Datasheet TLE 6250 V33 Datasheet (lnfineon)

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CAN-Transceiver TLE 6250

TLE 6250 V33

Final Data Sheet

Features

• CAN data transmission rate up to 1 MBaud

• Suitable for 12 V and 24 V applications

• Excellent EMC performance (very high immunity and
very low emission)

• Version for 5 V and 3.3 V micro controllers

• Bus pins are short circuit proof to ground and battery
voltage

• Over-temperature protection

• Very wide temperature range (- 40°C up to 150°C)

P-DSO-8-3

Type Ordering Code Package

TLE 6250 G Q67006-A9427 P-DSO-8-3

TLE 6250 C Q67000-A9594 (chip)

TLE 6250 G V33 Q67006-A9523 P-DSO-8-3

TLE 6250 C V33 Q67000-A9538 (chip)

Description

The CAN-transceiver TLE 6250 is a monolithic integrated circuit that is available as bare
die as well as in a P-DSO-8-3 package. The IC is optimized for high speed differential
mode data transmission in automotive and industrial applications and is compatible to
ISO/DIS 11898 (see page 12 and 20). It works as an interface between the CAN protocol
controller and the physical differential bus in both, 12 V and 24 V systems.

Note:
There are two versions available: one for 5 V logic and the other one for 3.3 V logic
requiring additional supply via the V

pin. The IC can be set to stand-by mode via an

33V

control input. In addition the 5 V-version offers a receive only mode feature to support
diagnostic functions.



The IC is based on the Smart Power Technology SPT

which allows bipolar and CMOS
control circuitry in accordance with DMOS power devices existing on the same
monolithic circuit. The TLE 6250 is designed to withstand the severe conditions of
automotive applications and provides excellent EMC performance.

Data Sheet Version 3.4 1 2002-10-08

TLE 6250

TLE 6250 V33

TxD

GND

CC

RxD

1

2

P-DSO-8-3

3

4

8

7

6

5

INH

CANH

CANLV

RM

TLE 6250 G

Figure 1 Pin Configuration (top view)

Pin Definitions and Functions

TxD

GND

CC

RxD

1

2

P-DSO-8-3

3

4

TLE 6250 GV33

8

7

6

5

INH

CANH

CANLV

V

33V

Pin No. Symbol Function

1TxDCAN transmit data input; 20 k

Ω pull up, LOW in dominant state

2GNDGround;

3V

CC

5 V Supply;

4RxDCAN receive data output; LOW in dominant state,

integrated pull up

5RMReceive-only input; (5 V-version), 20 k

Ω pull up, set low to

activate RxD-only mode

V

33V

Logic supply; (3.3 V-version) 3.3 V OR 5V microcontroller logic
supply can be connected here! The digital I/Os of the TLE6250V33
adopt to the connected microcontroller logic supply at V

6CANLLow line input; LOW in dominant state

7CANHHigh line output; HIGH in dominant state

8INHControl input; 20 kΩ pull, set LOW for normal mode

33V

Data Sheet Version 3.4 2 2002-10-08

Functional Block Diagram

TLE 6250

TLE 6250 V33

CANH

CANL

GND

TLE 6250 G

7

6

2

Output

Stage

=

Driver

Temp.-

Protection

Mode Control

Receiver

3

1

8

5

4

AEB02922

V

CC

TxD

INH

RM

RxD

Figure 2 Block Diagram TLE 6250 G

Data Sheet Version 3.4 3 2002-10-08

TLE 6250

TLE 6250 V33

CANH

CANL

GND

TLE 6250 G V33

7

6

2

Output

Stage

=

Driver

Temp.-

Protection

Mode Control

Receiver

3

5

1

8

4

AEB02923

V

CC

V

3.3 V

TxD

INH

RxD

Figure 3 Block Diagram TLE 6250 G V33

Data Sheet Version 3.4 4 2002-10-08

Application Information

TLE 6250

TLE 6250 V33

INH = 1

INH = 0
and RM = 1

Stand-by Mode

RM = 0 / 1

Normal Mode

INH = 0 RM = 1

INH = 0
and RM = 0

INH = 1

RM = 0

RM = 1

Receive-only Mode

INH = 0

RM = 0INH = 1

AED02924

Normal Mode

INH = 0

INH=1 INH=0

Stand-by

Mode

INH = 1

5V Version 3.3V Version

Figure 4 Mode State Diagram

Both, the TLE 6250 G as well as the TLE 6250 C offer three different operation modes
(see Figure 4), controlled by the INH and RM pin for the TLE6250 and only by the INH
pin for the 6250 V33. In the normal mode the device is able to receive and to transmit
messages whereas in the receive-only mode signals at the TxD input are not transmitted
to the CAN bus. The receive-only mode can be used for diagnostic purposes as well as
to prevent the bus being blocked by a faulty permanent dominant TxD input signal. The
stand-by mode is a low power mode that disables both, the receiver as well as the
transmitter. For the TLE 6250 G V33 and TLE 6250 C V33 the receive only mode
feature is not available. The inhibit feature for this versions works in the same way as for
the 5V versions.

