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ADDC02805SAKV Schematic ( PDF Datasheet ) - Analog Devices

Teilenummer ADDC02805SAKV
Beschreibung 28 V/66 W/100 W DC/DC Converters with Integral EMI Filter
Hersteller Analog Devices
Logo Analog Devices Logo 




Gesamt 18 Seiten
ADDC02805SAKV Datasheet, Funktion
a
28 V/66 W/100 W DC/DC Converters
with Integral EMI Filter
FEATURES
28 V dc Input, 5 V dc @ 20 A, 100 W Output
(ADDC02805SA)
28 V dc Input, 3.3 V dc @ 20 A, 66 W Output
(ADDC02803SC)
Integral EMI Filter Designed to Meet MIL-STD-461D
Low Weight: 80 Grams
NAVMAT Derated
Many Protection and System Features
APPLICATIONS
Commercial and Military Airborne Electronics
Missile Electronics
Space-Based Antennae and Vehicles
Mobile/Portable Ground Equipment
Distributed Power Architecture for Active Array Radar
ADDC02803SC/ADDC02805SA
FUNCTIONAL BLOCK DIAGRAM
– SENSE
+ SENSE
ADJUST
STATUS
VAUX
INHIBIT
SYNC
ISHARE
TEMP
–VIN
+VIN
OUTPUT SIDE
CONTROL
CIRCUIT
INPUT SIDE
CONTROL
CIRCUIT
EMI FILTER
ADDC02803SC
ADDC02805SA
FIXED
FREQUENCY
DUAL
INTERLEAVED
POWER TRAIN
OUTPUT
FILTER
RETURN
RETURN
RETURN
+VOUT
+VOUT
+VOUT
GENERAL DESCRIPTION
The ADDC02803SC and ADDC02805SA hybrid dc/dc con-
verters with integral EMI filters offer the highest power density
of any dc/dc converter with their features and in their power
range available today. The converters with integral EMI filters
are fixed frequency, 1 MHz square wave switching dc/dc power
supplies. They are not variable frequency resonant converters.
In addition to many protection features, these converters have
system level features that allow them to be used as components
in larger systems as well as stand-alone power supplies. The
units are designed for high reliability and high performance
applications where saving space and/or weight are critical.
The ADDC02803SC and ADDC02805SA are available in
three screening grades; all grades use a hermetically sealed,
molybdenum based hybrid package. Three screening levels
are available, including military SMD.
PRODUCT HIGHLIGHTS
1. Up to 60 W/cubic inch power density with an integral EMI
filter designed to meet all applicable requirements in MIL-
STD-461D when installed in a typical system setup.
2. Light weight: 80 grams
3. Operational and survivable over a wide range of input condi-
tions: 16 V–50 V dc; survives low line, high line and positive
and negative transients. See section entitled: Input Voltage
Range.
4. High reliability; NAVMAT derated
5. Protection features include:
Output Overvoltage Protection
Output Short Circuit Current Protection
Thermal Monitor/Shutdown
Input Overvoltage Shutdown
Input Transient Protection
6. System level features include:
Current Sharing for Parallel Operation
Inhibit Control
Output Status Signal
Synchronization for Multiple Units
Input Referenced Auxiliary Voltage Supply
REV. A
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices 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 Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700 World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 1998






ADDC02805SAKV Datasheet, Funktion
ADDC02803SC/ADDC02805SA
10
VIN = 28V
VIN = 18V
1
100
10
0.1
VIN = 28V
VIN = 18V
0.01
0.01
0.1 1
10
FREQUENCY – kHz
100
Figure 13. Incremental Input Impedance (Magnitude)
(ADDC02805SA)
10
VIN = 28V
1
VIN = 18V
0.1
0.01
10
100 1k 10k
FREQUENCY – Hz
100k
Figure 14. Incremental Input Impedance (Magnitude)
(ADDC02803SC)
100
1
0.1
10
100 1k
FREQUENCY – Hz
10k
100k
Figure 16. Incremental Output Impedance (Magnitude)
(ADDC02803SC)
1mV
100V
2.00 MHz/DIV
Figure 17. Output Voltage Ripple Spectrum
(ADDC02803SC)
10
1
0.1
0.01
0.1 1
10
FREQUENCY – kHz
100
Figure 15. Incremental Output Impedance (Magnitude)
(ADDC02805SA)
1mV
100V
2.00 MHz/DIV
Figure 18. Output Voltage Ripple Spectrum
(ADDC02805SA)
–6– REV. A

