INTERSIL 5962F9961701VSC

HS-4080ARH
Data Sheet
Febuary 2000
Radiation Hardened Full Bridge
N-Channel FET Driver
File Number
4563.3
Features
• Electrically Screened to SMD # 5962-99617
The HS-4080ARH is a monolithic, high frequency, medium
voltage Full Bridge N-Channel FET Driver IC. The device
includes a TTL-level input comparator, which can be used to
facilitate the “hysteresis” and PWM modes of operation. Its
HEN (high enable) lead can force current to freewheel in the
bottom two external power MOSFETs, maintaining the upper
power MOSFETs off. The HS-4080ARH is well suited for use
in distributed DC power supplies and DC to DC converters,
since it can switch at high frequencies.
These devices can also drive medium voltage motors, and
two HS-4080ARHs can be used to drive high performance
stepper motors, since the short minimum “on-time” can
provide fine micro-stepping capability.
Short propagation delays maximize control loop crossover
frequencies and dead-times, which can be adjusted to near
zero to minimize distortion, resulting in precise control of the
driven load.
• QML Qualified per MIL-PRF-38535 Requirements
• Radiation Environment
- Gamma Dose . . . . . . . . . . . . . . . . . 300kRAD(Si) (Max)
- Latch-up Immune RSG DI Process
• Drives N-Channel FET Full Bridge Including High Side
Chop Capability
• Bootstrap Supply Max Voltage to 95VDC
• TTL Comparator Input Levels
• Drives 1000pF Load with Rise and Fall Times of 50ns
• User-Programmable Dead Time
• Charge-Pump and Bootstrap Maintain Upper Bias
Supplies
• DIS (Disable) Pin Pulls Gates Low
• Operates From Single Supply . . . . . . . . . . . . . 12V to 18V
Constructed with the Intersil dielectrically isolated Rad Hard
Silicon Gate (RSG) process, these devices are immune to
Single Event Latch-up and have been specifically designed
to provide highly reliable performance in harsh radiation
environments. Complete your design with radiation
hardened MOSFETs from Intersil.
• Low Power Consumption
Specifications for Rad Hard QML devices are controlled
by the Defense Supply Center in Columbus (DSCC). The
SMD numbers listed here must be used when ordering.
• PWM Motion Control
Detailed Electrical Specifications for these devices are
contained in SMD 5962-99617. A “hot-link” is provided
on our homepage for downloading.
http://www.intersil.com/spacedefense/space.htm
Pinout
• Undervoltage Protection
Applications
• Full Bridge Power Supplies
Ordering Information
ORDERING NUMBER
INTERNAL
MKT. NUMBER
TEMP. RANGE
(oC)
5962F9961701VSC
HS9-4080ARH-Q
-55 to 125
5962F9961701QSC
HS9-4080ARH-8
-55 to 125
HS9-4080ARH/Proto
HS9-4080ARH/Proto
-55 to 125
HS-4080ARH (FLATPACK, CDFP3-F20)
TOP VIEW
BHB
1
20
BHO
HEN
2
19
BHS
DIS
3
18
BLO
VSS
4
17
BLS
OUT
5
16
VDD
IN+
6
15
VCC
IN-
7
14
ALS
HDEL
8
13
ALO
LDEL
9
12
AHS
AHB
10
11
AHO
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CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Copyright © Intersil Corporation 2000
HS-4080ARH
HS-4080ARH Preliminary Pin Descriptions
PIN
NUMBER
SYMBOL
DESCRIPTION
1
BHB
B High-side Bootstrap supply. External bootstrap diode and capacitor are required. Connect cathode of boot-strap
diode and positive side of bootstrap capacitor to this pin. Internal charge pump supplies 50µA out of this pin to maintain
bootstrap supply. Internal circuitry clamps the bootstrap supply to approximately 15V.
2
HEN
High-side Enable input. Logic level input that when low overrides IN+/IN- (Pins 6 and 7) to put AHO and BHO drivers
(Pins 11 and 20) in low output state. When HEN is high AHO and BHO are controlled by IN+/IN- inputs. The pin can
be driven by signal levels of 0V to 18V (no greater than VDD). An internal 100µA pull-up to VDD will hold HEN high, so
no connection is required if high-side and low-side outputs are to be controlled by IN+/IN -inputs.
3
DIS
DISable input. Logic level input that when taken high sets all four outputs low. DIS high overrides all other inputs. When
DIS is taken low the outputs are controlled by the other inputs. The pin can be driven by signal levels of 0V to 18V (no
greater than VDD). An internal 100µA pull-up to VDD will hold DIS high if this pin is not driven.
