IRF ML1000605D 100v input, dual output Datasheet

PD-97806
ML1000605D
100V Input, Dual Output
HIGH RELIABILITY
RADIATION HARDENED
LOW POWER
DC-DC CONVERTER
Description
The ML-Series of isolated DC-DC converters for space
applications are low power radiation hardened high
reliability devices designed for hostile radiation
environments such as those encountered by geostationary
earth orbit satellites, deep space probes and communication
systems. Features include small size, high efficiency,
low weight, and a good tolerance to total ionizing dose,
single event effects, and environmental stresses such
as temperature extremes, mechanical shock, and
vibration. All components are fully derated to meet the
requirements of EEE-INST-002 (NASA) and ECSS-Q30-11A (ESA). Extensive documentation including worst
case analysis, radiation susceptibility, thermal analysis,
stress analysis, and reliability analysis are available.
The ML-Series converter has two outputs – one positive
and one negative - each is independently regulated via
linear post regulators. The outputs are sequenced
during turn-on and turn-off such that negative output
comes up first at turn-on and stays up at turn-off until the
positive output has decreased. The ML-series converters
incorporate a fixed frequency flyback power converter
and internal EMI filter that meets the requirements for
most major satellite power buses. The converter includes
isolated On/Off telecommand with associated status
telemetry. The converter also includes input under
voltage shut-down functionality.
Due to the linear post regulation of the outputs, the MLSeries is well suited for use in RF-applications where
low noise, high output voltage accuracy, and high CS
attenuation is required.
Each converter is provided as a complete board
assembly for installation into the host equipment chassis.
The board is conformal coated (except for mating
surfaces) and is mounted in the host chassis using
screws. The board outline is L x W x H: 70mm x 50mm x
18mm. The weight is less than 50 grams.
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Features
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Total Dose > 100 krad(Si)
SEE > 82 MeV.cm2/mg
Low Weight < 50 grams
97V to 103V DC Input Range
O/P 1: +6.0V (up to 500mA)
O/P 2: -5.0V (up to 100mA)
Output Ripple: < 1mVrms (100Hz - 50MHz)
CS Rejection Input to Outputs: > 90dB
(50Hz - 1.0MHz)
10MΩ @ 100VDC Isolation
Input Under-Voltage Protection
Meets Conducted Emission Requirements of
Major Power Buses:
100Hz - 100kHz: 80dBuArms
100kHz - 10MHz: -20dB/decade
10MHz - 50MHz: 40dBuArms
Short Circuit and Overload Protection
Meets Derating Requirements of EEE-INST
002 and ECSS-Q-30-11A
Isolated On/Off Control via High Level Pulse
Command (Latching Relay)
Status Telemetry (Relay Contact Type)
Workmanship Per IPC-A610 Class 3
Board is Coated with ARATHANE-5750
Applications
n
Low Power RF Systems (like LNA) on-board
Satellites
Non-flight versions of the ML-Series converters
are available for system development purposes.
Variations in electrical specifications and
screening to meet custom requirements can be
accommodated.
1
04/22/13
ML1000605D
(100V Input, Dual Output)
Circuit Description
Design Methodology
The ML-Series converters utilize two-stage regulation
with a flyback topology with a switching frequency of
140kHz for primary regulation and linear post
regulation for each of the outputs.
The ML-Series is developed using a proven
conservative design methodology, which includes
selecting radiation tolerant, and established
reliability components and full derating to the
requirements of EEE-INST-002 and ECSS-ST-11A.
The Output power is limited under any load fault
condition to approximately 120% of rated output.
An overload condition on the positive output causes
the converter output to behave like a constant current
source with the output voltage dropping below
nominal. An overload condition at the negative output
causes the positive output to shut-down in order to
protect RF-transistors in the load. The converter will
resume normal operation when the load current is
reduced below the current limit point.
An under-voltage protection circuit prohibits the
converter from operating when the line voltage is
too low for safe operation. In case of an under
voltage event the converter will not start when the
input voltage returns to its nominal level before an
Off-command followed by an On-command has been
issued.
The isolated On/Off telecommand is made with a
latching relay and is intended for use with a 26V
pulse command. A status telemetry derived from a
spare set of contacts in the relay is used for status
telemetry.
