Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272 HVIC
High Voltage Integrated Circuit
600 Volts/±2 Amperes
M81700FP
1
Description:
M81700FP is a high voltage Power
MOSFET and IGBT module driver
for half-bridge applications.
Features:
£ Floating Supply Voltage
£ Output Current
£ Half-Bridge Driver
£ SOP-16
Applications:
£ HID
£ PDP
£ MOSFET Driver
£ IGBT Driver
£ Inverter Module Control
Ordering Information:
M81700FP is a ±2 Ampere,
600 Volt HVIC, High Voltage
Integrated Circuit
Outline Drawing and Circuit Diagram
RECOMMENDED MOUNT PAD
A
16
C
D
E
S
T
R
HJ
N
L
M
P
Q
B
E F
G
K
DETAIL "A"
DETAIL "A"
DETAIL "B"
DETAIL "B"
9
1 8
PIN NUMBER
1 LO 9 NC
2 LGND 10 NC
3 VCC 11 VDD
4 NC 12 HIN
5 NC 13 SD
6 VS 14 LIN
7 VB 15 GND
8 HO 16 NC
VDD/VCC
LEVEL
SHIFT
PULSE
GEN
HV
LEVEL
SHIFT
R
S
Q
VDD/VCC
LEVEL
SHIFT
VDD/VCC
LEVEL
SHIFT
R
S
Q
INTER
LOCK
UV DETECT
FILTER
UV DETECT
FILTER
S
R Q
R
DELAY
UV
SIGNAL R
S
Q
VDD
HIN
SD
LIN
GND
11
VB
HO
VS
VCC
LO
LGND
7
8
6
3
1
2
12
13
14
15
Dimensions Inches Millimeters
A 0.31±0.01 7.8±0.3
B 0.41±0.004 10.1±0.1
C 0.21±0.004 5.3±0.1
D 0.12 2.10
E 0.05 1.27
F 0.02±0.002 0.4±0.05
G 0.004 0.1
H 0.07 1.8
J 0.01±0.004 0.1±0.1
Dimensions Inches Millimeters
K 0.05 1.25
L 0.024±0.008 0.6±0.2
M 0.1±0.002 0.2±0.05
N 4°±4° 4°±4°
P 0.03 Max. 0.755 Max.
Q 0.006 0.15
R 0.05 Min. Min. 1.27
S 0.30 7.62
T 0.029 0.76
M81700FP
HVIC, High Voltage Integrated Circuit
600 Volts/±2 Amperes
2
Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
Absolute Maximum Ratings, Ta = 25°C unless otherwise specified
Characteristics Symbol M81701FP Units
High Side Floating Supply Absolute Voltage VB -0.5 ~ 624 Volts
High Side Floating Supply Offset Voltage VS -0.5 ~ 600 Volts
High Side Floating Supply Voltage (VBS = VB – VS) VBS -0.5 ~ 24 Volts
Allowable Offset Supply Voltage Minus Serge (PW < 1µs) -VS -5 Volts
High Side Output Voltage VHO VS – 0.5 ~ VB + 0.5 Volts
Low Side Fixed Supply Voltage VCC -0.5 ~ 24 Volts
Low Side Output Voltage VLO -0.5 ~ VCC + 0.5 Volts
Logic Supply Voltage VDD -0.5 ~ 24 Volts
Logic Input Voltage (HIN, LIN) VIN -0.5 ~ VDD + 0.5 Volts
Shutdown Input Voltage SD -0.5 ~ VDD + 0.5 Volts
Low Side Return Offset Voltage (VCC – LGND < 24V) LGND -5 ~ VCC + 0.5 Volts
Allowable Offset Supply Voltage Transient dVS/dt ±50 V/ns
Package Power Dissipation (Ta = 25°C, On Board) Pd 0.88 Watts
Linear Derating Factor (Ta > 25°C, On Board) K
θ
-8.8 mW/°C
Junction to Case Thermal Resistance Rth(j-c) 50 °C/W
Junction Temperature Tj -20 ~ 125 °C
Operation Temperature T
opr -20 ~ 75 °C
Storage Temperature Tstg -40 ~ 125 °C
Recommended Operating Conditions
