MURATA DTL4A

®
®
NEW
INNOVATION and EXCELLENCE
DTL Series
DTL4A Model
Digitally Programmable, 10A/150V
100 Watt, Electronic Loads
DATEL’s new DTL4A is an optically isolated, digitally programmable, serial-input,
electronic load. It is essentially a digitally controlled current source that can sink
currents from 0 to 10 Amps, at loading voltages from 2.5 to 150 Volts, up to a maximum
power of 100 Watts. The DTL4A is packaged in a thermally ef cient, 2" x 2" x 0.5"
metal package that incorporates an aluminum baseplate with through-hole spacers
for easy pcb mounting and/or external heat-sink attachment.
The DTL4A accepts a serialized, 12-bit, CMOS/TTL-compatible, digital input word
easily generated by any standard digital I/O card. The DTL4A buffers and then
optically isolates (500Vdc) the digital input data before storing it in a register and
presenting it to an on-board, 12-bit, digital-to-analog (D/A) converter. The D/A output
drives a near-ideal (10MΩ minimum output impedance), voltage-controlled current
source. One LSB (least signi cant bit) of the D/A converter corresponds to a 2.4mA
increment (0.024% of 10A) in load current.
The DTL4A features a max. ±3mA offset error and a max. ±0.1% gain error. It
has an impressive full-scale step response time of 100µsec and can be operated
dynamically at update rates up to 20kHz. Powered by a single +5V supply, the DTL4A
draws a mere 150mA (maximum).
While operating in the constant-current mode up to 10 Amps (100W max. power),
the output compliance voltage of the DTL4A is 2.5 to 150 Volts. Should the output/load
voltage drop below the 2.5V minimum required for proper biasing, an internal monitoring
circuit activates the DTL4A's output Fault line. See DATEL’s DTL2A-LC for compliance
voltages as low as 0.6V.
DTL4A’s and other electronic loads, controller boards, and software from DATEL
are outstanding building-block components for power-supply burn-in and test systems.
They are an extremely reliable, cost-effective solution that enables you to quickly
con gure impressively accurate systems.
Features
■
12-bit, optically isolated (500Vdc),
CMOS/TTL-compatible serial input
■
0-10 Amp output in 2.44mA increments
■
10MΩ minimum output impedance
■
Output voltage to 150 Volts
■
Output power to 100 Watts
■
±3mA offset error; ±0.1% gain error
■
100µsec full-scale step response
■
Update rates to 20kHz
■
Operate in parallel for higher power
■
Miniature, 2" x 2" metal package
Applications
■
Static/dynamic power-supply burn-in
■
Power-supply test and characterization
■
Battery capacity testing
■
Current-source testing
■
Capacitor discharge testing
■
Real-time load simulation
INPUT
BUFFERS
OPTO
ISOLATORS
CONTROL STROBE (CS)
+LOAD
+LOAD
CLOCK (CLK)
DATA
LATCH
SERIAL DATA INPUT (SDI)
12-BIT
D/A
AMPLIFIER
AND
CURRENT
SENSOR
POWER DEVICE
UNDER TEST
–LOAD
LATCH DATA (LD)
+5V SUPPLY
GROUND
–LOAD
UNDERVOLTAGE
DETECTION
ISOLATED
DC/DC
CONVERTER
FAULT
Figure 1. Simplified Schematic
DATEL, Inc., Mans eld, MA 02048 (USA) · Tel: (508)339-3000, (800)233-2765 Fax: (508)339-6356 · Email: [email protected] · Internet: www.datel.com
DTL Series
1 0 0 WAT T, S E R I A L - I N P U T E L E C T R O N I C L OA D S
Performance Specifications and Ordering Guide
➀
Input
Output
Model
Resolution
(Bits)
Logic
Compatibility
Current
(Amps)
Resolution
(mA) ➁
Compliance
Voltage
(Volts) ➂
Power
(Watts)
Package
(Case, Pinout)
DTL4A
12
CMOS/TTL ➃
0-10
2.44
2.5-150
0-100
C24, P31
➀ Typical at TA = +25°C with nominal +5V supply voltage unless noted.
➁ The smallest increment/decrement in output current is defined by one LSB (least significant bit) of the 12-bit
digital input word. One LSB is equal to full scale (FS) divided by 4096 which corresponds to 0.0244% of 10A or 2.44mA.
➂ For proper operation, the unit's output/load voltage must remain within this range. Voltages greater than the listed
maximum can damage the device. Voltages less than the minimum provide insufficient bias for the output stage
and will result in unpredictable or no operation. See Output Compliance Voltage and the Fault Line for details.
