-up and set in Debug mode. It is fully controllable via the SPI command.

Table 8. Device block operation for each state

State VDD 5 V-CAN I/O-X VAUX CAN LIN1/2

Power down OFF OFF OFF OFF High-impedance High-impedance

Init Reset ON OFF HS/LS off

Wake-up disable OFF

OFF:

CAN termination 25 k to GND

Transmitter / receiver /Wake-up

OFF

OFF:

internal 30 k pull-up

active. Transmitter:

receiver / Wake-up OFF.

LIN term OFF

INIT ON OFF (38) WU disable

(39)(40)(41)

OFF OFF OFF

Reset ON Keep SPI

config WU disable

(39)(40)(41)

OFF OFF OFF

Normal Request ON Keep SPI

config WU disable

(39)(40)(41)

OFF OFF OFF

Normal ON SPI config SPI config

WU SPI config SPI config SPI config SPI config

LP VDD OFF OFF OFF user defined

WU SPI config OFF OFF + Wake-up en/dis OFF + Wake-up en/dis

LP VDD ON ON(37) OFF user defined

WU SPI config OFF OFF + Wake-up en/dis OFF + Wake-up en/dis

SAFE output low:

Safe case A

safe case

A:ON

safe case B:

OFF

A: Keep SPI

config, B: OFF

HS/LS off

Wake-up by

change state

OFF OFF + Wake-up enable OFF + Wake-up enable

FLASH ON SPI config SPI config OFF SPI config OFF

Notes

37. With limited current capability

38. 5 V-CAN is ON in Debug mode.

39. I/O-0 and I/O-1, configured as an output high-side switch and ON in Normal mode will remain ON in RESET, INIT or Normal Request.

40. I/O-0, configured as an output low-side switch and ON in Normal mode will turn OFF when entering Reset mode, resume operation in Normal

mode.

41. I/O-1, configured as an output low-side switch and ON in Normal mode will remain ON in RESET, INIT or Normal Request.

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FUNCTIONAL DEVICE OPERATION

7.7 Illustration of device mode transitions

Figure 24. Power up normal and LP modes

SUP

RST

INT

SPI

MODE

DD-UV

(4.5 V typically)

RESET INIT

Series of SPI

Single SPI

NORMAL

BATFAIL

5V-CAN

>4.0 V

VAUX

APower up to Normal Mode

s_11

s_1

s_11: write INT registers

s_1: go to Normal mode

s_12

s_2

DD-UV

NORMAL LP V

OFF

s_2: go to

LP VDD OFF mode

s_12: LP Mode configuration

Normal to LP

SUP

RST

INT

SPI

5V-CAN

VAUX

legend:

s_13

s_3

NORMAL LP V

Normal to LP

SUP

RST

INT

SPI

5V-CAN

VAUX

s_13: LP Mode configuration

s_3: go to LP mode

OFF Mode V

ON Mode

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FUNCTIONAL DEVICE OPERATION

Figure 25. Wake-up from LP modes

7.8 Cyclic sense operation during LP modes

This function can be used in both LP modes: VDD OFF and VDD ON.

Cyclic sense is the periodic activation of I/O-0 to allow biasing of external contact switches. The contact switch state can be detected via

I/O-1, -2, and -3, and the device can Wake-up from either LP mode. Cyclic sense is optimized and designed primarily for closed contact

switch in order to minimize consumption via the contact pull-up resistor.

CWake-up from LP V

OFF Mode

-UV

(4.5 V typically)

RESET

NORMAL

s_14

s_4

REQUEST NORMAL

CAN bus

Based on reg configuration

CAN Wake-up

I/O-x toggle

pattern

Available Wake-up events (exclusive)

Wake-up detected

Start

FWU timer

duration (50-8192 ms)

SPI selectable

FWU timer

LP V

_OFF

SUP

RST

INT

SPI

MODE

5V-CAN

VAUX

s_14

s_4

NORMAL

REQUEST NORMAL

LP V

Based on reg configuration

CAN bus

CAN Wake-up

I/O-x toggle

pattern

current I

DD-OC

(3.0 mA typically)

DD OC

deglitcher or timer (100 us typically, 3 -32 ms)

Wake-up detected

Start

FWU timer

duration (50-8192 ms)

Stop

SPI selectable

FWU timer

SPI

Wake-up from LP V

ON Mode

SUP

RST

INT

SPI

MODE

5V-CAN

VAUX

LIN Bus

LIN Wake-up filter

LIN Bus

LIN Wake-up filter

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FUNCTIONAL DEVICE OPERATION

7.8.1 Principle

A dedicated timer provides an opportunity to select a cyclic sense period from 3.0 to 512 ms (selection in timer B).

At the end of the period, the I/O-0 will be activated for a duration of T_CSON (SPI selectable in INIT register, to 200 μs, 400 μs, 800 μs, or

1.6 ms). The I/O-0 HS transistor or LS transistor can be activated. The selection is done by the state of I/O-0 prior to entering in LP mode.

During the T-CSON duration, the I/O-x’s are monitored. If one of them is high, the device will detect a Wake-up. (Figure 26).

Cyclic sense period is selected by the SPI configuration prior to entering LP mode. Upon entering LP mode, the I/O-0 should be activated.

The level of I/O-1 is sense during the I/O-0 active time, and is deglitched for a duration of typically 30 μs. This means that I/O-1 should be

in the expected state for a duration longer than the deglitch time. The diagram below (Figure 26) illustrates the cyclic sense operation,

with I/O-0 HS active and I/O-1 Wake-up at high level.

Figure 26. Cyclic sense operation - switch to GND, wake-up by open switch

I/O-0

I/O-1

NORMAL MODE LP MODE

I/O-0 HS active in Normal mode I/O-0 HS active during cyclic sense active time

Cyclic sense period

Cyclic sense active time

RESET or NORMAL REQUEST MODE

Wake-up detected.

state of I/O-1 low => no Wake-up

Cyclic sense active

I/O-1 deglitcher time

I/O-1 high => Wake-up

I/O-0

I/O-1

Zoom

time (ex 200 us)

Wake-up event detected

I/O-0

I/O-1

S1 closed S1 openS1

(typically 30 us)

I/O-2

I/O-3

I/O-0

I/O-1

I/O-2

I/O-3

Upon entering in LP mode, all 3

contact switches are closed.

In LP mode, 1 contact switch is open.

High level is detected on I/O-x, and device wakes up.

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FUNCTIONAL DEVICE OPERATION

7.9 Cyclic INT operation during LP VDD on mode

7.9.1 Principle

This function can be used only in LP VDD ON mode (LP VDD ON). When Cyclic INT is selected and device is in LP VDD ON mode, the

device will generate a periodic INT pulse.

Upon reception of the INT pulse, the MCU must acknowledge the INT by sending SPI commands before the end of the next INT period

in order to keep the process going.

When Cyclic INT is selected and operating, the device remains in LP VDD ON mode, assuming the SPI commands are issued properly.

When no/improper SPI commands are sent, the device will cease Cyclic INT operation and leave LP VDD ON mode by issuing a reset.

The device will then enter into Normal Request mode. VDD current capability and VDD regulator behavior is similar as in LP VDD ON

mode.

7.9.1.1 Operation

Cyclic INT period selection: register timer B

SPI command in hex 0x56xx [example; 0x560E for 512ms cyclic Interrupt period (SPI command without parity bit)].

This command must be send while the device is in Normal mode.

SPI commands to acknowledge INT: (2 commands)

- read the Random code via the watchdog register address using the following command: MOSI 0x1B00 device report on MISO second

byte the RNDM code (MISO bit 0-7).

- write watchdog refresh command using the random code inverted: 0x5A RNDb.

These commands can occur at any time within the period.

Initial entry in LP mode with Cyclic INT: after the device is set in LP VDD ON mode, with cyclic INT enable, no SPI command is necessary

until the first INT pulse occurs. The acknowledge process must start only after the 1st INT pulse.

Leave LP mode with Cyclic INT:

This is done by a SPI Wake-up command, similar to SPI Wake-up from LP VDD ON mode: 0x5C10. The device will enter into Normal

Request mode.

Improper SPI command while Cyclic INT operates:

When no/improper SPI commands are sent, while the device is in LP VDD ON mode with Cyclic INT enable, the device will cease Cyclic

INT operation and leave LP VDD ON mode by issuing a reset. The device will then enter into Normal Request mode.

Figure 27 describes the complete Cyclic Interrupt operation.

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FUNCTIONAL DEVICE OPERATION

Figure 27. Cyclic interrupt operation

7.10 Behavior at power up and power down

7.10.1 Device power up

This section describe the device behavior during ramp up, and ramp down of VSUP/1, and the flexibility offered mainly by the Crank bit and

the two VDD undervoltage reset thresholds.

The figures below illustrate the device behavior during VSUP/1 ramp up. As the Crank bit is by default set to 0, VDD is enabled when

VSUP/1 is above VSUP TH 1 parameters.

NORMAL MODE

INT

SPI

Timer B

LP V

Cyclic INT period Cyclic INT period

LP V

ON MODE

ON mode

Read RNDM code

Write RNDM code inv.

1st period 2nd period

NORMAL

MODE

Cyclic INT period

3rd period

SPI Wake-up: 0x5C10

Write Timer B, select Cyclic INT period (ex: 512 ms, 0x560E)

Write Device mode: LP V

ON with Cyclic INT enable (example: 0x5C90)

Cyclic INT period

Legend for SPI commands

INT

SPI

RST

RESET and

REQUEST

Prepare LP V

ON In LP V

ON with Cyclic INT Leave LP

Improper or no

with Cyclic INT V

ON Mode

LP V

ON MODE

Leave LP V

ON and Cyclic INT due to improper operation

REQUEST

acknowledge SPI command

NORMAL

MODE

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FUNCTIONAL DEVICE OPERATION

Figure 28. VDD start-up versus VSUP/1 tramp

7.10.2 Device power down

The figures below illustrate the device behavior during VSUP/1 ramp down, based on Crank bit configuration, and VDD undervoltage reset

selection.

7.10.2.1 Crank bit reset (INIT watchdog register, Bit 0 =0)

Bit 0 = 0 is the default state for this bit.

During VSUP/1 ramp down, VDD remain ON until device enters in Reset mode due to a VDD undervoltage condition (VDD < 4.6 V or VDD <

3.2 V typically, threshold selected by the SPI). When device is in Reset, if VSUP/1 is below “VSUP_TH1”, VDD is turned OFF.

7.10.2.2 Crank bit set (INIT watchdog register, Bit 0 =1)

The bit 0 is set by SPI write. During VSUP/1 ramp down, VDD remains ON until device detects a POR and set BATFAIL. This occurs for a

VSUP/1 approx 3.0 V.

BAT

VSUP/1

SUP_TH1

SUP_NOMINAL

(ex 12 V)

DD NOMINAL

(ex 5.0 V)

VDD

Gnd

DD_START UP

DD_OFF

90% V

DD_START UP

10% V

DD_START UP

VDD

VSUP/1

I_VDD

SUP

slew rate

3390X

DD_UV TH

(typically 4.65 V)

RST

1.0 ms

SUP_NOMINAL

(3.3 V)

VDD

VSUP1

RESET

(ex 12 V)

BAT

DD_UV TH

(typ 3.0 V)

SUP_TH1

(4.1V)

Case 1: VDD 3.3V, “V

DD UV TH

3.0 V”,

with bit Crank =0 (default value)

Case 2: VDD 3.3V, “V

DD UV TH

3.0 V”, with bit Crank =1

SUP_NOMINAL

(3.3 V)

VDD

VSUP1

RESET

(ex 12 V)

BAT

DD_UV TH

(typ 3.0 V)

SUP_TH1

(4.1V)

minV

SUP

(2.8 V)

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Figure 29. VDD behavior during VSUP/1 ramp down

SUP_NOMINAL

(5.0 V)

VDD

VSUP/1

RST

(ex 12 V)

BAT

DD_UV TH

(typically 4.65 V)

SUP_TH1

(4.1 V)

SUP_NOMINAL

(5.0 V)

VDD

VSUP/1

RST

(ex 12 V)

BAT

DD_UV TH

(typically 4.65 V)

SUP_TH1

(4.1 V)

INT

DD_UV TH2

(typically 3.2 V)

SUP_NOMINAL

(5.0 V)

VDD

VSUP/1

RST

(ex 12 V)

BAT

DD_UV TH

(typically 4.65 V)

INT

DD_UV TH2

(typically 3.2 V)

BATFAIL (3.0 V)

(1)

(2)

(1) reset then (2) V

turn OFF

SUP_NOMINAL

(5.0 V)

VDD

VSUP/1

RST

(ex 12 V)

BAT

DD_UV TH

(typically 4.65 V)

BATFAIL (3.0 V)

Case 4: “VDD UV 4.6V”, with bit Crank = 1

Case 5: “VDD UV TH 3.2V”, with bit Crank = 0 (default value) Case 6: “VDD UV 3.2V”, with bit Crank = 1

Case 3: “VDD UV TH 4.6V”, with bit Crank = 0 (default value)

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FUNCTIONAL DEVICE OPERATION

7.11 Fail-safe operation

7.11.1 Overview

Fail-safe mode is entered when specific fail conditions occur. The ‘Safe state’ condition is defined by the resistor connected at the DGB

pin. Safe mode is entered after additional event or conditions are met: time out for CAN communication and state at I/O-1 pin.

Exiting the safe state is always possible by a Wake-up event: in the safe state, the device can automatically be awakened by CAN and

I/O (if configured as inputs). Upon Wake-up, the device operation is resumed: enter in Reset mode.

7.11.2 Fail-safe functionality

Upon dedicated event or issue detected at a device pin (i.e. RST short to VDD), the Safe mode can be entered. In this mode, the SAFE

pin is active low.

7.11.2.1 Description

Upon activation of the SAFE pin, and if the failure condition that make the SAFE pin activated have not recovered, the device can help

to reduce ECU consumption, assuming that the MCU is not able to set the whole ECU in LP mode. Two main cases are available:

7.11.2.2 Mode A

Upon SAFE activation, the MCU remains powered (VDD stays ON), until the failure condition recovers (i.e. S/W is able to properly

control the device and properly refresh the watchdog).

7.11.2.3 Modes B1, B2 and B3

Upon SAFE activation, the system continues to monitor external event, and disable the MCU supply (turn VDD OFF). The external

events monitored are: CAN traffic, I/O-1 low level or both of them. 3 sub cases exist, B1, B2 and B3.

Note: no CAN traffic indicates that the ECU of the vehicle are no longer active, thus that the car is being parked and stopped. The I/O low

level detection can also indicate that the vehicle is being shutdown, if the I/O-1 pin is connected for instance to a switched battery signal

(ignition key on/off signal).

The selection of the monitored events is done by hardware, via the resistor connected at DBG pin, but can be over written by software,

via a specific SPI command.

By default, after power up the device detect the resistor value at DBG pin (upon transition from INIT to Normal mode), and, if no specific

SPI command related to Debug resistor change is send, operates according to the detected resistor.

The INIT MISC register allow you to verify and change the device behavior, to either confirm or change the hardware selected behavior.

Device will then operate according to the SAFE mode configured by the SPI.

