ETC ATW2812S-SLV

LAMBDA ADVANCED ANALOG INC.
λ
ATW2800S Series
Single Output, Hybrid - High Reliability
DC/DC Converter
DESCRIPTION
FEATURES
The ATW2800S Series of DC/DC converters feature
high power density and an extended temperature
range for use in military and industrial applications.
Designed to MIL-STD-704 input requirements, these
devices have nominal 28VDC inputs with +5, +12V
and +15V single outputs.
The circuit design
incorporates a pulse width modulated push-pull
topology operating in the feed-forward mode at a
nominal switching frequency of 270KHz. Input to
output isolation is achieved through the use of
transformers in the forward and feedback circuits.
n
19 To 40 Volt Input Range (28VDC Nominal)
n
30 Watts Output Power
n
Indefinite Short Circuit and Overload
Protection
n
22.8 W/in3 Power Density
n
Fast Loop Response For Superior Transient
Characteristics
n
Operating Temperature Range From -55°C to
+125°C Available
The advanced feedback design provides fast loop
response for superior line and load transient
characteristics and offers greater reliability and
radiation tolerance than devices incorporating
optical feedback circuits.
n
Popular Industry Standard Pin-Out
n
Resistance Seam Welded Case For Superior
Long Term Hermeticity
n
Efficiencies Up to 83%
Three standard temperature grades are offered.
Refer to Part Number section. They are provided in
a flanged package for more severe enviroments.
n
Shutdown From External Signal
n
Military Screening
n
250,000 Hour MTBF at 85°C
n
MIL-PRF-38534 Compliant Versions
Available
Manufactured in a facility fully qualified to MIL-PRF38534, these converters are available in four
screening grades to satisfy a wide range of
requirements. The CH grade is fully compliant to
the requirements of MIL-PRF-38534 for class H.
The HB grade is processed and screened to the
class H requirement, but may not necessarily meet
all of the other MIL-PRF-38534 requirements, e.g.,
element evaluation and Periodic Inspection (P.I.)
not required. Both grades are tested to meet the
complete group "A" test specification over the full
military temperature range without output power
deration. Two grades with more limited screening
are also available for use in less demanding
applications. Variations in electrical, mechanical
and screening can be accommodated. Contact
Lambda Advanced Analog for special requirements.
SPECIFICATIONS
ATW2805S
ABSOLUTE MAXIMUM RATINGS
Input Voltage
Soldering Temperature
Case Temperature
-0.5V to 50V
300°C for 10 seconds
Operating-55°C to +125°C
Storage -65°C to +135°C
TABLE I. Electrical Performance Characteristics
Test
Symbol
Conditions
-55°C ≤ TC ≤ +125°C
VIN = 28 V dc ±5%, CL = 0 unless
otherwise specified
Group A
subgroups
Device
types
Limits
Min
Output voltage
VOUT
IOUT = 0
1
All
2,3
Output current 1/
IOUT
VIN = 19, 28, and 40 V dc
1,2,3
All
Output ripple voltage 2/
VRIP
VIN = 19, 28, and 40 V dc
B.W. = dc to 2 MHz
1,2,3
All
Output power 1/ 3/
POUT
VIN = 19, 28, and 40 V dc
1,2,3
All
Line regulation 4/
VRLINE
VIN = 19, 28, and 40 V dc
IOUT = 0, 3000, and 6000 mA
1
All
Unit
Max
4.95
5.05
4.90
5.10
0.0
6000
50
30
mA
mV p-p
W
5
2,3
V
mV
20
Load regulation 4/
VRLOAD
VIN = 19, 28, and 40 V dc
IOUT = 0, 3000, and 6000 mA
1,2,3
All
30
mV
Input current
IIN
IOUT = 0, inhibit (pin 2) tied to input
return (pin 10)
1,2,3
All
18
mA
IOUT = 0, inhibit (pin 2) = open
Input ripple current 2/
IRIP
IOUT = 6000 mA
B.W. = dc to 2 MHz
Efficiency
EFF
Isolation
40
1,2,3
All
20
IOUT = 6000 mA,
TC = +25°C
1
All
78
ISO
Input to output or any pin
to case (except pin 7) at 500 V dc, TC
= +25°C
1
All
100
Capacitive load 5/ 6/
CL
No effect on dc performance,
TC = +25°C
4
All
500
µF
Power dissipation load fault
PD
Overload, TC = +25°C 7/
1
All
12
W
%
MΩ
9
Short circuit, TC = +25°C
See footnotes at end of table.
