BTS611L1E3128ANTMA1_技术文档

®

PROFET

BTS611L1

Smart Two Channel Highside Power Switch

Features

Product Summary

•

Overload protection

Overvoltage protection V_bb(AZ)

43

V

Current limitation

Short circuit protection

Thermal shutdown

Overvoltage protection (including load dump)

Fast demagnetization of inductive loads

V

5.0 ... 34 V

both

parallel

Operating voltage

bb(on)

channels: each

On-state resistance R_ON

Load current (ISO) I_L(ISO)

200

2.3

4

100

4.4

4

mΩ

A

1

)

Reverse battery protection

Undervoltage and overvoltage shutdown with

auto-restart and hysteresis

Current limitation

I_L(SCr)

A

•

Open drain diagnostic output

Open load detection in ON-state

CMOS compatible input

Loss of ground and loss of V protection

Electrostatic discharge (ESD) protection

TO-220AB/7

bb

7

Application

7

1

•

1

µC compatible power switch with diagnostic

feedback for 12 V and 24 V DC grounded loads

All types of resistive, inductive and capacitve

loads

1

Straight leads

SMD

Standard

Replaces electromechanical relays, fuses and discrete circuits

General Description

N channel vertical power FET with charge pump, ground referenced CMOS compatible input and diagnostic

feedback, monolithically integrated in Smart SIPMOS technology. Providing embedded protective functions.

+ V

bb

4

Current

limit 1

Gate 1

Voltage

source

Overvoltage

protection

V

Logic

OUT1

Limit for

Level shifter

Rectifier 1

Voltage

sensor

unclamped

ind. loads 1

1

7

Temperature

sensor 1

3

6

IN1

IN2

Charge

pump 1

Open load

Short to Vbb

detection 1

Logic

ESD

Charge

pump 2

5

Gate 2

protection

ST

Current

limit 2

OUT2

R

Level shifter

Rectifier 2

Limit for

unclamped

ind. loads 2

Load

Temperature

sensor 2

Open load

R

O1

O2

Short to Vbb

GND

detection 2

GND

PROFET

2

Signal GND

Load GND

1)

With external current limit (e.g. resistor R =150 Ω) in GND connection, resistor in series with ST

GND

connection, reverse load current limited by connected load.

Semiconductor Group

1 of 15

2003-Oct-01

®

PROFET

BTS611L1

1

Symbol

OUT1 (Load, L)

GND

Function

Output 1, protected high-side power output of channel 1

Logic ground

2

3

IN1

Input 1, activates channel 1 in case of logical high signal

4

V

Positive power supply voltage,

the tab is shorted to this pin

bb

Diagnostic feedback: open drain, low on failure

5

6

7

ST

IN2

Input 2, activates channel 2 in case of logical high signal

Output 2, protected high-side power output of channel 2

OUT2 (Load, L)

Maximum Ratings at Tj = 25 °C unless otherwise specified

Parameter

Symbol

Values

Unit

V

Supply voltage (overvoltage protection see page 4)

V_bb

43

34

Supply voltage for full short circuit protection

T_{j Start}=-40 ...+150°C

V

4⁾

Load dump protection²⁾V_LoadDump= U_A+ V_s, U_A= 13.5 V V_{Load dump}

60

V

R_I³⁾= 2 Ω, R_L= 5.3 Ω, t_d= 200 ms, IN= low or high

Load current (Short circuit current, see page 5)

Operating temperature range

Storage temperature range

I_L

self-limited

-40 ...+150

-55 ...+150

A

T_j

T_stg

P_tot

°C

Power dissipation (DC), T_C≤ 25 °C

36

W

Inductive load switch-off energy dissipation, single pulse

V_bb=12V, T_j,start=150°C, T_C=150°C const.

one channel, I_L= 2.3 A, Z_L= 89mH, 0 Ω: E_AS

290

580

mJ

both channels parallel, I_L= 4.4 A, Z_L= 47mH, 0 Ω:

see diagrams on page 9

Electrostatic discharge capability (ESD)

(Human Body Model)

IN: V_ESD

all other pins:

1.0

2.0

kV

acc. MIL-STD883D, method 3015.7 and ESD assn. std. S5.1-1993

Input voltage (DC)

V_IN

I_IN

I_ST

-10 ... +16

±2.0

V

mA

Current through input pin (DC)

Current through status pin (DC)

see internal circuit diagrams page 7

±5.0

2)

Supply voltages higher than V_bb(AZ)require an external current limit for the GND and status pins, e.g. with a

150 Ω resistor in the GND connection and a 15 kΩ resistor in series with the status pin. A resistor for the

protection of the input is integrated.

