INTERPOINT FMSA-461

FEATURES
• –55°C to +125°C operation
• 50 dB minimum attenuation
at 500 kHz
• Compliant to MIL-STD-461C, CE03
• Compatible with MIL-STD-704E
DC power bus
EMI INPUT FILTER
28 VOLT INPUT
FMSA EMI FILTER
0.8 AMP
MODEL
FMSA-461
0.8 amp
Size (max.): 0.980 x 0.805 x 0.270 (24.89 x 20.45 x 6.86 mm)
See cases “A maximum dimensions” and “A1” for dimensions.
Weight:
10.3 grams typical, 11.5 grams maximum
Screening: Standard, ES or Class H
See “QA Screening: Class H, QML” for more information.
DESCRIPTION
The FMSA-461 EMI filter module has been designed as a
companion for Interpoint MSA flyback power converters. Multiple
MSA power converters can be operated from a single filter provided
the total power line current does not exceed the filter maximum
rating. The FMSA filter will reduce the MSA’s power line reflected
ripple current to within the limit of MIL-STD-461C, Method CE03, as
shown in the example of Figures 4 and 5.
The FMSA is fabricated using thick film hybrid technology and is
sealed in a metal package for military, aerospace and other applications requiring EMI suppression. The filter uses only ceramic
capacitors for reliable high temperature operation.
OPERATION
The MSA power converter has an internal 2 µF capacitor across its
input power terminals. When the MSA and FMSA filters are used
together, this capacitor becomes part of the filter and forms its final
LC output section. When 2 or 3 MSAs are used with a single filter,
this capacitor becomes 4 µF or 6 µF respectively, rather than 2 µF,
improving the rejection vs. frequency.
The FMSA filter can also be used with other types of Interpoint
power converters (MHF, MHF+, MHE, MHD, and DCH series) to
comply with CE03. For MHF, MHF+, MHD, and MHE models, the
converter has an LC type line filter such that an inductor is seen
looking into its positive input terminal. For these converters, it is
necessary to terminate the filter with a capacitor to insure unconditionally stable operation. A capacitor across the filter output terminals of greater than 4µF or the optional damping circuit shown on
the connection diagram will be adequate for stable operation. No
capacitor is required for MSA, or DCH models.
OPTIONAL DAMPING CIRCUIT
The optional damping circuit (Figure 2) can be used to prevent filter
overshoot caused by MIL-STD-704A 80 V, or other, transients
having rise times of less than 200 µSec. This damping can be alternately provided with a 1.50 Ω resistor in series with the filter positive
input where the additional line loss can be tolerated. For transients
with rise times of greater than 200 µsec, there is no overshoot and
the damping circuit is not required.
LAYOUT REQUIREMENTS
The case of the filter must be connected to the case of the converter
through a low impedance connection to minimize EMI.
EMI INPUT FILTERS
FMSA EMI FILTER
0.8 AMP
ABSOLUTE MAXIMUM RATINGS
RECOMMENDED OPERATING CONDITIONS
Input Voltage
• 0 to 50 VDC continuous
• 80 V for 100 ms transient
Lead Soldering Temperature (10 sec per lead)
• 300°C
Storage Temperature Range (Case)
• –65°C to +150°C
Input Voltage Range
• 16 to 40 VDC continuous
Case Operating Temperature (Tc)
• –55°C to +125°C full power
Derating Input/Output Current
• Derate linearly from 100% at 100°C to 0.60
amps at 125°C case. Above 125°C derate to 0%.
TYPICAL CHARACTERISTICS
Capacitance
• 0.045 µF max, any pin to case
Isolation
• 100 megohm minimum at 500 V
• Any pin to case, except case pin
Electrical Characteristics: 25°C Tc, nominal Vin, unless otherwise specified.