In case the receive-only feature is not used the RM pin has to be left open. When the
stand-by mode is not used the INH pin has to be connected to ground level in order to
switch the TLE 6250 in normal mode.

Data Sheet Version 3.4 5 2002-10-08

TLE 6250

Application Information for the 3.3V Version

The TLE 6250V33 can be used for both; 3.3V and 5V microcontroller logic supply as
shown below. Don´t apply external resistors between the power supply and this pin. This
may cause a voltage drop and so reduce the available voltage at this pin.

TLE 6250 G V33

7

CANH

CANL

6

100

nF

22 µF

GND

2

V

I

e.g. TLE 4476

GND

INH

8

RxD

4

1

TxD

V

5

33V

V

3

CC

100 nF 100 nF

V

Q1

V

Q2

22 µF

3.3V

µP

GND

100 nF

5V

3.3V

22 µF

22 µF

TLE 6250 G V33

7

CANH

CANL

6

V

I

100

nF

RxD

GND

2

e.g. TLE 4270

GND

INH

TxD

V

V

33V

V

CC

100 nF

Q

8

4

1

5V

5

3

100 nF

5V

22 µF

Application with 3.3V I/O supply Application with 5V I/O supply

µP

GND

Data Sheet Version 3.4 6 2002-10-08

Electrical

TLE 6250

Characteristics

TLE6250 G

(5V Version)

Data Sheet Version 3.4 7 2002-10-08

Electrical Characteristics

Absolute Maximum Ratings

Parameter Symbol Limit Values Unit Remarks

min. max.

Voltages

TLE 6250

Supply voltage

CAN input voltage

V

CC

V

CANH/L

– 0.3 6.5 V –

– 40 40 V –

(CANH, CANL)

Logic voltages at

V

I

– 0.3 V

CC

V0 V < VCC < 5.5 V

INH, RM, TxD, RxD

Electrostatic discharge
voltage at CANH,CANL

Electrostatic discharge
voltage

V

V

ESD

ESD

– 6 6 kV human body model

(100 pF via 1.5 k

Ω)

– 2 2 kV human body model

(100 pF via 1.5 k

Ω)

Temperatures

Junction temperature

T

j

– 40 160 °C –

Note: Maximum ratings are absolute ratings; exceeding any one of these values may

cause irreversible damage to the integrated circuit.

Data Sheet Version 3.4 8 2002-10-08

Operating Range

Parameter Symbol Limit Values Unit Remarks

min. max.

TLE 6250

Supply voltage

Junction temperature

V

T

CC

j

4.5 5.5 V –

– 40 150 °C –

Thermal Resistances

Junction ambient

R

thj-a

– 185 K/W –

Thermal Shutdown (junction temperature)

Thermal shutdown

T

jsD

160 200 °C10 °C hysteresis

temperature

Data Sheet Version 3.4 9 2002-10-08

Electrical Characteristics

TLE 6250

4.5 V <

V

<5.5V; RL=60Ω; V

CC

INH

< V

; – 40 °C < Tj < 150 °C; all voltages with

INH,ON

respect to ground; positive current flowing into pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

Current Consumption

Current consumption

Current consumption I

Current consumption

I

CC

CC

I

CC

– 6 10 mA recessive state;

V

= V

TxD

CC

– 45 70 mA dominant state;

V

= 0 V

TxD

– 6 10 mA receive-only mode;

RM = low

Current consumption

I

CC,stb

– 110µA stand-by mode;

TxD = RM = high

Receiver Output R

×D

HIGH level output
current

LOW level output
current

Transmission Input T×D

HIGH level input voltage
threshold

LOW level input voltage
threshold

TxD pull up resistance

note1) V

diff

= V

CANH

– V

CANL

I

RD,H

I

RD,L

V

V

R

TD,H

TD,L

TD

– -4 -2 mA VRD = 0.8 × VCC,

V

diff

< 0.4 V

note 1)