➃ See Performance/Functional Specifications for details.
M E C H A N I C A L S P E C I F I C AT I O N S
PA R T N U M B E R S T R U C T U R E
DTL
2.00
(50.80)
4 A
A-Series
High Reliability
DATEL
Electronic Load
ALUMINUM BASEPLATE
METAL CASE
0.50
(12.70)
Case C24
Voltage Range:
4 = 2.5 to 150V
0.060 ±0.002 DIA.
(1.524 ±0.051)
0.040 ±0.002 DIA.
(1.016 ±0.051)
0.20 MIN
(5.08)
1.800
(45.72)
0.10
(2.54)
1.640
(41.66)
0.08
(2.03)
T E M P E R AT U R E D E R AT I N
8
7
100
6
90
80
Output Power/Load (Watts)
5
1.20
(30.48)
6 EQ. SP. @
0.200 (5.08)
9
2.00
1.640
(41.66) (50.80)
4
3
10
2
70
1
11
60
0.40
(10.16)
50
BOTTOM VIEW
#4-40 CLEAR THRU
(TYP. 4 PL)
40
0.22
(5.59)
30
I/O Connections
20
10
0
10
20
30
40
50
60
70
80
90
100
Baseplate Temperature (°C)
The horizontal axis of the above chart references the temperature of the DTL4A’s aluminum baseplate. The device can continually dissipate up to 100 Watts if the baseplate
is maintained at or below +50°C. At +25°C ambient temperature, with no heat sink or
supplemental air flow, the DTL4A can reliably dissipate a continuous 10 Watts.
Pin
Function P31
Pin
Function P31
1
Fault
7
Control Strobe (CS)
2
Ground
8
–Load
3
+5 Volt Supply
9
–Load
4
Latch Data (LD)
10
+Load
5
Serial Data In (SDI)
11
+Load
6
Clock (CLK)
Contact DATEL for Heat Sink information.
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DTL4A Model
1 0 0 WAT T, S E R I A L - I N P U T E L E C T R O N I C L OA D S
Performance/Functional Specifications
Typical @ TA = +25°C with nominal +5V supply voltage, unless noted.
➀ The smallest increment/decrement in output current is defined by one LSB (least significant
bit) of the 12-bit digital input word. One LSB is equal to full scale (FS) divided by 4096 which
corresponds to 0.0244% of 10A or 2.44mA.
➁ For proper operation, the unit's output/load voltage must remain within this range. Voltages
greater than the listed maximum can damage the device. Voltages less than the minimum
provide insufficient bias for the output stage and will result in unpredictable or no operation.
See Output Compliance Voltage and the Fault Line for details.
➂ Offset error is defined as the current sunk/sourced by the DTL4A’s output, under any output
voltage conditions, when the digital input word is all "0's."
➃ Full scale step (10 Amps) settling to within ±2.44mA of its final value.
➄ See Temperature Derating.
➅ Applies over all specified ranges/combinations of load voltage/current, operating temperature,
and VCC.
Digital Inputs/Outputs
Logic Compatibility (Pins 1, 4-7)
CMOS/TTL
Input Logic Levels:
Logic "1"
Logic "0"
+2 Volts, minimum
+0.8 Volts, maximum
Input Logic Loading:
Logic "1" (IIH @ VIH = 5 Volts)
Logic "0" (IIL @ VIL = 0 Volts)
20µA, maximum
–0.6mA, maximum
Output Logic Levels:
Logic "1" (@ 150µA)
Logic "0" (@ 1.6mA)
+3.5 Volts, minimum
+0.4 Volts, maximum
Timing
See Timing Diagram
Absolute Maximum Ratings
Output
Power Supply Voltage (+VCC, Pin 3)
–0.5 to +5.5 Volts
Current:
Range
Resolution ➀
Accuracy ➅
Digital Input Voltage (Pins 4-7)
–0.5 to +5.5 Volts
0-10 Amps
0.024%FS (2.44mA)
±1%, maximum
Output Reverse-Polarity Protection
No protection
Output Overvoltage Protection
No protection
Output Undervoltage Protection
Yes (See Fault Line)
Case Temperature
+105°C
Storage Temperature (Ambient)
–40 to +125°C
+300°C
Voltage Range ➁
2.5-150 Volts
Power Range
0-100 Watts
Impedance
10MΩ, minimum
Offset Error ➂
±3mA, maximum
Gain Error
±0.1%, maximum
Lead Temperature (soldering, 10 sec.)
