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AD667–SPECIFICATIONS
Model
AD667J
Typ
Min
DIGITAL INPUTS
Resolution
Logic Levels (TTL, Compatible, T MIN–TMAX)1
VIH (Logic “l’’)
VIL (Logic “0”)
IIH (VIH = 5.5 V)
IIL (VIL = 0.8 V)
(@ TA = +258C, 612 V, 615 V power supplies unless otherwise noted)
Max
Min
AD667K
Typ
12
+5.5
+0.8
10
5
+2.0
0
3
1
TRANSFER CHARACTERISTICS
ACCURACY
Linearity Error @ +25°C
TA = TMIN to TMAX
Differential Linearity Error @ +25°C
TA = TMIN to TMAX
Gain Error 2
Unipolar Offset Error 2
Bipolar Zero 2
+2.0
0
3
1
±2
±5
±1
±5
CONVERSION SPEED
Settling Time to ± 0.01% of FSR for
FSR Change (2 kΩi500 pF Load)
with 10 kΩ Feedback
with 5 kΩ Feedback
For LSB Change
Slew Rate
4
3
10
± 2.5, ± 5, ± 10,
+5, +10
±5
3
2
1
±5
0.05
9.90
0.1
POWER SUPPLY SENSITIVITY
VCC = +11.4 V to +16.5 V dc
VEE = –11.4 V to –16.5 V dc
POWER SUPPLY REQUIREMENTS
Rated Voltages
Range4
Supply Current
+11.4 V to +16.5 V dc
–11.4 V to –16.5 V dc
611.4
10.00
1.0
10.10
5
5
10
10
± 12, ± 15
616.5
8
20
TEMPERATURE RANGE
Specification
Storage
Bits
+5.5
+0.8
10
5
V
V
µA
µA
± 15
±3
± 10
4
3
611.4
0
–65
+70
+125
µs
µs
µs
V/µs
0.05
mA
Ω
mA
10.00
1.0
10.10
V
mA
5
5
10
10
ppm of FS/%
ppm of FS/%
616.5
V
V
12
25
mA
mA
+70
+125
°C
°C
± 12, ± 15
8
20
12
25
ppm of FSR/°C
ppm of FSR/°C
ppm of FSR/°C
ppm of FSR/°C
V
40
9.90
0.1
LSB
LSB
LSB
LSB
% FSR3
LSB
% of FSR
± 2.5, ± 5, ± 10,
+5, +10
40
REFERENCE OUTPUT
External Current
12
10
ANALOG OUTPUT
Ranges 4
Output Current
Output Impedance (DC)
Short Circuit Current
±2
±5
± 30
±3
± 10
3
2
1
Units
± 1/8
61/4
± 1/4
61/2
± 1/4
61/2
Monotonicity Guaranteed
± 0.1
60.2
±1
62
± 0.05
60.1
+1/4
61/2
± 1/2
63/4
± 1/2
63/4
Monotonicity Guaranteed
± 0.1
60.2
±1
62
± 0.05
60.1
DRIFT
Differential Linearity
Gain (Full Scale) T A = 25°C to TMIN or TMAX
Unipolar Offset T A = –25°C to TMIN or TMAX
Bipolar Zero T A = 25°C to TMIN or TMAX
Max
0
–65
NOTES
1
The digital input specifications are 100% tested at +25°C, and guaranteed but not tested over the full temperature range.
Adjustable to zero.
3
FSR means “Full-Scale Range” and is 20 V for ± 10 V range and 10 V for the ± 5 V range.
4
A minimum power supply of ± 12.5 V is required for a ± 10 V full-scale output and ± 11.4 V is required for all other voltage ranges.
2
Specifications subject to change without notice.
Specifications shown in boldface are tested on all production units at final electrical
test. Results from those tests are used to calculate outgoing quality levels. All min and
max specifications are guaranteed, although only those shown in boldface are tested
on all production units.