24– mA VRD = 0.2 × VCC,

note 1)

– 0.5×

V

CC

0.3×
V

CC

0.4×
V

CC

V

> 1 V

diff

0.7×
V

CC

V recessive state;

– V dominant state

10 25 50 kΩ –

Data Sheet Version 3.4 10 2002-10-08

TLE 6250

Electrical Characteristics (cont’d)

V

4.5 V <

<5.5V; RL=60Ω; V

CC

respect to ground; positive current flowing into pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

Inhibit Input (pin INH)

INH

< V

; – 40 °C < Tj < 150 °C; all voltages with

INH,ON

min. typ. max.

HIGH level input voltage

V

INH,H

– 0.5×

threshold

LOW level input voltage
threshold

INH pull up resistance

V

R

INH,L

INH

0.3×
V

CC

10 25 50 kΩ –

Receive only Input (RM) (5V version only)

HIGH level input voltage

V

RM,H

– 0.5×

threshold

LOW level input voltage
threshold

RM pull up resistance

V

R

RM,L

RM

0.3×
V

CC

10 25 50 kΩ –

V

CC

0.4×
V

CC

V

CC

0.4×
V

CC

0.7×
V

CC

V stand-by mode;

– V normal mode

0.7×
V

CC

V normal mode;

– V receive-only mode

Data Sheet Version 3.4 11 2002-10-08

TLE 6250

Electrical Characteristics (cont’d)

V

4.5 V <

<5.5V; RL=60Ω; V

CC

respect to ground; positive current flowing into pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

Bus Receiver

INH

< V

; – 40 °C < Tj < 150 °C; all voltages with

INH,ON

min. typ. max.

Differential receiver
threshold voltage,
recessive to dominant

V

diff,d

– 0.75 0.90 V – 20 V < (V

V
V

CANL

= V

diff

) < 25 V

CANH

edge

Differential receiver
threshold voltage
dominant to recessive

V

diff,r

0.50 0.60 – V – 20 V < (V

V
V

CANL

= V

diff

) < 25 V

CANH

edge

Common Mode Range CMR -20 – 25 V VCC = 5V

Differential receiver

V

diff,hys

– 150 – mV –

hysteresis

CANH, CANL input

R

i

10 20 30 kΩ recessive state

resistance

Differential input

R

diff

20 40 60 kΩ recessive state

resistance

CANH

– V

CANH

– V

,

CANL

,

CANL

Data Sheet Version 3.4 12 2002-10-08

Electrical Characteristics (cont’d)

TLE 6250

4.5 V <

V

<5.5V; RL=60Ω; V

CC

INH

< V

; – 40 °C < Tj < 150 °C; all voltages with

INH,ON

respect to ground; positive current flowing into pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

Bus Transmitter

CANL/CANH recessive
output voltage

CANH, CANL recessive

V

CANL/H

V

diff

0.4 ×

V

CC

– 0.6 ×

V

CC

V V

- 1 – 0.05 V V

TxD

TxD

= V

= V

CC

CC

output voltage difference

V

= V

diff

no load; (see note 2)

CANL dominant output
voltage

CANH dominant output
voltage

CANH

– V

CANL

V

V

CANL

CANH

––2.0 V V

V

2.8 ––V V

V

TxD

= 5 V

CC

TxD

= 5 V

CC

= 0 V;

= 0 V;

CANH, CANL dominant
output voltage difference

V

diff

= V

CANH

– V

CANL

CANL short circuit
current

CANH short circuit
current

CANH short circuit
current

Output current

Output current

V

diff

I

CANLsc

I

CANHsc

I

CANHsc

I

CANH,lk

I

CANH,lk

1.5 – 3.0 V V

50 120 200 mA V

– 150 – mA

-200 -120 -50 mA V

– -120 – mA V

= 0 V;

TxD

V

= 5 V

CC

CANLshort

V

CANLshort

CANHshort

CANHshort

= 18 V

= 36 V

= 0 V

= -5 V

-50 -300 -400 µA VCC=0V, V

-50 -100 -150

V

µA V

V

CANL

=0V, V

CC

CANL

= -7 V

= -2 V

50 280 400 µA VCC=0V, V

50 100 150

V

µA V

V

CANL

=0V, V

CC

CANL

= 7 V

= 2 V

CANH

CANH

CANH

CANH

=

=

=

=

note 2) deviation from ISO/DIS 11898

Data Sheet Version 3.4 13 2002-10-08

Electrical Characteristics (cont’d)