Table 9 illustrates the complete options available:

Table 9. Fail-safe options

Resistor at

DBG pin SPI coding - register INIT MISC bits [2,1,0]

(higher priority that Resistor coding)

Safe mode

code VDD status

<6.0 k bits [2,1,0) = [111]: verification enable: resistor at DBG pin is

typically 0 kohm (RA) - Selection of SAFE mode A Aremains ON

typically 15 k bits [2,1,0) = [110]: verification enable: resistor at DBG pin is

typically 15 kohm (RB1) - Selection of SAFE mode B1 B1 Turn OFF 8.0 s after CAN traffic bus idle

detection.

typically 33 k bits [2,1,0) = [101]: verification enable: resistor at DBG pin is

typically 33 kohm (RB2 - Selection of SAFE mode B2 B2 Turn OFF when I/O-1 low level detected.

typically 68 k bits [2,1,0) = [100]: verification enable: resistor at DBG pin is

typically 68 kohm (RB3) - Selection of SAFE mode B3 B3 Turn OFF 8.0 s after CAN traffic bus idle

detection AND when I/O-1 low level detected.

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FUNCTIONAL DEVICE OPERATION

7.11.2.4 Exit of safe mode

Exit of the safe state with VDD OFF is always possible by a Wake-up event: in this safe state the device can automatically awakened by

CAN and I/O (if I/O Wake-up was enable by the SPI prior to enter into SAFE mode). Upon Wake-up, the device operation is resumed, and

device enters in Reset mode. The SAFE pin remains active, until there is a proper read and clear of the SPI flags reporting the SAFE

conditions.

Figure 30. Safe operation flow chart

7.11.2.5 Conditions to set SAFE pin active low

Watchdog refresh issue: SAFE activated at 1st reset pulse or at the second consecutive reset pulse (selected by bit 4, INIT watchdog

VDD low: VDD < RST-TH. SAFE pin is set low at the same time as the RST pin is set low. The RST pin is monitored to verify that reset is not

clamped to a low level preventing the MCU to operate. If this is the case, the Safe mode is entered.

watchdog failure

VDD low:

Rst s/c GND:

- SAFE low

8 consecutive watchdog failure (5)

State A: RDBG <6.0 k AND

- SAFE low

- Reset: 1.0 ms

- VDD ON

- Reset low

INIT, b) ECU external signal

State B1: RDBG =15k AND

State B3:

State B2: - SAFE low

- Reset low

- VDD OFF

a) Evaluation of

Bus idle timeout expired

Normal, FLASH

VDD <VDD_UVTH

Rst <2.5 V, t >100 ms

Device state:

RESET NR

bit 4, INIT watchdog = 1 (1) detection of 2nd

consecutive watchdog failure

SAFE low

SAFE high

SAFE low

Reset: 1.0 ms pulse

bit 4, INIT watchdog = 0 (1) Reset: 1.0 ms pulse

Normal Request

power up, or SPI

at DBG pin during

RESET

SAFE pin release

failure recovery, SAFE pin remains low

SPI (3)

AND Bus idle time out expired

RESET Wake-up (2), VDD ON, SAFE pin remains low

(SAFE high)

Failure events

1) bit 4 of INIT Watchdog register

2) Wake-up event: CAN, LIN or I/O-1 high level (if I/O-1 Wake-up previously enabled)

3) SPI commands: 0x1D80 or 0xDD80 to release SAFE pin

4) Recovery: reset low condition released, VDD low condition released, correct SPI watchdog refresh

5) detection of 8 consecutive watchdog failures: no correct SPI watchdog refresh command occurred for duration of 8 x 256 ms.

6) Dynamic behavior: 1.0 ms reset pulse every 256 ms, due to no watchdog refresh SPI command, and device state transition

Legend:

RDBG = 33 k AND I/O-1 low

RDBG =47 k AND I/O-1 low

- VDD ON

(6)

- SAFE low

- VDD ON

- Reset low

periodic pulse

State A: RDBG <6.0 k AND

watchdog failure

(VDD low or RST s/c GND) failure

safe state A

safe state B

Resistor detected

between RESET and NORMAL REQUEST mode, or INIT RESET and INIT modes.

- bus idle time out

- I/O-1 monitoring

monitoring (7):

7) 8 second timer for bus idle timeout. I/O-1 high to low transition.

SAFE Operation Flow Chart

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FUNCTIONAL DEVICE OPERATION

7.11.2.6 SAFE mode A illustration

Figure 31 illustrates the event and consequences when SAFE mode A is selected via the appropriate debug resistor or SPI configuration.

Figure 31. SAFE mode A behavior illustration

RST

failure event, i.e. watchdog

SAFE OFF state ON state

8 x 256 ms delay time to enter in SAFE mode

RST

SAFE

to evaluate resistor at DBG pin

and monitor ECU external events

1st 8th

2nd

Behavior Illustration for Safe State A (RDG < 6.0 kohm), or Selection by the SPI

step 1: Failure illustration

RST

failure event, V

low

SAFE OFF state ON state

100 ms delay time to enter in SAFE mode

to evaluate resistor at DBG pin

and monitor ECU external events

DD_UV TH

100ms

RST

SAFE

< V

DD_UV TH

GND GND

RST

failure event, Reset s/c GND

SAFE OFF state ON state

100 ms deglitcher time to activate SAFE and

enter in SAFE mode to evaluate resistor at the DBG pin

and monitor ECU external events

2.5 V

100ms

RST

SAFE

step 2: Consequence on

VDD, RST and SAFE

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FUNCTIONAL DEVICE OPERATION

7.11.2.7 SAFE mode B1, B2 and B3 illustration

Figure 32 illustrates the event, and consequences when SAFE mode B1, B2, or B3 is selected via the appropriate debug resistor or SPI

configuration.

Figure 32. SAFE modes B1, B2, or B3 behavior illustration

DBG resistor => safe state B1

RST

SAFE

CAN bus

CAN bus idle time

I/O-1

I/O-1 high to low transition

DBG resistor => safe state B2

DBG resistor => safe state B3

CAN bus

CAN bus idle time

I/O-1

I/O-1 high to low transition

step 2:

RST

failure event, i.e. watchdog

SAFE OFF state ON state

8 x 256 ms delay time to enter in SAFE mode

to evaluate resistor at the DBG pin

and monitor ECU external events

1st 8th

2nd

step 1: Failure illustration

RST

failure event, V

low

SAFE OFF state ON state

100 ms delay time to enter in SAFE mode

to evaluate resistor at DBG pin

and monitor ECU external events

DD_UV TH

100 ms

GND

RST

failure event, Reset s/c GND

SAFE OFF state ON state

100 ms deglitcher time to activate SAFE and

enter in SAFE mode to evaluate resistor at DBG pin

and monitor ECU external events

2.5 V

100 ms

RST

SAFE

OFF

RST

SAFE

If V

failure recovered

< V

DD_UV TH

OFF

GND

step 3: Consequences for VDD

If Reset s/c GND recovered

Behavior illustration for the safe state B (RDG > 10 kohm)

Wake-up

ECU external condition

met => VDD disable

ECU external event to

RDBG resistor or

disable VDD based on

SPI configuration

Exclusive detection of

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CAN INTERFACE

8CAN interface

8.1 CAN interface description

The figure below is a high level schematic of the CAN interface. It exist in a LS driver between CANL and GND, and a HS driver from

CANH to 5 V-CAN. Two differential receivers are connected between CANH and CANL to detect a bus state and to Wake-up from CAN

Sleep mode. An internal 2.5 V reference provides the 2.5 V recessive levels via the matched RIN resistors. The resistors can be switched

to GND in CAN Sleep mode. A dedicated split buffer provides a low-impedance 2.5 V to the SPLIT pin, for recessive level stabilization.

Figure 33. CAN interface block diagram

8.1.1 Can interface supply

The supply voltage for the CAN driver is the 5 V-CAN pin. The CAN interface also has a supply pass from the battery line through the

VSUP/2 pin. This pass is used in CAN Sleep mode to allow Wake-up detection.

During CAN communication (transmission and reception), the CAN interface current is sourced from the 5 V-CAN pin. During CAN LP

mode, the current is sourced from the VSUP/2 pin.

8.1.2 TXD/RXD mode

In TXD/RXD mode, both the CAN driver and the receiver are ON. In this mode, the CAN lines are controlled by the TXD pin level and the

CAN bus state is reported on the RXD pin.

The 5 V-CAN regulator must be ON. It supplies the CAN driver and receiver.The SPLIT pin is active and a 2.5 V biasing is provided on

the SPLIT output pin.

Differential

Receiver

Driver

2.5 V

Receiver

Pattern

Detection

CANH

CANL

VSUP/2

5V-CAN

Failure Detection Buffer

5V-CAN

SPLIT

Wake-up

& Management

TXD

RXD

5V-CAN

Thermal

SPI & State machine

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CAN INTERFACE

8.1.2.1 Receive only mode

This mode is used to disable the CAN driver, but leave the CAN receiver active. In this mode, the device is only able to report the CAN

state on the RXD pin. The TXD pin has no effect on CAN bus lines. The 5 V-CAN regulator must be ON. The SPLIT pin is active and a

2.5 V biasing is provided on the SPLIT output pin.

8.1.2.2 Operation in TXD/RXD mode

The CAN driver will be enabled as soon as the device is in Normal mode and the TXD pin is recessive.

When the CAN interface is in Normal mode, the driver has two states: recessive or dominant. The driver state is controlled by the TXD

pin. The bus state is reported through the RXD pin.

When TXD is high, the driver is set in the recessive state, and CANH and CANL lines are biased to the voltage set with 5 V-CAN divided

by 2, or approx. 2.5 V.

When TXD is low, the bus is set into the dominant state, and CANL and CANH drivers are active. CANL is pulled low and CANH is pulled

high.

The RXD pin reports the bus state: CANH minus the CANL voltage is compared versus an internal threshold (a few hundred mV).

If “CANH minus CANL” is below the threshold, the bus is recessive and RXD is set high.

If “CANH minus CANL” is above the threshold, the bus is dominant and RXD is set low.

The SPLIT pin is active and provides a 2.5 V biasing to the SPLIT output.

8.1.2.3 TXD/RXD mode and slew rate selection

The CAN signal slew rate selection is done via the SPI. By default and if no SPI is used, the device is in the fastest slew rate. Three slew

rates are available. The slew rate controls the recessive to dominant, and dominant to recessive transitions. This also affects the delay

time from the TXD pin to the bus and from the bus to the RXD. The loop time is thus affected by the slew rate selection.

8.1.2.4 Minimum baud rate

The minimum baud rate is determined by the shortest TXD permanent dominant timing detection. The maximum number of consecutive

dominant bits in a frame is 12 (6 bits of active error flag and its echo error flag).

The shortest TXD dominant detection time of 300 μs lead to a single bit time of: 300 μs / 12 = 25 μs.

So the minimum Baud rate is 1 / 25 μs = 40 kBaud.

8.1.2.5 Sleep mode

Sleep mode is a reduced current consumption mode. CANH and CANL drivers are disabled and CANH and CANL lines are terminated

to GND via the RIN resistor, the SPLIT pin is high-impedance. In order to monitor bus activities, the CAN Wake-up receiver can be enabled.

It is supplied internally from VSUP/2.

Wake-up events occurring on the CAN bus pin are reporting by dedicated flags in SPI and by INT pulse, and results in a device Wake-up

if the device was in LP mode. When the device is set back into Normal mode, CANH and CANL are set back into the recessive level. This

is illustrated in Figure 34.

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CAN INTERFACE

Figure 34. Bus signal in TXD/RXD and LP mode

8.1.2.6 Wake-up

When the CAN interface is in Sleep mode with Wake-up enabled, the CAN bus traffic is detected. The CAN bus Wake-up is a pattern

Wake-up. The Wake-up by the CAN is enabled or disabled via the SPI.

Figure 35. Single dominant pulse wake-up

8.1.2.7 Pattern wake-up

In order to Wake-up the CAN interface, the Wake-up receiver must receive a series of three consecutive valid dominant pulses, by

default when the CANWU bit is low. CANWU bit can be set high by SPI and the Wake-up will occur after a single pulse duration of 2.0 μs

(typically). A valid dominant pulse should be longer than 500 ns. The three pulses should occur in a time frame of 120 μs, to be considered

valid. When three pulses meet these conditions, the wake signal is detected. This is illustrated by the following figure.

CANL

CANH

TXD

RXD

2.5 V

CANL-DOM

CANH-DOM

CANL/CANH-REC

2.5 V

High ohmic termination (50 kohm) to GND

SPLIT

Dominant state Recessive state

Bus Driver Receiver

(bus dominant set by other IC)

High-impedance

Normal or Listen Only mode Normal or Listen Only mode

Go to sleep,

CANH-CANL

Sleep or Stand-by mode

CANL

CANH

Internal Wake-up signal

Dominant

CAN

Pulse # 1

Dominant

Pulse # 2

CAN WU1-F

Can Wake-up detected

bus

Internal differential Wake-up receiver signal

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CAN INTERFACE

Figure 36. Pattern wake-up - multiple dominant detection

8.1.3 BUS termination

The device supports the two main types of bus terminations:

• Differential termination resistors between CANH and CANL lines.

• SPLIT termination concept, with the mid point of the differential termination connected to GND through a capacitor and to the SPLIT pin.

• In application, the device can also be used without termination.

•Figure 37 illustrates some of the most common terminations.

Figure 37. Bus termination options

8.2 CAN bus fault diagnostic

The device includes diagnostic of bus short-circuit to GND, VBAT, and internal ECU 5.0 V. Several comparators are implemented on

CANH and CANL lines. These comparators monitor the bus level in the recessive and dominant states. The information is then managed

by a logic circuitry to properly determine the failure and report it.

CANL

CANH

Internal Wake-up signal

Dominant

Internal differential Wake-up receiver signal

CAN

Pulse # 1

Dominant

Pulse # 2

Dominant

Pulse # 3

Dominant

Pulse # 4

tCAN WU3-F tCAN WU3-F tCAN WU3-F

tCAN WU3-TO

Dominant Pulse # n: duration 1 or multiple dominant bits

Can Wake-up detected

bus

CANH

CANL

SPLIT CAN bus

Standard termination

CANH

CANL

SPLIT CAN bus

120

connect

CANH

CANL

SPLIT

No termination

connect

ECU connector

CAN bus

ECU connector

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Figure 38. CAN bus simplified structure truth table for failure detection

The following table indicates the state of the comparators when there is a bus failure, and depending upon the driver state.

8.2.1 Detection principle

In the recessive state, if one of the two bus lines are shorted to GND, VDD (5.0 V), or VBAT, the voltage at the other line follows the shorted

line, due to the bus termination resistance. For example: if CANL is shorted to GND, the CANL voltage is zero, the CANH voltage

measured by the Hg comparator is also close to zero.

In the recessive state, the failure detection to GND or VBAT is possible. However, it is not possible with the above implementation to

distinguish which of the CANL or CANH lines are shorted to GND or VBAT. A complete diagnostic is possible once the driver is turned

on, and in the dominant state.

