STMICROELECTRONICS VN03SP13TR

VN03SP

HIGH SIDE SMART POWER SOLID STATE RELAY
T YPE
V DSS
R DS(on)
I n( *)
V CC
VN03SP
60 V
0.5 Ω
0.7 A
26 V
■
■
■
■
■
■
■
MAXIMUM CONTINUOUS OUTPUT
CURRENT (#):9 A @ Tc=85oC
5 V LOGIC LEVEL COMPATIBLE INPUT
THERMAL SHUT-DOWN
UNDER VOLTAGE PROTECTION
OPEN DRAIN DIAGNOSTIC OUTPUT
INDUCTIVE LOAD FAST
DEMAGNETIZATION
VERY LOW STAND-BY POWER
DISSIPATION
DESCRIPTION
The VN03SP is a monolithic device made using
STMicroelectronics
VIPower
Technology,
intended for driving resistive or inductive loads
with one side grounded.
Built-in thermal shut-down protects the chip from
over temperature and short circuit.
The open drain diagnostic output indicates: open
load in off state, and in on state, output shorted to
10
1
PowerSO-10
VCC and overtemperature. Fast demagnetization
of inductive loads is archivied by negative (-18V)
load voltage at turn-off.
(*) In = Nominal current according to ISO definition for high side automotive switch (see note 1)
(#) The maximum continuous output current is the the current at Tc = 85 oC for a battery voltage of 13V which does not activate self
protection.
July 1998
1/9
VN03SP
ABSOLUTE MAXIMUM RATING
Symb ol
V (BR)DSS
I OUT
Parameter
Value
Unit
60
V
Output Current (cont.) at T c = 85 C
4
A
o
-4
A
±10
mA
-4
V
±10
mA
2000
V
Drain-Source Breakdown Voltage
o
IR
Reverse Output Current at T c = 85 C
I IN
Input Current
-V CC
Reverse Supply Voltage
I STAT
Status Current
V ESD
Electrostatic Discharge (1.5 kΩ, 100 pF)
P tot
Tj
T s tg
o
Power Dissipation at T c = 85 C
Junction Operating Temperature
Storage Temperature
CONNECTION DIAGRAMS
CURRENT AND VOLTAGE CONVENTIONS
2/9
14
W
-40 to 150
o
C
-55 to 150
o
C
VN03SP
THERMAL DATA
R t hj-ca se
R t hj- amb
Thermal Resistance Junction-case
Thermal Resistance Junction-ambient ($)
Max
Max
o
4.5
50
o
C/W
C/W
($) When mounted using minimum recommended pad size on FR-4 board
ELECTRICAL CHARACTERISTICS (VCC = 13 V; -40 ≤ Tj ≤ 125 oC unless otherwise specified)
POWER
Symb ol
VCC
Parameter
Test Cond ition s
Supply Voltage
o
In(*)
Nominal Current
T c = 85 C
R on
On State Resistance
I OUT = 0.7 A
I OUT = 0.7 A
Supply Current
Off St ate
On State
IS
V DS(MAX)
V DS(on) ≤ 0.5 (note 1)
Min.
Typ .
Max.
Un it
5.5
13
26
V
0.7
A
T j = 25 o C
o
Tj ≥ 25 C
Tc = 85 o C
Maximum Voltage Drop I OUT = 4 A
1
0.5
Ω
Ω
50
15
µA
mA
3.6
V
Max.
Un it
SWITCHING
Symb ol
Parameter
t d(on)(^)
Turn-on Delay Time Of
Output Current
I OUT = 0.7 A Resistive Load
Input Rise T ime < 0.1 µs
15
µs
Rise Time O f O utput
Current
I OUT = 0.7 A Resistive Load
Input Rise T ime < 0.1 µs
10
µs
Turn-off Delay Time O f I OUT = 0.7 A Resistive Load
Output Current
Input Rise T ime < 0.1 µs
15
µs
4
µs
t r (^)
t d(off )(^)
tf (^)
Test Cond ition s
Min.
Typ .