2
mA p-p
ATW2805S
TABLE I. Electrical Performance Characteristics - Continued.
Test
Symbol
Conditions
-55°C ≤ TC ≤ +125°C
VIN = 28 V dc ±5%, CL = 0 unless
otherwise specified
Group A
Subgroups
Device
Type
Limits
Min
Switching frequency
Output response to step
transient load changes 8/
Recovery time step transient
load changes 8/ 9/
FS
VOTLOAD
TTLOAD
IOUT = 6000 mA
4,5,6
Unit
Max
01
250
300
02
250
270
03
275
300
4000 mA to/from 6000 mA
4,5,6
All
-500
+500
500 mA to/from 2500 mA
4,5,6
All
-500
+500
4000 mA to/from 6000 mA
4
All
5,6
500 mA to/from 2500 mA
4
100
kHz
mV pk
µs
200
All
5,6
100
200
Turn on overshoot
VTonOS
IOUT = 0 and 6000 mA
4,5,6
All
500
mV pk
Turn on delay 10/
TonD
IOUT = 0 and 6000 mA
4,5,6
All
12
ms
Load fault recovery 6/ 10/
TrLF
4,5,6
All
12
ms
Notes:
1/
2/
3/
4/
5/
Parameter guaranteed by line and load regulation tests.
Bandwidth guaranteed by design. Tested for 20 KHz to 2 MHz.
Above +125°C case, derate output power linearly to 0 at +135°C.
Output voltage measured at load with remote sense leads connected across load.
Capacitive load may be any value from 0 to the maximum limit without compromising dc performance. A capacitive load in excess of the maximum limit
will not disturb loop stability but may interfere with the operation of the load fault detection circuitry, appearing as a short circuit during turn on.
6/ Parameter shall be tested as part of design characterization and after design or process changes. Thereafter parameters shall be guaranteed to the limits
specified in Table I.
7/ An overload is that condition with a load in excess of the rated load but less than that necessary to trigger the short circuit protection and is the condition of
maximum power dissipation.
8/ Load step transition time between 2 and 10 microseconds.
9/ Recovery time is measured from the initiation of the transient to where VOUT has returned to within ±1 percent of VOUT at 50 percent load.
10/Turn on delay time measurement is for either a step application of power at the input or the removal of a ground signal from the inhibit pin (pin 2) while
power is applied to the input.
3
SPECIFICATIONS
ATW2812S
ABSOLUTE MAXIMUM RATINGS
Input Voltage
Soldering Temperature
Case Temperature
-0.5V to 50V
300°C for 10 seconds
Operating-55°C to +125°C
Storage -65°C to +135°C
TABLE II. Electrical Performance Characteristics
Test
Symbol
Conditions
-55°C ≤ TC ≤ +125°C
VIN = 28 V dc ±5%, CL = 0 unless
otherwise specified
Group A
subgroups
Device
types
Limits
Min
Output voltage
VOUT
IOUT = 0
1
All
2,3
Output current 1/
IOUT
VIN = 19, 28, and 40 V dc
1,2,3
All
Output ripple voltage 2/
VRIP
VIN = 19, 28, and 40 V dc
B.W. = dc to 2 MHz
1,2,3
All
Output power 1/ 3/
POUT
VIN = 19, 28, and 40 V dc
1,2,3
All
Line
regulation 4/
VRLINE
VIN = 19, 28, and 40 V dc
IOUT = 0, 3000, and 6000 mA
1
All
Unit
Max
4.95
5.05
4.90
5.10
0.0
6000
50
30
mA
mV p-p
W
5
2,3
V
mV
20
Load
regulation 4/
VRLOAD
VIN = 19, 28, and 40 V dc
IOUT = 0, 3000, and 6000 mA
1,2,3
All
30
mV
Input current
IIN
IOUT = 0, inhibit (pin 2) tied to input
return (pin 10)
1,2,3
All
18
mA
IOUT = 0, inhibit (pin 2) = open
Input ripple current 2/
IRIP
IOUT = 6000 mA
B.W. = dc to 2 MHz
Efficiency
EFF
Isolation
40
1,2,3
All
20
IOUT = 6000 mA, TC = +25°C
1
All
78
ISO
Input to output or any pin
to case (except pin 7) at 500 V dc, TC
= +25°C
1
All
100
Capacitive load 5/ 6/
CL
No effect on dc performance,
TC = +25°C
4
All
500
µF
Power dissipation load fault
PD
Overload, TC = +25°C 7/
1
All
12
W
%
MΩ
9
Short circuit, TC = +25°C
See footnotes at end of table.
