INFINEON BTS5210G

BTS 5210G
Smart High-Side Power Switch
Two Channels: 2 x 140mΩ
Status Feedback
Product Summary
Vbb
Active channels
On-state Resistance
RON
Nominal load current
IL(NOM)
Current limitation
IL(SCr)
Package
Operating Voltage
one
140mΩ
2.4A
6.5A
5.5...40V
two parallel
70mΩ
3.9A
6.5A
P-DSO-14
General Description
•
•
N channel vertical power MOSFET with charge pump, ground referenced CMOS compatible input and

diagnostic feedback, monolithically integrated in Smart SIPMOS technology.
Providing embedded protective functions
Applications
•
•
•
•
µC compatible high-side power switch with diagnostic feedback for 12V and 24V grounded loads
All types of resistive, inductive and capacitve loads
Most suitable for loads with high inrush currents, so as lamps
Replaces electromechanical relays, fuses and discrete circuits
Basic Functions
•
•
•
•
•
•
•
Very low standby current
CMOS compatible input
Improved electromagnetic compatibility (EMC)
Fast demagnetization of inductive loads
Stable behaviour at undervoltage
Wide operating voltage range
Logic ground independent from load ground
Protection Functions
•
•
•
•
•
•
•
•
Block Diagram
Short circuit protection
Overload protection
Current limitation
Thermal shutdown
Overvoltage protection (including load dump) with external
resistor
Reverse battery protection with external resistor
Loss of ground and loss of Vbb protection
Electrostatic discharge protection (ESD)
Diagnostic Function
•
•
•
IN1
ST1
IN2
ST2
Logic
Channel 1
Channel 2
Load 1
Load 2
GND
Diagnostic feedback with open drain output
Open load detection in OFF-state
Feedback of thermal shutdown in ON-state
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Vbb
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2003-Oct-01
BTS 5210G
Functional diagram
GND
internal
voltage supply
logic
current limit
gate
control
+
charge
pump
VBB
clamp for
inductive load
OUT1
IN1
ST1
ESD
temperature
sensor
reverse
battery
protection
Open load
detection
channel 1
IN2
ST2
control and protection circuit
equivalent to
channel 1
OUT2
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BTS 5210G
Pin Definitions and Functions
Pin
Symbol
Function
Positive power supply voltage. Design the
wiring for the simultaneous max. short circuit
currents from channel 1 to 2 and also for low
thermal resistance
Logic Ground
Input 1,2 activates channel 1,2 in case
of logic high signal
Diagnostic feedback 1,2 of channel 1,2
open drain
1,7,
8,14
Vbb
2
3
5
4
6
GND
IN1
IN2
ST1
ST2
12,13
OUT1
9,10
OUT2
Output 1,2 protected high-side power output of
channel 1,2. Design the wiring for the max.
short circuit current; both output pins have to
be connected in parallel for operation
according this spec.
11
NC
Not Connected
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Pin configuration
(top view)
Vbb
GND
IN1
ST1
IN2
ST2
Vbb
1
2
3
4
5
6
7
•
14
13
12
11
10
9
8
Vbb
OUT1
OUT1
NC
OUT2
OUT2
Vbb
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BTS 5210G
Maximum Ratings at Tj = 25°C unless otherwise specified
Parameter
Symbol
Supply voltage (overvoltage protection see page 6)
Supply voltage for full short circuit protection
Tj,start = -40 ...+150°C
Load current (Short-circuit current, see page 6)
Load dump protection1) VLoadDump = VA + Vs, VA = 13.5 V
RI2) = 2 Ω, td = 400 ms; IN = low or high,
each channel loaded with RL = 13.5 Ω,
Operating temperature range
Storage temperature range
Power dissipation (DC)4)
Ta = 25°C:
Ta = 85°C:
(all channels active)
Maximal switchable inductance, single pulse
Vbb = 12V, Tj,start = 150°C4), see diagrams on page 10
IL = 2.9 A, EAS = 65 mJ, 0 Ω
one channel:
IL = 5.7 A, EAS = 125 mJ, 0 Ω
two parallel channels:
Electrostatic discharge capability (ESD)
IN:
(Human Body Model)
ST:
out to all other pins shorted:
Vbb
Vbb
Values
Unit
43
36
V
V
IL
VLoad dump3)
self-limited
60
A
V
Tj
Tstg
Ptot
-40 ...+150
-55 ...+150
3,05
1,59
°C
11,2
5,6
mH
1.0
4.0
8.0
kV
-10 ... +16
±0.3
±5.0
±5.0
V
mA
ZL
VESD
W
acc. MIL-STD883D, method 3015.7 and ESD assn. std. S5.1-1993
R=1.5kΩ; C=100pF
Input voltage (DC) see internal circuit diagram page 9
Current through input pin (DC)
Pulsed current through input pin5)
Current through status pin (DC)
1)
2)
3)
4)
5)
VIN
IIN
IINp
IST
Supply voltages higher than Vbb(AZ) require an external current limit for the GND and status pins (a 150Ω
resistor for the GND connection is recommended.