Characteristics Symbol Test Conditions Min. Typ. Max. Units
High Side Floating Supply Absolute Voltage VB VS + 10 — VS + 20 Volts
High Side Floating Supply Offset Voltage VS 0 — 500 Volts
High Side Floating Supply Voltage VBS VBS = VB – VS 10 — 20 Volts
Low Side Fixed Supply Voltage VCC 10 — 20 Volts
Logic Supply Voltage VDD 5 — 20 Volts
Logic Input Voltage VIN HIN, LIN 0 — VDD Volts
Shutdown Input Voltage SD 0 — VDD Volts
Low Side Return Offset Voltage LGND -5 — 5 Volts
0.5
1.5
2.0
THERMAL DERATING FACTOR
CHARACTERISTICS
TEMPERATURE, (°C)
PACKAGE POWER DISSIPATION, Pd, (WATTS)
0 25 75 100 125
0
1.0
50
3
M81700FP
HVIC, High Voltage Integrated Circuit
600 Volts/±2 Amperes
Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
Electrical Characteristics
Ta = 25°C, VCC = VBS (= VB – VS) = VDD = 15V, LGND = 0V unless otherwise specified
Characteristics Symbol Test Conditions Min. Typ. Max. Units
Floating Supply Leakage Current IFS VB = VS = 600V — — 1 µA
VBS Standby Current IBS — 0.4 0.7 mA
VCC Standby Current ICC — 0.75 1.5 mA
VDD Standby Current IDD — — 10 µA
High Level Output Voltage VOH IO = 0A, LO, HO 13.8 14.4 — Volts
Low Level Output Voltage VOL IO = 0A, LO, HO — — 0.1 Volts
High Level Input Threshold Voltage VIH15 HIN, LIN — 8.4 9.5 Volts
Low Level Input Threshold Voltage VIL15 HIN, LIN 6.0 6.8 — Volts
High Level Input Threshold Voltage VIH5 HIN, LIN (VDD = 5V) — 3.1 4.1 volts
Low Level Input Threshold Voltage VIL5 HIN, LIN (VDD = 5V) 1.4 2.4 — Volts
Shutdown High Level Input VISDH15 SD — 8.4 9.5 Volts
Threshold Voltage
Shutdown Low Level Input VISDL15 SD 6.0 6.8 — Volts
Threshold Voltage
Shutdown High Level Input VISDH5 SD (VDD = 5V) — 3.1 4.1 Volts
Threshold Voltage
Shutdown Low Level Input VISDL5 SD (VDD = 5V) 1.4 2.4 — Volts
Threshold Voltage
High Level Input Bias Current IIH VIN = 15V — 75 150 µA
Low Level Input Bias Current IIL VIN = 0V — — 1.0 µA
VBS Supply UV Reset Voltage VBSuvr 7.5 8.6 9.7 Volts
VBS Supply UV Hysteresis Voltage VBSuvh 0.1 0.4 0.7 Volts
VBS Supply UV Filter Time tVBSuv — 10 — µs
VCC Supply UV Reset Voltage VCCuvr 7.5 8.6 9.7 Volts
VCC Supply UV Hysteresis Voltage VCCuvh 0.1 0.4 0.7 Volts
VCC Supply UV Filter Time tVCCuv — 10 — µs
Output High Level Short Circuit IOH VO = 0V, VIN = 15V, PW < 10µs — -2.5 — Amperes
Pulsed Current
Output Low Level Short Circuit IOL VO = 15V, VIN = 0V, PW < 10µs — 2.5 — Amperes
Pulsed Current
Output High Level ON Resistance ROH IO = -200mA, ROH = (VOH – VO)/IO — 10 13 Ω
Output Low Level ON Resistance ROL IO = 200mA, ROL = VO /IO — 2.5 3 Ω
High Side Turn-On Propagation Delay tdLH(HO) CL = 1000pF between HO – VS — — 350 ns