4
mA p-p
ATW2812S
TABLE II. Electrical Performance Characteristics - Continued.
Test
Symbol
Conditions
-55°C ≤ TC ≤ +125°C
VIN = 28 V dc ±5%, CL = 0 unless
otherwise specified
Group A
Subgroups
Device
Type
Limits
Min
Switching frequency
Output response to step
transient load changes 8/
Recovery time step transient
load changes 8/ 9/
FS
VOTLOAD
TTLOAD
IOUT = 6000 mA
4,5,6
Unit
Max
01
250
300
02
250
270
03
275
300
4000 mA to/from 6000 mA
4,5,6
All
-500
+500
500 mA to/from 2500 mA
4,5,6
All
-500
+500
4000 mA to/from 6000 mA
4
All
5,6
500 mA to/from 2500 mA
4
100
kHz
mV pk
µs
200
All
5,6
100
200
Turn on overshoot
VTonOS
IOUT = 0 and 6000 mA
4,5,6
All
500
Turn on delay 10/
TonD
IOUT = 0 and 6000 mA
4,5,6
All
12
ms
Load fault recovery 6/ 10/
TrLF
4,5,6
All
12
ms
75
grams
Weight
Flange
mV pk
Notes:
1/
2/
3/
4/
5/
Parameter guaranteed by line and load regulation tests.
Bandwidth guaranteed by design. Tested for 20 KHz to 2 MHz.
Above +125°C case, derate output power linearly to 0 at +135°C.
Output voltage measured at load with remote sense leads connected across load.
Capacitive load may be any value from 0 to the maximum limit without compromising dc performance. A capacitive load in excess of the maximum limit
will not disturb loop stability but may interfere with the operation of the load fault detection circuitry, appearing as a short circuit during turn on.
6/ Parameter shall be tested as part of design characterization and after design or process changes. Thereafter parameters shall be guaranteed to the limits
specified in Table II.
7/ An overload is that condition with a load in excess of the rated load but less than that necessary to trigger the short circuit protection and is the condition of
maximum power dissipation.
8/ Load step transition time between 2 and 10 microseconds.
9/ Recovery time is measured from the initiation of the transient to where VOUT has returned to within ±1 percent of VOUT at 50 percent load.
10/ Turn on delay time measurement is for either a step application of power at the input or the removal of a ground signal from the inhibit pin (pin 2) while
power is applied to the input.