For further information please refer to the ML-Series
generic description available at www.irf.com.
2
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ML1000605D
(100V Input, Dual Output)
Specifications
Absolute Maximum Ratings
Recommended Operating Conditions
Input voltage range
Output power
Operating mounting point
temperature (Note 10)
Storage temperature
Input voltage range (Note 9)
Output power
Operating mounting point
temperature (Note 9)
Cold start temperature
-0.5Vdc to +120Vdc
Internally limited
-55°C to +100°C
-55°C to +125°C
Conditions
Condition
-55°C
* Meets full derating
Electrical Performance Characteristics
Parameter
+97Vdc to +103Vdc
0 to Max. Rated
-40°C to +75°C *
Limits
-40°C ≤ Tc ≤ +75°C
VIN = 100V DC ± 0.5%, CL = 0µF
Unit
Min
Nom
Max
97
100
103
V
+5.970
+6.00
+6.030
V
-4.975
-5.00
-5.025
unless otherwise specified
Primary Input Voltage
Note 1
Output voltage ( VOUT )
(O/P 1, O/P 2)
+6.0V
1
-5.0V
1
+6.0V
2
-5.0V
2
+6.0V
3
-5.0V
3
0% ≤ IOUT ≤ 100% of rated load
0% ≤ IOUT ≤ 100% of rated load
0% ≤ IOUT ≤ 100% of rated load
+5.940
+6.060
-4.950
-5.050
+5.880
6.120
-4.900
5.100
V
V
Output power ( POUT )
(O/P 1, O/P 2)
+6.0V
1,2,3
3.0
VIN = 97, 100, 103V
W
0.5
-5.0V
Output current ( IOUT )
(O/P 1, O/P 2)
+6.0V
1,2,3
0
500
0
100
IOUT = 10%, 50%, 100% rated
-1.0
1.0
mV
IOUT = 10%, 50%, 100% rated
VIN = 97, 100, 103V
-1.0
1.0
mV
1.0
mV
15
mA
VIN = 97, 100, 103V
-5.0V
Line regulation ( VRLINE )
1,2,3
Each output
Load regulation ( VRLOAD )
1,2,3
Each output
mA
VIN = 97, 100, 103V
Cross regulation ( VRCROSS )
Input current
1,2,3
VIN = 97, 100, 103V, Note 1
1,2,3
IOUT = 0, commanded On
10
Commanded Off
Switching frequency ( FS )
2.0
1,2,3
Notes 1, 7
126
1,2,3
0% ≤ IOUT ≤ 100% of rated load
85
140
154
kHz
95
V
2.0
12
ms
1.0
8.0
Input under voltage
Trig level
Output Sequencing
Turn-on delay O/P 2 to O/P 1
Turn-off delay O/P1 to O/P 2
1,2,3
IOUT ≥ 20% for Output 1
For Notes to Specifications, refer to page 5
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3
ML1000605D
(100V Input, Dual Output)
Electrical Performance Characteristics
(continued)
Conditions
Parameter
Condition
Limits
-40°C ≤ Tc ≤ +75°C
VIN = 100V DC ± 0.5%, CL = 0µF
Unit
Min
Nom
Max
unless otherwise specified
Output ripple ( VRIP )
VIN = 97, 100, 103V
Each output
IOUT = 100% rated load
+6.0V
1
Frequency domain 100Hz – 50MHz
1.0
Note 1
1.0
Time domain 100Hz – 50MHz
30
Notes 1, 2
30
-5.0V
+6.0V
1,2
-5.0V
mVrms
mVpp
Efficiency ( EFF )
For combined output power
of
IOUT = 20% rated load
37
38
1.75W
IOUT = 50% rated load
52
54
3.50W
IOUT = 100% rated load
60
62
Note 1
0.70W
1,2,3
%
Telecommand I/F
Pulse Voltage high
+22
+30
Pulse Voltage low
1,2,3
-40
0.5
V
Pulse duration
10
1000
ms
V
Telemetry
Converter On
1,2,3
400
Converter Off
422
450
1.0
ohm
Mohm
Current Limit Point
VOUT = 100mV below Nominal
Each output
+6.0V
1,2,3
-5.0V
Output response to
step load changes ( VTLD )
+6.0V
1,2,3
20% to / from 100% Load, Note 3
-5.0V
550
700
110
150
-70
-50
70
50
mA
mV pk
Recovery time,
20% to / from 100% Load , Notes 3, 4
step load changes ( TTLD )
+6.0
1,2,3
2.5
-5.0
ms
2.5
Turn-on Response
Overshoot ( VOS )
+6.0V
1,2,3
10% Load, Full Load
Note 5
60
-5.0V
2.0
Turn-on Delay
Capacitive Load ( CL )
+6.0V
-5.0V
mV
50
1
10
IOUT = 100% rated load
100
No effect on DC performance
100
ms
µF
Notes 1, 6
Each output
For Notes to Specifications, refer to page 5
4
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ML1000605D