TIMING SPECIFICATIONS
(All Models, T A = +25°C, VCC = +12 V or +15 V, V EE = –12 V or –15 V)
Symbol
Parameter
Min
Typ
Max
tDC
tAC
tCP
tDH
tSETT
Data Valid to End of CS
Address Valid to End of CS
CS Pulse Width
Data Hold Time
Output Voltage Settling Time
50
100
100
0
–
–
_
–
–
2
–
_
–
–
4
ns
ns
ns
ns
µs
ABSOLUTE MAXIMUM RATINGS
VCC to Power Ground . . . . . . . . . . . . . . . . . . . . . 0 V to +18 V
VEE to Power Ground . . . . . . . . . . . . . . . . . . . . . 0 V to –18 V
Digital Inputs (Pins 11–15, 17–28)
to Power Ground . . . . . . . . . . . . . . . . . . . . –1.0 V to +7.0 V
Ref In to Reference Ground . . . . . . . . . . . . . . . . . . . . . . ± 12 V
Bipolar Offset to Reference Ground . . . . . . . . . . . . . . . . ± 12 V
10 V Span R to Reference Ground . . . . . . . . . . . . . . . . . ± 12 V
20 V Span R to Reference Ground . . . . . . . . . . . . . . . . . ± 24 V
Ref Out, VOUT (Pins 6, 9) . . Indefinite Short to Power Ground
. . . . . . . . . . . . . . . . . . . . . . . . . . . Momentary Short to VCC
Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . 1000 mW
–2–
REV. A
AD667
Model
Min
DIGITAL INPUTS
Resolution
Logic Levels (TTL, Compatible, TMIN–TMAX)1
VIH (Logic “l’’)
VIL (Logic “0”)
IIH (VIH = 5.5 V)
IIL (VIL = 0.8 V)
TRANSFER CHARACTERISTICS
ACCURACY
Linearity Error @ +25°C
TA = TMIN to TMAX
Differential Linearity Error @ +25°C
TA = TMIN to TMAX
Gain Error2
Unipolar Offset Error 2
Bipolar Zero2
+2.0
0
3
1
REFERENCE OUTPUT
External Current
±2
±5
±1
±5
3
2
1
TEMPERATURE RANGE
Specification
Storage
Min
±5
+2.0
0
3
1
±2
±5
4
3
3
2
1
± 2.5, ± 5, ± 10,
+5, +10
10.10
5
5
10
10
8
20
–25
–65
616.5
3
1
±2
± 15
4
3
3
2
1
Units
12
Bits
+5.5
+0.7
10
5
V
V
µA
µA
630
63
610
4
3
±5
611.4
10.00
1.0
10.10
5
5
10
10
± 12, ± 15
8
20
616.5
611.4
+85
+150
–55
–65
µs
µs
µs
V/µs
0.05
mA
Ω
mA
10.00
10.10
V
mA
5
5
10
10
ppm of FS/%
ppm of FS/%
616.5
V
V
12
25
mA
mA
+125
+150
°C
°C
± 12, ± 15
8
20
12
25
ppm of FSR/°C
ppm of FSR/°C
ppm of FSR/°C
ppm of FSR/°C
V
40
9.90
1.0
LSB
LSB
LSB
LSB
% FSR3
LSB
% of FSR
± 2.5, ± 5, ± 10,
+5, +10
40
9.90
0.1
–25
–65
Max
± 1/8
61/2
± 1/8
63/4
± 1/4
63/4
Monotonicity Guaranteed
± 0.1
60.2
±1
62
± 0.05
60.1
± 15
±3
± 10
± 2.5, ± 5, ± 10,
+5, +10
±5
12
25
+85
+150
AD667S
Typ
+2.0
0
0.05
10.00
1.0
± 12, ± 15
Min
10
40
611.4
+5.5
+0.8
10
5
10
0.05
9.90
0.1
Max
± 1/8
61/4
± 1/4
61/2
± 1/4
61/2
Monotonicity Guaranteed
± 0.1
60.2
±1
62
± 0.05
60.1
TIMING DIAGRAMS
WRITE CYCLE #1
WRITE CYCLE #2
(Load Second Rank from First Rank; A2, A1, A0 = 1)
(Load First Rank from Data Bus; A3 = 1)
REV. A
AD667B
Typ
12
± 30
±3
± 10
10
POWER SUPPLY SENSITIVITY
VCC = +11.4 V to +16.5 V dc
VEE = –11.4 V to –16.5 V dc
POWER SUPPLY REQUIREMENTS
Rated Voltages
Range4
Supply Current
+11.4 V to +16.5 V dc
–11.4 V to –16.5 V dc
+5.5
+0.8
10
5
+1/4
61/2
± 1/2
63/4
± 1/2
63/4
Monotonicity Guaranteed
± 0.1
60.2
±1
62
± 0.05
60.1
ANALOG OUTPUT
Ranges 4
Output Current
Output Impedance (DC)
Short Circuit Current
Max
12
DRIFT
Differential Linearity
Gain (Full Scale) TA = 25°C to TMIN or TMAX
Unipolar Offset TA = 25°C to TMIN or TMAX
Bipolar Zero T A = 25°C to TMIN or T MAX
CONVERSION SPEED
Settling Time to ± 0.01% of FSR for
FSR Change (2 kΩi500 pF Load)
with 10 kΩ Feedback
with 5 kΩ Feedback
For LSB Change
Slew Rate
AD667A
Typ
–3–
AD667
PIN CONNECTIONS
PLCC, LCC
DIP
from the ideal analog output (a straight line drawn from 0 to FS
– 1 LSB) for any bit combination. The AD667 is laser trimmed
to 1/4 LSB (0.006% of FS) maximum error at +25°C for the K
and B versions and 1/2 LSB for the J, A and S versions.