RI = internal resistance of the load dump test pulse generator
VLoad dump is setup without the 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. See page 14
only for testing
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BTS 5210G
Thermal Characteristics
Parameter and Conditions
Symbol
min
Thermal resistance
junction - soldering point6)7)
junction – ambient6)
@ 6 cm2 cooling area
each channel: Rthjs
Rthja
one channel active:
all channels active:
Values
typ
max
Unit
15
----
K/W
Values
min
typ
max
Unit
-----
--45
40
Electrical Characteristics
Parameter and Conditions, each of the four channels
Symbol
at Tj = -40...+150°C, Vbb = 12 V unless otherwise specified
Load Switching Capabilities and Characteristics
On-state resistance (Vbb to OUT); IL = 2 A
each channel,
Tj = 25°C: RON
Tj = 150°C:
two parallel channels, Tj = 25°C:
----
110
210
55
140
280
70
mΩ
1.8
3.4
2.4
3.9
--
A
--
--
2
mA
---
100
100
250
270
µs
0.2
0.2
---
1.0
1.1
V/µs
V/µs
see diagram, page 11
Nominal load current
one channel active: IL(NOM)
two parallel channels active:
Device on PCB6), Ta = 85°C, Tj ≤ 150°C
Output current while GND disconnected or pulled up8); IL(GNDhigh)
Vbb = 32 V, VIN = 0,
see diagram page 9
Turn-on time9)
Turn-off time
RL = 12 Ω
Slew rate on 9)
Slew rate off 9)
6)
7)
8)
9)
IN
IN
to 90% VOUT: ton
to 10% VOUT: toff
10 to 30% VOUT, RL = 12 Ω: dV/dton
70 to 40% VOUT, RL = 12 Ω: -dV/dtoff
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. See page 14
Soldering point: upper side of solder edge of device pin 15. See page 14
not subject to production test, specified by design
See timing diagram on page 12.
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BTS 5210G
Parameter and Conditions, each of the four channels
Symbol
at Tj = -40...+150°C, Vbb = 12 V unless otherwise specified
Operating Parameters
Operating voltage
Undervoltage switch off10)
Overvoltage protection12)
I bb = 40 mA
Standby current13)
VIN = 0; see diagram page 11
Vbb(on)
Tj =-40°C...25°C: Vbb(u so)
Tj =125°C:
Vbb(AZ)
Tj =-40°C...25°C: Ibb(off)
Tj =150°C:
Tj =125°C:
Off-State output current (included in Ibb(off))
IL(off)
VIN = 0; each channel
Operating current 14), VIN = 5V,
one channel on: IGND
all channels on:
Protection Functions15)
Current limit, Vout = 0V, (see timing diagrams, page 12)
Tj =-40°C: IL(lim)
Tj =25°C:
Tj =+150°C:
Repetitive short circuit current limit,
Tj = Tjt
each channel IL(SCr)
two channels
Values
min
typ
max
Unit
5.5
--41
---47
40
4.5
4.511)
52
V
V
-----
5
--1
8
12
811)
5
µA
---
0.5
1.0
0.9
1.7
mA
--5
-9
--
14
---
A
---
6.5
6.5
---
A
--
2
--
ms
41
47
52
V
150
--
-10
---
°C
K
V
µA
(see timing diagrams, page 12)
Initial short circuit shutdown time
Vout = 0V
Tj,start =25°C: toff(SC)
(see timing diagrams on page 12)
Output clamp (inductive load switch off)16)
VON(CL)
at VON(CL) = Vbb - VOUT, IL= 40 mA
Thermal overload trip temperature
Thermal hysteresis
10)
11)
12)
13)
14)
15)
16)
Tjt
∆Tjt
is the voltage, where the device doesn´t change it´s switching condition for 15ms after the supply voltage
falling below the lower limit of Vbb(on)
not subject to production test, specified by design
Supply voltages higher than Vbb(AZ) require an external current limit for the GND and status pins (a 150Ω
resistor for the GND connection is recommended). See also VON(CL) in table of protection functions and
circuit diagram on page 9.
Measured with load; for the whole device; all channels off
Add IST, if IST > 0
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.