8.2.1.1 Number of samples for proper failure detection

The failure detector requires at least one cycle of the recessive and dominant states to properly recognize the bus failure. The error will

be fully detected after five cycles of the recessive-dominant states. As long as the failure detection circuitry has not detected the same

error for five recessive-dominant cycles, the error is not reported.

8.2.2 Bus clamping detection

If the bus is detected to be in dominant for a time longer than (TDOM), the bus failure flag is set and the error is reported in the SPI.

This condition could occur when the CANH line is shorted to a high-voltage. In this case, current will flow from the high-voltage short-

circuit, through the bus termination resistors (60 Ω), into the SPLIT pin (if used), and into the device CANH and CANL input resistors,

which are terminated to internal 2.5 V biasing or to GND (Sleep mode).

Table 10. Failure detection truth table

Failure description Driver recessive state Driver dominant state

Lg (threshold 1.75 V) Hg (threshold 1.75 V) Lg (threshold 1.75 V) Hg (threshold 1.75 V)

No failure 1 1 0 1

CANL to GND 0 0 0 1

CANH to GND 0 0 0 0

Lb (threshold VSUP -2.0 V) Hb (threshold VSUP -2.0 V) Lb (threshold VSUP -2.0 V) Hb (threshold VSUP -2.0 V)

No failure 0 0 0 0

CANL to VBAT 1 1 1 1

CANH to VBAT 1 1 0 1

L5 (threshold VDD -0.43 V) H5 (threshold VDD -0.43 V) L5 (threshold VDD -0.43 V) H5 (threshold VDD -0.43 V)

No failure 0 0 0 0

CANL to 5.0 V 1 1 1 1

CANH to 5.0 V 1 1 0 1

Hg CANH

CANLLg

VDD

Vrg

Hb Vrvb

Lb Vrvb

Logic

TXD

Diag

VDD (5.0 V)

GND (0.0 V)

Recessive level (2.5 V)

VBAT (12-14 V)

VRVB (VSUP-2.0 V)

VRG (1.75 V)

CANL dominant level (1.4 V)

CANH dominant level (3.6 V)

L5 Vr5

H5 Vr5

VR5 (VDD-.43 V)

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Depending upon the high-voltage short-circuit, the number of nodes, usage of the SPLIT pin, RIN actual resistor and mode state (Sleep

or Active) the voltage across the bus termination can be sufficient to create a positive dominant voltage between CANH and CANL, and

the RXD pin will be low. This would prevent start of any CAN communication and thus, proper failure identification requires five pulses on

TXD. The bus dominant clamp circuit will help to determine such failure situation.

8.2.3 RXD permanent recessive failure (does not apply to ‘C’ and ‘D’ versions)

The aim of this detection is to diagnose an external hardware failure at the RXD output pin and ensure that a permanent failure at RXD

does not disturb the network communication. If RXD is shorted to a logic high signal, the CAN protocol module within the MCU will not

recognize any incoming message. In addition, it will not be able to easily distinguish the bus idle state and can start communication at any

time. In order to prevent this, RXD failure detection is necessary. When a failure is detected, the RXD high flag is set and CAN switches

to receive only mode.

Figure 39. RXD path simplified schematic, RXD short to VDD detection

8.2.3.1 Implementation for detection

The implementation senses the RXD output voltage at each low to high transition of the differential receiver. Excluding the internal

propagation delay, the RXD output should be low when the differential receiver is low. When an external short to VDD at the RXD output,

RXD will be tied to a high level and can be detected at the next low to high transition of the differential receiver.

As soon as the RXD permanent recessive is detected, the RXD driver is deactivated.

Once the error is detected the driver is disabled and the error is reported via SPI in CAN register.

8.2.3.2 Recovery condition

The internal recovery is done by sampling a correct low level at TXD as shown in the following illustration.

Figure 40. RXD path simplified schematic, RXD short to VDD detection

CANH

CANL

Diff

VDD

Rxsense

RXD driver

RXD

TXD

TXD driver

VDD

Logic

Diag

CANL&H

Diff output

RXD output

RXD short to VDD

Prop delay

RXD flag

RXD flag latched

VDD/2 Sampling Sampling

The RXD flag is not the RXPR bit in the LPC register, and neither is the CANF in the INTR register.

CANL&H

Diff output

RXD output RXD short to VDD

RXD flag

RXD flag latched

Sampling

The RXD flag is not the RXPR bit in the LPC register, and neither is the CANF in the INTR register.

RXD no longer shorted to VDD

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8.2.4 TXD permanent dominant

8.2.4.1 Principle

If the TXD is set to a permanent low level, the CAN bus is set into dominant level, and no communication is possible. The device has a

TXD permanent timeout detector. After the timeout (TDOUT), the bus driver is disabled and the bus is released into a recessive state. The

TXD permanent flag is set.

8.2.4.2 Recovery

The TXD permanent dominant is used and activated when there is a TXD short to RXD. The recovery condition for a TXD permanent

dominant (recovery means the re-activation of the CAN drivers) is done by entering into a Normal mode controlled by the MCU or when

TXD is recessive while RXD change from recessive to dominant.

8.2.5 TXD to RXD short-circuit

8.2.5.1 Principle

When TXD is shorted to RXD during incoming dominant information, RXD is set to low. Consequently, the TXD pin is low and drives CANH

and CANL into a dominant state. Thus the bus is stuck in dominant. No further communication is possible.

8.2.5.2 Detection and recovery

The TXD permanent dominant timeout will be activated and release the CANL and CANH drivers. However, at the next incoming dominant

bit, the bus will then be stuck in dominant again. The recovery condition is same as the TXD dominant failure

8.2.6 Important information for bus driver reactivation

The driver stays disabled until the failure is/are removed (TXD and/or RXD is no longer permanent dominant or recessive state or shorted)

and the failure flags cleared (read). The CAN driver must be set by SPI in TXD/RXD mode in order to re enable the CAN bus driver.

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LIN BLOCK

9 LIN block

9.1 LIN interface description

The physical interface is dedicated to automotive LIN sub-bus applications.

The interface has 20 kbps and 10 kbps baud rates, and includes as well as a fast baud rate for test and programming modes. It has

excellent ESD robustness and immunity against disturbance, and radiated emission performance. It has safe behavior when a LIN bus

short-to-ground, or a LIN bus leakage during LP mode. Digital inputs are related to the device VDD pin.

9.1.1 Power supply pin (VSUP/2)

The VSUP/2 pin is the supply pin for the LIN interface. To avoid a false bus message, an undervoltage on VSUP/2 disables the

transmission path (from TXD to LIN) when

VSUP/2 falls below 6.1 V.

9.1.2 Ground pin (GND)

When there is a ground disconnection at the module level, the LIN interface do not have significant current consumption on the LIN bus

pin when in the recessive state.

9.1.3 LIN bus pin (LIN, lin1, lin2)

The LIN pin represents the single-wire bus transmitter and receiver. It is suited for automotive bus systems, and is compliant to the LIN

bus specification 2.1 and SAEJ2602-2. The LIN interface is only active during Normal mode.

9.1.3.1 Driver characteristics

The LIN driver is a LS MOSFET with internal overcurrent thermal shutdown. An internal pull-up resistor with a serial diode structure is

integrated so no external pull-up components are required for the application in a slave node. An additional pull-up resistor of 1.0 kΩ must

be added when the device is used in the master node. The 1.0 kΩ pull-up resistor can be connected to the LIN pin or to the ECU battery

supply.

The LIN pin exhibits no reverse current from the LIN bus line to VSUP/2, even in the event of a GND shift or VSUP/2 disconnection. The

transmitter has a 20 kbps, 10 kbps and fast baud rate, which are selected by SPI.

9.1.3.2 Receiver characteristics

The receiver thresholds are ratiometric with the device VSUP/2 voltage.

If the VSUP/2 voltage goes below typically 6.1 V, the LIN bus enters into a recessive state even if communication is sent on TXD.

If LIN driver temperature reaches the overtemperature threshold, the transceiver and receiver are disabled. When the temperature falls

below the overtemperature threshold, LIN driver and receiver will be automatically enabled.

9.1.4 Data input pin (TXD-L, TXD-L1, TXD-L2)

The TXD-L,TXD-L1 and TXD-L2 input pin is the MCU interface to control the state of the LIN output. When TXD-L is LOW (dominant),

LIN output is LOW. When TXD-L is HIGH (recessive), the LIN output transistor is turned OFF.

This pin has an internal pull-up current source to VDD to force the recessive state if the input pin is left floating.

If the pin stays low (dominant sate) more than t TXDDOM, the LIN transmitter goes automatically in recessive state. This is reported by flag

in LIN register.

9.1.5 Data output pin (RXD-L, RXD-L1, RXD-L2)

This output pin is the MCU interface, which reports the state of the LIN bus voltage. LIN HIGH (recessive) is reported by a high voltage

on RXD, LIN LOW (dominant) is reported by a low voltage on RXD.

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9.2 LIN operational modes

The LIN interface have two operational modes, Transmit receiver and LIN disable modes.

9.2.1 Transmit receive

In the TXD/RXD mode, the LIN bus can transmit and receive information.

When the 20 kbps baud rate is selected, the slew rate and timing are compatible with LIN protocol specification 2.1.

When the 10 kbps baud rate is selected, the slew rate and timing are compatible with J2602-2.

When the fast baud rate is selected, the slew rate and timing are much faster than the above specification and allow fast data transition.

The LIN interface can be set by the SPI command in TXD/RXD mode, only when TXD-L is at a high level. When the SPI command is send

while TXD-L is low, the command is ignored.

9.2.2 Sleep mode

This mode is selected by SPI, and the transmission path is disabled. Supply current for LIN block from VSUP/2 is very low (typically 3.0 μA).

LIN bus is monitor to detect Wake-up event. In the Sleep mode, the internal 725 kOhm pull-up resistor is connected and the 30 kOhm

disconnected. The LIN block can be awakened from Sleep mode by detection of LIN bus activity.

9.2.2.1 LIN bus activity detection

The LIN bus Wake-up is recognized by a recessive to dominant transition, followed by a dominant level with a duration greater than 70 μs,

followed by a dominant to recessive transition. This is illustrated in Figures 20 and 21. Once the Wake-up is detected, the event is reported

to the device state machine. An INT is generated if the device is in LP VDD ON mode, or VDD will restart if the device was in LP VDDOFF

mode. The Wake-up can be enable or disable by the SPI.

Fail-safe Features

Table 11 describes the LIN block behavior when there is a failure.

Table 11. LIN block failure

Fault Functionnal

mode Condition Consequence Recovery

LIN supply Undervoltage

TXD RXD

LIN supply voltage < 6.0 V (typically) LIN transmitter in recessive State Condition gone

TXD Pin Permanent

Dominant TXD pin low for more than t TXDDOM LIN transmitter in recessive State Condition gone

LIN Thermal Shutdown TXD RXD LIN driver temperature > 160 °C

(typically)

LIN transmitter and receiver

disabled

HS turned off

Condition gone

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10 Serial peripheral interface

10.1 High level overview

The device uses a 16 bits SPI, with the following arrangements:

MOSI, Master Out Slave In bits:

• bits 15 and 14 (called C1 and C0) are control bits to select the SPI operation mode (write control bit to device register, read back of

the control bits, read of device flag).

• bit 13 to 9 (A4 to A0) to select the register address.

• bit 8 (P/N) has two functions: parity bit in write mode (optional, = 0 if not used), Next bit ( = 1) in read mode.

• bit 7 to 0 (D7 to D0): control bits

MISO, Master In Slave Out bits:

• bits 15 to 8 (S15 to S8) are device status bits

• bits 7 to 0 (Do7 to Do0) are either extended device status bits, device internal control register content or device flags.

The SPI implementation does not support daisy chain capability.

Figure 41 is an overview of the SPI implementation.

Figure 41. SPI overview

10.2 Detail operation

The SPI operation deviation (does not apply to ‘C’ and ‘D’ versions).

In some cases, the SPI write command is not properly interpreted by the device. This results in either a ‘non received SPI command’ or

a ‘corrupted SPI command’. Important: Due to this, the tLEAD and tCSLOW parameters must be carefully acknowledged.

Only SPI write commands (starting with bits 15,14 = 01) are affected. The SPI read commands (starting with bits 15,14 = 00 or 11) are

not affected.

The occurrence of this issue is extremely low and is caused by the synchronization between internal and external signals. In order to

guarantee proper operation, the following steps must be taken.

1. Ensure the duration of the Chip Select Low (tCSLOW) state is >5.5 μs.

Note: In data sheet revisions prior to 7.0, this parameter is not specified and is indirectly defined by the sum of 3 parameters, tLEAD + 16

x tPCLK + tLAG (sum = 4.06 μs).

Bit 15 Bit 13 Bit 11Bit 12 Bit 10Bit 14 Bit 9 Bit 8

C1 A4 A2C0

Bit 7 Bit 5 Bit 3Bit 4 Bit 2Bit 6 Bit 1 Bit 0

D7 D5 D3D4 D2D6 D1 D0

control bits

A1 P/N

data

MOSI

S15 S13 S11S14 Do7 Do5 Do3Do4 Do2Do6 Do1 Do0

S12 S9

S10 S8

MISO

Device Status Extended Device Status, Register Control bits or Device Flags

Next bit = 1

SCLK

MOSI

MISO Tri-state Tri-state

SPI Wave Form, and Signals Polarity

S15 S14 Do0

C1 C0 D0

SCLK signal is low outside of CS active

CS active low. Must rise at end of 16 clocks,

MOSI and MISO data changed at SCLK rising edge

and sampled at falling edge. Msb first.

MISO tri-state outside of CS active

Don’t CareDon’t Care

for write commands, MOSI bits [15, 14] = [0, 1]

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2. Ensure SPI timing parameter tLEAD is a min. of 550 ns.

Note: In data sheet revisions prior to 7.0, the tLEAD parameter is a min of 30 ns.

3. Make sure to include a SPI read command after a SPI write command.

In case a series of SPI write commands is used, only one additional SPI read is necessary. The recommended SPI read command is

“device ID read: 0x2580” so device operation is not affected (ex: clear flag). Other SPI read commands may also be used.

When the previous steps are implemented, the device will operate as follows:

For a given SPI write command (named SPI write ‘n’):

• In case the SPI write command ‘n’ is not accepted, the following SPI command (named SPI ‘n+1’) will finish the write process of the

SPI write ‘n’, thanks to step 2 (tLAG > 550 ns) and step 3 (which is the additional SPI command ‘n+1’).

• By applying steps 1, 2, and 3, no SPI command is ignored. Worst case, the SPI write ‘n’ is executed at the time the SPI ‘n+1’ is sent.

This will lead to a delay in device operation (delay between SPI command ‘n’ and ‘n+1’).

Note: Occurrence of an incorrect command is reduced, thanks to step 1 (extension of tCSLOW duration to >5.5 μs).