TLE 6250 V33

4.5 V <

V

<5.5V; RL=60Ω; V

CC

INH

< V

; – 40 °C < Tj < 150 °C; all voltages with

INH,ON

respect to ground; positive current flowing into pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

Dynamic CAN-Transceiver Characteristics

Propagation delay
TxD-to-RxD LOW
(recessive to dominant)

Propagation delay
TxD-to-RxD HIGH
(dominant to recessive)

Propagation delay
TxD LOW to bus

t

d(L),TR

t

d(H),TR

t

d(L),T

– 150 280 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

– 150 280 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

– 100 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V

L

dominant

Propagation delay
TxD HIGH to bus

t

d(H),T

– 100 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V

L

recessive

Propagation delay
bus dominant to RxD
LOW

Propagation delay
bus recessive to RxD
HIGH

1)

t

d(L),R

t

d(H),R

– 50 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

– 50 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

Data Sheet Version 3.4 14 2002-10-08

Electrical

TLE 6250 V33

Characteristics

TLE6250 GV33

(3.3V Version)

Data Sheet Version 3.4 15 2002-10-08

TLE 6250 V33

Electrical Characteristics

Absolute Maximum Ratings

Parameter Symbol Limit Values Unit Remarks

min. max.

Voltages

Supply voltage

3.3 V supply

CAN input voltage

V

CC

V

33V

V

CANH/L

– 0.3 6.5 V –

– 0.3 5.5 V –

– 40 40 V –

(CANH, CANL)

Logic voltages at

V

I

– 0.3 V

CC

V0 V < VCC < 5.5 V

INH, RM, TxD, RxD

Electrostatic discharge
voltage at CANH,CANL

Electrostatic discharge
voltage

V

V

ESD

ESD

– 6 6 kV human body model

(100 pF via 1.5 k

Ω)

– 2 2 kV human body model

(100 pF via 1.5 k

Ω)

Temperatures

Junction temperature

T

j

– 40 160 °C –

Note: Maximum ratings are absolute ratings; exceeding any one of these values may

cause irreversible damage to the integrated circuit.

Data Sheet Version 3.4 16 2002-10-08

TLE 6250 V33

Operating Range

Parameter Symbol Limit Values Unit Remarks

min. max.

Supply voltage

3.3 V supply voltage

Junction temperature

V

V

T

CC

33V

j

4.5 5.5 V –

3.0 5.5 V –

– 40 150 °C –

Thermal Resistances

Junction ambient

R

thj-a

– 185 K/W –

Thermal Shutdown (junction temperature)

Thermal shutdown

T

jsD

160 200 °C10 °C hysteresis

temperature

Data Sheet Version 3.4 17 2002-10-08

Electrical Characteristics

TLE 6250 V33

4.5 V <
– 40

V

CC

°C < T

< 5.5 V; (3.0 V < V
< 150 °C; all voltages with respect to ground; positive current flowing into

j

< 3.6 V for 3.3 V version); RL=60Ω; V

33V

INH

pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

Current Consumption (3.3V version)

Current consumption

Current consumption I

Current consumption

Current consumption

I

CC+33V

CC+33V

I

33V

I

CC+33V,stb

– 6 10 mA recessive state;

V

= V

TxD

– 45 70 mA dominant state;

V

= 0 V

TxD

––2mA

– 110µA stand-by mode

TxD = high

Receiver Output R

×D

33V

< V

INH,ON

;

HIGH level output
current

LOW level output current I

Transmission Input T×D

HIGH level input voltage
threshold

LOW level input voltage
threshold

TxD pull up resistance

note1) V

diff

= V

CANH

– V

CANL

I

RD,H

RD,L

V

V

R

TD,H

TD,L

TD

– -2 -1 mA VRD = 0.8 × V

V

diff

< 0.4 V

note 1)

12– mA VRD = 0.2 × V

note 1)

– 0.55×

V

33V

0.3×
V

33V

0.45×
V

33V

V

> 1 V

diff

0.7×
V

33V

V recessive state;

– V dominant state;

10 25 50 kΩ –

33V

33V

,

,

Data Sheet Version 3.4 18 2002-10-08

TLE 6250 V33

Electrical Characteristics (cont’d)

V

4.5 V <

°C < T

– 40

< 5.5 V; (3.0 V < V

CC

< 150 °C; all voltages with respect to ground; positive current flowing into

j

pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

Inhibit Input (pin INH)

< 3.6 V for 3.3 V version); RL=60Ω; V

33V

min. typ. max.