High Side Turn-Off Propagation Delay tdHL(HO) CL = 1000pF between HO – VS — — 330 ns
High Side Turn-On Rise Time trH CL = 1000pF between HO – VS — — 60 ns
High Side Turn-Off Fall Time tfH CL = 1000pF between HO – VS — — 30 ns
Low Side Turn-On Propagation Delay tdLH(LO) CL = 1000pf between LO – GND — — 350 ns
Low Side Turn-Off Propagation Delay tdHL(LO) CL = 1000pf between LO – GND — — 330 ns
Low Side Turn-On Rise Time trL CL = 1000pf between LO – GND — — 60 ns
Low Side Turn-Off Rise Time tfL CL = 1000pf between LO – GND — — 30 ns
Delay Matching, ΔtdLH |tdLH(HO) – tdLH(LO)| — — 30 ns
High Side and Low Side Turn-On
Delay Matching, ΔtdHL |tdHL(HO) – tdHL(LO)| — — 30 ns
High Side and Low Side Turn-Off
Shutdown Propagation Delay tSD CL = 1000pF between HO-VS, — — 350 ns
CL = 1000pF between LO-GND
M81700FP
HVIC, High Voltage Integrated Circuit
600 Volts/±2 Amperes
4
Powerex, Inc., 200 E. Hillis Street, Youngwood, Pennsylvania 15697-1800 (724) 925-7272
LO
FUNCTION TABLE (X: H or L)
LO = OFF, HO = OFF
LO = ON, HO = OFF
LO = OFF, HO = ON
LO = OFF, HO = OFF, VBS UV tripped
LO = ON, HO = OFF, VBS UV tripped
LO = OFF, HO = OFF, VCC UV tripped
LO = OFF, HO = OFF, VCC UV tripped
LO = OFF, HO = OFF, SD = ON
L
L
H
H
X
X
L
H
X
HIN Behavioral State
L
H
L
H
L
H
X
X
X
H
H
H
H
L
L
H
H
H
H
H
H
H
H
H
L
L
H
L
L
H
*
L
L
L
L
L
L
H
L
*
L
H
L
L
L
Note : “L” state of VBS UV and VCC UV means that UV trip voltage.
* If both input signals are “H”, refer to TIMING DIAGRAM.
SD
L
L
L
L
L
L
L
L
H
LIN VBS UV VCC UV HO LO
HIN
HIN or LIN
HO or LO
SD
LIN
HO
TIMING DIAGRAM
1. Input/Output Timing Diagram
When input signal (HIN or LIN) is “H”, then output signal (HO or LO) is “H”. In the case of both input signals (HIN and LIN) are “H”,
first coming input signal (HIN or LIN) “H” is only accepted. Corresponding this signal, output signal (HO or LO) becomes “H”.
Corresponding the other signal (LIN or HIN), output signal (LO or HO) keeps “L”.
When shutdown input signal (SD) is “H”, then output signals (HO and LO) are “L”.
Output signals (HO and LO) keep “L” by shutdown input signal (SD) is “L” until next input signal (HIN or LIN) is “H”.
2. Shutdown Input Timing Diagram
Allowable high side floating supply voltage (VBS) transient or low side fixed supply voltage (VCC) transient are below 50V/µs.
In case VBS or VCC are started more than 50V/µs, output signal (HO or LO) may be “H”.
4. Allowable Supply Voltage Transient
VCC (VBS)
LO (HO)
LIN (HIN)
VCCuvt (VBSuvt)
VCCuvh (VBSuvh)
VCCuvr (VBSuvr)
tVCCuv (tVBSuv)
3. VCC (VBS) Supply Under Voltage Lockout Timing Diagram