ORDERING GUIDE
Modell
Temperature
Range—8C
Linearity
Gain
Error Max TC Max
@ +258C
ppm/8C Package Option2
AD667JN
AD667JP
AD667KN
AD667KP
AD667AD
AD667BD
AD667SD
AD667SE
AD667/883B
0 to +70
0 to +70
0 to +70
0 to +70
25 to +85
–25 to +85
–55 to +125
–55 to +125
–55 to +125
± 1/2 LSB
± 1/2 LSB
± 1/4 LSB
± 1/4 LSB
± 1/2 LSB
± 1/4 LSB
± 1/2 LSB
± 1/2 LSB
*
30
30
15
15
30
15
30
30
*
MONOTONICITY: A DAC is said to be monotonic if the
output either increases or remains constant for increasing digital
inputs such that the output will always be a nondecreasing function of input. All versions of the AD667 are monotonic over
their full operating temperature range.
Plastic DIP (N-28)
PLCC (P-28A)
Plastic DIP (N-28)
PLCC (P-28A)
Ceramic DIP (D-28)
Ceramic DIP (D-28)
Ceramic DIP (D-28)
LCC (E-28A)
*
DIFFERENTIAL NONLINEARITY: Monotonic behavior requires that the differential linearity error be less than 1 LSB
both at +25°C and over the temperature range of interest. Differential nonlinearity is the measure of the variation in analog
value, normalized to full scale, associated with a 1 LSB change
in digital input code. For example, for a 10 volt full-scale output, a change of 1 LSB in digital input code should result in a
2.44 mV change in the analog output (1 LSB = 10 V × 1/4096 =
2.44 mV). If in actual use, however, a 1 LSB change in the
input code results in a change of only 0.61 mV (1/4 LSB) in
analog output, the differential linearity error would be –1.83 mV,
or –3/4 LSB. The AD667K and B grades have a max differential
linearity error of 1/2 LSB, which specifies that every step will be
at least 1/2 LSB and at most 1 1/2 LSB.
NOTES
*Refer to AD667/883B military data sheet.
1
For details on grade and package offerings screened in accordance with MIL-STD883, refer to the Analog Devices Military Products Databook or current AD667/
883B data sheet.
2
D = Ceramic DIP; E = Leadless Ceramic Chip Carrier; N = Plastic DIP;
P = Plastic Leaded Chip.
THE AD667 OFFERS TRUE 12-BIT PERFORMANCE
OVER THE FULL TEMPERATURE RANGE
LINEARITY ERROR: Analog Devices defines linearity error as
the maximum deviation of the actual, adjusted DAC output
Table I. Output Voltage Range Connections
Output
Range
Digital
Input Codes
Connect
Pin 9 to
Connect
Pin 1 to
Connect
Pin 2 to
Connect
Pin 4 to
± 10 V
±5 V
± 2.5 V
0 V to +10 V
0 V to +5 V
Offset Binary
Offset Binary
Offset Binary
Straight Binary
Straight Binary
1
1 and 2
2
1 and 2
2
9
2 and 9
3
2 and 9
3
NC
1 and 9
9
1 and 9
9
6 (Through 50 Ω Fixed or 100 Ω Trim Resistor)
6 (Through 50 Ω Fixed or 100 Ω Trim Resistor)
6 (Through 50 Ω Fixed or 100 Ω Trim Resistor)
5 (or Optional Trim—See Figure 2)
5 (or Optional Trim—See Figure 2)
–4–
REV. A
AD667
ANALOG CIRCUIT CONNECTIONS
Internal scaling resistors provided in the AD667 may be connected
to produce bipolar output voltage ranges of ±10, ±5 or ±2.5 V or
unipolar output voltage ranges of 0 V to +5 V or 0 V to +10 V.
Gain and offset drift are minimized in the AD667 because of the
thermal tracking of the scaling resistors with other device components. Connections for various output voltage ranges are
shown in Table I.