PARAMETER
INPUT VOLTAGE
CONDITIONS
CONTINUOUS
TRANSIENT1, 100 ms
INPUT CURRENT1
NOISE REJECTION
500 kHz
1 MHz
5 MHz
TC = 25°C
NOISE REJECTION
DC RESISTANCE (RDC)
FMSA-461
TYP
28
—
—
—
—
—
—
MIN
0
—
—
50
50
45
—
MAX
40
80
0.80
—
—
—
1.2
UNITS
VDC
V
A
dB
dB
Ω
VOUT = VIN - IIN (RDC)
VDC
OUTPUT VOLTAGE
STEADY STATE
OUTPUT CURRENT
STEADY STATE (<100°C CASE)
—
—
0.80
A
INTERNAL POWER
DISSIPATION
MAXIMUM CURRENT
—
—
0.96
W
Notes:
1. Guaranteed by design, not tested.
0.65 ⍀
Positive
Input
20 ⍀
20 ⍀
Input
Common
>285 ␮H
6 ␮H
6 ␮H
6800 pF
500 V
2 ␮F
2 ␮F
Positive
Output
x2
0.014 ␮F / 500 V
x2
0.014 ␮F / 500 V
6800 pF
500 V
Output
Common
FMSA-461
0.014 ␮F / 500 V
The case ground connection between the filter and the converter should be as low an impedance as possible
to minimize EMI. Direct contact of baseplate to chassis ground provides the lowest impedance.
FIGURE 1: SCHEMATIC – TYPICAL VALUES
EMI INPUT FILTERS
DC/DC Converter
FMSA-461
Positive
Input
FMSA EMI FILTER
0.8 AMP
Positive
Output
Positive
Input
Positive
Output
C
Case
Ground
Input
Common
Case
Ground
R
Input
Common
Output
Common
The RC output is an optional
damping circuit. It is recommended in
applications where 80 volt line
transients may occur with rise times
<200 s. See text page one
"Connection and Operation."
C = 10 F, 100V –
C = Sprague 109D106X9100C2
R = 2.2 , 5%, 1/4 W, Carbon comp.
RL
Output
Common
Multiple units
allowed up to
rated output current.
RL
FIGURE 2: DAMPING CIRCUIT
PIN OUT
Pin
1
2, 3
4
5, 6
7
8
Designation
Positive Input
Positive Output
Case Ground
Output Common
Input Common
Case Ground
Squared corner and
dot on top of cover
indicate pin one.
1
8
2 3
BOTTOM
VIEW
FMSA
7
4
6 5
See cases “A maximum dimensions” and “A1” for dimensions.
FIGURE 3: PIN OUT
DSCC NUMBER
DSCC DRAWING
(5915)
96003-01HXC
MODEL NUMBERING KEY
FMSA-461 FILTER
SIMILAR PART
FMSA-461/883
For exact specifications for a DSCC product, refer to the
DSCC drawing: http://www.dscc.dla.mil/programs/smcr
FMSA - 461
/
883
Base Model
MIL-STD-461 Reference
Screening
(Standard screening has no designator
in this position.)
FMSA EMI FILTER
0.8 AMP
EMI INPUT FILTERS
Typical Performance Curves: 25°C Tc , nominal Vin, unless otherwise specified.
90
80
CE
A)
70
03
EMISSION LEVEL (dB
60
NARROWBAND
LI
M
IT
50
40
30
20
10
0
.015
0.1
1
FREQUENCY (MHz)
10
50
MSA2805S converter without a filter.
FIGURE 4
90
80
CE
03
A)
70
NARROWBAND
LI
M
EMISSION LEVEL (dB
60
IT
50
40
30
20
10
0
.015
0.1
1
FREQUENCY (MHz)
10
50
MSA2805S converters at full load with
an FMSA-461 EMI filter
FIGURE 5
MAGNITUDE OF Zo (Ohms)
10.0
3.2
1.0
0.32
0.10
1K
2 µF external capacitor on filter output
10K
100K
FREQUENCY (Hz)
1M
Typical Output Impedance (Z)
With Input Shorted
FMSA-461 EMI Filter
FIGURE 6
FMSA EMI Filter, Rev C, November 1, 2005 (format)
All technical information is believed to be accurate, but no responsibility is
assumed for errors or omissions. Interpoint reserves the right to make changes in
products or specifications without notice. MGH Series is a trademark of Interpoint
Corporation. Copyright © 1994 - 2006 Interpoint Corporation. All rights reserved.