4
VSS
Chip negative supply, generally will be ground.
5
OUT
OUTput of the input control comparator. This rail to rail output signal can be used for feedback and hysteresis.
6
IN+
Noninverting input of control comparator. This pin can only be driven by signal levels of 0V to 5.5V. If IN+ is greater
than IN- (Pin 7) then ALO and BHO are low level outputs and BLO and AHO are high level outputs. If IN+ is less than
IN- then ALO and BHO are high level outputs and BLO and AHO are low level outputs. DIS (Pin 3) high level will
override IN+/IN- control for all outputs. HEN (Pin 2) low level will override IN+/IN- control of AHO and BHO. When
switching in four quadrant mode, dead time in a half bridge leg is controlled by HDEL and LDEL (Pins 8 and 9).
7
IN-
Inverting input of control comparator. This pin can only be driven by signal levels of 0V to 5.5V. See IN+ (Pin 6)
description.
8
HDEL
High-side turn-on DELay. Connect resistor from this pin to VSS to set timing current that defines the turn-on delay of
both high-side drivers. The low-side drivers turn-off with no adjustable delay, so the HDEL resistor guarantees no
shoot-through by delaying the turn-on of the high-side drivers. HDEL reference voltage is approximately 5.1V.
9
LDEL
Low-side turn-on DELay. Connect resistor from this pin to VSS to set timing current that defines the turn-on delay of
both low-side drivers. The high-side drivers turn-off with no adjustable delay, so the LDEL resistor guarantees no shootthrough by delaying the turn-on of the low-side drivers. LDEL reference voltage is approximately 5.1V.
10
AHB
A High-side Bootstrap supply. External bootstrap diode and capacitor are required. Connect cathode of boot-strap
diode and positive side of bootstrap capacitor to this pin. Internal charge pump supplies 30µA out of this pin to maintain
bootstrap supply. Internal circuitry clamps the bootstrap supply to approximately 15V.
11
AHO
A High-side Output. Connect to gate of A High-side power MOSFET.
12
AHS
A High-side Source connection. Connect to source of A High-side power MOSFET. Connect negative side of bootstrap
capacitor to this pin.
13
ALO
A Low-side Output. Connect to gate of A Low-side power MOSFET.
14
ALS
A Low-side Source connection. Connect to source of A Low-side power MOSFET.
15
VCC
Positive supply to gate drivers. Must be same potential as VDD (Pin 16). Connect to anodes of two bootstrap diodes.
16
VDD
Positive supply to lower gate drivers. Must be same potential as VCC (Pin 15). De-couple this pin to VSS (Pin 4).
17
BLS
B Low-side Source connection. Connect to source of B Low-side power MOSFET.
18
BLO
B Low-side Output. Connect to gate of B Low-side power MOSFET.
19
BHS
B High-side Source connection. Connect to source of B High-side power MOSFET. Connect negative side of bootstrap
capacitor to this pin.
20
BHO
B High-side Output. Connect to gate of B High-side power MOSFET.
2
HS-4080ARH
Application Block Diagram
80V
12V
BHO
BHS
HEN
LOAD
BLO
DIS
HS-4080ARH
IN+
ALO
AHS
IN-
AHO
GND
GND
Typical Application (Hysteresis Mode Switching)
80V
1 BHB
BHO 20
2 HEN
BHS 19
DIS
3 DIS
BLO 18
4 VSS
BLS 17
5 OUT
6 IN+
6V
7 ININ
HS-4080ARH
12V
8 HDEL
LOAD
VDD 16
VCC 15
12V
ALS 14
ALO 13
9 LDEL
AHS 12
10 AHB
AHO 11
GND
+
6V
GND
3
HS-4080ARH
Die Characteristics
DIE DIMENSIONS:
ASSEMBLY RELATED INFORMATION:
4760µm x 5660µm (188 mils x 223 mils)
Thickness: 483µm ±25.4µm (19 mils ±1 mil)
INTERFACE MATERIALS:
Substrate Potential:
Unbiased (DI)
ADDITIONAL INFORMATION:
Glassivation:
Type: Phosphorus Silicon Glass
Thickness: 8.0kÅ ±1.0kÅ
Worst Case Current Density:
<2.0 x 105 A/cm2
Transistor Count:
Top Metallization:
432
Type: AlSiCu
Thickness: 16.0kÅ ±2kÅ
Substrate:
Radiation Hardened Silicon Gate,
Dielectric Isolation
Backside Finish:
Silicon
Metallization Mask Layout
HS-4080ARH
15
16
17
14
18
13
19
12
20
11
1
10
9
2
8
3
7
4
5
6
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Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements 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 Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see web site www.intersil.com
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