ETC BTS432E2

PROFET® BTS 432 E2
Smart Highside Power Switch
Features
Product Summary
VLoad dump
80
Vbb-VOUT Avalanche Clamp
58
Vbb (operation)
4.5 ... 42
Vbb (reverse)
-32
RON
38
IL(SCp)
44
IL(SCr)
35
IL(ISO)
11
• Load dump and reverse battery protection1)
• Clamp of negative voltage at output
• Short-circuit protection
• Current limitation
• Thermal shutdown
• Diagnostic feedback
• Open load detection in ON-state
• CMOS compatible input
• Electrostatic discharge (ESD) protection
• Loss of ground and loss of Vbb protection2)
• Overvoltage protection
• Undervoltage and overvoltage shutdown with autorestart and hysteresis
V
V
V
V
mΩ
A
A
A
5
5
Application
5
• µC compatible power switch with diagnostic feedback
for 12 V and 24 V DC grounded loads
• All types of resistive, inductive and capacitve loads
• Replaces electromechanical relays and discrete circuits
1
1
Straight leads
SMD
Standard
General Description
N channel vertical power FET with charge pump, ground referenced CMOS compatible input and diagnostic
feedback, integrated in Smart SIPMOS chip on chip technology. Fully protected by embedded protection
functions.
R bb
Voltage
Overvoltage
Current
Gate
source
protection
limit
protection
+ V bb
3
V Logic
2
Voltage
Charge pump
sensor
Level shifter
Limit for
unclamped
ind. loads
Rectifier
IN
OUT
5
Temperature
sensor
Open load
ESD
4
Logic
Load
detection
ST
Short circuit
detection
GND

PROFET
1
Signal GND
1)
2)
Load GND
No external components required, reverse load current limited by connected load.
Additional external diode required for charged inductive loads
Semiconductor Group
Page 1 of 14
1999-Mar.-22
BTS 432 E2
Pin
Symbol
Function
1
GND
-
Logic ground
2
IN
I
Input, activates the power switch in case of logical high signal
3
Vbb
+
Positive power supply voltage,
the tab is shorted to this pin
4
ST
S
Diagnostic feedback, low on failure
5
OUT
(Load, L)
O
Output to the load
Maximum Ratings at Tj = 25 °C unless otherwise specified
Parameter
Supply voltage (overvoltage protection see page 3)
Load dump protection VLoadDump = UA + Vs, UA = 13.5 V
RI= 2 Ω, RL= 1.1 Ω, td= 200 ms, IN= low or high
Load current (Short-circuit current, see page 4)
Operating temperature range
Storage temperature range
Power dissipation (DC)
Inductive load switch-off energy dissipation,
single pulse
Tj=150 °C:
Electrostatic discharge capability (ESD)
(Human Body Model)
Input voltage (DC)
Current through input pin (DC)
Current through status pin (DC)
Symbol
Vbb
Vs3)
Values
IL
Tj
Tstg
Ptot
self-limited
-40 ...+150
-55 ...+150
125
A
°C
1.7
2.0
J
kV
-0.5 ... +6
±5.0
±5.0
V
mA
≤1
≤ 75
≤ tbd
K/W
EAS
VESD
VIN
IIN
IST
63
66.5
Unit
V
V
W
see internal circuit diagrams page 6...
Thermal resistance
3)
4)
chip - case:
junction - ambient (free air):
SMD version, device on pcb 4):
RthJC
RthJA
VS is setup without DUT connected to the generator per ISO 7637-1 and DIN 40839
Device on 50mm*50mm*1.5mm epoxy PCB FR4 with 6cm2 (one layer, 70µm thick) copper area for Vbb
connection. PCB is vertical without blown air.
