STMICROELECTRONICS VNP10N07

VNP10N07
”OMNIFET”:
FULLY AUTOPROTECTED POWER MOSFET
TYPE
VNP10N07
■
■
■
■
■
■
■
■
■
■
V clamp
R DS(on)
I l im
70 V
0.1 Ω
10 A
LINEAR CURRENT LIMITATION
THERMAL SHUT DOWN
SHORT CIRCUIT PROTECTION
INTEGRATED CLAMP
LOW CURRENT DRAWN FROM INPUT PIN
DIAGNOSTIC FEEDBACK THROUGH INPUT
PIN
ESD PROTECTION
DIRECT ACCESS TO THE GATE OF THE
POWER MOSFET (ANALOG DRIVING)
COMPATIBLE WITH STANDARD POWER
MOSFET
STANDARD TO-220 PACKAGE
DESCRIPTION
The VNP10N07 is a monolithic device made
using SGS-THOMSON Vertical Intelligent Power
M0 Technology, intended for replacement of
standard power MOSFETS in DC to 50 KHz
applications. Built-in thermal shut-down, linear
1
2
3
TO-220
current limitation and overvoltage clamp protect
the chip in harsh enviroments.
Fault feedback can be detected by monitoring the
voltage at the input pin.
BLOCK DIAGRAM
April 1996
1/11
VNP10N07
ABSOLUTE MAXIMUM RATING
Symbol
Parameter
Value
Unit
V DS
Drain-source Voltage (V in = 0)
Internally Clamped
V
V in
Input Voltage
18
V
ID
Drain Current
Internally Limited
A
IR
Reverse DC O utput Current
-14
A
V esd
Electrostatic Discharge (C= 100 pF , R=1.5 KΩ)
P to t
Total Dissipation at T c = 25 o C
Tj
Tc
T st g
Operating Junction T emperature
Case Operating T emperature
2000
V
50
W
Internally Limited
o
C
Internally Limited
o
C
-55 to 150
o
C
Storage Temperature
THERMAL DATA
R t hj-ca se
R t hj- amb
Thermal Resistance Junction-case
Thermal Resistance Junction-ambient
Max
Max
o
2.5
62.5
o
C/W
C/W
ELECTRICAL CHARACTERISTICS (Tcase = 25 oC unless otherwise specified)
OFF
Symb ol
Parameter
Test Cond ition s
V CLAMP
Drain-source Clamp
Voltage
I D = 200 mA
V CL TH
Drain-source Clamp
Threshold Voltage
I D = 2 mA
V I NCL
Input-Source Reverse
Clamp Voltage
I in = -1 mA
I DSS
Zero Input Voltage
Drain Current (V in = 0)
V DS = 13 V
V DS = 25 V
V in = 0
V in = 0
I I SS
Supply Current from
Input Pin
V DS = 0 V
Vin = 10 V
V in = 0
V in = 0
Min.
Typ .
Max.
Un it
60
70
80
V
55
V
-1
-0.3
V
50
200
µA
µA
250
500
µA
Typ .
Max.
Un it
3
V
0.1
0.14
Ω
Ω
Max.
Un it
ON (∗)
Symb ol
Parameter
Test Cond ition s
Min.
0.8
V IN(th)
Input Threshold
Voltage
V DS = Vin
ID + Ii n = 1 mA
R DS( on)
Static Drain-source On
Resistance
V i n = 10 V
Vi n = 5 V
ID = 5 A
ID = 5 A
DYNAMIC
Symb ol
g fs (∗)
C oss
2/11
Parameter
Test Cond ition s
Forward
Transconductance
V DS = 13 V
ID = 5 A
Output Capacitance
V DS = 13 V
f = 1 MHz
Vin = 0
Min.
Typ .
6
8
350
S
500
pF
VNP10N07
ELECTRICAL CHARACTERISTICS (continued)
SWITCHING (∗∗)
Symb ol
Typ .
Max.
Un it
t d(on)
tr
t d(of f)
tf
Turn-on Delay Time
Rise Time
Turn-off Delay Time
Fall T ime
V DD = 15 V
V gen = 10 V
(see figure 3)
Id = 5 A
R gen = 10 Ω
50
80
230
100
100
160
400
180
ns
ns
ns
ns
t d(on)
tr
t d(of f)
tf
Turn-on Delay Time
Rise Time
Turn-off Delay Time
Fall T ime
V DD = 15 V
V gen = 10 V
(see figure 3)
Id = 5 A
R gen = 1000 Ω
600
0.9
3.8
1.7
900
2
6
2.5
ns
µs
µs
µs
Turn-on Current Slope
V DD = 15 V
V i n = 10 V
Total Input Charge
V DD = 12 V
(di/dt) on
Qi
Parameter
Test Cond ition s
Min.
ID = 5 A
R gen = 10 Ω
ID = 5 A
V in = 10 V
60
A/µs
30
nC
SOURCE DRAIN DIODE
Symb ol
Parameter
Test Cond ition s
V SD (∗)
Forward O n Voltage
I SD = 5 A
t r r (∗∗)
Reverse Recovery
Time
Reverse Recovery
Charge
Reverse Recovery
Current
I SD = 5 A
di/dt = 100 A/µs
V DD = 30 V
Tj = 25 oC
(see test circuit, figure 5)
Q r r (∗∗)
I RRM (∗∗)
Min.
Typ .
V in = 0
Max.
Un it
1.6
V
125
ns
0.3
µC
4.8
A
PROTECTION
Symb ol
I lim
Parameter
Test Cond ition s
Min.
Typ .
Max.