Sequence examples:

Example 1:

• 0x60C0 (CAN interface control) – in case this command is missed, next write command will complete it

• 0x66C0 (LIN interface control) – in case this command is missed, next read command will complete it

• 0x2580 (read device ID) – Additional command to complete previous LIN command, in case it was missed

Example 2:

• 0x60C0 (CAN interface control) - in case this command is missed, next write command will complete it

• 0x66C0 (LIN interface control) - in case this command is missed, next read command will complete it

• 0x2100 (read CAN register content) – this command will complete previous one, in case it was missed

• 0x2700 (read LIN register content)

SPI Operation if the CSB low flag is set to '1' (All product versions)

When the ‘CSB low’ flag is set (Bit 4 = '1' using the 0xE300 SPI command), the next SPI write commands are executed by the device only

if the SPI tLEAD time is between 30 ns and 2.5 µs maximum for the ‘C’ and ‘D’ versions, and 550 ns and 2.5 µs maximum for others

versions.

The occurrence of the CSB flag set to ‘1’ is extremely low and is directly linked to an intermittent short to ground on the board trace or a

CSB driven low by the MCU. In both cases, the CSB pin must be asserted low for more than 2.0 ms to set the flag.

The tLEAD time is represented in the SPI timing diagram (Figure 14) and corresponds to the time between CSB high to low transition and

first SCLK signal.

Note:

If the flag is cleared by a read command and the fault is no longer present, the 2.5 µs maximum of tLEAD time does not apply, but can also

be respected. This means if all the SPI write commands use a maximum tLEAD time of 2.5 µs, they are all interpreted by the device,

whatever the indication of the ‘CSB low’ flag.

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10.2.1 Bits 15, 14, and 8 functions

Table 12 summarizes the various SPI operation, depending upon bit 15, 14, and 8.

10.2.2 Bits 13-9 functions

The device contains several registers coded on five bits (bits 13 to 9).

Each register controls or reports part of the device’s function. Data can be written to the register to control the device operation or to set

the default value or behavior. Every register can also be read back in order to ensure that it’s content (default setting or value previously

written) is correct. In addition, some of the registers are used to report device flags.

10.2.2.1 Device status on MISO

When a write operation is performed to store data or control bits into the device, the MISO pin reports a 16 bit fixed device status composed

of 2 bytes: Device Fixed Status (bits 15 to 8) + extended Device Status (bits 7 to 0). In a read operation, MISO will report the Fixed device

status (bits 15 to 8) and the next eight bits will be the content of the selected register.

10.2.3 Register adress table

Table 13 is a list of device registers and addresses, coded with bits 13 to 9.

Table 12. SPI operations (bits 8, 14, & 15)

Control Bits MOSI[15-14], C1-C0 Type of Command Parity/Next

MOSI[8] P/N Note for Bit 8 P/N

Read back of register

content and block (CAN,

I/O, INT, LINs) real time

state. See Table 39.

1Bit 8 must be set to 1, independently of the parity function

selected or not selected.

Write to register

address, to control the

device operation

0If bit 8 is set to “0”: means parity not selected OR

parity is selected AND parity = 0

1if bit 8 is set to “1”: means parity is selected AND parity = 1

10 Reserved

11 Read of device flags

form a register address 1Bit 8 must be set to 1, independently of the parity function

selected or not selected.

Table 13. Device registers with corresponding address

Address

MOSI[13-9]

A4...A0

Description Quick Ref.

Name Functionality

0_0000 Analog Multiplexer MUX 1) Write ‘device control bits’ to register address.

2) Read back register ‘control bits’

0_0001 Memory byte A RAM_A

1) Write ‘data byte’ to register address.

2) Read back ‘data byte’ from register address

0_0010 Memory byte B RAM_B

0_0011 Memory byte C RAM_C

0_0100 Memory byte D RAM_D

0_0101 Initialization Regulators Init REG

1) Write ‘device initialization control bits’ to register address.

2) Read back ‘initialization control bits’ from register address

0_0110 Initialization Watchdog Init

watchdog

0_0111 Initialization LIN and I/O Init LIN I/O

0_1000 Initialization Miscellaneous functions Init MISC

0_1001 Specific modes SPE_MOD

1) Write to register to select device Specific mode, using

‘Inverted Random Code’

2) Read ‘Random Code’

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10.2.4 Complete SPI operation

Table 14 is a compiled view of all the SPI capabilities and options. Both MOSI and MISO information are described.

Note: P = 0 if parity bit is not selected or parity = 0. P = 1 if parity is selected and parity = 1.

10.2.5 Parity bit 8

10.2.5.1 Calculation

The parity is used for the write-to-register command (bit 15,14 = 01). It is calculated based on the number of logic one contained in bits

15-9,7-0 sequence (this is the entire 16 bits of the write command except bit 8).

Bit 8 must be set to 0 if the number of 1 is odd. Bit 8 must be set to 1if the number of 1 is even.

0_1010 Timer_A: watchdog & LP MCU consumption TIM_A

1) Write ‘timing values’ to register address

2) Read back register ‘timing values’

0_1011 Timer_B: Cyclic Sense & Cyclic Interrupt TIM_B

0_1100 Timer_C: watchdog LP & Forced Wake-up TIM_C

0_1101 Watchdog Refresh watchdog Watchdog Refresh Commands

0_1110 Mode register MODE

1) Write to register to select LP mode, with optional “Inverted

Random code” and select Wake-up functionality

2) Read operations:

Read back device ‘Current mode’

Read ‘Random Code’,

Leave ‘Debug mode’

0_1111 Regulator Control REG

1) Write ‘device control bits’ to register address, to select device

operation.

2) Read back register ‘control bits’.

3) Read device flags from each of the register addresses.

1_0000 CAN interface control CAN

1_0001 Input Output control I/O

1_0010 Interrupt Control Interrupt

1_0011 LIN1 interface control LIN1

1_0100 LIN2 interface control LIN2

Table 14. SPI capabilities with options

Type of Command MOSI/

MISO

Control bits

[15-14]

Address

[13-9]

Parity/Next

bits [8] Bit 7 Bits [6-0]

Read back of “device control bits” (MOSI bit

7 = 0)

Read specific device information (MOSI bit

7 = 1)

MOSI 00 address 1 0 000 0000

MISO Device Fixed Status (8 bits) Register control bits content

MOSI 00 address 1 1 000 0000

MISO Device Fixed Status (8 bits) Device ID and I/Os state

Write device control bit to address selected

by bits (13-9).

MISO return 16 bits device status

MOSI 01 address (note) Control bits

MISO Device Fixed Status (8 bits) Device Extended Status (8 bits)

Reserved MOSI 10 Reserved

MISO Reserved

Read device flags and Wake-up flags, from

(bit 7).

MISO return fixed device status (bit 15-8) +

flags from the selected address and sub-

address.

MISO 11 address Reserved 0Read of device flags form a register

address, and sub address LOW (bit 7)

MOSI Device Fixed Status (8 bits) Flags

MISO 11 address 1 1 Read of device flags form a register

address, and sub address HIGH (bit 7)

MOSI Device Fixed Status (8 bits) Flags

Table 13. Device registers with corresponding address (continued)

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10.2.5.2 Examples 1:

MOSI [bit 15-0] = 01 00 011 P 01101001, P should be 0, because the command contains 7 bits with logic 1. Thus the Exact command will

then be: MOSI [bit 15-0] = 01 00 011 0 01101001

10.2.5.3 Examples 2:

MOSI [bit 15-0] = 01 00 011 P 0100 0000, P should be 1, because the command contains 4 bits with logic 1. Thus the Exact command

will then be: MOSI [bit 15-0] = 01 00 011 1 0100 0000

10.2.5.4 Parity function selection

All SPI commands and examples do not use parity functions. The parity function is optional. It is selected by bit 6 in INIT MISC register.

If parity function is not selected (bit 6 of INIT MISC = 0), then Parity bits in all SPI commands (bit 8) must be ‘0’.

10.3 Detail of control bits and register mapping

The following tables contain register bit meaning arranged by register address, from address 0_000 to address 1_0100

10.3.1 MUX and RAM registers

Table 15. MUX Register(42)

MOSI First Byte [15-8]

[b_15 b_14] 0_0000 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 00 _ 000 P MUX_2 MUX_1 MUX_0 Int 2K I/O-att 0 0 0

Default state 0 0 0 0 0 0 0 0

Condition for default POR, 5 V-CAN off, any mode different from Normal

Bits Description

b7 b6 b5 MUX_2, MUX_1, MUX_0 - Selection of external input signal or internal signal to be measured at MUX-OUT pin

000 All functions disable. No output voltage at MUX-OUT pin

001 VDD regulator current recopy. Ratio is approx 1/97. Requires an external resistor or selection of Internal 2.0 K (bit 3)

010 Device internal voltage reference (approx 2.5 V)

011 Device internal temperature sensor voltage

100 Voltage at I/O-0. Attenuation or gain is selected by bit 3.

101 Voltage at I/O-1. Attenuation or gain is selected by bit 3.

110 Voltage at VSUP/1 pin. Refer to electrical table for attenuation ratio (approx 5)

111 Voltage at VSENSE pin. Refer to electrical table for attenuation ratio (approx 5)

b4 INT 2k - Select device internal 2.0 kohm resistor between AMUX and GND. This resistor allows the measurement of a voltage proportional

to the VDD output current.

0Internal 2.0 kohm resistor disable. An external resistor must be connected between AMUX and GND.

1Internal 2.0 kohm resistor enable.

b3 I/O-att - When I/O-0 (or I/O-1) is selected with b7,b6,b5 = 100 (or 101), b3 selects attenuation or gain

between I/O-0 (or I/O-1) and MUX-OUT pin

0Gain is approx 2 for device with VDD = 5.0 V (Ref. to electrical table for exact gain value)

Gain is approx 1.3 for device with VDD = 3.3 V (Ref. to electrical table for exact gain value)

1Attenuation is approx 4 for device with VDD = 5.0 V (Ref. to electrical table for exact attenuation value)

Attenuation is approx 6 for device with VDD = 3.3 V (Ref. to electrical table for exact attenuation value)

Notes

42. The MUX register can be written and read only when the 5V-CAN regulator is ON. If the MUX register is written or read while 5V-CAN is OFF, the

command is ignored, and the MXU register content is reset to default state (all control bits = 0).

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10.3.2 INIT registers

Note: these registers can be written only in INIT mode

Table 16. Internal memory registers A, B, C, and D, RAM_A, RAM_B, RAM_C, and RAM_D

MOSI First Byte [15-8]

[b_15 b_14] 0_0xxx [P/N]

MOSI Second Byte, bits 7-0

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

01 00 _ 001 P Ram a7 Ram a6 Ram a5 Ram a4 Ram a3 Ram a2 Ram a1 Ram a0

Default state 0 0 0 0 0 0 0 0

Condition for default POR

01 00 _ 010 P Ram b7 Ram b6 Ram b5 Ram b4 Ram b3 Ram b2 Ram b1 Ram b0

Default state 0 0 0 0 0 0 0 0

Condition for default POR

01 00 _ 011 P Ram c7 Ram c6 Ram c5 Ram c4 Ram c3 Ram c2 Ram c1 Ram c0

Default state 0 0 0 0 0 0 0 0

Condition for default POR

01 00 _ 100 P Ram d7 Ram d6 Ram d5 Ram d4 Ram d3 Ram d2 Ram d1 Ram d0

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Table 17. Initialization regulator registers, INIT REG (note: register can be written only in INIT mode)

MOSI First Byte [15-8]

[b_15 b_14] 0_0101 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 00 _ 101 P I/O-x sync VDDL rst[1] VDDL rst[0] VDD rstD[1] VDD rstD[0] VAUX5/3 Cyclic on[1] Cyclic on[0]

Default state 1 0 0 0 0 0 0 0

Condition for default POR

Bit Description

b7 I/O-x sync - Determine if I/O-1 is sensed during I/O-0 activation, when cyclic sense function is selected

0I/O-1 sense anytime

1I/O-1 sense during I/O-0 activation

b6, b5 VDDL RST[1] VDDL RST[0] - Select the VDD undervoltage threshold, to activate RST pin and/or INT

00 Reset at approx 0.9 VDD.

01 INT at approx 0.9 VDD, Reset at approx 0.7 VDD

10 Reset at approx 0.7 VDD

11 Reset at approx 0.9 VDD.

b4, b3 VDD RSTD[1] VDD RSTD[0] - Select the RST pin low lev duration, after VDD rises above the VDD undervoltage threshold

00 1.0 ms

01 5.0 ms

10 10 ms

11 20 ms

b2 [VAUX 5/3] - Select Vauxilary output voltage

0 VAUX = 3.3 V

1 VAUX = 5.0 V

b1, b0 Cyclic on[1] Cyclic on[0] - Determine I/O-0 activation time, when cyclic sense function is selected

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00 200 μs (typical value. Ref. to dynamic parameters for exact value)

01 400 μs (typical value. Ref. to dynamic parameters for exact value)

10 800 μs (typical value. Ref. to dynamic parameters for exact value)

11 1600 μs (typical value. Ref. to dynamic parameters for exact value)

Table 18. Initialization watchdog registers, INIT watchdog (note: register can be written only in INIT mode)

MOSI First Byte [15-8]

[b_15 b_14] 0_0110 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 00 _ 110 P WD2INT MCU_OC OC-TIM WD Safe WD_spi[1] WD_spi[0] WD N/Win Crank

Default state 0 1 0 0 0 1 0

Condition for default POR

Bit Description

b7 WD2INT - Select the maximum time delay between INT occurrence and INT source read SPI command

0Function disable. No constraint between INT occurrence and INT source read.

1INT source read must occur before the remaining of the current watchdog period plus 2 complete watchdog periods.

b6, b5 MCU_OC, OC-TIM - In LP VDD ON, select watchdog refresh and VDD current monitoring functionality. VDD_OC_LP threshold

is defined in device electrical parameters (approx 1.5 mA)

In LP mode, when watchdog is not selected

watchdog +

In LP VDD ON mode, VDD overcurrent has no effect

watchdog +

In LP VDD ON mode, VDD overcurrent has no effect

watchdog +

In LP VDD ON mode, VDD current > VDD_OC_LP threshold for a time > 100 μs (typically) is a wake-up event

watchdog +

In LP VDD ON mode, VDD current > VDD_OC_LP threshold for a time > I_mcu_OC is a wake-up event. I_mcu_OC time is

selected in Timer register (selection range from 3.0 to 32 ms)

In LP mode when watchdog is selected

watchdog +

00 In LP VDD ON mode, VDD current > VDD_OC_LP threshold has no effect. watchdog refresh must occur by SPI command.

watchdog +

01 In LP VDD ON mode, VDD current > VDD_OC_LP threshold has no effect. watchdog refresh must occur by SPI command.

watchdog +

10 In LP VDD ON mode, VDD overcurrent for a time > 100 μs (typically) is a wake-up event.

watchdog +

In LP VDD ON mode, VDD current > VDD_OC_LP threshold for a time < I_mcu_OC is a watchdog refresh condition. VDD current

> VDD_OC_LP threshold for a time > I_mcu_OC is a wake-up event. I_mcu_OC time is selected in Timer register (selection

range from 3.0 to 32 ms)

b4 WD Safe - Select the activation of the SAFE pin low, at first or second consecutive RESET pulse

0SAFE pin is set low at the time of the RST pin low activation

1SAFE pin is set low at the second consecutive time RST pulse

b3, b2 WD_spi[1] WD_spi[0] - Select the Watchdog (watchdog) Operation

00 Simple Watchdog selection: watchdog refresh done by a 8 bits or 16 bits SPI

01 Enhanced 1: Refresh is done using the Random Code, and by a single 16 bits.

10 Enhanced 2: Refresh is done using the Random Code, and by two 16 bits command.

Bit Description

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11 Enhanced 4: Refresh is done using the Random Code, and by four 16 bits command.

b1 WD N/Win - Select the Watchdog (watchdog) Window or Timeout operation

0Watchdog operation is TIMEOUT, watchdog refresh can occur anytime in the period

1Watchdog operation is WINDOW, watchdog refresh must occur in the open window (second half of period)

b0 Crank - Select the VSUP/1 threshold to disable VDD, while VSUP1 is falling toward GND

0 VDD disable when VSUP/1 is below typically 4.0 V (parameter VSUP-TH1), and device in Reset mode

1 VDD kept ON when VSUP/1 is below typically 4.0 V (parameter VSUP_TH1)

Table 19. Initialization LIN and I/O registers, INIT LIN I/O (note: register can be written only in INIT mode)

MOSI First Byte [15-8]

[b_15 b_14] 0_0111 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 00 _ 111 P I/O-1 ovoff LIN_T2[1] LIN_T2[0] LIN_T/1[1] LIN_T/1[0] I/O-1 out-en I/O-0 out-en Cyc_Inv

Default state 0 0 0 0 0 0 0

Condition for default POR

Bit Description

b7 I/O-1 ovoff - Select the deactivation of I/O-1 when VDD or VAUX overvoltage condition is detected

0Disable I/O-1 turn off.