Semiconductor Group
Page 2
1999-Mar.-22
BTS 432 E2
Electrical Characteristics
Parameter and Conditions
Symbol
at Tj = 25 °C, Vbb = 12 V unless otherwise specified
Values
min
typ
max
Unit
Load Switching Capabilities and Characteristics
On-state resistance (pin 3 to 5)
IL = 2 A
Tj=25 °C: RON
Tj=150 °C:
IL(ISO)
Nominal load current (pin 3 to 5)
ISO Proposal: VON = 0.5 V, TC = 85 °C
Output current (pin 5) while GND disconnected or
GND pulled up, VIN= 0, see diagram page 7,
Tj =-40...+150°C
Turn-on time
to 90% VOUT:
Turn-off time
to 10% VOUT:
RL = 12 Ω, Tj =-40...+150°C
Slew rate on
10 to 30% VOUT, RL = 12 Ω, Tj =-40...+150°C
Slew rate off
70 to 40% VOUT, RL = 12 Ω, Tj =-40...+150°C
Operating Parameters
Operating voltage 5)
Tj =-40...+150°C:
Undervoltage shutdown
Tj =-40...+150°C:
Undervoltage restart
Tj =-40...+150°C:
Undervoltage restart of charge pump
see diagram page 12
Tj =-40...+150°C:
Undervoltage hysteresis
∆Vbb(under) = Vbb(u rst) - Vbb(under)
Overvoltage shutdown
Tj =-40...+150°C:
Overvoltage restart
Tj =-40...+150°C:
Overvoltage hysteresis
Tj =-40...+150°C:
6
)
Overvoltage protection
Tj =-40°C:
Ibb=40 mA
Tj =25...+150°C:
Standby current (pin 3)
Tj=-40...+25°C:
VIN=0
Tj=150°C:
Leakage output current (included in Ibb(off))
VIN=0
Operating current (Pin 1) 7), VIN=5 V
5)
6)
7)
--
30
38
mΩ
9
55
11
70
--
A
--
--
1
mA
ton
toff
50
10
160
--
300
80
µs
dV /dton
0.4
--
2.5
V/µs
-dV/dtoff
1
--
5
V/µs
Vbb(on)
Vbb(under)
Vbb(u rst)
Vbb(ucp)
4.5
2.4
---
---6.5
42
4.5
4.5
7.5
V
V
V
V
∆Vbb(under)
--
0.2
--
V
Vbb(over)
Vbb(o rst)
∆Vbb(over)
Vbb(AZ)
--0.2
-67
12
18
6
52
----
V
V
V
V
25
60
--
µA
IL(off)
42
42
-60
63
----
IGND
--
1.1
--
mA
IL(GNDhigh)
Ibb(off)
µA
At supply voltage increase up to Vbb= 6.5 V typ without charge pump, VOUT ≈Vbb - 2 V
see also VON(CL) in table of protection functions and circuit diagram page 7. Meassured without load.
Add IST, if IST > 0, add IIN, if VIN>5.5 V
Semiconductor Group
Page 3
1999-Mar.-22
BTS 432 E2
Parameter and Conditions
Symbol
at Tj = 25 °C, Vbb = 12 V unless otherwise specified
Protection Functions
Initial peak short circuit current limit (pin 3 to 5) 8),
IL(SCp)
( max 400 µs if VON > VON(SC) )
Tj =-40°C:
Tj =25°C:
Tj =+150°C:
Repetitive short circuit current limit
IL(SCr)
Tj = Tjt (see timing diagrams, page 10)
Short circuit shutdown delay after input pos. slope
VON > VON(SC),
Tj =-40..+150°C: td(SC)
Values
min
typ
max
Unit
--24
-44
--
74
---
A
22
35
--
A
80
--
400
µs
VON(CL)
--
58
--
V
VON(SC)
Tjt
∆Tjt
EAS
ELoad12
ELoad24
-150
---
8.3
-10
--
---1.7
1.3
1.0
V
°C
K
J
---
-120
32
--
V
Ω
2
2
---
900
750
mA
min value valid only, if input "low" time exceeds 30 µs
Output clamp (inductive load switch off)
at VOUT = Vbb - VON(CL), IL= 30 mA
Short circuit shutdown detection voltage
(pin 3 to 5)
Thermal overload trip temperature
Thermal hysteresis
Inductive load switch-off energy dissipation 9),
Tj Start = 150 °C, single pulse
Vbb = 12 V:
Vbb = 24 V:
Reverse battery (pin 3 to 1) 10)
Integrated resistor in V bb line
Diagnostic Characteristics
Open load detection current
(on-condition)
8)
-Vbb
Rbb
Tj=-40 °C: IL (OL)
Tj=25..150°C:
Short circuit current limit for max. duration of 400 µs, prior to shutdown (see td(SC) page 4)
While demagnetizing load inductance, dissipated energy in PROFET is EAS= ∫ VON(CL) * iL(t) dt, approx.