5
SPECIFICATIONS
ATW2815S
ABSOLUTE MAXIMUM RATINGS
Input Voltage
Soldering Temperature
Case Temperature
-0.5V to 50V
300°C for 10 seconds
Operating-55°C to +125°C
Storage -65°C to +135°C
TABLE III. Electrical Performance Characteristics
Test
Symbol
Conditions
-55°C ≤ TC ≤ +125°C
VIN = 28 V dc ±5%, CL = 0 unless
otherwise specified
Group A
subgroups
Device
types
Limits
Min
Output voltage
VOUT
IOUT = 0
1
All
2,3
Output current 1/
IOUT
VIN = 17, 28, and 40 V dc
1,2,3
All
Output ripple voltage 2/
VRIP
VIN = 17, 28, and 40 V dc
B.W. = dc to 2 MHz
1,2,3
All
Output power 1/ 3/
POUT
VIN = 17, 28, and 40 V dc
1,2,3
All
Line
regulation
VRLINE
VIN = 17, 28, and 40 V dc
IOUT = 0, .677, and 1333 mA
1
All
Unit
Max
14.85
15.15
14.70
15.30
0.0
1333
60
20
mA
mV p-p
W
35
2,3
V
mV
75
Load
regulation
VRLOAD
VIN = 17, 28, and 40 V dc
IOUT = 0, .677, and 1333 mA
1,2,3
All
150
mV
Input current
IIN
IOUT = 0, inhibit (pin 2) tied to input
return (pin 10)
1,2,3
All
18
mA
IOUT = 0,
inhibit (pin 2) = open
Input ripple current 2/
IRIP
IOUT = 1333 mA
B.W. = dc to 2 MHz
Efficiency
EFF
Isolation
35
1,2,3
All
50
IOUT = 1333 mA, TC = +25°C
1
All
80
ISO
Input to output or any pin to case
(except pin 8) at 500 V dc, TC =
+25°C
1
All
100
Capacitive load 4/ 5/
CL
No effect on dc performance, TC =
+25°C
4
All
200
µF
Power dissipation load fault
PD
Overload, TC = +25°C 6/
1
All
6
W
%
MΩ
6
Short circuit, TC = +25°C
See footnotes at end of table.
6
mA p-p
ATW2815S
TABLE III. Electrical Performance Characteristics - Continued.
Test
Symbol
Conditions
-55°C ≤ TC ≤ +125°C
VIN = 28 V dc ±5%, CL = 0 unless
otherwise specified
Group A
subgroups
Device
types
Limits
Min
Switching frequency
FS
Output response to step
transient load changes 7/
VOTLOAD
IOUT = 1333 mA
4,5,6
50 percent load to/from 100 percent
load
4
4
225
275
02
225
245
03
250
275
All
-300
+300
-450
+450
-500
+500
-750
+750
All
5,6
Recovery time step transient
load changes 7/ 8/
TTLOAD
50 percent load to/from 100 percent
load
4
All
5,6
Output response to transient
step line changes 5/ 9/
Recovery time transient line
changes 5/ 8/ 9/
VOTLINE
TTLINE
Max
01
5,6
No load to/from 50 percent load
Unit
70
kHz
mV pk
µs
100
No load to 50 percent load
4,5,6
All
1500
50 percent load to no load
4,5,6
All
5
Input step 17 to 40 V dc
4,5,6
All
500
Input step 40 to 17 V dc
4,5,6
All
-1500
Input step 17 to 40 V dc
4,5,6
All
800
Input step 40 to 17 V dc
4,5,6
All
800
ms
mV pk
ms
Turn on overshoot
VTonOS
IOUT = 0 and 1333 mA
4,5,6
All
600
Turn on delay 10/
TonD
IOUT = 0 and 1333 mA
4,5,6
All
10
ms
4,5,6
All
10
ms
75
grams
Load fault recovery
Weight
5/
TrLF
Flange
mV pk
Notes:
1/
2/
3/
4/
Parameter guaranteed by line and load regulation tests.
Bandwidth guaranteed by design. Tested for 20 KHz to 2 MHz.
For operation at 16 V dc input, derate output power by 33 percent.
Capacitive load may be any value from 0 to the maximum limit without compromising dc performance. A capacitive load in excess of the maximum
limit will not disturb loop stability but may interfere with the operation of the load fault detection circuitry, appearing as a short circuit during turn on.
5/ Parameter shall be tested as part of design characterization and after design or process changes. Thereafter parameters shall be guaranteed to the limits
specified in Table III.
6/ An overload is that condition with a load in excess of the rated load but less than that necessary to trigger the short circuit protection and is the condition
of maximum power dissipation.
7/ Load step transition time between 2 and 10 microseconds.
8/ Recovery time is measured from the initiation of the transient to where VOUT has returned to within ±1 percent of VOUT at 50 percent load.
9/ Input step transition time between 2 and 10 microseconds.