If channels are connected in parallel, output clamp is usually accomplished by the channel with the lowest
VON(CL)
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2003-Oct-01
BTS 5210G
Parameter and Conditions, each of the four channels
Symbol
at Tj = -40...+150°C, Vbb = 12 V unless otherwise specified
Reverse Battery
Reverse battery voltage 17)
Drain-source diode voltage (Vout > Vbb)
IL = - 2.0 A, Tj = +150°C
-Vbb
-VON
Values
min
typ
max
Unit
---
-600
32
--
V
mV
Diagnostic Characteristics
Open load detection voltage
V OUT(OL)
1.7
2.8
4.0
V
Input and Status Feedback18)
Input resistance
RI
2.5
4.0
6.0
kΩ
VIN(T+)
VIN(T-)
∆ VIN(T)
td(STon)
-1.0
---
--0.2
10
2.5
--20
V
V
V
µs
td(STon)
30
--
--
µs
td(SToff)
--
--
500
µs
td(SToff)
--
--
20
µs
IIN(off)
IIN(on)
5
10
-35
20
60
µA
µA
VST(high)
VST(low)
5.4
--
---
-0.6
V
1
(see circuit page 9)
Input turn-on threshold voltage
Input turn-off threshold voltage
Input threshold hysteresis
Status change after positive input slope19)
with open load
Status change after positive input slope19)
with overload
Status change after negative input slope
with open load
Status change after negative input slope19)
with overtemperature
Off state input current
VIN = 0.4 V:
On state input current
VIN = 5 V:
Status output (open drain)
Zener limit voltage
IST = +1.6 mA:
ST low voltage
IST = +1.6 mA:
17)
Requires a 150 Ω resistor in GND connection. The reverse load current through the intrinsic drain-source
diode has to be limited by the connected load. Power dissipation is higher compared to normal operating
conditions due to the voltage drop across the 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 4 and
circuit page 9).
18) If ground resistors R
GND are used, add the voltage drop across these resistors.
19) not subject to production test, specified by design
Infineon Technologies AG
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BTS 5210G
Truth Table
( each channel )
Normal operation
Open load
Overtemperature
L = "Low" Level
H = "High" Level
IN
OUT
ST
L
H
L
H
L
H
Z
H
H
H
L
H
L
L
L20)
H
H
L
X = don't care
Z = high impedance, potential depends on external circuit
Status signal valid after the time delay shown in the timing diagrams
Parallel switching of channel 1 and 2 is easily possible by connecting the inputs and outputs in parallel (see truth
table). If switching channel 1 to 2 in parallel, the status outputs ST1 and ST2 have to be configured as a 'Wired
OR' function with a single pull-up resistor.
Terms
Ibb
V
V
ON1
V
ON2
1,7,8,14 Leadframe
bb
I IN1
I IN2
VIN1 V IN2
V
3
5
I ST1
4
I ST2
6
Vbb
IN1
IN2
OUT1
I L1
9,10
I L2
PROFET
OUT2
ST1
ST2
12,13
GND
ST1 V ST2
V
2
I
R
GND
OUT1
V
OUT2
GND
Leadframe (Vbb) is connected to pin 1,7,8,14
External RGND optional; single resistor RGND = 150 Ω for reverse battery protection up to the max.
operating voltage.
20)
L, if potential at the Output exceeds the OpenLoad detection voltage
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BTS 5210G
Overvolt. and reverse batt. protection
Input circuit (ESD protection), IN1 or IN2
+ 5V
R
IN
I
+ Vbb
R ST
V
IN
ESD-ZD I
I
RI
Z2
Logic
I
R ST ST
GND
OUT
V
Z1
The use of ESD zener diodes as voltage clamp at DC
conditions is not recommended.
GND
R GND
Signal GND
Status output, ST1 or ST2
ST
Open-load detection, OUT1 or OUT2
ESDZD
GND
Load GND
VZ1 = 6.1 V typ., VZ2 = 47 V typ., RGND = 150 Ω,
RST= 15 kΩ, RI= 3.5 kΩ typ.
In case of reverse battery the load current has to be
limited by the load. Temperature protection is not
active
+5V
R ST(ON)
R Load
OFF-state diagnostic condition:
Open Load, if VOUT > 3 V typ.; IN low
ESD-Zener diode: 6.1 V typ., max 0.3 mA; RST(ON) < 375 Ω
at 1.6 mA. The use of ESD zener diodes as voltage clamp at
DC conditions is not recommended.
V
bb
R
EXT
Inductive and overvoltage output clamp,
OFF
OUT1 or OUT2
V
+Vbb
VZ
Logic
unit
V
OUT
Open load
detection
ON
Signal GND
OUT
GND disconnect
Power GND
VON clamped to VON(CL) = 47 V typ.
IN
Vbb
PROFET
OUT
ST
GND
V
bb
V
IN
V
ST
V
GND
Any kind of load. In case of IN = high is VOUT ≈ VIN - VIN(T+).
Due to VGND > 0, no VST = low signal available.
