ETC VNQ830PEP

VNQ830PEP
®
QUAD CHANNEL HIGH SIDE DRIVER
TARGET SPECIFICATION
TYPE
VNQ830PEP
RDS(on)
60 mΩ (*)
IOUT
14 A (*)
VCC
36 V
(*) Per each channel
CMOS COMPATIBLE INPUTS
OPEN DRAIN STATUS OUTPUTS
■ ON STATE OPEN LOAD DETECTION
■ OFF STATE OPEN LOAD DETECTION
■ SHORTED LOAD PROTECTION
■ UNDERVOLTAGE AND OVERVOLTAGE
SHUTDOWN
■ LOSS OF GROUND PROTECTION
■ VERY LOW STAND-BY CURRENT
■ REVERSE BATTERY PROTECTION (**)
■
■
PowerSSO-24
ORDER CODES
PACKAGE
TUBE
PowerSSO-24 VNQ830PEP
DESCRIPTION
The VNQ830PEP is a monolithic device designed
in STMicroelectronics VIPower M0-3 Technology,
intended for driving any kind of load with one side
connected to ground.
Active VCC pin voltage clamp protects the device
T&R
VNQ830PEP13TR
against low energy spikes (see ISO7637 transient
compatibility table). Active current limitation
combined with thermal shutdown and automatic
restart protects the device against overload. The
device detects open load condition both in on and
off state. Output shorted to VCC is detected in the
off state.Device automatically turns off in case of
ground pin disconnection.
BLOCK DIAGRAM
VCC
VCC
CLAMP
OUTPUT1
OVERVOLTAGE
VCC
UNDERVOLTAGE
CLAMP 1
GND
INPUT1
INPUT2 CONTROL & PROTECTION
STATUS2 EQUIVALENT TO
CHANNEL1
DRIVER 1
LOGIC
VCC
STATUS1
CURRENT LIMITER 1
INPUT2
OUTPUT2
OVERTEMP. 1
INPUT3 CONTROL & PROTECTION
STATUS3 EQUIVALENT TO
CHANNEL1
OUTPUT3
OPENLOAD ON 1
STATUS2
VCC
INPUT3
OPENLOAD OFF 1
STATUS3
INPUT4
INPUT4 CONTROL & PROTECTION
STATUS4 EQUIVALENT TO
CHANNEL1
OUTPUT4
STATUS4
(**) See application schematic at page 8
October 2003 - Revision 1.3 (Working document)
1/11
This is preliminary information on a new product foreseen to be developed. Details are subject to change without notice.
VNQ830PEP
ABSOLUTE MAXIMUM RATING
Symbol
VCC
- VCC
- IGND
IOUT
- IOUT
IIN
ISTAT
VESD
Ptot
Tj
Tc
Tstg
Parameter
DC Supply Voltage
Reverse DC Supply Voltage
DC Reverse Ground Pin Current
DC Output Current
Reverse DC Output Current
DC Input Current
DC Status Current
Electrostatic Discharge (Human Body Model: R=1.5KΩ; C=100pF)
Value
41
- 0.3
- 200
Internally Limited
- 12
+/- 10
+/- 10
Unit
V
V
mA
A
A
mA
mA
- INPUT
4000
V
- STATUS
4000
V
- OUTPUT
5000
V
5000
83
Internally Limited
- 40 to 150
- 55 to 150
V
W
°C
°C
°C
- VCC
Power Dissipation TC=25°C
Junction Operating Temperature
Case Operating Temperature
Storage Temperature
CONNECTION DIAGRAM (TOP VIEW)
VCC
GND
INPUT1
STATUS1
INPUT2
STATUS2
INPUT3
STATUS3
INPUT4
STATUS4
N.C.
VCC
24
23
22
21
20
19
18
17
16
15
14
13
1
2
3
4
5
6
7
8
9
10
11
12
OUTPUT1
OUTPUT1
OUTPUT1
OUTPUT2
OUTPUT2
OUTPUT2
OUTPUT3
OUTPUT3
OUTPUT3
OUTPUT4
OUTPUT4
OUTPUT4
TAB = VCC
CURRENT AND VOLTAGE CONVENTIONS
IS
VINn
INPUTn
IOUTn
ISTATn
OUTPUTn
STATUSn
VOUTn
VSTATn
GND
IGND
2/11
VCC
VCC
IINn
VNQ830PEP
THERMAL DATA
Symbol
Rthj-case
Parameter
Thermal Resistance Junction-case
Value
1.5
Unit
°C/W
Rthj-amb
Thermal Resistance Junction-ambient
52 (*)
°C/W
(*) When mounted on a standard single-sided FR-4 board with 0.5cm2 of Cu (at least 35µm thick). Horizontal mounting and no artificial air
flow.