1Enable I/O-1 turn off, when VDD or VAUX overvoltage condition is detected.

b6, b5 LIN_T2[1], LIN_T2[0] - Select pin operation as LIN Master pin switch or I/O

00 pin is OFF

01 pin operation as LIN Master pin switch

10 pin operation as I/O: HS switch and Wake-up input

11 N/A

b4, b3 LIN_T/1[1], LIN_T/1[0] - Select pin operation as LIN Master pin switch or I/O

00 pin is OFF

01 pin operation as LIN Master pin switch

10 pin operation as I/O: HS switch and Wake-up input

11 N/A

b2 I/O-1 out-en- Select the operation of the I/O-1 as output driver (HS, LS)

0Disable HS and LS drivers of pin I/O-1. I/O-1 can only be used as input.

1Enable HS and LS drivers of pin I/O-1. Pin can be used as input and output driver.

b1 I/O-0 out-en - Select the operation of the I/O-0 as output driver (HS, LS)

0Disable HS and LS drivers of I/O-0 can only be used as input.

1Enable HS and LS drivers of the I/O-0 pin. Pin can be used as input and output drivers.

b0 Cyc_Inv - Select I/O-0 operation in device LP mode, when cyclic sense is selected

Bit Description

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0During cyclic sense active time, I/O is set to the same state prior to entering in to LP mode. During cyclic sense off time, I/O-0

is disable (HS and LS drivers OFF).

During cyclic sense active time, I/O is set to the same state prior to entering in to LP mode. During cyclic sense off time, the

opposite driver of I/O_0 is actively set. Example: If I/0_0 HS is ON during active time, then I/O_O LS is turned ON at expiration

of the active time, for the duration of the cyclic sense period.

Table 20. Initialization Miscellaneous Functions, INIT MISC (Note: Register can be written only in INIT mode)

MOSI First Byte [15-8]

[b_15 b_14] 0_1000 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 000 P LPM w

RNDM SPI parity INT pulse INT width INT flash Dbg Res[2] Dbg Res[1] Dbg Res[0]

Default state 0 0 0 0 0 0 0

Condition for default POR

Bit Description

b7 LPM w RNDM - This enables the usage of random bits 2, 1 and 0 of the MODE register to enter into LP VDD OFF or LP VDD

ON.

0Function disable: the LP mode can be entered without usage of Random Code

1Function enabled: the LP mode is entered using the Random Code

b6 SPI parity - Select usage of the parity bit in SPI write operation

0Function disable: the parity is not used. The parity bit must always set to logic 0.

1Function enable: the parity is used, and parity must be calculated.

b5 INT pulse -Select INT pin operation: low level pulse or low level

0INT pin will assert a low level pulse, duration selected by bit [b4]

1INT pin assert a permanent low level (no pulse)

b4 INT width - Select the INT pulse duration

0INT pulse duration is typically 100 μs. Ref. to dynamic parameter table for exact value.

1INT pulse duration is typically 25 μs. Ref. to dynamic parameter table for exact value.

b3 INT flash - Select INT pulse generation at 50% of the Watchdog Period in Flash mode

Function disable

Function enable: an INT pulse will occur at 50% of the Watchdog Period when device in Flash mode.

b2, b1, b0 Dbg Res[2], Dbg Res[1], Dbg Res[0] - Allow verification of the external resistor connected at DBG pin. Ref. to parametric

table for resistor range value.(43)

0xx Function disable

100 100 verification enable: resistor at DBG pin is typically 68 kohm (RB3) - Selection of SAFE mode B3

101 101 verification enable: resistor at DBG pin is typically 33 kohm (RB2 - Selection of SAFE mode B2

110 110 verification enable: resistor at DBG pin is typically 15 kohm (RB1) - Selection of SAFE mode B1

111 111 verification enable: resistor at DBG pin is typically 0 kohm (RA) - Selection of SAFE mode A

Notes

43. Bits b2,1 and 0 allow the following operation:

First, check the resistor device has detected at the DEBUG pin. If the resistor is different, bit 5 (Debug resistor) is set in INTerrupt

Second, over write the resistor decoded by device, to set the SAFE mode operation by SPI. Once this function is selected by bit 2 = 1,

this selection has higher priority than ‘hardware’, and device will behave according to b2,b1 and b0 setting

Bit Description

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10.3.3 Specific mode register

10.3.3.1 The SPE mode register is used for the following operation

- Set the device in RESET mode, to exercise or test the RESET functions.

- Go to INIT mode, using the Secure SPi command.

- Go to FLASH mode (in this mode the watchdog timer can be extended up to 32 s).

- Activate the SAFE pin by S/W.

This mode (called Special mode) is accessible from the secured SPI command, which consist of 2 commands:

1) reading a random code and

2) then write the inverted random code plus mode selection or SAFE pin activation:

Return to INIT mode is done as follow (this is done from Normal mode only):

1) Read random code:

MOSI : 0001 0011 0000 0000 [Hex:0x 13 00]

MISO report 16 bits, random code are bits (5-0)

miso = xxxx xxxx xxR5 R4 R3 R2 R1 R0 (RXD = 6 bits random code)

2) Write INIT mode + random code inverted

MOSI : 0101 0010 01 Ri5 Ri4 Ri3 Ri2 Ri1 Ri0 [Hex 0x 52 HH] (RIX = random code inverted)

MISO : xxxx xxxx xxxx xxxx (don’t care)

SAFE pin activation: SAFE pin can be set low, only in INIT mode, with following commands:

1) Read random code:

MOSI : 0001 0011 0000 0000 [Hex:0x 13 00]

MISO report 16 bits, random code are bits (5-0)

miso = xxxx xxxx xxR5 R4 R3 R2 R1 R0 (RXD = 6 bits random code)

2) Write INIT mode + random code bits 5:4 not inverted and random code bits 3:0 inverted

MOSI : 0101 0010 01 R5 R4 Ri3 Ri2 Ri1 Ri0 [Hex 0x 52 HH] (RIX = random code inverted)

MISO : xxxx xxxx xxxx xxxx (don’t care)

Return to Reset or Flash mode is done similarly to the go to INIT mode, except that the b7 and b6 are set according to the table above

(b7, b6 = 00 - go to reset, b7, b6 = 10 - go to Flash).

Table 21. Specific mode register, SPE_MODE

MOSI First Byte [15-8]

[b_15 b_14] 01_001 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 001 P Sel_Mod[1] Sel_Mod[0] Rnd_C5b Rnd_C4b Rnd_C3b Rnd_C2b Rnd_C1b Rnd_C0b

Default state 0 0 0 0 0 0 0

Condition for default POR

Bit Description

b7, b6 Sel_Mod[1], Sel_Mod[0] - Mode selection: these 2 bits are used to select which mode the device will enter upon a SPI

command.

00 RESET mode

01 INIT mode

10 FLASH mode

11 N/A

b5....b0 [Rnd_C4b... Rnd_C0b] - Random Code inverted, these six bits are the inverted bits obtained from the SPE MODE Register

read command.

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10.3.4 Timer registers

Table 22. Timer register A, LP VDD overcurrent & watchdog period normal mode, TIM_A

MOSI First Byte [15-8]

[b_15 b_14] 01_010 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 010 P I_mcu[2] I_mcu[1] I_mcu[1] watchdog

Nor[4] W/D_N[4] W/D_Nor[3] W/D_N[2] W/D_Nor[0]

Default state 0 0 0 1 1 1 1 0

Condition for default POR

LP VDD overcurrent (ms)

b6, b5

00 01 10 11

03 (def) 612 24

1 4 8 16 32

Watchdog period in device normal mode (ms)

b4, b3

b2, b1, b0

000 001 010 011 100 101 110 111

00 2.5 510 20 40 80 160 320

01 3 6 12 24 48 96 192 384

10 3.5 714 28 56 112 224 448

11 4 8 16 32 64 128 256 (def) 512

Table 23. Timer register B, cyclic sense and cyclic INT, in device LP mode, TIM_B

MOSI First Byte [15-8]

[b_15 b_14] 01_011 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 011 P Cyc-sen[3] Cyc-sen[2] Cyc-sen[1] Cyc-sen[0] Cyc-int[3] Cyc-int[2] Cyc-int[1] Cyc-int[0]

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Cyclic sense (ms)

b6, b5, b4

000 001 010 011 100 101 110 111

0 3 6 12 24 48 96 192 384

1 4 8 16 32 64 128 256 512

Cyclic interrupt (ms)

b2, b1, b0

000 001 010 011 100 101 110 111

06 (def) 12 24 48 96 192 384 768

1 8 16 32 64 128 258 512 1024

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10.3.5 Watchdog and mode registers

Table 24. Timer register C, watchdog LP mode or flash mode and forced wake-up timer, TIM_C

MOSI First Byte [15-8]

[b_15 b_14] 01_100 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 100 P WD-LP-F[3] WD-LP-F[2] WD-LP-F[1] WD-LP-F[0] FWU[3] FWU[2] FWU[1] FWU[0]

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Table 25. Typical timing values

Watchdog in LP VDD ON mode (ms)

b6, b5, b4

000 001 010 011 100 101 110 111

012 24 48 96 192 384 768 1536

116 32 64 128 256 512 1024 2048

Watchdog in flash mode (ms)

b6, b5, b4

000 001 010 011 100 101 110 111

048 (def) 96 192 384 768 1536 3072 6144

1256 512 1024 2048 4096 8192 16384 32768

Forced wake-up (ms)

b2, b1, b0

000 001 010 011 100 101 110 111

048 (def) 96 192 384 768 1536 3072 6144

164 128 258 512 1024 2048 4096 8192

Table 26. Watchdog refresh register, watchdog(44)

MOSI First Byte [15-8]

[b_15 b_14] 01_101 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 101 P 0 0 0 0 0 0 0 0

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Notes

44. The Simple Watchdog Refresh command is in hexadecimal: 5A00. This command is used to refresh the watchdog and also to

transition from INIT mode to Normal mode, and from Normal Request mode to Normal mode (after a wake-up of a reset)

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Prior to enter in LP VDD ON or LP VDD OFF, the Wake-up flags must be cleared or read.

This is done by the following SPI commands (See Table 39, Device flag, I/O real time and device identification):

0xE100 for CAN Wake-up clear

0xE380 for I/O Wake-up clear

0xE700 for LIN1 Wake-up clear

0xE900 for LIN2 Wake-up clear

If Wake-up flags are not cleared, the device will enter into the selected LP mode and immediately Wake-up. In addition, the CAN failure

flags (i.e. CAN_F and CAN_UF) must be cleared in order to meet the low power current consumption specification. This is done by the

following SPI command:

0xE180 (read CAN failure flags)

When the device is in LP VDD ON mode, the Wake-up by a SPI command uses a write to ‘Normal Request mode’, 0x5C10.

Table 27. MODE register, mode

MOSI First Byte [15-8]

[b_15 b_14] 01_110 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 110 P mode[4] mode[3] mode[2] mode[1] mode[0] Rnd_b[2] Rnd_b[1] Rnd_b[0]

Default state N/A N/A N/A N/A N/A N/A N/A N/A

Table 28. LP VDD off selection and FWU / cyclic sense selection

b7, b6, b5, b4, b3 FWU Cyclic Sense

0 1100 OFF OFF

0 1101 OFF ON

0 1110 ON OFF

0 1111 ON ON

Table 29. LP VDD on selection and operation mode

b7, b6, b5, b4, b3 FWU Cyclic Sense Cyclic INT Watchdog

1 0000 OFF OFF OFF OFF

1 0001 OFF OFF OFF ON

1 0010 OFF OFF ON OFF

1 0011 OFF OFF ON ON

1 0100 OFF ON OFF OFF

1 0101 OFF ON OFF ON

1 0110 OFF ON ON OFF

1 0111 OFF ON ON ON

1 1000 ON OFF OFF OFF

1 1001 ON OFF OFF ON

1 1010 ON OFF ON OFF

1 1011 ON OFF ON ON

1 1100 ON ON OFF OFF

1 1101 ON ON OFF ON

1 1110 ON ON ON OFF

1 1111 ON ON ON ON

b2, b1, b0

Random Code inverted, these 3bits are the inverted bits obtained from the previous SPI command.

The usage of these bits are optional and must be previously selected in the INIT MISC register [See

bit 7 (LPM w RNDM) in Table 20]

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10.3.5.1 Mode register features

The mode register includes specific functions and a ‘global SPI command’ that allow the following:

- read device current mode

- read device Debug status

- read state of SAFE pin

- leave Debug state

- release or turn off SAFE pin

- read a 3 bit Random Code to enter in LP mode

These global commands are built using the MODE register address bit [13-9], along with several combinations of bit [15-14] and bit [7].

Note, bit [8] is always set to 1.

10.3.5.2 Entering into LP mode using random code

- LP mode using Random Code must be selected in INIT mode via bit 7 of the INIT MISC register.

- In Normal mode, read the Random Code using 0x1D00 or 0x1D80 command. The 3 Random Code bits are available on MISO bits 2,1 and 0.

- Write LP mode by inverting the 3 random bits.

Example - Select LP VDD OFF without cyclic sense and FWU:

1. in hex: 0x5C60 to enter in LP VDD OFF mode without using the 3 random code bits.

2. if Random Code is selected, the commands are:

- Read Random Code: 0x1D00 or 0x1D80,

MISO report in binary: bits 15-8, bits 7-3, Rnd_[2], Rnd_[1], Rnd_[0].

- Write LP VDD OFF mode, using Random Code inverted:

in binary: 0101 1100 0110 0 Rnd_b[2], Rnd_b[1], Rnd_b[0].

Table 30 summarizes these commands

Table 31 describes MISO bits 7-0, used to decode the device’s current mode.

Table 30. Device modes

Global commands and effects

Read device current mode, Leave debug mode.