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BTS 5210G
Inductive load switch-off energy
dissipation
GND disconnect with GND pull up
E bb
IN
Vbb
E AS
PROFET
OUT
IN
ST
GND
PROFET
=
V
V
bb
V
IN ST
V
ZL
{
R
EL
ER
L
Energy stored in load inductance:
2
EL = 1/2·L·I L
While demagnetizing load inductance, the energy
dissipated in PROFET is
EAS= Ebb + EL - ER= VON(CL)·iL(t) dt,
Vbb
PROFET
L
ST
GND
Vbb disconnect with energized inductive
load
IN
OUT
GND
Any kind of load. If VGND > VIN - VIN(T+) device stays off
Due to VGND > 0, no VST = low signal available.
high
ELoad
Vbb
with an approximate solution for RL > 0 Ω:
OUT
EAS=
ST
IL· L
(V + |VOUT(CL)|)
2·RL bb
ln (1+ |V
IL·RL
OUT(CL)|
)
GND
V
Maximum allowable load inductance for
a single switch off (one channel)4)
L = f (IL ); Tj,start = 150°C, Vbb = 12 V, RL = 0 Ω
bb
For inductive load currents up to the limits defined by ZL
(max. ratings and diagram on page 10) each switch is
protected against loss of Vbb.
ZL [mH]
1000
Consider at your PCB layout that in the case of Vbb disconnection with energized inductive load all the load current
flows through the GND connection.
100
10
1
1
2
3
4
5
6
IL [A]
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BTS 5210G
Typ. on-state resistance
RON = f (Vbb,Tj ); IL = 2 A, IN = high
RON [mOhm]
Tj = 150°C
240
180
25°C
120
-40°C
60
0
5
7
9
11
30
40
Vbb [V]
Typ. standby current
Ibb(off) = f (Tj ); Vbb = 9...34 V, IN1,2 = low
Ibb(off) [µA]
45
40
35
30
25
20
15
10
5
0
-50
0
50
100
150
200
Tj [°C]
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BTS 5210G
Timing diagrams
All channels are symmetric and consequently the diagrams are valid for channel 1 to
channel 4
Figure 2b: Switching a lamp:
Figure 1a: Vbb turn on:
IN1
IN
IN2
V bb
ST
V
OUT1
V
V
OUT
OUT2
ST1 open drain
I
L
ST2 open drain
t
t
Figure 2a: Switching a resistive load,
turn-on/off time and slew rate definition:
Figure 3a: Turn on into short circuit:
shut down by overtemperature, restart by cooling
IN
IN1
other channel: norm al operation
VOUT
I
90%
t on
L1
dV/dtoff
I
L(lim)
I
dV/dton
10%
t
L(SCr)
off
t
IL
ST
off(SC)
t
t
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Heating up of the chip may require several milliseconds, depending
on external conditions
2003-Oct-01
BTS 5210G
Figure 5a: Open load: detection in OFF-state, turn
on/off to open load
Open load of channel 1; other channels normal
operation
Figure 3b: Turn on into short circuit:
shut down by overtemperature, restart by cooling
(two parallel switched channels 1 and 2)
IN1/2
IN1
I
L1
+I
VOUT1
L2
2xIL(lim)
I L1
I
t
L(SCr)
ST
off(SC)
ST1/2
10µs
500µs
t
ST1 and ST2 have to be configured as a 'Wired OR' function
ST1/2 with a single pull-up resistor.
Figure 6a: Status change after, turn on/off to
overtemperature
Overtemperature of channel 1; other channels normal
operation
Figure 4a: Overtemperature:
Reset if Tj <Tjt
IN1
IN
ST
ST
30µs
20µs
V
OUT
T
J
t
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BTS 5210G
Package and Ordering Code
Published by
Infineon Technologies AG,
St.-Martin-Strasse 53,
D-81669 München
© Infineon Technologies AG 2001
All Rights Reserved.
Standard: P-DSO-14
Sales Code
BTS 5210G
Ordering Code
Q67060-S7502
Attention please!
The information herein is given to describe certain
components and shall not be considered as a guarantee of
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.
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).
All dimensions in millimetres
Definition of soldering point with temperature Ts:
upper side of solder edge of device pin 15.
Warnings
Due to technical requirements components may contain
dangerous substances. For information on the types in
question please contact your nearest Infineon Technologies
Office.
Pin 15
Infineon Technologies Components may only be used in lifesupport 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 lifesupport 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.
Printed circuit board (FR4, 1.5mm thick, one layer
70µm, 6cm2 active heatsink area) as a reference for
max. power dissipation Ptot, nominal load current
IL(NOM) and thermal resistance Rthja
25m
12m
12m
6 8m
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2003-Oct-01