74HC14D@653 - NXP SEMICONDUCTORS - Datasheet.Directory

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L9638

October 2004

1 FEATURES

■Single-wire transceiver for LIN-protocol

■Transmission rate up to 20 kbaud

■Operating power supply voltage range 6V ≤ Vs

≤ 26V (40V for transients)

■Low quiescent current in sleep mode (typ.10µA)

■Wake-up through LIN-bus, Enable input (from

µC CMOS compatible) or Wake-up input (edge

driven)

■Wide input and output range -24V ≤ VLIN ≤ Vs

■Integrated pull/down/up resistors for LIN, TxD,

RxD, EN, INH

■Inhibit output with low resistance (<40Ω) versus

Vs and short circuit protection

■CMOS compatible TxD, RxD Interface

■EMI robustness optimised

■Thermal shutdown and LIN short circuit

protection

2 DESCRIPTION

The L9638 is a monolithic integrated circuit for

LIN-bus interface function between the protocol

handler in the controller and the physical bus in

automotive applications.

As well as it can be used in standard ISO 9141

systems.

SO-8

LIN BUS TRANSCEIVER

Figure 1. Block Diagram

TxD

WUP

RxD LIN

INH

Internal

Voltage

Regulator

Int.5V

GND

Glitch

Filter

Glitch

Filter

VS_D

Control

Logic

Protection

VS_D

TxD

WUP

RxD LIN

INH

Internal

Voltage

Regulator

Int.5V

GND

Glitch

Filter

TxD

WUP

RxD LIN

INH

Internal

Voltage

Regulator

Int.5V

GND

Glitch

Filter

Glitch

Filter

VS_D

Control

Logic

Protection

VS_D

e 1.

Part Number Package

L9638D SO-8

L9638D013TR Tape & Reel

Rev. 4

L9638

2/14

Table 2. Pin Description

Figure 2. Pin Connection

Table 3. Absolute Maximum Ratings

Table 4. Thermal Data

Pin No. Pin Name Function

1 RxD Receive data Output

2 EN Enable Input

Digital control signal for low power modes

3 WUP Wake-Up Input

Local wake-up from sleep mode sensitive to positive and negative edges

4 TxD Transmit data Input

5 GND Ground

6 LIN Bidirectional I/O

7 Vs Supply voltage

8 INH Inhibit Output, battery related high side switch for controlling external Voltage

Regulator

Symbol Parameter Value Unit

VSSupply Voltage -0.3 to 40 V

VLIM Pin Voltage -24 to 40 V

VINH ,WUP Pin Voltage -0.3 to 40 V

VRxD ,TxD, EN Pin Voltage -0.3 to 6 V

VESD HBM: all pins withstand ±2KV; pin 6 (LIN) is able to withstand

±8kV versus GND and +8/-5kV versus VS

Symbol Parameter Value Unit

TJ_OP Operating junction temperature -40 to150 °C

Rth j-amb Thermal steady state junction to ambient resistance 145 K/W

TJ_SD Thermal shutdown temperature 170 ±20 °C

Tstg Storage temperature -55 to 150 °C

RxD

WUP

TxD GND

LIN

INH1

D04AT514

3/14

L9638

Table 5. Electrical Characteristics

(VS = 6V to 26V; TJ = -40 to 150 °C unless otherwise specified)

Item Symbol Parameter Test Condition Min. Typ. Max. Unit

1Supplies

1.1 VSSupply Voltage 6 26 V

1.2 ISleep Supply Vs Curent in sleep

mode

VEN = VEN low 10 30 µA

1.3 IShort Supply Vs Curent with bus

short circuit

VEN = VEN low 150 500 1700 µA

1.4 IDStand-by Supply Vs Current in Stand-

by Mode with bus recessive

VLIN = VLINHigh

VEN = VENLow

VTxD = VTxDHigh

30 100 200 µA

1.5 IDStand-by Supply Vs Current in Stand-

by Mode with bus dominant

(Receive only Mode)