Keep SAFE pin as is.

MOSI in hexadecimal: 1D 00

MOSI bits 15-14 bits 13-9 bit 8 bit 7 bits 6-0

00 01 110 1 0 000 0000

MISO bit 15-8 bit 7-3 bit 2-0

Fix Status device current mode Random code

Read device current mode

Release SAFE pin (turn OFF).

MOSI in hexadecimal: 1D 80

MOSI bits 15-14 bits 13-9 bit 8 bit 7 bits 6-0

00 01 110 1 1 000 0000

MISO bit 15-8 bit 7-3 bit 2-0

Fix Status device current mode Random code

Read device current mode, Leave debug mode.

Keep SAFE pin as is.

MOSI in hexadecimal: DD 00

MISO reports Debug and SAFE state (bits 1,0)

MOSI bits 15-14 bits 13-9 bit 8 bit 7 bits 6-0

11 01 110 1 0 000 0000

MISO bit 15-8 bit 7-3 bit 2 bit 1 bit 0

Fix Status device current mode XSAFE DEBUG

Read device current mode, Keep DEBUG mode

Release SAFE pin (turn OFF).

MOSI in hexadecimal: DD 80

MISO reports Debug and SAFE state (bits 1,0)

MOSI bits 15-14 bits 13-9 bit 8 bit 7 bits 6-0

11 01 110 1 1 000 0000

MISO bit 15-8 bit 7-3 bit 2 bit 1 bit 0

Fix Status device current mode XSAFE DEBUG

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Table 32 describes the SAFE and DEBUG bit decoding.

Table 31. MISO bits 7-3

Device current mode, any of the above commands

b7, b6, b5, b4, b3 MODE

0 0000 INIT

0 0001 FLASH

0 0010 Normal Request

0 0011 Normal mode

1 XXXX Low Power mode (Table 29)

Table 32. SAFE and DEBUG status

SAFE and DEBUG bits

b1 description

0SAFE pin ON, driver activated

1SAFE pin OFF, not activated

b0 description

0Debug mode OFF

1Debug mode Active

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10.3.6 Regulator, CAN, I/O, INT and lin registers

Table 33. Regulator register

MOSI First Byte [15-8]

[b_15 b_14] 01_111 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 01_ 111 P VAUX[1] VAUX[0] -5V-can[1] 5V-can[0] VDD bal en VDD bal auto VDD OFF en

Default state 0 0 N/A 0 0 N/A N/A N/A

Condition for default POR POR

Bits Description

b7 b6 VAUX[1], VAUX[0] - Vauxilary regulator control

00 Regulator OFF

01 Regulator ON. undervoltage (UV) and Overcurrent (OC) monitoring flags not reported. VAUX is disabled when UV or OC

detected after 1.0 ms blanking time.

10 Regulator ON. undervoltage (UV) and overcurrent (OC) monitoring flags active. VAUX is disabled when UV or OC detected after

1.0 ms blanking time.

11 Regulator ON. undervoltage (UV) and overcurrent (OC) monitoring flags active. VAUX is disabled when UV or OC detected after

25 μs blanking time.

b4 b3 5 V-can[1], 5 V-can[0] - 5V-CAN regulator control

00 Regulator OFF

01 Regulator ON. Thermal protection active. undervoltage (UV) and overcurrent (OC) monitoring flags not reported. 1.0 ms

blanking time for UV and OC detection. Note: by default when in Debug mode

10 Regulator ON. Thermal protection active. undervoltage (UV) and overcurrent (OC) monitoring flags active. 1.0 ms blanking time

for UV and OC detection.

11 Regulator ON. Thermal protection active. undervoltage (UV) and overcurrent (OC) monitoring flags active after 25 μs blanking

time.

b2 VDD bal en - Control bit to Enable the VDD external ballast transistor

0External VDD ballast disable

1External VDD ballast Enable

b1 VDD bal auto - Control bit to automatically Enable the VDD external ballast transistor, if VDD is > typically 60 mA

0Disable the automatic activation of the external ballast

1Enable the automatic activation of the external ballast, if VDD > typically 60 mA

b0 VDD OFF en - Control bit to allow transition into LP VDD OFF mode (to prevent VDD turn OFF)

0Disable Usage of LP VDD OFF mode

1Enable Usage of LP VDD OFF mode

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Table 34. CAN register(45)

MOSI First byte [15-8]

[b_15 b_14] 10_000 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 10_ 000P CAN mod[1] CAN mod[0] Slew[1] Slew[0] Wake-up 1/3 - - CAN int

Default state 1 0 0 0 0 - - 0

Condition for default note POR POR POR

Bits Description

b7 b6 CAN mod[1], CAN mod[0] - CAN interface mode control, Wake-up enable / disable

00 CAN interface in Sleep mode, CAN Wake-up disable.

01 CAN interface in receive only mode, CAN driver disable.

10 CAN interface is in Sleep mode, CAN Wake-up enable. In device LP mode,

CAN Wake-up is reported by device Wake-up. In device Normal mode, CAN Wake-up reported by INT.

11 CAN interface in transmit and receive mode.

b5 b4 Slew[1] Slew[0] - CAN driver slew rate selection

00/11 FAST

01 MEDIUM

10 SLOW

b3 Wake-up 1/3 - Selection of CAN Wake-up mechanism

03 dominant pulses Wake-up mechanism

1Single dominant pulse Wake-up mechanism

b0 CAN INT - Select the CAN failure detection reporting

0Select INT generation when a bus failure is fully identified and decoded (i.e. after 5 dominant pulses on TxCAN)

1Select INT generation as soon as a bus failure is detected, event if not fully identified

Notes

45. The first time the device is set to Normal mode, the CAN is in Sleep Wake-up enabled (bit7 = 1, bit 6 =0). The next time the device is

set in Normal mode, the CAN state is controlled by bits 7 and 6.

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Table 35. I/O register

MOSI First byte [15-8]

[b_15 b_14] 10_001 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 10_ 001P I/O-3 [1] I/O-3 [0] I/O-2 [1] I/O-2 [0] I/O-1 [1] I/O-1 [0] I/O-0 [1] I/O-0 [0]

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Bits Description

b7 b6 I/O-3 [1], I/O-3 [0] - I/O-3 pin operation

00 I/O-3 driver disable, Wake-up capability disable

01 I/O-3 driver disable, Wake-up capability enable.

10 I/O-3 HS driver enable.

11 I/O-3 HS driver enable.

b5 b4 I/O-2 [1], I/O-2 [0] - I/O-2 pin operation

00 I/O-2 driver disable, Wake-up capability disable

01 I/O-2 driver disable, Wake-up capability enable.

10 I/O-2 HS driver enable.

11 I/O-2 HS driver enable.

b3 b2 I/O-1 [1], I/O-1 [0] - I/O-1 pin operation

00 I/O-1 driver disable, Wake-up capability disable

01 I/O-1 driver disable, Wake-up capability enable.

10 I/O-1 LS driver enable.

11 I/O-1 HS driver enable.

b1 b0 I/O-0 [1], I/O-0 [0] - I/O-0 pin operation

00 I/O-0 driver disable, Wake-up capability disable

01 I/O-0 driver disable, Wake-up capability enable.

10 I/O-0 LS driver enable.

11 I/O-0 HS driver enable.

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Table 36. INT register

MOSI First byte [15-8]

[b_15 b_14] 10_010 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 10_ 010P CAN failure MCU req LIN2 fail LIN1fail I/O SAFE -Vmon

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Bits Description

b7 CAN failure - control bit for CAN failure INT (CANH/L to GND, VDD or VSUP, CAN overcurrent, Driver Overtemp, TXD-PD,

RXD-PR, RX2HIGH, and CANBUS Dominate clamp)

0INT disable

1INT enable.

b6 MCU req - Control bit to request an INT. INT will occur once when the bit is enable

0INT disable

1INT enable.

b5 LIN2 fail - Control bit to enable INT when of failure on LIN2 interface

0INT disable

1INT enable.

b4 LIN/1 fail - Control bit to enable INT when of failure on LIN1 interface

0INT disable

1INT enable.

b3 I/O - Bit to control I/O interruption: I/O failure

0INT disable

1INT enable.

b2 SAFE - Bit to enable INT when of: Vaux overvoltage, VDD overvoltage, VDD Temp pre-warning, VDD undervoltage(46), SAFE

resistor mismatch, RST terminal short to VDD, MCU request INT.(47)

0INT disable

1INT enable.

b0 VMON - enable interruption by voltage monitoring of one of the voltage regulator: VAUX, 5 V-CAN, VDD (IDD Overcurrent, VSUV,

VSOV, VSENSELOW, 5V-CAN low or thermal shutdown, VAUX low or VAUX overcurrent

0INT disable

1INT enable.

Notes

46. If VDD undervoltage is set to 70% of VDD, see bits b6 and b5 in Table 15 on page 69.

47. Bit 2 is used in conjunction with bit 6. Both bit 6 and bit 2 must be set to 1 to activate the MCU INT request.

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Table 37. LIN/1 Register(49)

MOSI First byte [15-8]

[b_15 b_14] 10_010 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 10_ 011P LIN mode[1] LIN mode[0] Slew rate[1] Slew rate[0] -LIN T/1 on - VSUP ext

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Bits Description

b7 b6 LIN mode [1], LIN mode [0] - LIN/1 interface mode control, Wake-up enable / disable

00 LIN/1 disable, Wake-up capability disable

01 not used

10 LIN/1 disable, Wake-up capability enable

11 LIN/1 Transmit Receive mode(48)

b5 b4 Slew rate[1], Slew rate[0] LIN/1 slew rate selection

00 Slew rate for 20 kbit/s baud rate

01 Slew rate for 10 kbit/s baud rate

10 Slew rate for fast baud rate

11 Slew rate for fast baud rate

b2 LIN T/1 on

0LIN/1 termination OFF

1LIN/1 termination ON

b0 VSUP ext

0LIN goes recessive when device VSUP/2 is below typically 6.0 V. This is to meet J2602 specification

1LIN continues operation below VSUP/2 6.0 V, until 5 V-CAN is disabled.

Notes

48. The LIN interface can be set in TXD/RXD mode only when the TXD-L input signal is in recessive state. An attempt to set TXD/RXD

mode, while TXD-L is low, will be ignored and the LIN interface remains disabled.

49. In order to use the LIN interface, the 5V-CAN regulator must be set to ON.

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10.4 Flags and device status

10.4.1 Description

The table below is a summary of the device flags, I/O real time level, device Identification, and includes examples of SPI commands (SPI

commands do not use parity functions). They are obtained using the following commands.

This command is composed of the following:

bits 15 and 14:

• [1 1] for failure flags

• - [0 0] for I/O real time status, device identification and CAN LIN driver receiver real time state.

• bit 13 to 9 are the register address from which the flags is to be read.

•bit 8 = 1 (this is not parity bit function, as this is a read command).

When a failure event occurs, the respective flag is set and remains latched until it is cleared by a read command (provided the failure

event has recovered).

Table 38. LIN2 register(51)

MOSI First byte [15-8]

[b_15 b_14] 10_010 [P/N]

MOSI Second Byte, bits 7-0

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

01 10_ 100P LIN mode[1] LIN mode[0] Slew rate[1] Slew rate[0] -LIN T2 on - VSUP ext

Default state 0 0 0 0 0 0 0 0

Condition for default POR

Bits Description

b7 b6 LIN mode [1], LIN mode [0] - LIN 2 interface mode control, Wake-up enable / disable

00 LIN2 disable, Wake-up capability disable

01 not used

10 LIN2 disable, Wake-up capability enable

11 LIN2 Transmit Receive mode(50)

b5 b4 Slew rate[1], Slew rate[0] LIN 2slew rate selection

00 Slew rate for 20 kbit/s baud rate

01 Slew rate for 10 kbit/s baud rate

10 Slew rate for fast baud rate

11 Slew rate for fast baud rate

b2 LIN T2 on

0LIN 2 termination OFF

1LIN 2 termination ON

b0 VSUP ext

0LIN goes recessive when device VSUP/2 is below typically 6.0 V. This is to meet J2602 specification

1LIN continues operation below VSUP/2 6.0 V, until 5 V-CAN is disabled.

Notes

50. The LIN interface can be set in TXD/RXD mode only when the TXD-L input signal is in a recessive state. An attempt to set TXD/RXD

mode while TXD-L is low, will be ignored and the LIN interface will remain disabled.

51. In order to use the LIN interface, the 5V-CAN regulator must be set to ON.

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Table 39. Device flag, I/O real time and device identification

Bits 15-14 13-9 8 7 6 5 4 3 2 1 0

MOSI

MOSI bits 15-7

Next 7 MOSI bits (bits 6.0) should be “000_0000”

bits [15,

14]

Address

[13-9] bit 8 bit

MISO 8 Bits Device Fixed Status

(bits 15...8)

MISO bits [7-0], device response on MISO pin

bit 7 bit 6 bit 5 bit 4 bit 3 bit 2 bit 1 bit 0

REG

11 0_1111

REG 1 0 VAUX_LOW

VAUX_overCU

RRENT

5V-CAN_

THERMAL

SHUTDO

5V-CAN_

overCURR

ENT

VSENSE_

LOW

VSUP_

underVOLT

AGE

IDD-OC-

NORMAL

MODE

11 1 - - -

VDD_

THERMAL

SHUTDOW

RST_LOW

(<100 ms)

VSUP_

BATFAIL

IDD-OC-LP

VDDON

MODE

Hexa SPI commands to get Vreg Flags: MOSI 0x DF 00, and MOSI Ox DF 80

CAN

11 1_0000

CAN 1

0CAN

Wake-up -CAN

Overtemp RXD low(52) Rxd high TXD dom Bus Dom

clamp

CAN

Overcurren

1CAN_UF CAN_F CANL

to VBAT

CANL to

VDD

CANL to

GND

CANH to

VBAT

CANH to

VDD

CANH to

GND

Hexa SPI commands to get CAN Flags: MOSI 0x E1 00, and MOSI 0x E1 80

00 1_0000

CAN 1 1 CAN Driver

State

CAN

Receiver

State

CAN WU

en/dis - - - - -

Hexa SPI commands to get CAN real time status: MOSI 0x 21 80

I/O

11 1_0001

I/O 1

0HS3 short

to GND

HS2 short to

GND

SPI parity

error

CSB low

>2.0 ms VSUP/2-UV VSUP/1-OV I/O_O

thermal

watchdog

flash mode

50%

1I/O_1-3

Wake-up

I/O_0-2

Wake-up

SPI Wake-

up FWU INT service

Timeout

LP VDD

OFF

Reset

request

Hardware

Leave

Debug

Hexa SPI commands to get I/O Flags and I/O Wake-up: MOSI 0x E3 00, and MOSI 0x E3 80

00 1_0001

I/O 1 1 I/O_3

state

I/O_2

state I/O_1 state I/O_0 state

Hexa SPI commands to get I/O real time level: MOSI 0x 23 80

SAFE

11 1_0010

SAFE 1

0INT

request RST high DBG

resistor

VDD temp

Pre-warning VDD UV

VDD

Overvoltag

VAUX_overVO

LTAGE

1 - - - VDD low

>100 ms

VDD low

RST

RST low

>100 ms

multiple

Resets

watchdog

refresh

failure

Hexa SPI commands to get INT and RST Flags: MOSI 0x E5 00, and MOSI 0x E5 80

00 1_0010

SAFE 1 1 VDD (5.0 V

or 3.3 V)

device

p/n 1

device

p/n 0 id4 id3 id2 id1 id0

Hexa SPI commands to get device Identification: MOSI 0x 2580

example: MISO bit [7-0] = 1011 0100: MC33904, 5.0 V version, silicon Rev. C and D

LIN/1 11 1_0011

LIN 1 1 0 - LIN1

Wake-up

LIN1 Term

short to

GND

LIN 1

Overtemp RXD1 low RXD1 high TXD1 dom LIN1 bus

dom clamp

Hexa SPI commands to get LIN 2 Flags: MOSI 0x E7 00

1_0011

LIN 1 1 1 LIN1 State LIN1 WU

en/dis - - - - - -

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Hexa SPI commands to get LIN1 real time status: MOSI 0x 27 80

LIN2 11 1_0100

LIN 2 1 0 - LIN2

Wake-up

LIN2 Term

short to

GND

LIN 2

Overtemp RXD2 low RXD2 high TXD2 dom LIN2 bus

dom clamp

Hexa SPI commands to get LIN 2 Flags: MOSI 0x E9 00

00 1_0100

LIN 2 1 1 LIN2 State LIN2 WU

en/dis - - - - - -

Hexa SPI commands to get LIN2 real time status: MOSI 0x 29 80

Notes

52. Not available on ‘C’ and ‘D’ versions

Table 40. Flag descriptions

Flag Description

REG

VAUX_LOW

Description Reports that VAUX regulator output voltage is lower than the VAUX_UV threshold.