3)

4)

R = internal resistance of the load dump test pulse generator

V_{Load dump}is setup without the DUT connected to the generator per ISO 7637-1 and DIN 40839

I

Semiconductor Group

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2003-Oct-01

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PROFET

BTS611L1

Thermal Characteristics

Parameter and Conditions

Symbol

Values

Unit

min

typ

max

K/W

Thermal resistance

chip - case, both channels: R_thJC

--

3.5

7.0

75

each channel:

junction - ambient (free air):

SMD version, device on PCB⁵⁾:

R

thJA

37

Electrical Characteristics

Parameter and Conditions, each channel

Symbol

Values

Unit

at Tj = 25 °C, V = 12 V unless otherwise specified

bb

min

--

typ

max

Load Switching Capabilities and Characteristics

On-state resistance (pin 4 to 1 or 7)

R_ON

I_L= 1.8 A

T=25 °C:

j

160

200

400

mΩ

each channel

T=150 °C:

j

320

2.3

4.4

Nominal load current, ISO Norm (pin 4 to 1 or 7)

V_ON= 0.5 V, T = 85 °C each channel: I_L(ISO)

both channels parallel:

1.8

3.5

--

A

C

Output current (pin 1 or 7) while GND disconnected

I_L(GNDhigh)

--

10

mA

or GND pulled up, V =30 V, V = 0, see diagram

bb

IN

page 8

Turn-on time

Turn-off time

IN

to 90% V_OUT: t_on

to 10% V_OUT: t_off

80

200

400

µs

R_L= 12 Ω, T =-40...+150°C

j

Slew rate on

10 to 30% V_OUT, R_L= 12 Ω, T =-40...+150°C

dV /dt_on

-dV/dt_off

0.1

--

1 V/µs

j

Slew rate off

70 to 40% V_OUT, R_L= 12 Ω, T =-40...+150°C

j

Device on 50mm*50mm*1.5mm epoxy PCB FR4 with 6cm²(one layer, 70µm thick) copper area for V

connection. PCB is vertical without blown air.

5)

bb

Semiconductor Group

3

2003-Oct-01

®

PROFET

BTS611L1

Parameter and Conditions, each channel

Symbol

Values

Unit

at Tj = 25 °C, V = 12 V unless otherwise specified

bb

min

typ

max

Operating Parameters

Operating voltage⁶⁾

Undervoltage shutdown

Undervoltage restart

T =-40...+150°C: V_bb(on)

5.0

3.5

--

34

V

j

T =-40...+150°C: V_bb(under)

j

5.0

T =-40...+25°C: V_{bb(u rst)}

5.0

7.0

j

T =+150°C:

j

Undervoltage restart of charge pump

see diagram page 13

V_bb(ucp)

--

5.6

0.2

7.0

V

Undervoltage hysteresis

∆V_bb(under)= V_{bb(u rst)}- V_bb(under)

∆V_bb(under)

--

Overvoltage shutdown

Overvoltage restart

Overvoltage hysteresis

Overvoltage protection⁷⁾

I_bb=40 mA

T =-40...+150°C: V_bb(over)

34

33

--

43

--

V

j

T =-40...+150°C: V_{bb(o rst)}

j

T =-40...+150°C: ∆V_bb(over)

j

0.5

47

--

T =-40...+150°C: V_bb(AZ)

j

42

--

Standby current (pin 4)

V_IN=0

I_bb(off)

--

14

17

30

35

µA

T_j=-40...+25°C:

T_j= 150°C:

I_L(off)

I_GND

--

12

Leakage output current (included in I_bb(off)

VIN=0

Operating current (Pin 2)⁸⁾, V_IN=5 V

both channels on, _Tj=-40...+150°C

Operating current (Pin 2)⁸⁾

)

--

4

2

6

3

mA

one channel on, _Tj=-40...+150°C:

6)

At supply voltage increase up to V = 5.6 V typ without charge pump, V

≈V - 2 V

bb

OUT

7)

8)

See also V

in table of protection functions and circuit diagram page 8.