VLIN = VLINLow

VEN = VENLow

0.5 1.1 2.5 mA

1.6 IsNormal Supply Vs Current in

Normal Mode with bus

recessive

VEN = VENHigh

VLIN = VLINHigh

VTxD = VTxDHigh

300 500 700 µA

1.7 IsNormal Supply Vs Current in

Normal Mode with bus

dominant

VEN = VENHigh

VLIN = VLINLow

VTxD = VTxDLow

0.9 1.8 3.5 mA

2LIN Bus Interface

2.1 VBUSDom Receive Threshold Voltage

recessive to dominant state

VLIN<18V 0.40.450.5 Vs

2.2 VBUSRec Receive Threshold Voltage

dominant to recessive state

VLIN ≥8V 0.50.550.6 Vs

2.3 VHYS Receive Threshold

Hysteresis

VBUSRec-VBUSDom 0.05 0.1 0.17 Vs

2.4 VBUScnt Tolerance centre value of

Receiver

(VBUSRec+VBUSDom)/2 0.475 0.5 0.525 Vs

2.5 ILINON Input Current dominant

state

VTxD = VTxDLow

VLIN = VS

40 100 160 mA

2.5.1 ILINOff Input Current recessive

state

VTxD = VTxDHigh

VLIN = Vs

-10 10 µA

2.5.2 ILINOff Input Current recessive

state

VTxD = VTxDHigh; VS = 12V;

VLIN = 0V (Bus dominant )

-1 mA

2.6 VLINDom Drive Voltage dominant

state

VTxD = VTxDLow

ILIN = 40mA

1.2 V

2.7 RLIN Output pull up resistor 20 30 47 kΩ

2.8 fLIN-RxD Transmission Frequency RVs-LIN =1100Ω

CLIN-GND =10nF

20 kHz

2.9 dVLIN/dt Slew rate rising edge From 10% to 90% of VLIN 123V/µs

L9638

4/14

2.10 dVLIN/dt Slew rate falling edge From 90% to 10% of VLIN -3 -2 -1 V/µs

2.11 tsym Rising/ Falling edge

symmetry

tsym= tslope_fall - tslope_rise -5 -5 µs

2.12 ttrans_pd Propagation delay of

transmitter

See Fig.2

ttrans_pd = max (ttrans_pdr,

trans_pdf)

4µs

2.13 trec_pd Propagation delay of

receiver

See Fig.2

trec_pd = max (trec_pdr, trec_pdf)

6µs

2.14 trec_sym Symmetry of receiver

propagation delay rising

edge w.r.t. falling edge

See Fig.2

trec_sym= (trec_pdf -trec_pdr)

-2 2 µs

2.15 ttrans_sym Symmetry of transmitter

propagation delay rising

edge w.r.t. falling edge

See Fig.2

ttrans_sym = (ttrans_pdf -ttrans_pdr)

-2 2 µs

2.16 tLINgs Bus wake-up glitch

suppression time

See Fig.3 VLIN = VLINLow 40 100 µs

3Transmission Input TxD

3.1 VTxDLow Input Voltage dominant

state

1.5 V

3.2 VTxDHigh Input Voltage recessive

state

3.5 V

3.3 RTxD TxD pull up resistor 5 10 25 KΩ

4Receive Output RxD

4.1 VRxDLow Output Voltage dominant

state

IRxD = 2mA 1.5 V

4.2 VRxDHigh Output Voltage recessive

state

IRxD≥10µA4.5V

4.3 RRxD RxD pull up resistor 5 10 25 kΩ

5Inhibit Output INH

5.1 RON(INH) Switch on resistance

between Vs and INH

IINH=-15mA; Vs=13.5V 20 40 Ω

5.2 ION(INH) INH output current Normal or stand-by mode 15 30 50 mA

5.3 ROFF(INH) Switch off INH pull down

resistor

51025kΩ

6Wake Up Input WUP

6.1 VWUPLow Low level input voltage 1.5 V

6.2 VWUPHigh High level input voltage 3.5 Vs+0.

Table 5. Electrical Characteristics (continued)

(VS = 6V to 26V; TJ = -40 to 150 °C unless otherwise specified)