VON(CL)
2
EAS= 1/2 * L * IL * (
), see diagram page 8
VON(CL) - Vbb
10) Reverse load current (through intrinsic drain-source diode) is normally limited by the connected load.
Reverse current IGND of ≈ 0.3 A at Vbb= -32 V through the logic heats up the device. Time allowed under
these condition is dependent on the size of the heatsink. Reverse IGND can be reduced by an additional
external GND-resistor (150 Ω). Input and Status currents have to be limited (see max. ratings page 2 and
circuit page 7).
9)
Semiconductor Group
Page 4
1999-Mar.-22
BTS 432 E2
Parameter and Conditions
Symbol
Values
min
typ
max
VIN(T+)
1.5
--
2.4
V
VIN(T-)
1.0
--
--
V
-1
0.5
--
-30
V
µA
10
25
50
µA
80
200
400
µs
td(ST)
350
--
1600
µs
VST(high)
VST(low)
5.4
--
6.1
--
-0.4
V
at Tj = 25 °C, Vbb = 12 V unless otherwise specified
Input and Status Feedback11)
Input turn-on threshold voltage
Tj =-40..+150°C:
Input turn-off threshold voltage
Tj =-40..+150°C:
∆ VIN(T)
IIN(off)
Input threshold hysteresis
Off state input current (pin 2)
VIN = 0.4 V:
On state input current (pin 2)
VIN = 3.5 V: IIN(on)
Status invalid after positive input slope
(short circuit)
Tj=-40 ... +150°C:
Status invalid after positive input slope
(open load)
Tj=-40 ... +150°C:
Status output (open drain)
Zener limit voltage Tj =-40...+150°C, IST = +1.6 mA:
ST low voltage Tj =-40...+150°C, IST = +1.6 mA:
11)
td(ST SC)
Unit
If a ground resistor RGND is used, add the voltage drop across this resistor.
Semiconductor Group
Page 5
1999-Mar.-22
BTS 432 E2
Truth Table
Input-
Output
level
level
432
D2
432
E2/F2
432
I2
L
H
L
H
L
H
L
H
L
H
L
H
L
H
L
H
H
H
H
L
H
L
H
H (L13))
L
L
L14)
L14)
L
L
H
H
H
L
H
L
H
H (L13))
L
L
H
H
H
H
H
H
L
H
H
L
L
H
L
L
L14)
L14)
L
L
Normal
operation
Open load
Short circuit
to GND
Short circuit
to Vbb
Overtemperature
Undervoltage
Overvoltage
Status
12)
H
L
L
H
H
L
L
L
L
L
L
L = "Low" Level
H = "High" Level
Terms
Status output
+5V
Ibb
3
I IN
2
Vbb
IN
V
VST
IN
OUT
PROFET
I ST
V
R ST(ON)
IL
4
5
ST
GND
1
bb
R
GND
IGND
VOUT
GND
R
ESDZD
ESD-Zener diode: 6.1 V typ., max 5 mA;
RST(ON) < 250 Ω at 1.6 mA, ESD zener diodes are not
designed for continuous current
Short Circuit detection
Input circuit (ESD protection)
IN
ST
VON
Fault Condition: VON > 8.3 V typ.; IN high
I
+ V bb
ESDZDI1 ZDI2
I
I
V
ON
GND
OUT
ZDI1 6.1 V typ., ESD zener diodes are not designed for
continuous current
12)
13)
14)
Logic
unit
Short circuit
detection
Power Transistor off, high impedance
Low resistance short Vbb to output may be detected by no-load-detection
No current sink capability during undervoltage shutdown
Semiconductor Group
Page 6
1999-Mar.-22
BTS 432 E2
Inductive and overvoltage output clamp
GND disconnect
+ V bb
V
3
Z
V
IN
ON
2
Vbb
PROFET
OUT
V
VON clamped to 58 V typ.