Fall T ime Of Output
Current
I OUT = 0.7 A Resistive Load
Input Rise T ime < 0.1 µs
(di/dt) on
Turn-on Current Slope
I OUT = 0.7 A
I OUT = I OV
0.05
0.5
1
A/µs
A/µs
(di/dt) off
Turn-off Current Slope
I OUT = 0.7 A
I OUT = I OV
0.14
3
3
A/µs
A/µs
V demag
Inductive Load Clamp
Voltage
I OUT = 0.7 A
L = 1 mH
-24
-18
-14
V
Test Cond ition s
Min.
Typ .
Max.
Un it
0.8
V
(•)
V
LOGIC INPUT
Symb ol
Parameter
VI L
Input Low Level
Voltage
VI H
Input High Level
Voltage
V I(hyst.)
Input Hysteresis
Voltage
I IN
V ICL
2
0.5
Input Current
VI N = 5 V
VI N = 2 V
V I N = 0.8 V
Input Clamp Voltage
I IN = 10 mA
I IN = -10 mA
250
V
500
250
25
5.5
6
-0.7
-0.3
µA
µA
µA
V
V
3/9
VN03SP
ELECTRICAL CHARACTERISTICS(continued)
PROTECTION AND DIAGNOSTICS
Symb ol
Parameter
Test Cond ition s
V STAT
Status Voltage Output
Low
V USD
Under Voltage Shut
Down
V SCL
Status Clamp Voltage
I STAT = 10 mA
I STAT = -10 mA
Over Current
R LOAD < 10 mΩ
I OV
Min.
Typ .
I STAT = 1.6 mA
Max.
Un it
0.4
V
5
V
6
-0.7
V
V
-40 T c 125 o C
28
o
A
I AV
Average Current in
Short Circuit
I OL
Open Load Current
Level
5
T TSD
Thermal Shut-down
Temperature
140
o
C
TR
Reset Temperature
125
o
C
V OL
Open Load Voltage
Level
Off-State (note 2)
t 1(on)
Open Load Filtering
Time
t 1(of f)
R LOAD < 10 mΩ
Tc = 85 C
0.9
35
A
70
mA
2.5
3.75
5
V
(note 3)
1
5
10
ms
Open Load Filtering
Time
(note 3)
1
5
10
ms
t 2(of f)
Open Load Filtering
Time
(note 3)
1
5
10
ms
t povl
Status Delay
(note 3)
5
10
µs
t po l
Status Delay
(note 3)
50
700
µs
(^) See Switchig Time Waveforms
() The VIH is internally clamped at 6V about. It is possible to connect this pin to an higher voltage via an external resistor calculated to not
exceed 10 mA at the input pin.
note 1:The Nominal Current is the current at Tc = 85 oC for battery voltage of 13V which produces a voltage drop of 0.5 V
note 2:IOL (off) = (VCC -VOL)/ROL (see figure)
note 3:t1(on): minimum open load duration which acctivates the status output
t1(off): minimum load recovery time which desactivates the status output
t2(off): minimum on time after thermal shut down which desactivates status output
tpo vl tpol: ISO definition (see figure)
Note 2 Relevant Figure
4/9
Note 3 Relevant Figure
VN03SP
Switching Time Waveforms
FUNCTIONAL DESCRIPTION
The device has a diagnostic output which
indicates open load conditions in off state as well
as in on state, output shorted to VCC and
overtemperature. The truth table shows input,
diagnostic and output voltage level in normal
operation and in fault conditions. The output
signals are processed by internal logic. The
open load diagnostic output has a 5 ms filtering.
The filter gives a continuous signal for the fault
condition after an initial delay of about 5 ms. This
means that a disconnection during normal
operation, with a duration of less than 5 ms does
not affect the status output. Equally, any
re-connection of less than 5 ms during a
disconnection duration does not affect the status
output. No delay occur for the status to go low in
case of overtemperature conditions. From the
falling edge of the input signal the status output
initially low in fault condition (over temperature or
open load) will go back with a delay (tpovl)in case
of overtemperature condition and a delay (tpol) in
case of open load. These feature fully comply
with International Standard Office (I.S.O.)
requirement for automotive High Side Driver.
To protect the device against short circuit and
over current conditions, the thermal protection
turns the integrated Power MOS off
at
a
minimum
junction
temperature of 140 oC.