Item Symbol Parameter Test Condition Min. Typ. Max. Unit

5/14

L9638

Note: 1. Room temperature evaluated - no 100% tested

6.3 tWUPgs Remote wake-up delay time Transitioning on WUP 40 100 µs

7Enable Input EN

7.1 VENLow Low level input voltage 1.5 V

7.2 VENHigh High level input voltage 3.5 V

7.3 REN EN pull down resistor 5 10 25 KΩ

7.4 tgts Go to sleep delay time VEN = VENlow 40 100 µs

7.5 tENgs EN wake-up glitch

suppression time

VEN = VENhigh 40 100 µs

8AC Timing Parameters

8.1 D1 Duty Cycle 1 THRec(max) = 0.744 x VSUP;

THDom(max) = 0.581 x VSUP;

Vsup = 7.0 to 18V; tbit = 50µs;

D1 = tBus_rec(min)/2 x tBit

(CBUS; RBUS) 1nF; 1kΩ/6.8nF;

660Ω/10nF; 500Ω

0.396

8.2 D2 Duty Cycle 2 THRec(min) = 0.284 x VSUP;

THDom(min) = 0.422 x VSUP;

Vsup = 7.6 to 18V; tbit = 50µs;

D2 = tBus_rec(min)/2 x tBit

(CBUS; RBUS) 1nF; 1kΩ/6.8nF;

660Ω/10nF; 500Ω

0.581

8.3 D3 Duty Cycle 3 THRec(max) = 0.778 x VSUP;

THDom(max) = 0.616 x VSUP;

Vsup = 7.0 to 18V; tbit = 96µs;

D3 = tBus_rec(min)/2 x tBit

(CBUS; RBUS) 1nF; 1kΩ/6.8nF;

660Ω/10nF; 500Ω

0.417

8.4 D4 Duty Cycle 4 THRec(min) = 0.251 x VSUP;

THDom(min) = 0.389 x VSUP;

Vsup = 7.6 to 18V; tbit = 96µs;

D4 = tBus_rec(min)/2 x tBit

(CBUS; RBUS) 1nF; 1kΩ/6.8nF;

660Ω/10nF; 500Ω

0.591

9Fault Conditions

9.1 ILIN_NO_GND LIN current with GND

disconnected

GND = Vs = 12V

0V< VLIM < 18V (1)

-1 1 mA

9.2 ILIN_NO_Vs LIN current with VS

grounded

V = GND, 0V < VLIN < 18V

(1)

100 µA

Table 5. Electrical Characteristics (continued)

(VS = 6V to 26V; TJ = -40 to 150 °C unless otherwise specified)

Item Symbol Parameter Test Condition Min. Typ. Max. Unit

L9638

6/14

3 TIMING DIAGRAM

Figure 3. Definition of Bus Timing Parameters

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L9638

Figure 4. Typical Bus Timing

Figure 5. Typical Wake-up Timing

VTxD

VLIN

VRxD

ttrans_pdf ttrans_pdr

Receive Dominant Threshold

Receive Recessive Threshold

trec_pdr

trec_pdf

90%

10%

VTxD

VLIN

VRxD

ttrans_pdf ttrans_pdr

Receive Dominant Threshold

Receive Recessive Threshold

trec_pdr

trec_pdf

90%

10%

VLIN

t<tLINgs gstLIN

VRxD

VINH

L9638

8/14

4 FUNCTIONAL DESCRIPTION

The L9638 is a monolithic bus driver designed to provide bidirectional serial communication in Local In-

terconnect Network (LIN).

In addition to the integrated physical layer (specified in LIN specification rev. 2.0), further control in- and

output functions simplify various system requirements like controlled power saving modes or additional

external wake up capability.

4.1 Operating modes

There are four possible modes of operation: normal, standby, sleep and short circuit. The transitions be-

tween the various operation modes are described in the diagram.

4.2 Standby mode

This mode is reached after power up the system or due to a received wake-up condition from sleep mode.

The device is able to receive at RxD, but could not transmit any data. This prevents the disturbance of the

LIN bus line due to a not correctly working µC. Entering the standby mode, the INH output will set to HIGH

by simultaneous switching off the internal pull down resistor to reduce the current consumption. This al-

lows the control of connected power supply devices.

