AD DAC1132 High pergormance digital to analog converter Datasheet

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HighPerformance
Digital-to-AnalogConverter
DEVICES
PRELIMINARY TECHNICAL DATA
FEATURES
12 Bit Resolution
. Input Register Included
Small Module Package
Programmable Output Ranges
0 to +70° C Monotonicity
Low 8ppmfC Gain TC
2J1.sSettling Time
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GENERAL DESCRIPTION
The DACl132 is a 12 bit, high performance digital-to-analog
converter packaged in a very compact 2" x 2" x 0.4" module.
It comes complete with an input storage register and a fast
settling output amplifier which can be jumper programmed to
produce either of five output voltage ranges. Performance
specifications include 2Jl.Ssettling time to 0.01 %, 8ppm/C
gain temperatUre coefficient, :!:~LSB linearity error, and
monotonicity from 0 to +70°C.
OUTPUT CHARACTERISTICS
The 12 binary-weighted current sources which form the basis
of the digital-to-analog conversion process are directly controlled by the digital data stored in the input register. The
combined output of these sources is applied to the internal op
amp summing junction to produce a voltage output signal. By
connecting jumpers between the proper module pins, various
values of op amp feedback resistance and thus, output voltage
ranges can be selected.
The DACl132 combines the ADS 62 integrated circuit DIA
with a TTL input register, an output amplifier, and a precision
reference source to form a complete converter package. The
laser trimmed ADS62 which consists of precision current
switches, and a very stable thin film resistor network provides
the DACl132 with excellent performance over temperatUre
and makes possible its small module size.
In order to produce bipolar outputs, the current input to the
internal op amp is offset by ~ Full Scale. This offset current is
generated bv the precision internal reference source and is applied to the op amp summing junction by means of a jumper
connected betWeen appropriate module terminals.
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DIGITAL INPUT CHARACTERISTICS
The TTLlDTL compatible storage register contained within
the DAC1132 accepts either Binary or Offset Binary coded
inputs. Digital data appearing at the converter's 12 input terminals will be strobed into the register whenever a positive
going transition is applied to the STROBE input (pin 6).
With the STROBE input held at either logic "0" or logic "1",
the input data may be changed without affecting either the
contents of the register or the output of the converter. The
transfer characteristics of the DACl132 are such that a full
scale digital input (111111111111) results in a positive full
scale voltage output.
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Note: this data sheet includes "Preliminary Technical Data" describing
a new product. Though highly unlikely, it may be necessary to alter the
specifications to reflect life data collected during the initial months of
the product's use.
Information furnished by Analog Devices is believed to ba 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
panies which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Route 1 Industrial Park; P.O. Box 280; Norwood, Mass. 02062
Tel: 617/329-4700
TWX: 710/394-6577
West Coast
Tel: 213/595-1783
Mid-West
Tel: 312/297-87"10
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SPECIFICATIONS
(typical @+25°C and rated supply voltages, unlessotherwise specified)
DIGITAL
OUTLINE DIMENSIONS AND
PIN DESIGNATIONS
Dimensionsshown in inches and (mm).
12 Bits
RESOLUTION
INPUTS
OV ~ Logic "0" ~ 0.8V
+2V ~ Logic "1" ~ +5V
1 Standard TTL Loadlbit
2 Standard TTL Loads
20ns (Min)
20ns (Min)
5ns
Logic Levels
Data Input Load
Strobe Input Load
Strobe Pulse Width
. Data Setup Time
Data Hold Time
---~
INPUT CODES
Unipolar
_.. Bipolar -OUTPUT RANGES
f-
Reference Voltage
TEMPERATURE RANGE
Operating
POWER S.UPPLY SENSITIVITy3
Gain
Offset (unipolar)
Offset (bipolar)
Reference
AD1uSTMENTS (User Provided)
Gain
Offset
o.41 MAX
(10.4)
0.2MIN
~""2.01MAX
f
NOTE:
Terminal pins installed only in shaded hole
locations.
Module weight: 1.6 ounces (45 grams)
All pins are gold plated half-hard brass,
(MIL-G-45204), 0.019" :to.OO1" (0.483
:to.025mm) dia.
For plug-in mounting card order Board
No. AC1506 @$30.