10/ Turn on delay time measurement is for either a step application of power at the input or the removal of a ground signal from the inhibit pin (pin 2) while
power is applied to the input.
7
BLOCK DIAGRAM
INPUT
FILTER
1
OUTPUT
FILTER
5
2
CONTROLLER
6
8
ERROR
AMP
& REF
10
4
Available Screening Levels and Process Variations for ATW 2800S Series
Requirement
MIL-STD-883 method
Temperature Range
Element Evaluation
Internal Visual
Temperature Cycle
Constant Acceleration
Burn-in
Final Electrical (Group A)
Seal, Fine & Gross
External Visual
◆ per Commercial Standards
No Suffix
ES Suffix
-55°C to +85°C -55°C to +115°C
2017
1010, Cond C
2001, Cond A
1015
Specification
1014
2009
◆
✔
Cond A
500g
96hrs @105°C
25°C
✔
✔
25°C
◆
HB Suffix
-55°C to +125°C
✔
✔
5,000g
160hrs @125°C
-55, +25, +125°C
✔
✔
PART NUMBER
ATW 28xx S / x - xxx
Model
Input Voltage
Synchronization Option
Omit for standard
MSTR — Master
SLV — Slave
Output Voltage
Single Output
3
Temperature Range
Omit for -55°C to +85°C (Industrial)
ES — -55°C to +105°C (Environmental)
HB — -55°C to +125°C (Military Screening)
CH — -55½C to +125°C (DESC Compliant)
8
CH Suffix
-55°C to +125°C
MIL-PRF-38534
✔
✔
5,000g
160hrs @125°C
-55,+25, +125°C
✔
✔
TYPICAL CHARACTERISTICS
Waveforms shown are for ATW2805
2 mV/div
2 mA/div
2 µs/div
Figure 1 Output Ripple Voltage
VIN = 28 VDC, Full Load
2 µs/div
Figure 2 Input Ripple Voltage
VIN = 28 VDC, Full Load
1 mV/div
1 mV/div
2 ms/div
Figure 3 Turn-on Response @Full Load
100 µs/div
Figure 4 Turn-on Response, @Full Load
5.5 V
5.5 V
100 mV/div
100 mV/div
4.5 V
4.5 V
100 µs/div
Figure 5 Load Step Response
Load Step 0 to 6.0 ADC
(No Load to Full Load)
9
2 ms/div
Figure 6 Load Step Response
Load Step 3.0 to 0 ADC
(Full Load to No Load)
TYPICAL CHARACTERISTICS (Continued)
5.5 V
6.5 V
100 mV/div
100 mV/div
4.5 V
4.5 V
50 µs/div
Figure 7 Load Step Response
Load Step 3.0 ADC to 6.0 ADC
(Half Load to Full Load)
100 µs/div
Figure 9 Line Step Response
A: Output @ 100 mV V/div, Full Load
B: Input step @ 19 VDC to 40 VDC
50 µs/div
Figure 8 Load Step Response
Load Step 6.0 ADC to 3.0 ADC
(Full Load to Half Load)
100 µs/div
Figure 10 Line Step Response
A: Output @ 100 mV/div, Full Load
B: Input Step 40 VDC to 19 VDC
10
TYPICAL CHARACTERISTICS (Continued)
Figure 12 Audio Rejection with AFC461 EMI Filter
MECHANICAL OUTLINE
2.700 max
(68.580)
0.090R max
1.350 max
(34.290)
1.00 ± 0.005
(25.400 ± 0.127)
10
1
Pin #1
Bottom
View
2.360 ± 0.005
(59.944 ± 0.127)
0.162D ± 0.005 2 places
(4.115 ± 0.127)
1.950 max
(49.530)
0.050 max
(1.270)
6
0.500 max
(12.700)
4 x 0.400 ± 0.005 = 1.600 ± 0.010
(10.160 ± 0.127) (40.640 ± 0.254)
0.040D ± 0.002 x 0.260L ± 0.010
(1.016 ± 0.050) (6.604 ± 0.254)
PIN DESIGNATION
Pin 1
Pin 2
Pin 3
Pin 4
Pin 5
Positive input
Inhibit input
Neg. remote sense*
Output common
Positive output
Pin 10
Pin 9
Pin 8
Pin 7
Pin 6
Input common
N/C
N/C**
Case ground
Pos. remote sense*
*ATW2805S only. ATW2812S, ATW2815S have N/C.