ELECTRICAL CHARACTERISTICS (8V<VCC<36V; -40°C< Tj <150°C, unless otherwise specified)
POWER OUTPUT
Symbol
VCC
VUSD
VOV
Parameter
Operating Supply Voltage
Undervoltage Shut-down
Overvoltage Shut-down
RON (*)
On State Resistance
Test Conditions
Min
5.5
3
36
Typ
13
4
Max
36
5.5
IOUT =2A; Tj =25 °C
60
Unit
V
V
V
mΩ
IOUT =2A; VCC> 8V
20
120
60
mΩ
µA
Off State; VCC=13V; VIN=VOUT=0V
IS
IL(off1) (**)
IL(off2) (**)
IL(off3) (**)
IL(off4) (**)
Supply Current
Off State Output Current
Off State Output Current
Off State Output Current
Off State Output Current
Off State; VCC=13V; VIN=VOUT=0V;
Tj=25°C
20
40
µA
On State; VCC=13V; VIN=5V; IOUT=0A
8.5
13.5
50
0
5
3
mA
µA
µA
µA
µA
Typ
Max
Unit
VIN=VOUT=0V
VIN=0V; VOUT=3.5V
VIN=VOUT=0V; VCC=13V; Tj =125°C
VIN=VOUT=0V; VCC=13V; Tj =25°C
0
-75
Test Conditions
RL=6.5Ω from VIN rising edge to
VOUT=1.3V
RL=6.5Ω from VIN falling edge to
VOUT=11.7V
Min
(**) Per each channel
SWITCHING (VCC =13V)
Symbol
Parameter
td(on)
Turn-on Delay Time
td(off)
Turn-off Delay Time
dVOUT/
dt(on)
Turn-on Voltage Slope
RL=6.5Ω from VOUT=1.3V to
VOUT=10.4V
dVOUT/
dt(off)
Turn-off Voltage Slope
RL=6.5Ω from VOUT=11.7V to
VOUT=1.3V
30
µs
30
µs
See
relative
diagram
See
relative
diagram
V/µs
V/µs
LOGIC INPUT
Symbol
VIL
IIL
VIH
IIH
VI(hyst)
VICL
Parameter
Input Low Level
Low Level Input Current
Input High Level
High Level Input Current
Input Hysteresis Voltage
Input Clamp Voltage
Test Conditions
VIN = 1.25V
Min
Typ
1
3.25
VIN = 3.25V
IIN = 1mA
IIN = -1mA
Max
1.25
10
0.5
6
6.8
-0.7
8
Unit
V
µA
V
µA
V
V
V
3/11
1
VNQ830PEP
ELECTRICAL CHARACTERISTICS (continued)
VCC - OUTPUT DIODE
Symbol
VF
Parameter
Forward on Voltage
Test Conditions
-IOUT=2A; Tj=150°C
Min
Typ
Max
0.6
Unit
V
STATUS PIN
Symbol
VSTAT
ILSTAT
CSTAT
VSCL
Parameter
Test Conditions
Status Low Output Voltage ISTAT= 1.6 mA
Status Leakage Current
Normal Operation; VSTAT= 5V
Status Pin Input
Normal Operation; VSTAT= 5V
Capacitance
ISTAT= 1mA
Status Clamp Voltage
ISTAT= - 1mA
Min
6
Typ
6.8
Max
0.5
10
Unit
V
µA
100
pF
8
V
-0.7
V
PROTECTIONS
Symbol
TTSD
TR
Thyst
tSDL
Parameter
Shut-down Temperature
Reset Temperature
Thermal Hysteresis
Status Delay in Overload
Conditions
Ilim
Current limitation
Vdemag
Turn-off Output Clamp
Voltage
Test Conditions
Min
150
135
7
Typ
175
14
18
5.5V < VCC < 36V
IOUT=2A; L= 6mH
Unit
°C
°C
°C
20
µs
23
A
23
A
15
Tj>TTSD
VCC=13V
Max
200
VCC-41 VCC-48 VCC-55
V
OPENLOAD DETECTION
Symbol
IOL
tDOL(on)
VOL
TDOL(off)
Parameter
Openload ON State