INH

< V

INH,ON

;

HIGH level input voltage
threshold

LOW level input voltage
threshold

INH pull up resistance

V

V

R

INH,H

INH,L

INH

– 0.55×

V

33V

0.3×
V

33V

0.45×
V

33V

0.7×
V

33V

V stand-by mode;

– V normal mode;

10 25 50 kΩ –

Data Sheet Version 3.4 19 2002-10-08

TLE 6250 V33

Electrical Characteristics (cont’d)

V

4.5 V <

°C < T

– 40

< 5.5 V; (3.0 V < V

CC

< 150 °C; all voltages with respect to ground; positive current flowing into

j

pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

Bus Receiver

< 3.6 V for 3.3 V version); RL=60Ω; V

33V

min. typ. max.

INH

< V

INH,ON

;

Differential receiver
threshold voltage,
recessive to dominant

V

diff,d

– 0.75 0.90 V – 20 V < (V

V
V

CANL

= V

diff

) < 25 V

CANH

edge

Differential receiver
threshold voltage
dominant to recessive

V

diff,r

0.50 0.60 – V – 20 V < (V

V
V

CANL

= V

diff

) < 25 V

CANH

edge

Common Mode Range CMR -20 – 25 V VCC = 5V

Differential receiver

V

diff,hys

– 150 – mV –

hysteresis

CANH, CANL input

R

i

10 20 30 kΩ recessive state

resistance

Differential input

R

diff

20 40 60 kΩ recessive state

resistance

CANH

– V

CANH

– V

,

CANL

,

CANL

Data Sheet Version 3.4 20 2002-10-08

Electrical Characteristics (cont’d)

TLE 6250 V33

4.5 V <
– 40

V

CC

°C < T

< 5.5 V; (3.0 V < V
< 150 °C; all voltages with respect to ground; positive current flowing into

j

< 3.6 V for 3.3 V version); RL=60Ω; V

33V

INH

pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

min. typ. max.

Bus Transmitter

CANL/CANH recessive
output voltage

CANH, CANL recessive

V

CANL/H

V

diff

0.4 ×

V

CC

– 0.6 ×

V

CC

V V

- 1 – 0.05 V V

TxD

TxD

= V

= V

output voltage difference

V

= V

diff

no load; (see note 2)

CANL dominant output
voltage

CANH dominant output
voltage

CANH

– V

CANL

V

V

CANL

CANH

––2.0 V V

V

2.8 ––V V

V

TxD

= 5 V

CC

TxD

= 5 V

CC

= 0 V;

= 0 V;

33V

33V

< V

INH,ON

;

CANH, CANL dominant
output voltage difference

V

diff

= V

CANH

– V

CANL

CANL short circuit
current

CANH short circuit
current

CANH short circuit
current

Output current

Output current

V

diff

I

CANLsc

I

CANHsc

I

CANHsc

I

CANH,lk

I

CANH,lk

1.5 – 3.0 V V

50 120 200 mA V

– 150 – mA

-200 -120 -50 mA V

– -120 – mA V

= 0 V;

TxD

V

= 5 V

CC

CANLshort

V

CANLshort

CANHshort

CANHshort

= 18 V

= 36 V

= 0 V

= -5 V

-50 -300 -400 µA VCC=0V, V

-50 -100 -150

V

µA V

V

CANL

=0V, V

CC

CANL

= -7 V

= -2 V

50 280 300 µA VCC=0V, V

50 100 150

V

µA V

V

CANL

=0V, V

CC

CANL

= 7 V

= 2 V

CANH

CANH

CANH

CANH

=

=

=

=

note 2) deviation from ISO/DIS 11898

Data Sheet Version 3.4 21 2002-10-08

TLE 6250 V33

Electrical Characteristics (cont’d)

V

4.5 V <

°C < T

– 40

< 5.5 V; (3.0 V < V

CC

< 150 °C; all voltages with respect to ground; positive current flowing into

j

pin; unless otherwise specified.

Parameter Symbol Limit Values Unit Remarks

Dynamic CAN-Transceiver Characteristics

< 3.6 V for 3.3 V version); RL=60Ω; V

33V

min. typ. max.