(100V Input, Dual Output)
Electrical Performance Characteristics
Parameter
Condition
EMC conducted
susceptibility
1
(Line rejection)
Electromagnetic Interference
(EMI), conducted emission
(CE)
Isolation
1
1
(continued)
Conditions
-40°C ≤ Tc ≤ +75°C
VIN = 100V DC ± 0.5%, CL = 0µF
unless otherwise specified
IOUT = 100% rated load
Primary power sine wave injection of
2Vp-p, 100Hz to 1MHz, Note 1
Limits
Unit
Min
Nom
96
110
IOUT = 100% rated load, Notes 1, 7
Input to Output, any potential to
telecommand input and any potential to
telemetry output, test @ 100VDC
dB
Limits per Figures 4 and 5
10
Device Weight
Failure Rate
Max
MIL-HDBK-217F2, SF, 35°C, Note 8
MΩ
50
g
60
FITs
Notes: Specification and Electrical Performance Characteristics Tables
1.
Parameter is tested as part of design characterization or after design changes. Thereafter, parameter shall
be guaranteed to the limits specified.
2. Guaranteed for a D.C. to 50MHz bandwidth. Tested using a 10.7MHz bandwidth.
3. Load current step transition time ≥ 10 µs.
4. Recovery time is measured from the initiation of the transient to where V OUT has returned to within ±1% of
its steady state value.
5. Turn-on delay time from application of telecommand pulse to the point where Output 2 = 98% of nominal
output voltage.
6. Capacitive load may be any value from 0 to the maximum limit without compromising the output sequencing
performance. A capacitive load in excess of the maximum limit may influence the output sequencing
performance and start-up time, converter operation and dc performance will remain intact.
7. The switching frequency and 1st and 2nd harmonic of the input ripple is tested on every unit.
8. MIL-HDBK-217F2 stress-dependent method is used with 2 exceptions: For soldering a fixed failure rate at
0.035FIT is used and for power MOSFETs the dissipated power (instead of rated power) is used for the Pr
parameter. 1 FIT is 1 failure in 109 hours.
9. The converter meets full derating per EEE-INST-002 and ECSS-Q-30-11A with the following exception: For
Schottky diode JANS1N5819 a maximum derated junction temperature of +110°C. For EEE-INST-002 it is
required that ceramic capacitors with a voltage stress below 10V shall be rated for minimum 100V - in the
product such capacitors is rated for 50V minimum.
10. Although operation temperatures between -55°C to +100°C and -40°C to+75°C is guaranteed, no
parameter limits are specified.
Electrical Performance Characteristics - Definition of Conditions
Condition Definition
1
2
3
Comment
BOL @ +25°C interface temperature
Initial setting
BOL @ -40°C to +75°C interface temperature Initial setting and worst case temperature variation
EOL @ -40°C to +75°C interface temperature Worst case performance including initial setting,
temperature variation, aging and radiation degradation
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5
ML1000605D
(100V Input, Dual Output)
Model Definition and Test Plans
Model Definition
Model
Description
Build Standard
EBB
The EBB is an electrical
representative model.
The PCB will be hand soldered by the engineering group. No
staking and conformal coating is foreseen
Preferably same type of EEE parts as intended for flight, but
lower grade will be used for convenience. For resistors and
capacitors different types with same basic characteristics may be
used
The EBB is intended to be
used by customers in their
proto type at equipment
level.