Therefore for systems, that will be controlled only by the LIN bus line (particular ECUs, that works as slave

node) a power management can easy build up on that function. It is recommended to power up the sys-

tem before the communication will start, otherwise additional delay times have to be regarded.

Because of integrated filtering of external WUP input, the INH output can alternatively be used to simplify

a software filtering procedure to detect an external edge sensitive signal by connecting INH versus a se-

ries resistor to an interrupt capable input of the µC.

4.3 Normal mode

This mode can only be reached from standby or sleep mode by setting the EN input to HIGH. Transmis-

sion and receiving of data stream via the LIN line is possible. An integrated pull up resistor in series with

a diode at LIN provides either required recessive state (HIGH) as well as a protection against reverse pow-

er supply. In master node application, a LOW ohmic resistor in series with a diode has to be connected

externally between LIN and battery to allow the maximum transmission rate.

The receiver converts the battery supply related signal at LIN to a logic supply compatible output at RxD.

Integrated filter in addition with the supply voltage related threshold and hysteresis provide optimal noise

suppression.

The transmitter shifts the logic supply related data stream at TxD to battery level at LIN. A read back func-

tion is possible by evaluating the mirrored state from the LIN line at the output RxD.

4.4 Short circuit mode

The L9638 provides a special operation mode for shorted LIN bus lines to ground. In that case, the whole

LIN network is blocked. If the protocol handler in the µC detects a "time out" condition, that could be un-

ambiguously identified as a short to ground condition in the bus line, the whole LIN node could be discon-

nected from the network by setting EN input to LOW.

This will switch INH output from active HIGH to LOW. Additionally RxD output, that remains in the domi-

nant state and maybe block the µC will set to HIGH ohmic state.

The L9638 won't accept any transition at TxD. This short circuit mode will be stable until the dominant state

on LIN will be cleared. In that case, the device will switch to the sleep mode. According to that, the current

consumption of a blocked LIN network will be reduced to the resulting short circuit current in the LIN line.

Especially for sporadically happening shorts due to damaged cable isolation, the LIN network will be au-

tomatically reset. Therefore no special power up procedure is required.

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L9638

4.5 Sleep mode

This mode allows the lowest current consumption of the transceiver. It'll be reached either by setting the

EN input to LOW (assuming no occurring wake-up event) while being in the normal mode or in case of a

removed short to ground at LIN while being in the short circuit mode.

The INH output will be switched from HIGH to LOW. A further transmission via TxD is prevented. The de-

vice is waiting on any wake-up requests either by LIN (dominant level) or WUP (rising or falling edge). This

will set the device from sleep mode to standby mode. An implemented filter prevents unwished wake-ups

due to occurring glitches or EMI at LIN or WUP.

4.6 Wake-up

The L9638 provides several wake-up conditions from sleep mode:

– Remote wake-up by a dominant level at LIN

– Local wake-up by a falling or rising edge at WUP

– Mode change by setting EN to HIGH

The INH output will be set from LOW to HIGH after each kind of valid wake-up conditions. For remote

wake-up via LIN, RxD will be activated and set as well to a dominant state.

This allows fast reaction for powered µC with connected interrupt capable receive inputs.

4.7 Fail-safe features

To prevent possible states, that will block the communication line in case of a failed µC operation, the

L9638 has implemented some special fail-safe features:

– After detected a clear short to ground state at the LIN pin by the protocol handler in the µC, the trans-

ceiver or the complete power supply of the ECU control logic could be switched off by setting the EN

input from HIGH to LOW. The device will stay in that special short circuit mode until the state of the

LIN bus will switch back from dominant to recessive. No power up or special reset procedures are

required to clear that fail-safe state. L9638 could be reactivated with the usual wake-up signals.

– The TxD and EN inputs support default recessive bus states by internal pull up or down sources

– The output stage of the transmitter is current limited to protect against a shorten LIN to battery

– A thermal shutdown protects the device against over temperature caused destruction. In case of a

permanent overload condition, the output stage will be switched off after reaching the shut down tem-

perature and reactivated after cooling down to the switch on temperature.