6 Page









ADDC02805SAKV pdf, datenblatt
ADDC02803SC/ADDC02805SA
Potential System Instability: The preceding analysis assumes
dc voltages and currents. For ac waveforms the incremental
input model for the POL converter must also include the effects
of its input filter and control loop dynamics. When the POL
converter is connected to a power source, modeled as a voltage
source, VS, in series with an inductor, LS, and some positive
resistor, RS, the network of Figure 33 results.
RS LS
VS INPUT
TERMINALS
LP
CP
–|RN|
ADI DC/DC CONVERTER
Figure 33. Model of Power Source and POL Converter
Connection
The network shown in Figure 33 is second order and has the
following characteristic equation:
s2(LS
+
LP
)C
+
s
(LS + LP )
–|RN |
+
RSCP

+1
=
0
For the power delivery to be efficient, it is required that
RS << RN. For the system to be stable, however, the following
relationship must hold:
CP
|
RN
|>
(LS + LP
RS
)
or
RS
>
(LS + LP )
CP |RN |
Notice from this result that if (LS + LP) is too large, or if RS is
too small, the system might be unstable. This condition would
first be observed at low input line and full load since the abso-
lute value of RN is smallest at this operating condition.
If an instability results and it cannot be corrected by changing
LS or RS, such as during the MIL-STD-461D tests due to the
LISN requirement, one possible solution is to place a capacitor
across the input of the POL converter. Another possibility is to
place a small resistor in series with this extra capacitor.
The analysis has so far assumed the source of power was a volt-
age source (e.g., a battery) with some source impedance. In
some cases, this source may be the output of a front-end (FE)
converter. Although each FE converter is different, a model for
a typical one would have an LC output filter driven by a voltage
source whose value was determined by the feedback loop. The
LC filter usually has a high Q, so the compensation of the feed-
back loop is chosen to help dampen any oscillations that result
from load transients. In effect, the feedback loop adds “positive
resistance” to the LC network.
When the POL converter is connected to the output of this FE
converter, the POL’s “negative resistance” counteracts the
effects of the FE’s “positive resistance” offered by the feedback
loop. Depending on the specific details, this might simply mean
that the FE converter’s transient response is slightly more oscil-
latory, or it may cause the entire system to be unstable.
For the ADDC02803SC and ADDC02805SA, LP is approxi-
mately 1 µH and CP is approximately 4 µF. Figures 13 and 14
show a more accurate depiction of the input impedance of the
converter as a function of frequency. The negative resistance is,
itself, a very good incremental model for the power state of the
converter for frequencies into the several kHz range.
NAVMAT DERATING
NAVMAT is a Navy power supply reliability manual frequently
cited by specifiers of power supplies. A key section of NAVMAT
P4855-1A discusses guidelines for derating designs and their
components. The two key derating criteria are voltage derating
and power derating. Voltage derating is done to reduce the possi-
bility of electrical breakdown, whereas power derating is done to
maintain the component material below a specified maximum
temperature. While power deratings are typically stated in terms
of current limits (e.g., derate to x% of maximum rating), NAVMAT
also specifies a maximum junction temperature of the semicon-
ductor devices in a power supply. The NAVMAT component
deratings applicable to the ADDC02805SA and ADDC02803SC
are as follows:
Resistors
80% voltage derating
50% power derating
Capacitors
50% voltage and ripple voltage derating
70% ripple current derating
Transformers and Inductors
60% continuous voltage and current derating
90% surge voltage and current derating
20°C less than rated core temperature
30°C below insulation rating for hot spot temperature
25% insulation breakdown voltage derating
40°C maximum temperature rise
Transistors
50% power derating
60% forward current (continuous) derating
75% voltage and transient peak voltage derating
110°C maximum junction temperature
Diodes (Switching, General Purpose, Rectifiers)
70% current (surge and continuous) derating
65% peak inverse voltage derating
110°C maximum junction temperature
Diodes (Zeners)
70% surge current derating
60% continuous current derating
50% power derating
110°C maximum junction temperature
Microcircuits (Linears)
70% continuous current derating
75% signal voltage derating
110°C maximum junction temperature
The ADDC02803SC and ADDC02805SA can meet all the
derating criteria listed above. There are, however, a few areas of
the NAVMAT deratings where meeting the guidelines unduly
sacrifices performance of the circuit. The standard unit therefore
makes the following exceptions.
Common-Mode EMI Filter Capacitors: The standard sup-
ply uses 500 V capacitors to filter common-mode EMI. NAVMAT
guidelines would require 1000 V capacitors to meet the 50%
voltage derating (500 V dc input to output isolation), resulting
in less common-mode capacitance for the same space. In typi-
cal electrical power supply systems, where the load ground is
eventually connected to the source ground, common-mode
voltages never get near the 500 V dc rating of the standard
–12–
REV. A

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