Detection Threshold
Openload ON State
Detection Delay
Openload OFF State
Voltage Detection
Threshold
Openload Detection Delay
at Turn Off
Test Conditions
Typ
Max
Unit
35
70
140
mA
200
µs
3.5
V
1000
µs
VIN=5V
IOUT=0A
VIN=0V
1.5
OPEN LOAD STATUS TIMING (with external pull-up)
VOUT > VOL
Min
OVER TEMP STATUS TIMING
IOUT< IOL
Tj > TTSD
VINn
VINn
VSTATn
VSTATn
tSDL
tDOL(off)
4/11
2
2.5
tDOL(on)
tSDL
VNQ830PEP
Switching time Waveforms
VOUTn
90%
80%
dVOUT/dt(off)
dVOUT/dt(on)
10%
t
VINn
td(on)
td(off)
t
TRUTH TABLE
CONDITIONS
Normal Operation
Current Limitation
Overtemperature
Undervoltage
Overvoltage
Output Voltage > VOL
Output Current < IOL
INPUT
L
H
L
H
H
L
H
L
H
L
H
L
H
L
H
OUTPUT
L
H
L
X
X
L
L
L
L
L
L
H
H
L
H
STATUS
H
H
H
(Tj < TTSD) H
(Tj > TTSD) L
H
L
X
X
H
H
L
H
H
L
5/11
VNQ830PEP
ELECTRICAL TRANSIENT REQUIREMENTS ON VCC PIN
ISO T/R 7637/1
Test Pulse
I
II
TEST LEVELS
III
IV
1
2
3a
3b
4
5
-25 V
+25 V
-25 V
+25 V
-4 V
+26.5 V
-50 V
+50 V
-50 V
+50 V
-5 V
+46.5 V
-75 V
+75 V
-100 V
+75 V
-6 V
+66.5 V
-100 V
+100 V
-150 V
+100 V
-7 V
+86.5 V
ISO T/R 7637/1
Test Pulse
1
2
3a
3b
4
5
CLASS
C
E
6/11
I
C
C
C
C
C
C
TEST LEVELS RESULTS
II
III
C
C
C
C
C
C
C
C
C
C
E
E
Delays and
Impedance
2 ms 10 Ω
0.2 ms 10 Ω
0.1 µs 50 Ω
0.1 µs 50 Ω
100 ms, 0.01 Ω
400 ms, 2 Ω
IV
C
C
C
C
C
E
CONTENTS
All functions of the device are performed as designed after exposure to disturbance.
One or more functions of the device is not performed as designed after exposure and cannot be returned
to proper operation without replacing the device.
VNQ830PEP
Figure 1: Waveforms
NORMAL OPERATION
INPUTn
OUTPUT VOLTAGEn
STATUSn
UNDERVOLTAGE
VUSDhyst
VCC
VUSD
INPUTn
OUTPUT VOLTAGEn
STATUSn
undefined
OVERVOLTAGE
VCC<VOV
VCC>VOV
VCC
INPUTn
OUTPUT VOLTAGEn
STATUSn
OPEN LOAD with external pull-up
INPUTn
VOUT>VOL
OUTPUT VOLTAGEn
VOL
STATUSn
OPEN LOAD without external pull-up
INPUTn
OUTPUT VOLTAGEn
STATUSn
OVERTEMPERATURE
Tj
TTSD
TR
INPUTn
OUTPUT CURRENTn
STATUSn
7/11
1
VNQ830PEP
APPLICATION SCHEMATIC
+5V
+5V
VCC
Rprot
STATUSn
Dld
µC
Rprot
INPUTn
OUTPUTn
GND
RGND
VGND
GND PROTECTION
REVERSE BATTERY
NETWORK
AGAINST
Solution 1: Resistor in the ground line (RGND only). This
can be used with any type of load.
The following is an indication on how to dimension the
RGND resistor.
1) RGND ≤ 600mV / IS(on)max.
2) RGND ≥ (−VCC) / (-IGND)
where -IGND is the DC reverse ground pin current and can
be found in the absolute maximum rating section of the
device’s datasheet.