Set / Reset condition Set: VAUX below threshold for t >100 μs typically. Reset: VAUX above threshold and flag read (SPI)

VAUX_overCUR

RENT

Description Report that current out of VAUX regulator is above VAUX_OC threshold.

Set / Reset condition Set: Current above threshold for t >100 μs. Reset: Current below threshold and flag read by SPI.

5 V-CAN_

THERMAL

SHUTDOWN

Description Report that the 5 V-CAN regulator has reached overtemperature threshold.

Set / Reset condition Set: 5 V-CAN thermal sensor above threshold. Reset: thermal sensor below threshold and flag read

(SPI)

5V-CAN_UV

Description Reports that 5 V-CAN regulator output voltage is lower than the 5 V-CAN UV threshold.

Set / Reset condition Set: 5V-CAN below 5V-CAN UV for t >100 μs typically. Reset: 5V-CAN > threshold and flag read (SPI)

5V-can_

overcurrent

Description Report that the CAN driver output current is above threshold.

Set / Reset condition Set: 5V-CAN current above threshold for t>100 μs. Reset: 5V-CAN current below threshold and flag

read (SPI)

VSENSE_

LOW

Description Reports that VSENSE pin is lower than the VSENSE LOW threshold.

Set / Reset condition Set: VSENSE below threshold for t >100 μs typically. Reset: VSENSE above threshold and flag read

(SPI)

VSUP_

UNDERVOLTAG

Description Reports that VSUP/1 pin is lower than the VS1_LOW threshold.

Set / Reset condition Set: VSUP/1 below threshold for t >100 μs typically. Reset: VSUP/1 above threshold and flag read (SPI)

IDD-OC-

NORMAL MODE

Description Report that current out of VDD pin is higher that IDD-OC threshold, while device is in Normal mode.

Set / Reset condition Set: current above threshold for t>100 μs typically. Reset; current below threshold and flag read (SPI)

VDD_

THERMAL

SHUTDOWN

Description Report that the VDD has reached overtemperature threshold, and was turned off.

Set / Reset condition Set: VDD OFF due to thermal condition. Reset: VDD recover and flag read (SPI)

RST_LOW

(<100 ms)

Description Report that the RST pin has detected a low level, shorter than 100 ms

Set / Reset condition Set: after detection of reset low pulse. Reset: Reset pulse terminated and flag read (SPI)

VSUP_

BATFAIL

Description Report that the device voltage at VSUP/1 pin was below BATFAIL threshold.

Set / Reset condition Set: VSUP/1 below BATFAIL. Reset: VSUP/1 above threshold, and flag read (SPI)

IDD-OC-LP

VDDON mode

Description Report that current out of VDD pin is higher that IDD-OC threshold LP, while device is in LP VDD ON

mode.

Set / Reset condition Set: current above threshold for t>100 μs typically. Reset; current below threshold and flag read (SPI)

Table 39. Device flag, I/O real time and device identification

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CAN

CAN driver

state

Description Report real time CAN bus driver state: 1 if Driver is enable, 0 if driver disable

Set / Reset condition

Set: CAN driver is enable. Reset: CAN driver is disable. Driver can be disable by SPI command (ex

CAN set in RXD only mode) or following a failure event (ex: TXD Dominant). Flag read SPI command

(0x2180) do not clear the flag, as it is “real time” information.

CAN receiver

state

Description Report real time CAN bus receiver state: 1 if Enable, 0 if disable

Set / Reset condition

Set: CAN bus receiver is enable. Reset: CAN bus receiver is disable. Receiver disable by SPI

command (ex: CAN set in sleep mode). Flag read SPI command (0x2180) do not clear the flag, as it

is “real time” information.

CAN WU

enable

Description Report real time CAN bus Wake-up receiver state: 1 if WU receiver is enable, 0 if disable

Set / Reset condition

Set: CAN Wake-up receiver is enable. Reset: CAN Wake-up receiver is disable. Wake-up receiver is

controlled by SPI, and is active by default after device Power ON. SPI command (0x2180) do not

change flag state.

CAN

Wake-up

Description Report that Wake-up source is CAN

Set / Reset condition Set: after CAN wake detected. Reset: Flag read (SPI)

CAN

Overtemp

Description Report that the CAN interface has reach overtemperature threshold.

Set / Reset condition Set: CAN thermal sensor above threshold. Reset: thermal sensor below threshold and flag read (SPI)

RXD low(53) Description Report that RXD pin is shorted to GND.

Set / Reset condition Set: RXD low failure detected. Reset: failure recovered and flag read (SPI)

Rxd high Description Report that RXD pin is shorted to recessive voltage.

Set / Reset condition Set: RXD high failure detected. Reset: failure recovered and flag read (SPI)

TXD dom Description Report that TXD pin is shorted to GND.

Set / Reset condition Set: TXD low failure detected. Reset: failure recovered and flag read (SPI)

Bus Dom

clamp

Description Report that the CAN bus is dominant for a time longer than tDOM

Set / Reset condition Set: Bus dominant clamp failure detected. Reset: failure recovered and flag read (SPI)

CAN

Overcurrent

Description Report that the CAN current is above CAN overcurrent threshold.

Set / Reset condition Set: CAN current above threshold. Reset: current below threshold and flag read (SPI)

CAN_UF Description Report that the CAN failure detection has not yet identified the bus failure

Set / Reset condition Set: bus failure pre detection. Reset: CAN bus failure recovered and flag read

CAN_F Description Report that the CAN failure detection has identified the bus failure

Set / Reset condition Set: bus failure complete detetction.Reset: CAN bus failure recovered and flag read

CANL

to VBAT

Description Report CAN L short to VBAT failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

CANL to VDD Description Report CANL short to VDD

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

CANL to GND Description Report CAN L short to GND failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

CANH

to VBAT

Description Report CAN H short to VBAT failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

CANH to VDD Description Report CANH short to VDD

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

CANH to

GND

Description Report CAN H short to GND failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

Notes

53. Not available on ‘C’ and ‘D’ versions

Table 40. Flag descriptions

Flag Description

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I/O

HS3 short to

GND

Description Report I/O-3 HS switch short to GND failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

HS2 short to

GND

Description Report I/O-2 HS switch short to GND failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

SPI parity

error

Description Report SPI parity error was detected.

Set / Reset condition Set: failure detected. Reset: flag read (SPI)

CSB low

>2.0 ms

Description Report SPI CSB was low for a time longer than typically 2.0 ms

Set / Reset condition Set: failure detected. Reset: flag read (SPI)

VSUP/2-UV

Description Report that VSUP/2 is below VS2_LOW threshold.

Set / Reset condition Set VSUP/2 below VS2_LOW thresh. Reset VSUP/2 > VS2_LOW thresh and flag read (SPI)

VSUP/1-OV

Description Report that VSUP/1 is above VS_HIGH threshold.

Set / Reset condition Set VSUP/1 above VS_HIGH threshold. Reset VSUP/1 < VS_HIGH thresh and flag read (SPI)

I/O-0 thermal

Description Report that the I/O-0 HS switch has reach overtemperature threshold.

Set / Reset condition Set: I/O-0 HS switch thermal sensor above threshold. Reset: thermal sensor below threshold and flag

read (SPI)

watchdog

flash mode

50%

Description Report that the watchdog period has reach 50% of its value, while device is in Flash mode.

Set / Reset condition Set: watchdog period > 50%. Reset: flag read

I/O-1-3 Wake-

Description Report that Wake-up source is I/O-1 or I/O-3

Set / Reset condition Set: after I/O-1 or I/O-3 wake detected. Reset: Flag read (SPI)

I/O-0-2 Wake-

Description Report that Wake-up source is I/O-0 or I/O-2

Set / Reset condition Set: after I/O-0 or I/O-2 wake detected. Reset: Flag read (SPI)

SPI Wake-up Description Report that Wake-up source is SPI command, in LP VDD ON mode.

Set / Reset condition Set: after SPI Wake-up detected. Reset: Flag read (SPI)

FWU Description Report that Wake-up source is forced Wake-up

Set / Reset condition Set: after Forced Wake-up detected. Reset: Flag read (SPI)

INT service

Timeout

Description Report that INT timeout error detected.

Set / Reset condition Set: INT service timeout expired. Reset: flag read.

LP VDD OFF Description Report that LP VDD OFF mode was selected, prior Wake-up occurred.

Set / Reset condition Set: LP VDD OFF selected. Reset: Flag read (SPI)

Reset request Description Report that RST source is an request from a SPI command (go to RST mode).

Set / Reset condition Set: After reset occurred due to SPI request. Reset: flag read (SPI)

Hardware

Leave Debug

Description Report that the device left the Debug mode due to hardware cause (voltage at DBG pin lower than

typically 8.0 V).

Set / Reset condition Set: device leave debug mode due to hardware cause. Reset: flag read.

Table 40. Flag descriptions

Flag Description

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INT

INT request Description Report that INT source is an INT request from a SPI command.

Set / Reset condition Set: INT occurred. Reset: flag read (SPI)

RST high Description Report that RST pin is shorted to high voltage.

Set / Reset condition Set: RST failure detection. Reset: flag read.

DBG resistor Description Report that the resistor at DBG pin is different from expected (different from SPI register content).

Set / Reset condition Set: failure detected. Reset: correct resistor and flag read (SPI).

VDD TEMP PRE-

WARNING

Description Report that the VDD has reached overtemperature pre-warning threshold.

Set / Reset condition Set: VDD thermal sensor above threshold. Reset: VDD thermal sensor below threshold and flag read

(SPI)

VDD UV

Description Reports that VDD pin is lower than the VDDUV threshold.

Set / Reset condition Set: VDD below threshold for t >100 μs typically. Reset: VDD above threshold and flag read (SPI)

VDD

overVOLTAGE

Description Reports that VDD pin is higher than the typically VDD + 0.6 V threshold. I/O-1 can be turned OFF if

this function is selected in INIT register.

Set / Reset condition Set: VDD above threshold for t >100 μs typically. Reset: VDD below threshold and flag read (SPI)

VAUX_overVOL

TAGE

Description Reports that VAUX pin is higher than the typically VAUX + 0.6 V threshold. I/O-1 can be turned OFF if

this function is selected in INIT register.

Set / Reset condition Set: VAUX above threshold for t >100 μs typically. Reset: VAUX below threshold and flag read (SPI)

VDD LOW

>100 ms

Description Reports that VDD pin is lower than the VDDUV threshold for a time longer than 100 ms

Set / Reset condition Set: VDD below threshold for t >100 ms typically. Reset: VDD above threshold and flag read (SPI)

VDD LOW

Description Report that VDD is below VDD undervoltage threshold.

Set / Reset condition Set: VDD below threshold. Reset: fag read (SPI)

VDD (5.0 V or

3.3 V)

Description 0: mean 3.3 V VDD version

1: mean 5.0 V VDD version

Set / Reset condition N/A

Device P/N1

and 0

Description

Describe the device part number:

00: MC33903

01: MC33904

10: MC33905S

11: MC333905D

Set / Reset condition N/A

Device id 4 to

Description

Describe the silicon revision number

10010: silicon revision A (Pass 3.1)

10011: silicon revision B (Pass 3.2)

10100: silicon revision C and D

Set / Reset condition N/A

RST low

>100 ms

Description Report that the RST pin has detected a low level, longer than 100 ms (Reset permanent low)

Set / Reset condition Set: after detection of reset low pulse. Reset: Reset pulse terminated and flag read (SPI)

Multiple

Resets

Description Report that the more than 8 consecutive reset pulses occurred, due to missing or wrong watchdog

refresh.

Set / Reset condition Set: after detection of multiple reset pulses. Reset: flag read (SPI)

watchdog

refresh failure

Description Report that a wrong or missing watchdog failure occurred.

Set / Reset condition Set: failure detected. reset: flag read (SPI)

Table 40. Flag descriptions

Flag Description

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10.4.2 Fix and extended device status

For every SPI command, the device response on MISO is fixed status information. This information is either:

Two Bytes

Fix Status + Extended Status: when a device write command is used (MOSI bits 15-14, bits C1 C0 = 01)

One Byte

Fix Status: when a device read operation is performed (MOSI bits 15-14, bits C1 C0 = 00 or 11).

LIN/1/2

LIN/1/2 bus

dom clamp

Description Report that the LIN/1/2 bus is dominant for a time longer than tDOM

Set / Reset condition Set: Bus dominant clamp failure detected. Reset: failure recovered and flag read (SPI)

LIN/1/2 State

Description Report real time LIN interface TXD/RXD mode. 1 if LIN is in TXD/RXD mode. 0 is LIN is not in TXD/

RXD mode.

Set / Reset condition

Set: LIN in TXD RXD mode. Reset: LIN not in TXD/RXD mode. LIN not in TXD/RXD mode by SPI

command (ex LIN set in Sleep mode) or following a failure event (ex: TxL Dominant). Flag read SPI

command (0x2780 or 0x2980) do not clear it, as it is ‘real time’ flag.

LIN/1/2 WU

Description Report real time LIN Wake-up receiver state. 1 if LIN Wake-up is enable, 0 if LIN Wake-up is disable

(means LIN signal will not be detected and will not Wake-up the device).

Set / Reset condition

Set: LIN WU enable (LIN interface set in Sleep mode Wake-up enable). Reset: LIN Wake-up disable

(LIN interface set in Sleep mode Wake-up disable). Flag read SPI command (0x2780 or 0x2980) do

not clear the flag, as it is ‘real time’ information.