EBB models are built at
IR’s Danish Design Center.
EQM
The EQM is an electrical
and mechanical
representative model.
The EQM is intended to be
used by customer in their
EQM at equipment level.
Flight standard for processes.
Same type of EEE parts as intended for flight, but lower grade
may be used for convenience.
FM
Flight standard models.
Full flight standard
Test Plan - A
The EBB must pass the following tests:
Test No.
6
Type of Test
Location* Remarks
1
Electrical performance test,
room temperature incl. Limited
EMC test (CE 50kHz-1MHz)
IRD
Acceptance Test Procedure
2
Electrical performance test in
temperature (Q-level)
IRD
Acceptance Test Procedure
3
Electrical performance test,
room temperature incl. Limited
EMC test (CE 50kHz-1MHz)
IRD
Acceptance Test Procedure
4
Final Inspection
IRD
General inspection Procedure
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ML1000605D
(100V Input, Dual Output)
Test Plan - B
The EQM must pass the following tests:
Test No.
Type of Test
Location*
Remarks
1
Electrical performance test, room
temperature incl. Limited EMC test
(CE 50kHz-1MHz)
IRSJ
Acceptance Test Procedure
2
Thermal cycling with electrical
monitoring of input and outputs
(Q-level)
IRSJ
Acceptance Test Procedure
10 cycles
3
Electrical performance test in
temperature (Q-level)
IRSJ
Acceptance Test Procedure
4
Random Vibration test in
(Q-level)
External
test house
Vibration Test Procedure
5
Electrical performance test, room
temperature incl. Limited EMC test
(CE 50kHz-1MHz)
IRSJ
Acceptance Test Procedure
6
Mechanical Measurements
IRSJ
Acceptance Test Procedure
7
Final Inspection
IRSJ
General inspection Procedure
Test Plan - C
The FM must pass the following tests:
Test No.
Type of Test
Location*
Remarks
1
Electrical performance test, room
temperature incl. Limited EMC test
(CE 50kHz-1MHz)
IRSJ
Acceptance test procedure
2
Electrical performance
temperature (A-levels)
in
IRSJ
Acceptance test procedure
3
Electrical performance test, room
temperature incl. Limited EMC test
(CE 50kHz-1MHz)
IRSJ
Acceptance test procedure
4
Electrical performance test, room
temperature
IRSJ
Acceptance Test Procedure
5
Mechanical Measurements
IRSJ
Acceptance test procedure
6
Final Inspection
IRSJ
General inspection procedure
test
Note:
Location* - IRD: IR’s Danish Design Center, Skovlunde, Denmark
- IRSJ: IR’s Site in San Jose, California, USA
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7
ML1000605D
(100V Input, Dual Output)
Radiation Performance
TID
The TID radiation performance is guaranteed by worst case analysis with radiation degradation data for
each radiation sensitive component used in the DC-DC converter. For TID radiation verification testing
(RVT) for each wafer lot for all sensitive components is part of the EEE parts requirements per table below.
TID RVT Plan Table
Component Type
RVT Plan (applicable to all flight lots)
JANS2N2222A
LDRS 0.01 to 0.1 rad up to 200 krad per IR RVT plan
JANS2N2907A
LDRS 0.01 to 0.1 rad up to 200 krad per IR RVT plan
JANSR2N7492T2
RVT by Manufacturer (HDR)
IRHF57214SESCS
RVT by Manufacturer (HDR)
IRHLUB770Z4SCS
RVT by Manufacturer (HDR)
IRHLUB7970Z4SCS
RVT by Manufacturer (HDR)
LM124AWR
RVT by Manufacturer (ELDRS)
IS2-1009RH
RVT by Manufacturer (HDR)
LDRS 0.01 to 0.1 rad up to 100 krad per IR RVT plan
UC1845A
LDRS 0.01 to 0.1 rad/s up to 100kRad per IR RVT plan
SEE
The SEE radiation performance is guaranteed by a combination of derating and mitigation at circuit level.
For mitigation at circuit level both theoretical analysis and testing with imposed SEE effects are performed.
The applicable SEE and mitigation concept is presented in table below.
The maximum output perturbation is 5% of the nominal output voltage during any SEE.