Isolation Voltage:
Digital Inputs/Output to ±Load
Any Pin to Case
500Vdc, minimum
500Vdc, minimum
These are stress ratings. Exposure of devices to any of these conditions may adversely
affect long-term reliability. Proper operation under conditions other than those listed in the
Performance/Functional Specifications Table is not implied.
Isolation Resistance
100MΩ, minimum
Dynamic Performance
Output Slew Rate
TECHNICAL NOTES
±10A/µsec, minimum
Output Settling Time ➃
100µsec
Digital Input Update Rate
to 20kHz
Overview
The DTL4A is a digitally programmable, CMOS/TTL-compatible, serial-input
current sink. It’s output/load current range is 0 to 10 Amps (in 2.44mA
increments), over a compliance voltage range of 2.5 to 150 Volts and an output/
load power range of 0 to 100 Watts. The device’s digital I/O coding is straight
binary (see table below). A digital input of all "0’s" forces a load current of 0
Amps. A digital input of all "1’s" forces a load current of 9.99756 Amps.
Power Requirements
Power Supply Range (+VCC, Pin 3)
+4.75-5.25 Volts (+5V nominal)
Power Supply Current
110mA typ., 150mA max.
Environmental
Operating Temperature ➄
–40 to +100°C (Case)
Storage Temperature
–40 to +125°C (Ambient)
Humidity (Non-condensing)
to 95%
Altitude Above Sea Level
In a typical power-supply test or burn-in application, the output pins of the
device under test (DUT) are connected to the DTL4A’s +Load (pins 10 and 11)
and –Load (pins 8 and 9) outputs. The DTL4A’s operation is controlled by its
four digital input lines (Serial Data In, Clock, Latch Data and Control Strobe).
10,000 feet
Physical
Dimensions
2" x 2" x 0.5" (51 x 51 x 12.7mm)
Shielding
6-sided (Connected to pin 2)
Case Material
Tin-plated steel shell with
aluminum baseplate
Pin Material
Brass, solder coated
Mounting Holes
Through-hole spacers, #4-40 clearance
Weight
1.9 ounces (54 grams)
Serial Input Data Word
MSB
Load Current (Amps)
LSB
DTL4A
1111
1111
1111
9.9976
1100
0000
0000
7.5000
1000
0000
0000
5.0000
0111
1111
1111
4.9976
0100
0000
0000
2.5000
0010
0000
0000
1.2500
0000
0000
0001
0.0024
0000
0000
0000
0.0000
Mapping of the Serial-Input Data to Load Current
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DTL Series
1 0 0 WAT T, S E R I A L - I N P U T E L E C T R O N I C L OA D S
Output Compliance Voltage and the Fault Line
Initialization
For proper operation, the DTL4A’s output/load voltage must
always be between 2.5 and 150 Volts. The device cannot be used
to directly load low-voltage, e.g. 1.8V or 2.5V, power components or
to simulate a true short circuit (0 Volts). Voltages greater than 150V
can damage the device. Voltages <2.5V will result in insufficient
biasing of the output current source and consequently unpredictable or no operation. Accordingly, we have installed an internal
output/load-voltage monitoring circuit. If the output/load voltage
drops below 2.5V and the DTL4A’s output is at risk of becoming
disabled, the Fault line activates.
The Fault line is an optically isolated, active-low function with
an open-collector output (internal 10kΩ pull-up resistor to +5V).
Under normal conditions, its output is high (logic "1"). Under fault
conditions (VOUT < 2.5V), its output drops to a logic "0." There is
no output/load-voltage monitoring circuit for voltages greater than
150V, and operation above 150V can damage the device.
An "offset supply" can be inserted between the DTL4A’s –Load
output (pins 8 and 9) and the power device under test (DUT)
to "translate" the DTL4A’s 147.5V output/load voltage range. The
offset supply must have adequate current capabilities and be connected with the polarities indicated in Figure 2 below. Under no
circumstances should the voltage across the DTL4A’s output be
allowed to experience a polarity reversal.
If a 5V/20A offset supply is inserted as shown, the range of
DUT voltages will be –2.5 to +145 Volts. Such a configuration
can be used for true short-circuit testing. A mechanical relay can
be used to short the outputs of the DUT while the offset supply
ensures the DTL4A always sees at least 5 Volts across its outputs.
Preparing the DTL4A to accept new digital data is accomplished by applying
logic "1's" to Control Strobe (CS, pin 7), Latch Data (LD, pin 4) and Clock
(CLK, pin 6) with all signals present and stable for a minimum of 1µsec.