Overvolt. and reverse batt. protection
V
Z
V
IN
V
GND
1
ST
V
GND
Any kind of load. In case of Input=high is V OUT ≈ VIN - VIN(T+) .
Due to VGND >0, no VST = low signal available.
+ V bb
R IN
bb
5
ST
4
GND
OUT
GND disconnect with GND pull up
R bb
3
IN
Logic
V
R ST
ST
GND
2
IN
OUT
Vbb
PROFET
PROFET
4
OUT
5
ST
GND
1
R GND
Signal GND
Rbb = 120 Ω typ., VZ +Rbb*40 mA = 67 V typ., add
RGND, RIN, RST for extended protection
V
V
bb
V
IN ST
V
GND
Any kind of load. If V GND > VIN - VIN(T+) device stays off
Due to VGND >0, no VST = low signal available.
Open-load detection
ON-state diagnostic condition: VON < RON * IL(OL); IN
high
Vbb disconnect with charged inductive
load
+ V bb
3
high
2
IN
PROFET
VON
ON
4
OUT
5
ST
GND
OUT
Logic
unit
Vbb
1
Open load
detection
V
bb
3
high
2
IN
Vbb
PROFET
4
OUT
5
ST
GND
1
V
Semiconductor Group
Page 7
bb
1999-Mar.-22
BTS 432 E2
Inductive Load switch-off energy
dissipation
E bb
E AS
IN
PROFET
=
ELoad
Vbb
ST
OUT
EL
GND
ER
Energy dissipated in PROFET EAS = Ebb + EL - ER.
2
ELoad < EL, EL = 1/2 * L * I L
Semiconductor Group
Page 8
1999-Mar.-22
BTS 432 E2
Options Overview
all versions: High-side switch, Input protection, ESD protection, load dump and
reverse battery protection , protection against loss of ground
Type
Logic version
BTS 432D2 432E2 432F2 432I2
Overtemperature protection
Tj >150 °C, latch function 15)16)
Tj >150 °C, with auto-restart on cooling
Short-circuit to GND protection
switches off when VON>8.3 V typ.15)
(when first turned on after approx. 200 µs)
D
E
X
F
I
X
X
X
X
X
X
X
Open load detection
in OFF-state with sensing current 30 µA typ.
in ON-state with sensing voltage drop across
power transistor
X
X
X
X
Undervoltage shutdown with auto restart
X
X
X
X
Overvoltage shutdown with auto restart
X
X
X
X
overtemperature
X
X
X
X
short circuit to GND
X
X
X
X
-17)
-17)
-17)
X
open load
X
X
X
X
undervoltage
X
-
-
X
overvoltage
X
-
-
X
X
X
X
X
X
X
X
Status feedback for
short to Vbb
Status output type
CMOS
X
Open drain
X
Output negative voltage transient limit
(fast inductive load switch off)
to Vbb - VON(CL)
X
Load current limit
high level (can handle loads with high inrush currents)
X
medium level
X
low level (better protection of application)
15)
Latch except when Vbb -VOUT < VON(SC) after shutdown. In most cases VOUT = 0 V after shutdown (VOUT ≠
0 V only if forced externally). So the device remains latched unless Vbb < VON(SC) (see page 4). No latch
between turn on and td(SC).