ON(CL)

Add I , if I > 0, add I , if V >5.5 V

ST

IN

Semiconductor Group

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2003-Oct-01

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PROFET

BTS611L1

Parameter and Conditions, each channel

Symbol

Values

Unit

at Tj = 25 °C, V = 12 V unless otherwise specified

bb

min

typ

max

Protection Functions⁹⁾

Initial peak short circuit current limit (pin 4 to 1

or 7)

I_L(SCp)

_Tj=-40°C:

5.5

4.5

2.5

9.5

7.5

4.5

13

11

7

A

_Tj=25°C:

_Tj=+150°C:

Repetitive short circuit shutdown current limit

I_L(SCr)

T_j= T_jt(see timing diagrams, page 11)

--

4

--

Output clamp (inductive load switch off)

at V_OUT= V_bb- V_ON(CL)

I_L= 40 mA: V_ON(CL)

41

150

--

47

--

53

--

V

°C

K

Thermal overload trip temperature

T_jt

Thermal hysteresis

Reverse battery (pin 4 to 2) ¹⁰⁾

∆T_jt

-V_bb

10

--

32

V

Reverse battery voltage drop (V > V

)

out

bb

I_L= -1.8 A, each channel

T=150 °C: -V_ON(rev)

j

--

mV

610

--

Diagnostic Characteristics

Open load detection current

T_j=-40 °C: I_{L (OL)}

10

--

200

150

mA

V

(on-condition)

T_j=25 ..150°C:

Open load detection voltage¹¹⁾(off-condition)

T_j=-40..150°C:

V_OUT(OL)

2

3

4

Internal output pull down

(pin 1 or 7 to 2), V_OUT=5 V, T_j=-40..150°C

R_O

4

10

30

kΩ

9)

Integrated protection functions are designed to prevent IC destruction under fault conditions described in the

data sheet. Fault conditions are considered as "outside" normal operating range. Protection functions are not

designed for continuous repetitive operation.

Requires 150 Ω resistor in GND connection. The reverse load current through the intrinsic drain-source

diode has to be limited by the connected load. Note that the power dissipation is higher compared to normal

operating conditions due to the voltage drop across the intrinsic drain-source diode. The temperature

protection is not active during reverse current operation! Input and Status currents have to be limited (see

max. ratings page 2 and circuit page 8).

10)

11)

External pull up resistor required for open load detection in off state.

Semiconductor Group

5

2003-Oct-01

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PROFET

BTS611L1

Parameter and Conditions, each channel

Symbol

Values

Unit

at Tj = 25 °C, V = 12 V unless otherwise specified

bb

min

2.5

typ

max

Input and Status Feedback¹²⁾

Input resistance

T_j=-40..150°C, see circuit page 7

R_I

3.5

6

kΩ

Input turn-on threshold voltage

Input turn-off threshold voltage

Input threshold hysteresis

T_j=-40..+150°C: V_IN(T+)

T_j=-40..+150°C: V_IN(T-)

∆ V_IN(T)

1.7

1.5

--

3.5

--

V

0.5

--

V

Off state input current (pin 3 or 6), V_IN= 0.4 V,

T_j=-40..+150°C

I_IN(off)

1

50

µA

On state input current (pin 3 or 6), V_IN= 3.5 V,

T_j=-40..+150°C

I_IN(on)

20

50

90

µA

µs

Delay time for status with open load after switch

off (other channel in off state)

(see timing diagrams, page 12), T_j=-40..+150°C

t_{d(ST OL4)}

100

320

800

Delay time for status with open load after switch

off (other channel in on state)

t_{d(ST OL5)}

--

5

20

µs

(see timing diagrams, page 12), T_j=-40..+150°C

Status invalid after positive input slope

t_d(ST)

200

600

(open load)

T =-40 ... +150°C:

j

Status output (open drain)

Zener limit voltage T =-40...+150°C, I_ST= +1.6 mA: V_ST(high)

5.4

--

6.1

--

0.4

0.6

V

j

ST low voltage

T =-40...+25°C, I_ST= +1.6 mA: V_ST(low)

j

T = +150°C, I_ST= +1.6 mA:

j

12)

If a ground resistor R

is used, add the voltage drop across this resistor.

GND

Semiconductor Group

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BTS611L1

Truth Table

IN1

IN2

OUT1

OUT2

ST

BTS611L1 BTS612N1

Normal operation

Open load

L

H

L

H

L

H

L

H

L

H

Z

H

L

H

L

H

L

H

L

13)

Channel 1

H(L

)

H

X

H

X

H

L

13)

Channel 2

Channel 1

L

H

X

L

H

L

H

L

H

X

L

H

X

H

Z

H

L

H

X

H(L

L

H

L

H

L

14)

Short circuit to V

Overtemperature

bb

L

H

15)

14)

H(L

L

)

Channel 2

L

H

X

L

X

H

L

H

X

L

H

L

H

X

L

H

X

L

H

X

L

X

L

H

L

X

L

H

L

H

L

H

15)

H(L

both channel

H

L

H

L

H

L

H

Channel 1

Channel 2

H

L

H

Undervoltage/ Overvoltage

L = "Low" Level

H = "High" Level

X = don't care

Z = high impedance, potential depends on external circuit

Status signal after the time delay shown in the diagrams (see fig 5. page 12...13)

Terms

Input circuit (ESD protection)

R

I

V

bb

IN

ON1

V

4

V

bb

I

ON2

IN1

V

3

6

bb

I

IN1

IN2

ST

L1

ESD-ZD_I

1

7

I

OUT1

OUT2

I

IN2

PROFET

I

GND

L2

V

I

ST

V

GND

2

IN2

IN1

5

V

ST

ESD zener diodes are not to be used as voltage clamp

at DC conditions. Operation in this mode may result in

a drift of the zener voltage (increase of up to 1 V).