**Or synchronization option.
11
5
APPLICATION INFORMATION
Inhibit Function
Connecting the inhibit input (Pin 2) to input common (Pin 10) will cause the converter to shut
down. It is recommended that the inhibit pin be
driven by an open collector device capable of
sinking at least 400 µA of current. The open circuit voltage of the inhibit input is 11.5 ±1 VDC.
To take advantage of this capability, the system
designer must assign one of the converters as the
master. Then, by definition, the remaining converters become slaves and will operate at the
masters’ switching frequency. The user should
be aware that the synchronization system is failsafe; that is, the slaves will continue operating
should the master frequency be interrupted for
any reason. The layout must be such that the
synchronization output (pin 8) of the master device is connected to the synchronization input (pin
8) of each slave device. It is advisable to keep
this run short to minimize the possibility of radiating the 250 KHz switching frequency.
The appropriate parts must be ordered to utilize
this feature. After selecting the converters required for the system, a ‘MSTR’ suffix is added
for the master converter part number and a ‘SLV’
suffix is added for slave part number. See Part
Number section.
EMI Filter
An optional EMI filter (AFC461) will reduce the input ripple current to levels below the limits imposed by MIL-STD-461 CEO3.
Remote Sense (ATW2805S only)
Better than 0.1% line and load regulation (case
temperature constant) are typical when the remote sense leads are used. If the remote sense
leads are left unconnected, then the output voltage (measured at pins 4 and 5) will rise approximately 5.4 VDC.
If the remote sense leads are shorted together,
the output voltage may rise above 10 VDC depending on load, posibly damaging both the converter and load.
Device Synchronization
Whenever multiple DC/DC converters are utilized
in a single system, significant low frequency noise
may be generated due to slight differences in the
switching frequencies of the converters (beat
frequency noise). Because of the low frequency
nature of this noise (typically less than 10 KHz), it
is difficult to filter out and may interfere with
proper operation of sensitive systems (communications, radar or telemetry). Lambda Advanced
Analog offers an option which provides synchronization of multiple AHE/ATW type converters, thus
eliminating this type of noise.
1
FILTER
4
3
1
10
ATW2815D/ES-SLV
SLAVE
SYSTEM
BUS
1
10
52467
52467
52467
ATW2805S/CH
ATW2805S/CH-SLV
ATW2805S/CH-MSTR
5962-921101HZX
5962-921102HZX
5962-921103HZX
52467
52467
52467
ATW2812S/CH
ATW2812S/CH-SLV
ATW2812S/CH-MSTR
5962-9159904HZX
5962-9159905HZX
5962-9159906HZX
52467
52467
52467
ATW2815S/CH
ATW2815S/CH-SLV
ATW2815S/CH-MSTR
4
5
5
ATW2812S/ES-SLV
SLAVE
+15V
COMM
-15V
4
+12V
COMM
8
Typical Synchronization Connection Diagram
ATW2805S EFFICIENCY
Vendor
similar
PIN
5962-9157904HZX
5962-9157905HZX
5962-9157906HZX
+5V
COMM
2
Efficiency (%)
Vendor
CAGE
number
5
ATW2805S/ES-MSTR
8
STANDARDIZED MILITARY DRAWING
CROSS REFERENCE
Standardized
military drawing
PIN
10
Output Power (Watts)
12
NOTES
Lambda Advanced Analog
The information in this data sheet has been carefully checked and is believed to be accurate; however no
responsibility is assumed for possible errors. These specifications are subject to change without notice.
LAMBDA ADVANCED ANALOG INC.
λ
MIL-PRF-38534 Certified
ISO9001 Registered
9848
2270 Martin Avenue
Santa Clara CA 95050-2781
(408) 988-4930 FAX (408) 988-2702