Applicable SEE and Mitigation Methods Table
Component Type
Applicable SEE
Mitigation Concept
RH MOSFET
SEGR
Vds derating in combination with SEE SOA
curves from manufacturer data sheet
Op-Amp
SET, 15us perturbation to rail
Mitigation at circuit level (filtering)
Voltage reference
SET, 10us perturbation to rail
Mitigation at circuit level (filtering)
PWM
SET, 15us perturbation to rail
Mitigation at circuit level (filtering)
Double Pulses
Mitigation at circuit level (filtering, no
saturation of magnetic parts)
Missing Pulses
Mitigation at circuit level (filtering, no
saturation of magnetic parts)
8
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ML1000605D
(100V Input, Dual Output)
EEE Parts Technical Standard
For component screening and DPA rules, refer to the generic ML-Series data sheet at www.irf.com.
Random Vibration
Axis
X, Y, Z
Frequency Range (Hz)
Level
20-100
+6 dB/oct
100-1600
0.5 SQR(g)/Hz
1600-2000
-12 dB/oct
PSD Level (grms)
Duration (S)
29.9
180
Fig 1- Block Diagram
Primary
Power
Bus
Int.Supply
Input Filter
Rectifier
&
Filter
Rectifier &
Filter
Linear
Regulator
V1: +6V 500mA
Start-Up
Resistor
TC ON
Fly-Back
Transformer
Latching
Relay
TC OFF
Rectifier
&
Filter
on/off
TM
UVP
Monitor &
Latch
Disable
PWM
Controller
Output
Sequencing
Fly-Back
Power
Switch
Current
Shunt
Internal
aux
Rectifier
&
Filter
Negative
Linear
Regulator
V2: -5V 100mA
Grounding and Isolation Scheme
Parameter
Grounding & Isolation Performance
Isolation:
Primary to Secondary:
Telecommand:
Status TM:
Grounding:
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> 10 MOhm // < 50nF
Floating
Floating
Secondary return bound to chassis via multiple screw connections
9
ML1000605D
(100V Input, Dual Output)
Interface Schematics
Fig 2 - Power Input:
J1
PRIMARY POWER BUS
R1
3
PRIMARY POWER BUS
11
L2
L1
L3
PRIMARY POWER BUS RETURN
To Fly-back converter and
Startup Circuit
C1
CR1
1
R4
PRIMARY POWER BUS RETURN
C8
9
C6
C9
C7
Component
Component Type
Package
Value
Voltage (V)
C1
BR40 II
RADIAL
0.56µF
200
C6
CDR33BX
SMD 1210
27nF
100
C7
CDR33BX
SMD 1210
27nF
100
C8
CDR33BX
SMD 1210
27nF
100
C9
CDR33BX
SMD 1210
27nF
100
CR1
1N5806US
A- MFLF
2.5A
150
10
L1
R6.3
TOROID
2 X109.8µH
L2
HIGH FLUX
TOROID
90µH
L3
HIGH FLUX
TOROID
30µH
R1
RWR81S
RWR
9.09ohms
500
R4
RM1206B
SMD 1206
21.5ohms
100
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ML1000605D
(100V Input, Dual Output)
Fig 3 - TM / TC Interface:
J1
TC On return
13
CR205
TC On
TC Off
R201
7
K1
CR206
6
R202
CR201
CR203
4
ON
9
OFF
5
CR202
From Input Filter
10
CR204
CR207
R218
CR208
14
R219
TC Off return
Relay is shown ON
R220
8
Status TM
CR213
CR214
R203
R223
15
8
Status TM Return
3
From Primary
AUX.