Un it
VDS = 13 V
V DS = 13 V
7
7
10
10
14
14
A
A
20
50
30
80
µs
µs
Drain Current Limit
V i n = 10 V
Vi n = 5 V
t dl im (∗∗)
Step Response
Current Limit
V i n = 10 V
Vi n = 5 V
T jsh (∗∗)
Overtemperature
Shutdown
150
o
C
T j rs (∗∗)
Overtemperature Reset
135
o
C
I gf (∗∗)
Fault Sink Current
V i n = 10 V
Vi n = 5 V
E as (∗∗)
Single Pulse
Avalanche Energy
starting T j = 25 o C
V DD = 20 V
V i n = 10 V R gen = 1 KΩ L = 10 mH
50
20
VDS = 13 V
V DS = 13 V
0.4
mA
mA
J
(∗) Pulsed: Pulse duration = 300 µs, duty cycle 1.5 %
(∗∗) Parameters guaranteed by design/characterization
3/11
VNP10N07
PROTECTION FEATURES
During normal operation, the Input pin is
electrically connected to the gate of the internal
power MOSFET. The device then behaves like a
standard power MOSFET and can be used as a
switch from DC to 50 KHz. The only difference
from the user’s standpoint is that a small DC
current (Iiss) flows into the Input pin in order to
supply the internal circuitry.
The device integrates:
- OVERVOLTAGE
CLAMP
PROTECTION:
internally set at 70V, along with the rugged
avalanche characteristics of the Power
MOSFET stage give this device unrivalled
ruggedness and energy handling capability.
This feature is mainly important when driving
inductive loads.
- LINEAR CURRENT LIMITER CIRCUIT: limits
the drain current Id to Ilim whatever the Input
pin voltage. When the current limiter is active,
the device operates in the linear region, so
power dissipation may exceed the capability of
the heatsink. Both case and junction
temperatures increase, and if this phase lasts
long enough, junction temperature may reach
the overtemperature threshold Tjsh.
4/11
- OVERTEMPERATURE AND SHORT CIRCUIT
PROTECTION: these are based on sensing
the chip temperature and are not dependent on
the input voltage. The location of the sensing
element on the chip in the power stage area
ensures fast, accurate detection of the junction
temperature. Overtemperature cutout occurs at
minimum 150oC. The device is automatically
restarted when the chip temperature falls
below 135oC.
- STATUS FEEDBACK: In the case of an
overtemperature fault condition, a Status
Feedback is provided through the Input pin.
The internal protection circuit disconnects the
input from the gate and connects it instead to
ground via an equivalent resistance of 100 Ω.
The failure can be detected by monitoring the
voltage at the Input pin, which will be close to
ground potential.
Additional features of this device are ESD
protection according to the Human Body model
and the ability to be driven from a TTL Logic
circuit (with a small increase in RDS(on)).
VNP10N07
Thermal Impedance
Derating Curve
Output Characteristics
Transconductance
Static Drain-Source On Resistance vs Input
Voltage
Static Drain-Source On Resistance
5/11
VNP10N07
Static Drain-Source On Resistance
Input Charge vs Input Voltage
Capacitance Variations
Normalized Input Threshold Voltage vs
Temperature
Normalized On Resistance vs Temperature
Normalized On Resistance vs Temperature
6/11
VNP10N07
Turn-on Current Slope
Turn-on Current Slope
Turn-off Drain-Source Voltage Slope
Turn-off Drain-Source Voltage Slope
Switching Time Resistive Load
Switching Time Resistive Load
7/11
VNP10N07
Switching Time Resistive Load
Current Limit vs Junction Temperature
Step Response Current Limit
Source Drain Diode Forward Characteristics
8/11
VNP10N07
Fig. 1: Unclamped Inductive Load Test Circuits
Fig. 2: Unclamped Inductive Waveforms
Fig. 3: Switching Times Test Circuits For
Resistive Load
Fig. 4: Input Charge Test Circuit
Fig. 5: Test Circuit For Inductive Load Switching
And Diode Recovery Times
Fig. 6: Waveforms
9/11
VNP10N07
TO-220 MECHANICAL DATA
mm
DIM.
MIN.
inch
TYP.
MAX.
MIN.
TYP.
MAX.
A
4.40
4.60
0.173
0.181
C
1.23
1.32
0.048
0.051
D
2.40
2.72
0.094
D1
0.107
1.27
0.050
E
0.49
0.70
0.019
0.027
F
0.61
0.88
0.024
0.034
F1
1.14
1.70
0.044
0.067
F2
1.14
1.70
0.044
0.067
G
4.95
5.15
0.194
0.203
G1
2.4
2.7
0.094
0.106
H2
10.0
10.40
0.393
0.409
14.0
0.511
0.551
L2
16.4
L4
0.645
13.0
2.65
2.95
0.104
0.116
L6
15.25
15.75
0.600
0.620
L7
6.2
6.6
0.244
0.260
L9
3.5
3.93
0.137
0.154
DIA.
3.75
3.85
0.147
0.151
D1
C
D
A
E
L5
H2
G
G1
F1
L2
F2
F
Dia.
L5
L9
L7
L6
10/11
L4
P011C
VNP10N07
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsability 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 SGS-THOMSON Microelectronics. Specifications mentioned
in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied.
SGS-THOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express
written approval of SGS-THOMSON Microelectonics.
 1996 SGS-THOMSON Microelectronics - Printed in Italy - All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
Australia - Brazil - Canada - China - France - Germany - Hong Kong - Italy - Japan - Korea - Malaysia - Malta - Morocco - The Netherlands Singapore - Spain - Sweden - Switzerland - Taiwan - Thailand - United Kingdom - U.S.A
.
11/11