INH

TLE 6250

< V

INH,ON

;

Propagation delay
TxD-to-RxD LOW
(recessive to dominant)

Propagation delay
TxD-to-RxD HIGH
(dominant to recessive)

Propagation delay
TxD LOW to bus
dominant

Propagation delay
TxD HIGH to bus
recessive

Propagation delay
bus dominant to RxD
LOW

Propagation delay
bus recessive to RxD
HIGH

t

d(L),TR

t

d(H),TR

t

d(L),T

t

d(H),T

t

d(L),R

t

d(H),R

– 150 280 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

– 150 280 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

– 100 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V

L

– 100 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V

L

– 50 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

– 50 140 ns CL = 47 pF;

R

= 60 Ω; VCC = 5 V;

L

C

= 20 pF

RxD

Data Sheet Version 3.4 22 2002-10-08

Diagrams

TLE 6250

TLE 6250 V33

8

INH

TxD

RM

RxD

V

CC

1

5

4

20 pF

3

5 V

47 pFΩ60

7

6

47 pF 60

7

Ω

6

CANH

CANL

GND

2

5V Version 3.3V Version

Figure 5 Test Circuits for Dynamic Characteristics

CANH

CANL

GND

2

INH

TxD

RxD

V

3.3V

V

CC

8

1

4

20 pF

5

3

3.3 V

100 nF

5 V

100 nF100 nF

AES02925

Data Sheet Version 3.4 23 2002-10-08

V

TxD

V

CC(33V)

GND

TLE 6250

TLE 6250 V33

V

DIFF

V

RxD

V

CC(33V)

t

d(L), T

V

DIFF(d)

t

d(L), R

0.3

V

CC(33V)

t

d(H), T

V

DIFF(r)

t

d(H), R

GND

t

d(L), TR

t

d(H), TR

Figure 6 Timing Diagrams for Dynamic Characteristics

0.7

V

CC(33V)

t

t

t

AET02926

Data Sheet Version 3.4 24 2002-10-08

Application

TLE 6250

TLE 6250 V33

120 Ω

V

Bat

CAN
Bus

7

6

CANH

CANL

V

I

TLE 6250 G

RM

INH

RxD

TxD

GND

V

2

V

CC

Q

5

8

4

1

3

100 nF

µP

GND

100 nF

5 V

e.g. TLE 4270

22 µF 100 nF

GND

22 µF

ECU 1

120 Ω

7

6

22 µF 100 nF

TLE 6250 G V33

RxD

CANH

CANL

V

GND

2

V

I

e.g. TLE 4476

GND

8

INH

4

1

TxD

5

3.3 V

V

CC

100 nF

V

Q1

V

Q2

µP

100 nF100 nF

GND

5 V

3.3 V

22 µF22 µF

ECU X

AES02927

Figure 7 Application Circuit

Data Sheet Version 3.4 25 2002-10-08

Package Outlines

P-DSO-8-3

(Plastic Dual Small Outline Package)

TLE 6250

TLE 6250 V33

Sorts of Packing

Package outlines for tubes, trays etc. are contained in our
Data Book “Package Information”

SMD = Surface Mounted Device

GPS09032

Dimensions in mm

Data Sheet Version 3.4 26 2002-10-08

Edition 2002-10-08

Published by Infineon Technologies AG,
St.-Martin-Strasse 53,
D-81541 München, Germany

© Infineon Technologies AG 2002.

All Rights Reserved.

Attention please!

The information herein is given to describe
certain components and shall not be consid­ered as warranted characteristics.

Terms of delivery and rights to technical
change reserved.

We hereby disclaim any and all warranties,
including but not limited to warranties of
non-infringement, regarding circuits, descrip­tions and charts stated herein.

Infineon Technologies is an approved CECC
manufacturer.

TLE 6250

TLE 6250 V33

Information

For further information on technology, deliv­ery terms and conditions and prices please
contact your nearest Infineon Technologies
Office in Germany or our Infineon Technolo­gies Representatives worldwide (see ad­dress list).

Warnings

Due to technical requirements components
may contain dangerous substances. For in­formation on the types in question please
contact your nearest Infineon Technologies
Office.

Infineon Technologies Components may only
be used in life-support devices or systems
with the express written approval of Infineon
Technologies, if a failure of such components
can reasonably be expected to cause the fail­ure of that life-support device or system, or to
affect the safety or effectiveness of that de­vice or system. Life support devices or sys­tems are intended to be implanted in the hu­man body, or to support and/or maintain and
sustain and/or protect human life. If they fail, it
is reasonable to assume that the health of the
user or other persons may be endangered.

Data Sheet Version 3.4 27 2002-10-08