Power Dissipation in RGND (when VCC<0: during reverse
battery situations) is:
PD= (-VCC)2/RGND
This resistor can be shared amongst several different
HSD. Please note that the value of this resistor should be
calculated with formula (1) where IS(on)max becomes the
sum of the maximum on-state currents of the different
devices.
Please note that if the microprocessor ground is not
common with the device ground then the RGND will
produce a shift (IS(on)max * RGND) in the input thresholds
and the status output values. This shift will vary
DGND
depending on how many devices are ON in the case of
several high side drivers sharing the same RGND.
If the calculated power dissipation leads to a large resistor
or several devices have to share the same resistor then
the ST suggests to utilize Solution 2 (see below).
Solution 2: A diode (DGND) in the ground line.
A resistor (RGND=1kΩ) should be inserted in parallel to
DGND if the device will be driving an inductive load.
This small signal diode can be safely shared amongst
several different HSD. Also in this case, the presence of
the ground network will produce a shift (j600mV) in the
input threshold and the status output values if the
microprocessor ground is not common with the device
ground. This shift will not vary if more than one HSD
shares the same diode/resistor network.
Series resistor in INPUT and STATUS lines are also
required to prevent that, during battery voltage transient,
the current exceeds the Absolute Maximum Rating.
Safest configuration for unused INPUT and STATUS pin
is to leave them unconnected.
8/11
1
1
VNQ830PEP
LOAD DUMP PROTECTION
OPEN LOAD DETECTION IN OFF STATE
Dld is necessary (Voltage Transient Suppressor) if the
load dump peak voltage exceeds VCC max DC rating. The
same applies if the device will be subject to transients on
the VCC line that are greater than the ones shown in the
ISO T/R 7637/1 table.
Off state open load detection requires an external pull-up
resistor (RPU) connected between OUTPUT pin and a
positive supply voltage (VPU) like the +5V line used to
supply the microprocessor.
The external resistor has to be selected according to the
following requirements:
1) no false open load indication when load is connected:
in this case we have to avoid VOUT to be higher than
VOlmin; this results in the following condition
VOUT=(VPU/(RL+RPU))RL<VOlmin.
2) no misdetection when load is disconnected: in this
case the VOUT has to be higher than VOLmax; this
results in the following condition RPU<(VPU–VOLmax)/
IL(off2).
Because Is(OFF) may significantly increase if Vout is pulled
high (up to several mA), the pull-up resistor RPU should
be connected to a supply that is switched OFF when the
module is in standby.
The values of VOLmin, VOLmax and IL(off2) are available in
the Electrical Characteristics section.
µC I/Os PROTECTION:
If a ground protection network is used and negative
transient are present on the VCC line, the control pins will
be pulled negative. ST suggests to insert a resistor (Rprot)
in line to prevent the µC I/Os pins to latch-up.
The value of these resistors is a compromise between
the leakage current of µC and the current required by the
HSD I/Os (Input levels compatibility) with the latch-up limit
of µC I/Os.
-VCCpeak/Ilatchup ≤ Rprot ≤ (VOHµC-VIH-VGND) / IIHmax
Calculation example:
For VCCpeak= - 100V and I latchup ≥ 20mA; VOHµC ≥ 4.5V
5kΩ ≤ Rprot ≤ 65kΩ.
Recommended Rprot value is 10kΩ.
Open Load detection in off state
V batt.
VPU
VCC
RPU
INPUT
DRIVER
+
LOGIC
IL(off2)
OUT
+
R
STATUS
VOL
RL
GROUND
9/11
VNQ830PEP
mm.
DIM.
MIN.
A2
1.9
a1
0
b
0.34
c
0.23
D
10.2
E
7.4
e
H
L
10.1
0.55
N
10/11
0.4
0.46
0.32
10.4
7.6
8.8
PR
EL
h
0.07
IM
G1
2.15
0.8
e3
G
MAX.
2.22
A
1.9
IN
A
TYP
RY
PowerSSO-24™ MECHANICAL DATA
0.1
0.06
10.5
0.4
0.85
10º
X
3.9
4.3
Y
6.1
6.5
VNQ830PEP
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 results from its use. No license is
granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications 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 components in life support devices or systems without express written approval of STMicroelectronics.
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 2003 STMicroelectronics - Printed in ITALY- All Rights Reserved.
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11/11