7
6
VC
1
2
C103
U101
PWM
VR101
Component
Component Type
Package
Value
Voltage (V)
CR201
CR202
1N6640US
1N6640US
D-5D
D-5D
0.3A
0.3A
75
75
CR203
CR204
1N6640US
1N6640US
D-5D
D-5D
0.3A
0.3A
75
75
CR205
CR206
1N6640US
1N6640US
D-5D
D-5D
0.3A
0.3A
75
75
CR207
CR208
1N6640US
1N6640US
D-5D
D-5D
0.3A
0.3A
75
75
CR213
CR204
1N6640US
1N6640US
D-5D
D-5D
75
75
C103
K201
CWR29
J422-26M SHOC
SMD H
TO-5
0.3A
0.3A
33µF
R118
R119
RM1206B
RM1206B
SMD 1206
SMD 1206
21.5kohms
21.5kohms
100
100
R120
R123
RM1206B
RM1206B
SMD 1206
SMD 1206
21.5kohms
21.5kohms
100
100
R201
R202
RM1206B
RM1206B
SMD 1206
SMD 1206
215ohms
215ohms
100
100
VR101
1N4109UR-1
DO-213AA
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25
26.5
15
11
ML1000605D
(100V Input, Dual Output)
EMI Performance
Fig 4 - Typical Conducted Emission Performance at Power Input:
Fig 5 - Typical Conducted Emission Performance at Output 1:
12
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ML1000605D
(100V Input, Dual Output)
Power Conversion Efficiency
Fig 6 - Typical Power Conversion Efficiency Vs +6V Output Current Parametric
with -5V Output Current
Typical Efficiency, Vin 100V, I/F temperature +75°C
65%
60%
55%
50%
45%
0.020A
0.050A
40%
0.100A
35%
0.10A
0.15A
0.20A
0.25A
0.30A
0.35A
0.40A
0.45A
0.50A
+6V Output Current
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13
ML1000605D
(100V Input, Dual Output)
Recommended Mounting Stud Design
It is foreseen with a mounting stud design with circular mounting studs made out of aluminum with a
diameter of 4.0mm and a treaded hole support mounting with M2 screws.
5pcs M2 screws are used for mounting the board. Mounting torque shall be 30Ncm ± 5.0Ncm.
14
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ML1000605D
(100V Input, Dual Output)
Mechanical Interface
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15
ML1000605D
(100V Input, Dual Output)
Pin Designation Tables
Input Terminals Assignment List
Output Terminals Assignment List
Indent.: Input Terminals (Solder, Pins, Straight)
Indent.: Output Terminals (Solder Pads)
Pin #
Pin #
1
9
2
10
3
11
4
12
5
13
6
14
7
15
8
Function
Input Power Return
Input Power Return
Rerserved
Rerserved
Input Power
Input Power
Chasis (Ground)
Voltage TM
Chasis (Ground)
TC On Return
TC On
TC Off Return
TC Off
TM Status Return
TM Status
Pin #
1
3
5
7
Pin #
2
4
6
8
Function
V1 (Positive Output)
Chasis (Ground)
Chasis (Ground)
V2 (Negative Output)
Thermal Design Information
The thermal design for the ML-Series is solely based on heat conduction through the mounting
interfaces/mounting screws into the host equipment chassis.
The maximum power loss during normal operation is 2.0W. The temperature profile for the board
based on all screw mounting points kept at isothermal level is given below.
16
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ML1000605D
(100V Input, Dual Output)
Part Numbering
ML 100 06 05 D /XXX
Model
ML-Series
Nominal Input
Voltage
100 = 100V
Output 1
Quality Level
EBB = Elegant Bread Board Model
EQM = Engineering Qualification Model
Blank = Fight Model
Number of Outputs
D = Dual Outputs
06 = 6V
Output 2
05 = 5V
Application Information
Standard Documentation
n Interface Control Drawing
n User’s Manual
n End Item Data Package with CoC, Applicable Configuration, MIP Photo and Test Results
Design Justification Documentation
The following documentation can be made available upon request:
n Worst Case Analysis
n Parts Stress Analysis
n Thermal Analysis
n Mechanical Analysis
n FMECA
n Reliability Assessment
n Declared Components List
n Declared Materials List
n Declared Process List
WORLD HEADQUARTERS: 101 N, Sepulveda Blvd., El Segundo, California 90245, USA Tel: (310) 252-7105
IR SAN JOSE: 2520 Junction Avenue, San Jose, California 95134, USA Tel: (408) 434-5000
IR DENMARK: Literbuen10C, DK-2740 Skovlunde, Denmark, Tel: +45 4457 5010
Visit us at www.irf.com for sales contact information.
Data and specifications subject to change without notice. 04/2013
www.irf.com
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