– Defined output status in under voltage, loss of Vs or GND condition with no impact to the bus line or

the connected µC

L9638

10/14

Figure 6. State Diagram

0 0 float 0 1 Vs

NORMAL

WUP

LIN

Power-up

1 1 float 1 1 Vs

mode

1 0 float 0 1 Vs

1 1 float 1 1 Vs

HiZ HiZ X 0 0 0

SHORT CIRCUIT

TxD RxD WUP LIN EN INH

HiZ HiZ X 1 0 0

SLEEP

float 0 float 0 0 Vs

STANDBY

(with LIN=1)

if t(EN=0 after 1->0)

>tgts

and no wake up event

TxD RxD WUP LIN EN INH

float 1 float 1 0 Vs

don’t

care, input signal is stable high or low

HiZ

internal pull up is switched off;

TxD

input signal may be high or low or transitioning

RxD

output signal is high impedance.

float

input signal may be high or low or transitioning

if t(EN=1 after 0->1)

>tENgs

(with LIN=0)

if t(EN=0 after 1->0)

>tgts

if t(LIN=0 after 1->0)

>tLINgs

tdelay

=tWUPgs

if (LIN=1)

0 0 float 0 1 Vs

NORMAL

WUP

LIN

Power-up

1 1 float 1 1 Vs

mode

1 0 float 0 1 Vs

1 1 float 1 1 Vs

HiZ HiZ X 0 0 0

SHORT CIRCUIT

TxD RxD WUP LIN EN INH

HiZ HiZ X 1 0 0

SLEEP

float 0 float 0 0 Vs

STANDBY

(with LIN=1)

if t(EN=0 after 1->0)

>tgts

and no wake up event

TxD RxD WUP LIN EN INH

float 1 float 1 0 Vs

don’t

care, input signal is stable high or low

HiZ

internal pull up is switched off;

TxD

input signal may be high or low or transitioning

RxD

output signal is high impedance.

float

input signal may be high or low or transitioning

if t(EN=1 after 0->1)

>tENgs

(with LIN=0)

if t(EN=0 after 1->0)

>tgts

if t(LIN=0 after 1->0)

>tLINgs

tdelay

=tWUPgs

if (LIN=1)

11/14

L9638

Figure 7. Typical Application Circuit

WUP

TXD

INH

RXD

GND

LIN

L9638D

VCR

RES

GND

L4979D

VCW

µC

TXD

RXD

GND

RES

VCC

VBAT

CTW

CTR

CLIN

EXTERNAL

SWITCH

RSRLIN

LIN

BUS

Suggested Values

CS =100 nF CTW = 47 nF CLIN_MASTER = 1 nF RS = 100 kΩ

CTR = 1 nF CO = 10 µF CLIN_SLAVE = 220 pF RLIN = 1 kΩ

L9638

12/14

OUTLINE AND

MECHANICAL DATA

DIM.

mm inch

MIN. TYP. MAX. MIN. TYP. MAX.

A 1.35 1.75 0.053 0.069

A1 0.10 0.25 0.004 0.010

A2 1.10 1.65 0.043 0.065

B 0.33 0.51 0.013 0.020

C 0.19 0.25 0.007 0.010

(1)

4.80 5.00 0.189 0.197

E 3.80 4.00 0.15 0.157

e 1.27 0.050

H 5.80 6.20 0.228 0.244

h 0.25 0.50 0.010 0.020

L 0.40 1.27 0.016 0.050

k 0˚ (min.), 8˚ (max.)

ddd 0.10 0.004

Note: (1) Dimensions D does not include mold flash, protru-

sions or gate burrs.

Mold flash, potrusions or gate burrs shall not exceed

0.15mm (.006inch) in total (both side).

SO-8

0016023 C

13/14

L9638

Table 6. Revision History

Date Revision Description of Changes

April 2004 1 First Issue

April 2004 2 Changed maturity from Product Preview in Final;

Corrected Order Codes;

Changed min. value of the item 1.4 of the Table 4 in the page 3.

October 2004 3 Add VESD in table 3;

Changed numbers item of the table 5 and add item 9

October 2004 4 Updated figure 7 on page11/14.

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to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not

authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.

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L9638