When the temperature returns to 125 oC the
switch is automatically turned on again. In short
circuit the protection reacts with virtually no
delay, the sensor being located in the region of
the die where the heat is generated. Driving
inductive loads, an internal function of the
device ensures the fast demagnetizationwith a
typical voltage (Vdemag) of -18V.
This function allows to greatly reduce the power
dissipation according to the formula:
Pdem = 0.5 • Lload • (Iload)2• [(VCC+Vdemag)/Vdemag]
•f
where f = switching frequency and
Vdemag = demagnetization voltage
Based on this formula it is possible to know
the value of inductance and/or current to avoid
a thermal shut-down. The maximum inductance
which causes the chip temperature to reach the
shut down temperature in a specific thermal
environment, is infact a function of the load
current for a fixed VCC, Vdemag and f.
PROTECTING THE DEVICE AGAIST LOAD
DUMP - TEST PULSE 5
The device is able to withstand the test pulse
No. 5 at level II (Vs = 46.5V) according to the
ISO T/R 7637/1
without
any
external
component. This means that all functions of the
device are performed as designed
after
exposure to disturbance at level II. The VN06SP
is able to withstand the test pulse No.5 at level
III adding an external resistor of 150 ohm
between GND pin and ground plus a filter
capacitor of 1000 µF between VCC pin and
ground (if RLOAD ≤ 20 Ω).
PROTECTING
THE
DEVICE
AGAINST
REVERSE BATTERY
The simplest way to protect the device against a
continuous reverse battery voltage (-26V) is to
insert a Schottky diode between GND pin and
ground, as shown in the typical application circuit
(fig.3).
The consequences of the voltage drop across
this diode are as follows:
If the input is pulled to power GND, a negative
voltage of -Vf is seen by the device. (Vil, Vih
thresholds and Vstat are increased by Vf with
respect to power GND).
The undervoltage shutdown level is increa- sed
by Vf.
If there is no need for the control unit to handle
external analog signals referred to the power
GND, the best approach is to connect the
reference potential of the control unit to node [6]
(see application circuit in fig. 4), which becomes
the common signal GND for the whole control
board avoiding shift of Vih, Vil and Vstat. This
solution allows the use of a standard diode.
5/9
VN03SP
TRUTH TABLE
INPUT
O UTPUT
DIAGNOST IC
Normal Operation
L
H
L
H
H
H
O pen Circuit (No Load)
H
H
L
O ver-temperature
H
L
L
Under-voltage
X
L
H
Short load to V CC
L
H
L
Figure 1: Waveforms
Figure 2: Over Current Test Circuit
6/9
VN03SP
Figure 3: Typical Application Circuit With A Schottky Diode For Reverse Supply Protection
Figure 4: Typical Application Circuit With Separate Signal Ground
7/9
VN03SP
PowerSO-10 MECHANICAL DATA
mm
DIM.
MIN.
inch
TYP.
MAX.
MIN.
TYP.
MAX.
A
3.35
3.65
0.132
0.144
A1
0.00
0.10
0.000
0.004
B
0.40
0.60
0.016
0.024
c
0.35
0.55
0.013
0.022
D
9.40
9.60
0.370
0.378
D1
7.40
7.60
0.291
0.300
E
9.30
9.50
0.366
0.374
E1
7.20
7.40
0.283
0.291
E2
7.20
7.60
0.283
0.300
E3
6.10
6.35
0.240
0.250
E4
5.90
6.10
0.232
e
1.27
0.240
0.050
F
1.25
1.35
0.049
0.053
H
13.80
14.40
0.543
0.567
1.80
0.047
h
0.50
L
0.002
1.20
q
1.70
0.067
o
α
0.071
8o
0
B
0.10 A B
10
5
e
0.25
B
=
=
=
E4
=
=
=
1
E1
=
E3
=
E2
=
E
=
=
=
H
6
SEATING
PLANE
DETAIL ”A”
A
C
M
Q
h
D
= D1 =
=
=
SEATING
PLANE
A
F
A1
A1
L
DETAIL ”A”
α
0068039-C
8/9
VN03SP
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences
of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is
granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specification mentioned in this publication are
subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products
are not authorized for use as critical compone nts in life support devices or systems without express written approval of STMicroelectronics.
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 1998 STMicroelectronics – Printed in Italy – All Rights Reserved
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