LIN/1/2

Wake-up

Description Report that Wake-up source is LIN/1/2

Set / Reset condition Set: after LIN/1/2 wake detected. Reset: Flag read (SPI)

LIN/1/2 Term

short to GND

Description Report LIN/1/2 short to GND failure

Set / Reset condition Set: failure detected. Reset failure recovered and flag read (SPI)

LIN/1/2

overtemp

Description Report that the LIN/1/2 interface has reach overtemperature threshold.

Set / Reset condition Set: LIN/1/2 thermal sensor above threshold. Reset: sensor below threshold and flag read (SPI)

RXD-L/1/2

low

Description Report that RXD/1/2 pin is shorted to GND.

Set / Reset condition Set: RXD low failure detected. Reset: failure recovered and flag read (SPI)

RXD-L/1/2

high

Description Report that RXD/1/2pin is shorted to recessive voltage.

Set / Reset condition Set: RXD high failure detected. Reset: failure recovered and flag read (SPI)

TXD-L/1/2

dom

Description Report that TXD/1/2 pin is shorted to GND.

Set / Reset condition Set: TXD low failure detected. Reset: failure recovered and flag read (SPI)

Table 41. Status bits description

Bits 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

MISO INT WU RST CAN-

GLIN-G I/O-G SAFE-

VREG-

CAN-

BUS

CAN-

LOC LIN2 LIN1 I/O-1 I/O-0 VREG-

1VREG-0

Bits Description

INT Indicates that an INT has occurred and that INT flags are pending to be read.

WU Indicates that a Wake-up has occurred and that Wake-up flags are pending to be read.

RST Indicates that a reset has occurred and that the flags that report the reset source are pending to be read.

CAN-G The INT, WU, or RST source is CAN interface. CAN local or CAN bus source.

LIN-G The INT, WU, or RST source is LIN2 or LIN1 interface

I/O-G The INT, WU, or RST source is I/O interfaces.

SAFE-G The INT, WU, or RST source is from a SAFE condition

VREG-G The INT, WU, or RST source is from a Regulator event, or voltage monitoring event

CAN-LOC The INT, WU, or RST source is CAN interface. CAN local source.

CAN-BUS The INT, WU, or RST source is CAN interface. CAN bus source.

Table 40. Flag descriptions

Flag Description

NXP Semiconductors 91

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SERIAL PERIPHERAL INTERFACE

LIN2 The INT, WU, or RST source is LIN2 interface

LIN/LIN1 The INT, WU, or RST source is LIN1 interface

I/O-0 The INT, WU, or RST source is I/O interface, flag from I/O sub adress Low (bit 7 = 0)

I/O-1 The INT, WU, or RST source is I/O interface, flag from I/O sub adress High (bit 7 = 1)

VREG-1 The INT, WU, or RST source is from a Regulator event, flag from REG register sub adress high (bit 7 = 1)

VREG-0 The INT, WU, or RST source is from a Regulator event, flag from REG register sub adress low (bit 7 = 0)

Bits Description

92 NXP Semiconductors

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TYPICAL APPLICATIONS

11 Typical applications

Figure 42. 33905D typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

SUP2

I/O-1

CANL

CANH

SPLIT

I/O-0

MCU

BAT

Safe Circuitry

BAT

CAN BUS

BAUX

AUX

SAFE

MUX A/D

SPI

CAN

SENSE

SUP1

CAUX

SUP

INT

RST

RF module

Switch Detection Interface

CAN xcvr

Safing Micro Controller

5.0 V (3.3 V)

DBG

eSwitch

RXD-L1

TXD-L1

LIN1

RXD-L2

TXD-L2

LIN2

1.0 k

22 k

100 nF

>4.7

>2.2

4.7 nF

<10 k

4.7 k *

* Optional

Notes

54.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP1/VSUP2 pins

(54)

LIN1

LIN TERM1

LIN BUS 1

1.0 k

VSUP1/2

option 1 option 2

LIN2

LIN TERM2

LIN BUS 1

1.0 k

VSUP1/2

option 1 option 2

>1.0

N/C

NXP Semiconductors 93

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TYPICAL APPLICATIONS

Figure 43. 33905S typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

VDD

VSUP2

I/O-1

CANL

CANH

SPLIT

I/O-0

MCU

BAT

Q1*

Safe Circuitry

BAT

CAN BUS

VBAUX VAUX

SAFE

MUX A/D

SPI

CAN

VSENSE

VSUP1

VCAUX

SUP

VDD

INT

RST

RF module

Switch Detection Interface

CAN xcvr

Safing Micro Controller

5.0 V (3.3 V)

DBG

eSwitch

RXD-L1

TXD-L1

LIN1

I/O-3

SUP

1.0 k

22 k

100 nF

22 μF

>1.0 μF

>4.7 μF

>2.2 μF

4.7 nF

<10 k

4.7 k *

(55)

Notes

55.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP1/VSUP2 pins

LIN1

LIN TERM1

LIN BUS 1

1.0 k

VSUP1/2

option 1 option 2

94 NXP Semiconductors

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TYPICAL APPLICATIONS

Figure 44. 33904 typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

VDD

VSUP2

I/O-1

CANL

CANH

DBG

SPLIT

I/O-0

MCU

BAT

Q1*

Safe Circuitry

BAT

CAN BUS

VBAUX VAUX

SAFE

MUX A/D

SPI

CAN

VSENSE

VSUP1

VCAUX

SUP

VDD

INT

RST

RF module

Switch Detection Interface

CAN xcvr

function

eSwitch

Safing Micro Controller

5V (3.3 V)

I/O-3

I/O-2

SUP

BAT

1.0 k

22 k

100 nF

100nF

100 nF

22 μF

>4.7 μF

>2.2 μF

4.7 nF

<10 k

4.7 k *

100 nF

* Optional

22 k

(56)

Notes

56.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP1/VSUP2 pins

>1.0 μF

N/C

NXP Semiconductors 95

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TYPICAL APPLICATIONS

Figure 45. 33903 typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

VDD

CANL

CANH

DBG

SPLIT

I/O-0

MCU

Safe Circuitry

BAT

CAN BUS

SAFE

SPI

CAN

SUP

VDD

INT

RST

function

22 k 100 nF

>1.0 μF

>4.7 μF

4.7 nF

(57)

Notes

57.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP1/VSUP2 pins

VSUP1

BAT

SUP

100 nF

22 μFVSUP2

N/C

96 NXP Semiconductors

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TYPICAL APPLICATIONS

Figure 46. 33903D typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

VDD

VSUP

CANL

CANH

SPLIT

IO-0

MCU

BAT

Safe Circuitry

BAT

CAN BUS

SAFE

MUX A/D

SPI

CAN

VSENSE

SUP

VDD

INT

RST

DBG

RXD-L1

TXD-L1

LIN1

RXD-L2

TXD-L2

LIN2

LIN BUS 1 LIN1

LIN-T1

1.0 k

22 k

100 nF

22 μF

>1.0 μF>4.7 μF

4.7 nF

4.7 k (optional)

* = Optional

1.0 k

option1 option2

LIN BUS 2 LIN2

LIN-T2

1.0 k

option1 option2

VSUP

Notes

58.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP pin

NXP Semiconductors 97

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TYPICAL APPLICATIONS

Figure 47. 33903S typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

VDD

VSUP

CANL

CANH

SPLIT

MCU

BAT

Safe Circuitry

BAT

CAN BUS

SAFE

MUX A/D

SPI

CAN

VSENSE

SUP

VDD

INT

RST

DBG

RXD-L

TXD-L

LIN

LIN BUS LIN

LIN-T

1.0 k

22 k

100 nF

22 μF

>1.0 μF>4.7 μF

4.7 nF

4.7 k (optional)

* = Optional

1.0 k

option1 option2

VSUP

Notes

59.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP pin

60. Leave N/C pins open.

IO-3

SUP

IO-0

N/C

98 NXP Semiconductors

33903/4/5

TYPICAL APPLICATIONS

Figure 48. 33903P typical application schematic

SCLK

MOSI

INT

5V-CAN

MISO

RXD

TXD

GND

RST

VDD

VSUP

CANL

CANH

SPLIT

MCU

BAT

Safe Circuitry

BAT

CAN BUS

SAFE

MUX A/D

SPI

CAN

VSENSE

SUP

VDD

INT

RST

DBG

1.0 k

22 k

100 nF

22 μF

>1.0 μF>4.7 μF

4.7 nF

4.7 k (optional)

* = Optional

Notes

61.

Tested per specific OEM EMC requirements for CAN and LIN with additional

capacitor > 10

μF

on VSUP pin

62. Leave N/C pins open.

IO-3

SUP

IO-0

N/C

I/O-2

BAT

100 nF

22 k

NXP Semiconductors 99

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TYPICAL APPLICATIONS

The following figure illustrates the application case where two reverse battery diodes can be used for optimization of the filtering and

buffering capacitor at the VDD pin. This allows using a minimum value capacitor at the VDD pin to guarantee reset-free operation of the

MCU during the cranking pulse and temporary (50 ms) loss of the VBAT supply.

Applications without an external ballast on VDD and without using the VAUX regulator are illustrated as well.

Figure 49. Application options

ex2: Split V

SUP

Supply

ex 4: No External Transistor - No VAUX

ex 3: No External Transistor, V

~100 mA Capability

ex1: Single V

SUP

Supply

Optimized solution for cranking pulses.

C1 is sized for MCU power supply buffer only.

VDD

VSUP2 VE

BAT

VBAUX VAUX

5.0 V/3.3 V

VSUP1

Partial View

VDD

BAT

VBAUX

VDD

BAT

VDD

BAT

VSUP2

VSUP1

VSUP2

VSUP1

VSUP2

VSUP1

VCAUX

VAUX

VCAUX

VBAUX VAUXVCAUX

Partial View

5.0 V/3.3 V

delivered by internal path transistor.

100 NXP Semiconductors

33903/4/5

PACKAGING

12 Packaging

12.1 SOIC 32 package dimensions

For the most current package revision, visit www.NXP.com and perform a keyword search using the “98A” listed below.

NXP Semiconductors 101

33903/4/5

PACKAGING

102 NXP Semiconductors

33903/4/5

PACKAGING

NXP Semiconductors 103

33903/4/5

PACKAGING

12.2 SOIC 54 package dimensions

104 NXP Semiconductors

33903/4/5

PACKAGING

NXP Semiconductors 105

33903/4/5

PACKAGING

106 NXP Semiconductors

33903/4/5

REVISION HISTORY

13 Revision history

Revision Date Description of changes

4.0 9/2010

• Initial Release - This document supersedes document MC33904_5.

• Initial release of document includes the MC33903 part number, the VDD 3.3 V version description, and the silicon revision

rev. 3.2. Change details available upon request.

5.0 12/2010

• Added 7.9. Cyclic INT operation during LP VDD on mode 47

• Changed VSUP pin to VSUP1 and pin 2 (NC) to VSUP2 for the 33903 device

• Removed . Drop voltage without external PNP pass transistor 19 for VDD=3.3 V devices

• Added VSUP1-3.3 to . VDD Voltage regulator, VDD pin 19.

• Added . Pull-up Current, TXD, VIN = 0 V 23 for VDD=3.3 V devices

• Revised 10.3.1. MUX and RAM registers 68

• Revised 41. Status bits description 90

• Added 10.3.5.2. Entering into LP mode using random code 77.

6.0 4/2011

• Removed part numbers MCZ33905S3EK/R2, MCZ33904A3EK/R2 and MCZ33905D3EK/R2, and added part numbers

MCZ33903BD3EK/R2, MCZ33903BD5EK/R2, MCZ33903BS3EK/R2 and MCZ33903BS5EK/R2.

• Voltage Supply was improved from 27V to 28V.

• Changed Classification from Advance Information to Technical Data.

• Updated Notes in Tables 8.

• Revised Tables 8; Attenuation/Gain ratio for I/O-0 and I/O-1 actual voltage: to reflect a Typical value.

• Corrected typographical errors throughout.

• Added Chip temperature: MUX-OUT voltage (guaranteed by design and characterization) parameter to Tables 8.

• Updated I/O pins (I/O-0: I/O-3) on page 33.

7.0 9/2011

• Updated VOUT-5.0-EMC maximum

• Updated tLEAD parameter

• Added tCSLOW parameter

• Updated the Detail operation section to reflect the importance of acknowledging tLEAD and tCSLOW.

• Corrected typographical error in Tables 34 CAN REGISTER for Slew Rate bits b5,b4

8.0 1/2011

• Added 12 PCZ devices to the ordering information

• Bit label change on Table 39 from INT to SAFE

• Revised notes on Table 1 to include “C” version

•Split Falling Edge of CS to Rising Edge of SCLK to differentiate the “C” version

• Added “C” version note to Table 39 and Table 40

• Added device ID 10100 Rev C, Pass 3.3 to Device id 4 to 0

• Added Debug mode DBG voltage range parameter. Already detailed in text.

• Added the MC33903P device, making additions throughout the document, where applicable.

9.0

2/2012 • Changed all PC devices to MC devices.

4/2013 • No technical changes. Revised back page. Updated document properties. Added SMARTMOS sentence to first

paragraph.

10.0 2/2014

• Added package type in Table 1.

• Added new parameter to Output Voltage on page 19 for VDD

• Added (22)

• Updated section 7.5.2.2. Watchdog in debug mode 40. Replaced “set” by “left”.

11.0 8/2014

• Changed tCS-TO in the Dynamic electrical characteristics from 2.5 to 2.0

• Note added to MUX-output (MUXOUT) on page 33 of Functional pin description

• Added a paragraph in the SPI Detail operation section for the maximum tLEAD time in case the ‘CSB low’ flag is set

• Added maximum tLEAD time in case the ‘CSB low’ flag is set to 1 in the Dynamic electrical characteristics table

12.0 8/2016

• Updated as per CIN 201608012I

• Added ‘D’ version orderable part numbers to Table 1, Table 2, and Table 3

• Updated note (2), (5), (9)

• Added note (3), (6), (10) (‘C’ versions are no longer recommended for new design) to Table 1, Table 2, and Table 3

• Added reference to ‘D’ version in the document where applicable

• Updated flag description for device id 4 to 0 in Table 40

• Updated to NXP document format and style

13.0 5/2017

• Updated Figure 29 to include 3.3 V information

• Updated workflow step 3 in Figure 30 (SPI commands: changed 0xDD00 to 0x1D80)

• Updated bit 1 description in Table 32

14.0 2/2018

• Updated note (7) (deleted “Output current limited to 100 mA”)

• Updated values for VRST-VTH in Table 6 as per CIN 201712019I

• Removed typ. and max. values for VRST-VTH (Low threshold, VDD = 5.0 V)

• Removed min. and typ. values for VRST-VTH (High threshold, VDD = 5.0 V)

• Removed typ. and max. values for VRST-VTH (Low threshold, VDD = 3.3 V)

• Removed min. and typ. values for VRST-VTH (High threshold, VDD = 3.3 V)

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There are no expressed or implied copyright licenses granted hereunder to design or fabricate any integrated circuits

based on the information in this document. NXP reserves the right to make changes without further notice to any

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purpose, nor does NXP 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 NXP 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

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Document Number: MC33903_4_5

Rev. 14.0

2/2018