2.0p.s (3.0p.s Max) to 0.01 %T
IY2LSB
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I8.0ppm/C
(I10ppm/C Max)
of Reading
I13p.V/C (I16p.V/C Max)
I2.6ppm/C
(I3.2ppm/C Max)
I2.8ppm/C
(I3.0ppm/C Max)
of Full Scale
I5ppm/C (I12ppm/C Max)
0 to +70°C
-55°C to +lOO°C
+15V I3% @ 32mA (37mA Max)
-15V I3% @ 27mA (30mA Max)
+5V I3% @ 140mA (150mA Max)
POWER REQUIREMENTS
1 For a lOV
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Unipolar Offset
Bipolar Offset2
Differential Nonlinearity
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Binary
Offset Binary
0 to +5V @ lamA
0 to +10V @ 10mA
I2.5V @ 10mA
I5V @ lamA
I10V @ 10mA
OUTPUT IMPEDANCE
SETTLING TIME
LINEARITY ERROR
TEMPERATURE COEFFICIENT
Gain2
PRICE (1-9)
2.01 MAX
(51.1)
8
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BLOCK DIAGRAM
BIT8 14
8
-
8
4
15 BIT9
16 BIT 10
BIT7 13
BIT6 12
BITS 11
17 BIT 11
18 LSB
BIT410
BIT 3 9
4mV/V
4mV/V
4mV/V
2p.V/V
21 BIPOLAR
OFFSET
BIT28
(7mV/V Max)
(7mV/V Max)
(7mVN Max)
(5IlV/V Max)
22 GAIN
MSB 7
STROBE 8
~
24
+5V 3
+15V 2
~+5V
28 ANALOG
~+15V
27 SUM JUNCT.
-15V 1
~-I5V
KEY K
28 OFFSET
ADJUST
0
GNO S
IRLSB (Min)
I10LSB
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ADJ.
23 20V
10V
25 REF. OUT
CUT
'= 5.1k11
step.
2 These figures
include
the effects
of Reference
Voltage
Temperature
Drift.
For :tl5V supplies only with +l5V and -l5V supplies tracking.
Specifications subject to change without notice.
3
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DIGITAL INPUT DATA
All digital inputs to the DAC1132 are fully DTL/TTL compatible, The 12 data inputs (pins 7-18) each represent one
standard TTL load and the STROBE (pin 6) represents two
TTL loads, The converter uses Binary input code to produce
unipolar outputs and Offset Binary code to produce bipolar
outputs,
The two 5krl. feedback resistors associated with the op amp of
Figure 2 are used to determine the output voltage range. Serial
and parallel combinations of these resistors yield three different
resistance values. Table 1 shows the feedback connections used.
to obtain the various output voltage ranges.
Provided that certain timing requirements are met, data appearing at the converter's input terminals is loaded into the
register by the positive-going edge of the strobe pulse, Figure
1 illustrates the required strobe timing,
Unipolar Units
:t2.5V
:t5.0V
:t10V
Output Range
Bipolar Units
0 to +5V
Oto+lOV
Pins jumpered Together
Pin 23 To:
Pin 26 To:
24
24
23
27
--
--
Table 1. Range Programming Table
DATA MUST BE STABLE~
-.<5ns
:
20ns
MIN
SETUP .
I
MIN ~
~OLD
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20ns MIN
PULSE WIDTH
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'1.5V
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20ns
INPUT-OUTPUT RELATIONSHIPS
Table 2 and Table 3 list the analog outputs associated with
various digital inputs for unipolar and bipolar units respectively.
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25ns
DIGIT AL INPUT
NOMINAL VOLTAGE OUTPUT
40ns
0 to +IOV
Range
+4.9988V
+0.0012V
O.OOOOV
+9.9976V
+0.0024V
O.OOOOV
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Figure 1. Strobe Timing Diagram
Note that the input data must be stable for at least 20ns before
and 5ns after the pulse's leading edge. Note also that the strobe
pulse must be a minimum of 20ns wide. In order to allow adequate time for the converter's analog output to settle between
conversions, the strobe frequency should be limited to 500kHz.
8
0 to +5V
Range
OUTPUT CONNECTIONS
Figure 2, below, shows the output configuration of the
DAC1132 in simplified form.
23 20V RANGE
24 10V RANGE
25 REFERENCE OUT
26 ANALOG OUTPUT
Offset Binary Code
111111111111
100000000001
100000000000
000000000000
Relationships
NOMINAL VOLTAGE OUTPUT
:t2.5V
Range
0
0 TO -2mA
FROM I.C. DIA
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Table 2. Unipolar Input-Output
DIGIT AL INPUT
21 BIPOLAR
OFFSET
995011
Binary Code
111111111111
000000000001
000000000000
:t5V
Range
:tIOV
Range
t-9.9951V
+2.4988V +4.9976V
0.0012V
0.0048V
0.0024V
O.OOOOV
O.OOOOV O.OOOOV
-10.0000V
-2.5000V -5.0000V
27 SUMMING JUNCT.
28 OFFSET ADJUST
Table 3. Bipolar Input-Output Relationships
2.2M
GAIN, AND OFFSET ADJUSTMENTS
The gain and offset adjustments are made with two external potentiometers which the user supplies. With certain
digital inputs applied, these potentiometers are adjusted until
the desired output voltage is obtained. The voltmeter used to
measure the output must be capable of clear and stable resolution of 1/10LSB in the region of zero and full scale. The
adjustment procedure, described below, should be carefully
followed to assure optimum converter performance.