16) With latch function. Reseted by a) Input low, b) Undervoltage, c) Overvoltage
17) Low resistance short V to output may be detected by no-load-detection
bb
Semiconductor Group
Page 9
1999-Mar.-22
BTS 432 E2
Timing diagrams
Figure 2b: Switching an inductive load
Figure 1a: Vbb turn on:
IN
IN
t d(bb IN)
V
bb
td(ST)
ST
*)
V
V
OUT
OUT
A
ST open drain
I
L
IL(OL)
t
A
t
in case of too early V IN=high the device may not turn on (curve A)
td(bb IN) approx. 150 µs
*) if the time constant of load is too large, open-load-status may
occur
Figure 2a: Switching a lamp,
Figure 3a: Turn on into short circuit,
IN
IN
ST
ST
V
OUT
V
OUT
td(SC)
I
L
I
L
t
t
td(SC) approx. 200µs if V bb - VOUT > 8.3 V typ.
Semiconductor Group
Page 10
1999-Mar.-22
BTS 432 E2
Figure 3b: Turn on into overload,
Figure 4a: Overtemperature:
Reset if Tj <Tjt
IN
IN
IL
ST
I L(SCp)
IL(SCr)
V
OUT
T
ST
J
t
t
Heating up may require several milliseconds , V bb - VOUT < 8.3 V
typ.
Figure 5a: Open load: detection in ON-state, turn
on/off to open load
Figure 3c: Short circuit while on:
IN
IN
ST
ST
V
V OUT
IL
t
d(ST)
OUT
I
L
**)
t
open
t
**) current peak approx. 20 µs
Semiconductor Group
Page 11
1999-Mar.-22
BTS 432 E2
Figure 5b: Open load: detection in ON-state, open
load occurs in on-state
Figure 6b: Undervoltage restart of charge pump
VON [V]
VON(CL)
V on
IN
off
td(ST OL1)
t d(OL ST2)
ST
V
V
off
OUT
V
V
bb(u rst)
normal
I
open
V
normal
L
V
bb(over)
bb(o rst)
bb(u cp)
bb(under)
on
V bb
t
Vbb [V]
td(ST OL1) = tbd µs typ., t d(ST OL2) = tbd µs typ
charge pump starts at Vbb(ucp) =6.5 V typ.
Figure 7a: Overvoltage:
Figure 6a: Undervoltage:
IN
IN
V bb
Vbb
V
bb(under)
V ON(CL)
Vbb(over)
V bb(o rst)
Vbb(u cp)
V
bb(u rst)
V
OUT
V OUT
ST
ST open drain
t
Semiconductor Group
Page 12
t
1999-Mar.-22
BTS 432 E2
Package and Ordering Code
All dimensions in mm
Standard TO-220AB/5
BTS 432 E2
TO-220AB/5, Option E3043 Ordering code
Ordering code
Q67060-S6202-A2
BTS 432 E2 E3043
Q67060-S6202-A4
SMD TO-220AB/5, Opt. E3062 Ordering code
BTS432E2 E3062A T&R:
Semiconductor Group
Page 13
Q67060-S6202-A6
1999-Mar.-22
BTS 432 E2
Published by Siemens AG, Bereich Halbleiter Vetrieb, Werbung,
Balanstraße 73, D-81541 München
 Siemens AG 1999. All Rights Reserved
Attention please!
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liability is only assumed for components, not for applications,
processes and circuits implemented within components or
assemblies. The information describes a type of component and
shall not be considered as warranted characteristics. Terms of
delivery and rights to change design reserved. For questions on
technology, delivery and prices please contact the Semiconductor
Group Offices in Germany or the Siemens Companies and
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information on the types in question please contact your nearest
Siemens Office, Semiconductor Group. Siemens AG is an approved
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Packing: Please use the recycling operators known to you. We can
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Components used in life-support devices or systems must be
expressly authorised for such purpose! Critical components18) of
the Semiconductor Group of Siemens AG, may only be used in life
supporting devices or systems 19) with the express written approval
of the Semiconductor Group of Siemens AG.
18) A critical component is a component used in a life-support
device or system whose failure can reasonably be expected to
cause the failure of that life-support device or system, or to
affect its safety or effectiveness of that device or system.
19) Life support devices or systems are intended (a) to be
implanted in the human body or (b) support and/or maintain
and sustain and/or protect human life. If they fail, it is
reasonably to assume that the health of the user or other
persons may be endangered.
Semiconductor Group
Page 14
1999-Mar.-22