OUT1

V

I

OUT2

GND

R

GND

13)

14)

With additional external pull up resistor

An external short of output to V_bb, in the off state, causes an internal current from output to ground. If R_GND

is used, an offset voltage at the GND and ST pins will occur and the V_{ST low}signal may be errorious.

Low resistance to V_bbmay be detected in the ON-state by the no-load-detection

15)

Semiconductor Group

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2003-Oct-01

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BTS611L1

Open-load detection

Status output

ON-state diagnostic condition: V_ON< R_ON* I_L(OL); IN

+5V

high

+ V

bb

R_ST(ON)

ST

ESD-

ZD

V

ON

GND

ESD-Zener diode: 6.1 V typ., max 5 mA;

< 380 Ω at 1.6 mA, ESD zener diodes are not

to be used as voltage clamp at DC conditions.

Operation in this mode may result in a drift of the zener

voltage (increase of up to 1 V).

OUT

R

ST(ON)

Open load

detection

Logic

unit

Inductive and overvoltage output clamp

OFF-state diagnostic condition: V_OUT> 3 V typ.; IN low

+ V

bb

V

Z

R

EXT

V_ON

OFF

V

OUT

PROFET

GND

Open load

detection

Logic

unit

R

O

V

ON

clamped to 47 V typ.

Signal GND

Overvolt. and reverse batt. protection

+ V

GND disconnect

bb

V

Z2

R

I

bb

I

V

IN1

4

bb

IN2

V

3

bb

Logic

IN1

1

OUT1

OUT2

ST

R

ST

PROFET

IN2

6

V

Z1

7

ST

5

GND

2

R

GND

V

IN2

IN1

GND

ST

Signal GND

V

R

= 6.1 V typ., V = 47 V typ., R = 3.5 kΩ typ,

Z2 I

= 150 Ω

GND

Z1

Any kind of load. In case of Input=high is V_OUT≈ V_IN- V_IN(T+)

.

Due to V_GND>0, no V_ST= low signal available.

Semiconductor Group

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2003-Oct-01

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BTS611L1

GND disconnect with GND pull up

Inductive Load switch-off energy

dissipation

E

4

bb

V

3

6

bb

E

IN1

IN2

ST

AS

1

7

OUT1

OUT2

V

IN1

E

Load

L

PROFET

V

bb

IN

V

IN2

GND

2

5

OUT

PROFET

=

ST

GND

L

V

GND

ST

V

bb

Z

{

R

L

E

R

Any kind of load. If V_GND> V_IN- V_IN(T+)device stays off

Due to V_GND>0, no V_ST= low signal available.

V

disconnect with energized inductive

Energy stored in load inductance:

bb

2

L

load

1

E = ^/·L·I

L

2

While demagnetizing load inductance, the energy

dissipated in PROFET is

4

V

3

bb

IN1

IN2

ST

1

7

OUT1

OUT2

E_AS= E_bb+ E_L- E_R= V_ON(CL)·i_L(t) dt,

high

PROFET

6

5

with an approximate solution for R_L> 0Ω:

I_L·L

2·R_L

I_L·R_L

|V_OUT(CL)|

GND

2

E =

AS

·(V_bb+|V_OUT(CL)|)· ln (1+

)

Maximum allowable load inductance for

a single switch off (both channels parallel)

L = f (I_L); T_j,start= 150°C,T_C= 150°C const.,

V_bb= 12 V, R_L= 0 Ω

V

bb

Normal load current can be handled by the PROFET

itself.

L [mH]

1000

V

disconnect with charged external

bb

inductive load

4

V

3

bb

IN1

1

7

100

10

1

OUT1

OUT2

high

PROFET

IN2

6

D

ST

5

GND

2

V

bb

If other external inductive loads L are connected to the PROFET,

additional elements like D are necessary.