During this interval, it does not matter whether or not data is present on the
Serial Data In (SDI, pin 5) line.
Serial Data
Following initialization, the 12-bit digital word representing the desired output
current is applied to the SDI pin. The serial data should appear starting with
the most significant bit (MSB, bit 1, D11) and ending with the least significant
bit (LSB, bit 12, D0). With each data bit present and stable on the SDI line,
the CLK must be toggled through a low-to-high transition to register that bit.
Twelve rising clock edges, at rates up to 500kHz, are required to clock all 12
digital bits into the DTL4A’s input register.
Latching Data and Presenting It to the D/A
After loading the LSB, the serial data word is latched by bringing the Control
Strobe (pin 7) high and then toggling the Latch Data pin (pin 4) through a
high-low-high sequence. Approximately 100µsec later, the output current will
settle to its final desired value.
Software: C Language
The following steps describe a typical timing sequence when using the
DTL4A’s 4 digital inputs and a programming language such as C. Using 4 bits
of a typical 8-bit port, assign BIT_0 to the Control Strobe (CS, pin 7), BIT_1
to Latch Data (LD, pin 4), BIT_2 to Serial Data In (SDI, pin 5), and BIT_3
to the Clock (CLK, pin 6).
1. Initialize with Control Strobe, Latch Data, and Clock high:
BIT_0 = 1, BIT_1 = 1, BIT_2 = X (don’t care), BIT_3 = 1
+LOAD
11
10
2. Bring the Control Strobe low.
BIT_0 = 0
+
DTL4A
DUT
5V
3. Apply the MSB (D11) of the serial data word to Serial Data In.
BIT_2 = 0 or 1
9
–LOAD
–
+
SHORT
CIRCUIT
RELAY
–
8
4. Toggle the Clock high-low-high.
BIT_3 = 1 to 0 to 1
Figure 2. An "Offset Supply" Enables
True Short-Circuit Testing
5. Apply D10 of the serial data word to Serial Data In.
BIT_2 = 0 or 1
6. Toggle the Clock high-low-high.
BIT_3 = 1 to 0 to 1
Thermal Considerations
The DTL4A can reliably handle 100W loads if its case temperature is
maintained at or below +50°C. With no heat sinking or auxiliary cooling, the
device can only handle loads up to 10 Watts. Please refer to the Temperature
Derating Curve for additional information. DATEL’s Electronic Load Applications Engineers can assist you in developing heat-sink solutions for your
higher-power DTL4A applications. Please contact us for details.
7. Repeat the process for remaining data bits D9 through D0.
8. Drive the Control Strobe high.
BIT_0 = 1
9. Toggle the Latch Data input high-low-high.
BIT_1 = 1 to 0 to 1.
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DTL4A Model
1 0 0 WAT T, S E R I A L - I N P U T E L E C T R O N I C L OA D S
tdh
D11
SDI
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
tds
tin
CLK
tcl
tcss
tcsh
tch
CS
tld1
tld2
LD
tldw
Timing
Min.
Typ.
Max.
CLK
–
–
200
Units
tin
1
–
–
tcl = tch
tcss
tcsh
tld1
tld2
tldw
tds
tdh
1
–
–
µsec
1
–
–
µsec
1
–
–
µsec
2
–
–
µsec
2
–
–
µsec
2
–
–
µsec
kHz
µsec
0.5
–
–
µsec
0.5
–
–
µsec
Figure 3. DTL4A Timing Diagram
®
®
INNOVATION and EXCELLENCE
ISO 9001 REGISTERED
DS-0478
9/00
DATEL (UK) LTD. Tadley, England Tel: (01256)-880444
DATEL S.A.R.L. Montigny Le Bretonneux, France Tel: 01-34-60-01-01
DATEL GmbH München, Germany Tel: 89-544334-0
DATEL KK Tokyo, Japan Tel: 3-3779-1031, Osaka Tel: 6-354-2025
DATEL, Inc. 11 Cabot Boulevard, Mansfield, MA 02048-1151
Tel: (508) 339-3000 (800) 233-2765 Fax: (508) 339-6356
Internet: www.datel.com
Email: [email protected]
DATEL makes no representation that the use of its products in the circuits described herein, or the use of other technical information contained herein, will not infringe upon existing or future patent rights. The descriptions contained herein
do not imply the granting of licenses to make, use, or sell equipment constructed in accordance therewith. Specifications are subject to change without notice. The DATEL logo is a registered DATEL, Inc. trademark.
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