CASES
CASE A MAXIMUM DIMENSIONS
BOTTOM VIEW
Dot on top of case
indicates pin one.
See cases A1 - A3 0.805 max
for pin configurations. (20.45)
0.980 max
(24.89)
Materials
Header
Cases A1 and A2
Kovar/Nickel/Gold
Case A3
Kovar/Nickel)
Cover
Kovar/Nickel
Pins
Kovar/Nickel/Gold,
matched glass seal
Case dimensions in inches (mm)
Tolerance ±0.005 (0.13) for three decimal places
±0.01 (0.3) for two decimal places
unless otherwise specified
CAUTION
Heat from reflow or wave soldering may damage the device.
Solder pins individually with heat application not exceeding 300°C for 10 seconds per pin.
Case A maximum dimensions, Rev B, September 23, 2005
Please refer to the numerical dimensions for accuracy. All information is believed to be accurate,
but no responsibility is assumed for errors or omissions. Interpoint reserves the right to make
changes in products or specifications without notice.
Copyright © 1999-2005 Interpoint Corp. All rights reserved.
CASES
BOTTOM VIEW CASE A1
FMSA EMI Filter and STF EMI Filter
Projection Weld
Seam Seal
Squared corner and dot on
top of case indicate pin one.
2 3
8
4
0.097
(2.46)
0.000
7
6 5
0.135 (3.43)
0.735 (18.67)
0.835 (21.21)
0.000
1
0.397
(10.08)
0.27 ±0.02
(6.9 ±0.5)
0.000
0.270 max
(6.98)
0.27 ±0.02
(6.9 ±0.5)
0.000
0.270 max
(6.86)
0.697
(17.70
0.018 ± 0.002 dia.
(0.46 ± 0.05)
Seal hole: 0.056 ±0.002 (1.42 ±0.05)
Case dimensions in inches (mm)
Tolerance ±0.005 (0.13) for three decimal places
±0.01 (0.3) for two decimal places
unless otherwise specified
CAUTION
Heat from reflow or wave soldering may damage the device.
Solder pins individually with heat application not exceeding 300°C for 10 seconds per pin
Case A1, Rev B, September 8, 2005
Please refer to the numerical dimensions for accuracy. All information is believed to be accurate,
but no responsibility is assumed for errors or omissions. Interpoint reserves the right to make
changes in products or specifications without notice.
Copyright © 1999-2005 Interpoint Corp. All rights reserved.
QUALITY ASSURANCE
CLASS H, QML SCREENING
TEST
125°C
STANDARD
non-QML
125°C
/ES
non-QML
Class H
/883
QML
Pre-cap Inspection
Method 2017, 2032
yes
yes
yes
Temperature Cycle (10 times)
Method 1010, Cond. C, -65°C to 150°C, ambient
Method 1010, Cond. B, -55°C to 125°C, ambient
no
no
no
yes
yes
no
Constant Acceleration
Method 2001, 3000 g
Method 2001, 500g
no
no
no
yes
yes
no
Burn-In
Method 1015, 160 hours at 125°C case, typical
96 hours at 125°C case, typical
no
no
no
yes
yes
no
Final Electrical Test MIL-PRF-38534, Group A
Subgroups 1 through 6: -55°C, +25°C, +125°C case
Subgroups 1 and 4: +25°C case
no
yes
no
yes
yes
no
Hermeticity Test
Fine Leak, Method 1014, Cond. A
Gross Leak, Method 1014, Cond. C
Gross Leak, Dip (1 x 10-3)
no
no
yes
yes
yes
no
yes
yes
no
Final Visual Inspection
Method 2009
yes
yes
yes
Test methods are referenced to MIL-STD-883 as determined by MIL-PRF-38534.
Class H,
QML Screening
page 1 of 1
QA Screening Class H, QML Rev B November 1, 2005 (typo).
This revision supercedes all previous releases. All technical information is believed to be accurate, but no responsibility is
assumed for errors or omissions. Interpoint reserves the right to
make changes in products or specifications without notice.
Copyright © 2005 Interpoint Corporation. All rights reserved.