Figure 2. Output Circuit Block Diagram
External jumper connections determine whether the
DAC1132 will be a unipolar or a bipolar device. Figures 3a and
3b below show the proper connections for both configurations.
0
BIPOLAR
OFFSET
0
210
BIPOLAR
OFFSET
210-
0
0
0
0
0
0
REF. OUT. 250
REF. OUT. 250
0
8
CW
28
0
0
20kl1
20 TURN
OFFSET
ADJUST
GAIN ADJ. 22
+15V
+15V
0
OFFSET
ADJUST
The proper connection for the offset potentiometer was shown
in Figures 3a and 3b. The gain potentiometer should be connected as shown below in Figure 4.
0
OFFSET
ADJUST
CW
28
0
20kn
20 TURN
OFFSET
ADJUST
CW
0
10011
20 TURN
GAIN ADJUST
REF. OUT. 25
0
a. Unipolar
-15V
b. Bipolar
-15V
Figure 4. Gain Adjustment
Figure 3. Unipolar/Bipolar Output Connection
-3--
---
--
-
Connection
For unipolar units apply a digital input of 000000000000 and
adjust the offset potentiometer until an output of OV :tl/l0LSB
is obtained.
The output voltage range is programmed by means of jumpers
which the user installs as shown in Figure 7.
For bipolar units apply a digital input of 000000000000 and
adjust the offset potentiometer until the negative full scale output shown in Table 3 is obtained within :tl/l0LSB.
Once the appropriate offset adjustment has been made,
apply a digital input of 111111111111. Adjust the gain
potentiometer until the positive full scale output shown in
Table 2 or Table 3 is obtained within :tl/l0LSB.
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+5V
SUPPLY
<15V
SUPPLY
:
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POWER SUPPLY AND GROUNDING CONNECTIONS
The proper power supply and grounding connections are
shown below in Figure 5.
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+5V
2
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OUTPUT VOLTAGE RANGE
5
0
0 to +10V
0 to +5V
:t2.5V
:t5V
:tlOV
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Figure 5. Power Supply and Grounding Connections
Capacitors have been added within the DAC1132 to bypass
the :t15V and +5V power inputs. Under normal circumstances, no external bypass capacitors are needed.
REFERENCE OUTPUT
The +10V reference output (pin 25) is used to set the converter's gain as shown in Figure 4 and to provide the offset for
bipolar devices as shown in Figure 3. It may also be used to
provide a reference voltage for otner circuits in the user's system provided that the output current is limited. No more
than 1.5 mA should be drawn from bipolar devices and no
more than 2.5mA should be drawn from unipolar devices. Excessive current drain will degrade the converter's analog output
and could damage the internal reference source.
Figure 7. AC 1506 Range Programming
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n
DAC1132
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The pin connections are as shown below in Table 4.
Pin
A
B
C
D
E
F
H
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THE AC1506 MOUNTING CARD
The AC1506 mounting card is available to assist in the application ofthe DAC1132. This 4.5" x 3.0" printed circuit card,
shown below in Figure 6, has sockets which allow a DAC1132
to be plugged directly onto it. It includes the necessary gain,
and offset adjustment potentiometers and it mates with a
Cinch 250-22-30-170 (or equivalent) edge connector which is
supplied with every card.
4.500
JUMPER CONNECTION
A-C
A - C, F - H
D - E, A - C, F - H
D E,A
C
A - B, D - E
K
L
M
Designation
MSB
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Bit 8
Bit 9
Bit 10
Bit 11
Pin
N
P
R
S
T
U
V
W
X
Y
Z
Designanon
Bit 12
N.C.
N.C.
Ground
Ref. Out.
Analog Out.
Strobe
+5V
+15V
-15V
Ground
8
Table 4. AC1506 Pin Designations
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Z
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(114.301
~
Iz
a:
B.
~
3.000
(76.201
8
DIMENSIONS
SHOWN
ARE IN INCHES
AND (MMI.
Figure 6. AC1506 Outline Drawing
-4-