2

3

4

5

6

7

8

I

[A]

L

Semiconductor Group

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2003-Oct-01

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BTS611L1

Typ. transient thermal impedance chip case

Z

_thJC= f(t_p), one Channel active

Z

_thJC[K/W]

10

1

0.1

D=

0.5

0.2

0.1

0.05

0.02

0.01

0

0.01

1E-5 1E-4 1E-3 1E-2 1E-1 1E0

1E1

t

[s]

p

Typ. transient thermal impedance chip case

Z_thJC= f(t_p), both Channel active

Z

_thJC[K/W]

10

1

0.1

D=

0.5

0.2

0.1

0.05

0.02

0.01

0

0.01

1E-5 1E-4 1E-3 1E-2 1E-1 1E0

1E1

t

[s]

p

Semiconductor Group

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BTS611L1

Both channels are symmetric and consequently the diagrams

are valid for each channel as well as for permuted channels

Timing diagrams

Figure 1a: V turn on:

Figure 2b: Switching an inductive load

bb

IN1

IN2

IN

V

bb

t

d(ST)

ST

*)

V

OUT1

V

OUT

V

OUT2

I

L

ST open drain

I

L(OL)

t

*) if the time constant of load is too large, open-load-status may

occur

Figure 2a: Switching a lamp:

Figure 3a: Short circuit

shut down by overtempertature, reset by cooling

IN

other channel: normal operation

IN

ST

V

OUT

I

L

I

L(SCp)

I

L(SCr)

I

L

t

ST

t

Heating up may require several milliseconds, depending on

external conditions

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BTS611L1

Figure 5b: Open load: detection in ON-state, turn

on/off to open load

Figure 4a: Overtemperature:

Reset if T <T

j

jt

IN1

IN2

channel 2: normal operation

IN

V

ST

OUT1

V

OUT

I

L1

channel 1: open load

t

d(ST)

d(ST OL4)

d(ST)

d(ST OL5)

T

J

ST

t

Figure 5c: Open load: detection in ON- and OFF-state

(with R

), turn on/off to open load

EXT

Figure 5a: Open load: detection in ON-state, open

load occurs in on-state

IN1

IN2

IN1

channel 2: normal operation

IN2

channel 2: normal operation

V

OUT1

V

OUT1

I_L1

channel 1: open load

t

channel 1:

I

L1

open

load

open

load

normal

load

ST

t

d(ST)

d(ST OL5)

d(ST)

t

d(ST OL1)

t

d(ST OL1)

t

d(ST OL2)

t

ST

t

t_{d(ST OL5)}depends on external circuitry because of high

impedance

t_{d(ST OL1)}= 30 µs typ., t_{d(ST OL2)}= 20 µs typ

Semiconductor Group

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2003-Oct-01

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PROFET

BTS611L1

Figure 6a: Undervoltage:

Figure 7a: Overvoltage:

IN

V

bb

V

ON(CL)

bb(over)

bb(o rst)

bb

V

bb(u cp)

bb(under)

V

bb(u rst)

V

OUT

V

OUT

ST

ST open drain

t

Figure 6b: Undervoltage restart of charge pump

V

ON(CL)

V

on

V

bb(over)

V

bb(o rst)

bb(u rst)

V

bb(u cp)

V

bb(under)

V

bb

charge pump starts at V_bb(ucp)=5.6 V typ.

Semiconductor Group

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2003-Oct-01

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BTS611L1

Package and Ordering Code

All dimensions in mm

Changed since 04.96

Date Change

Standard TO-220AB/7

Ordering code

Dec

t_{d(ST OL4)}max reduced from 1500

BTS611L1

Q67060-S6302-A2

1996 to 800µs, typical from 400 to

320µs, min limit unchanged

E_ASmaximum rating and diagram

and ZthJC diagram added

ESD capability increased

Typ. reverse battery voltage drop -

V_ON(rev)added

TO 220AB/7, Opt. E3230 Ordering code

BTS611L1 E3230

Q67060-S6314

SMD TO 220AB/7, Opt. E3128 Ordering code

BTS611L1 E3128A T&R:

Q67060-S6302-A4

Semiconductor Group

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2003-Oct-01

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BTS611L1

Published by

Infineon Technologies AG,

St.-Martin-Strasse 53,

D-81669 München

Attention please!

The information herein is given to describe certain

components and shall not be considered as a guarantee of

characteristics.

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Due to technical requirements components may contain

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Infineon Technologies Components may only be used in life-

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endangered.

Semiconductor Group

15

2003-Oct-01


型号：	BTS611L1E3128ANTMA1
厂家：	Infineon
描述：	Buffer/Inverter Based Peripheral Driver, 7.5A, PSSO6, TO-220AB, 7 PIN 驱动接口集成电路
文件：	总15页 (文件大小：312K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

BTS611L1E3128ANTMA1 [INFINEON]

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