Figure 3. ± 5 V Bipolar Voltage Output
INTERNAL/EXTERNAL REFERENCE USE
The AD667 has an internal low noise buried Zener diode reference which is trimmed for absolute accuracy and temperature
coefficient. This reference is buffered and optimized for use in a
high speed DAC and will give long-term stability equal or superior
to the best discrete Zener reference diodes. The performance of
the AD667 is specified with the internal reference driving the
DAC since all trimming and testing (especially for full-scale
error and bipolar offset) is done in this configuration.
Figure 1. Output Amplifier Voltage Range Scaling Circuit
UNIPOLAR CONFIGURATION (Figure 2)
This configuration will provide a unipolar 0 volt to +10 volt output range. In this mode, the bipolar offset terminal, Pin 4, should
be grounded if not used for trimming.
The internal reference has sufficient buffering to drive external
circuitry in addition to the reference currents required for the
DAC (typically 0. 5 mA to Ref In and 1.0 mA to Bipolar Offset). A minimum of 0.1 mA is available for driving external
loads. The AD667 reference output should be buffered with an
external op amp if it is required to supply more than 0.1 mA
output current. The reference is typically trimmed to ± 0.2%,
then tested and guaranteed to ± 1.0% max error. The temperature coefficient is comparable to that of the full-scale TC for a
particular grade.
If an external reference is used (10.000 V, for example), additional trim range must be provided, since the internal reference
has a tolerance of ± 1%, and the AD667 full-scale and bipolar
offset are both trimmed with the internal reference. The gain
and offset trim resistors give about ± 0.25% adjustment range,
which is sufficient for the AD667 when used with the internal
reference.
Figure 2. 0 V to +10 V Unipolar Voltage Output
STEP I . . . ZERO ADJUST
Turn all bits OFF and adjust zero trimmer R1, until the output
reads 0.000 volts (1 LSB = 2.44 mV). In most cases this trim is
not needed, and Pin 4 should be connected to Pin 5.
It is also possible to use external references other than 10 volts.
The recommended range of reference voltage is from +8 to
+11 volts, which allows both 8.192 V and 10.24 V ranges to be
used. The AD667 is optimized for fixed-reference applications.
If the reference voltage is expected to vary over a wide range in a
particular application, a CMOS multiplying DAC is a better
choice.
STEP II . . . GAIN ADJUST
Turn all bits ON and adjust 100 Ω gain trimmer R2, until the
output is 9.9976 volts. (Full scale is adjusted to 1 LSB less than
nominal full scale of 10.000 volts.)
Reduced values of reference voltage will also permit the ± 12
volt ± 5% power supply requirement to be relaxed to ± 12 volts
± 10%.
BIPOLAR CONFIGURATION (Figure 3)
This configuration will provide a bipolar output voltage from
–5.000 to +4.9976 volts, with positive full scale occurring with
all bits ON (all 1s).
It is not recommended that the AD667 be used with external
feedback resistors to modify the scale factor. The internal resistors are trimmed to ratio-match and temperature-track the other
resistors on the chip, even though their absolute tolerances are
± 20%, and absolute temperature coefficients are approximately
–50 ppm/°C. If external resistors are used, a wide trim range
(± 20%) will be needed and temperature drift will be increased
to reflect the mismatch between the temperature coefficients of
the internal and external resistors.
STEP I . . . OFFSET ADJUST
Turn OFF all bits. Adjust 100 Ω trimmer R1 to give –5.000
volts output.
STEP II . . . GAIN ADJUST
Turn ON all bits. Adjust 100 Ω gain trimmer R2 to give a reading of +4.9976 volts.
REV. A
–5–
AD667
Small resistors may be added to the feedback resistors in order
to accomplish small modifications in the scaling. For example, if
a 10.24 V full scale is desired, a 140 Ω 1% low TC metal-film
resistor can be added in series with the internal (nominal) 5k
feedback resistor, and the gain trim potentiometer (between
Pins 6 and 7) should be increased to 200 Ω. In the bipolar
mode, increase the value of the bipolar offset trim potentiometer
also to 200 Ω.
b. Fine-Scale Settling, CF = 0 pF
GROUNDING RULES
The AD667 brings out separate analog and power grounds to
allow optimum connections for low noise and high speed performance. These grounds should be tied together at one point,
usually the device power ground. The separate ground returns
are provided to minimize current flow in low level signal paths.
The analog ground at Pin 5 is the ground point for the output
amplifier and is thus the “high quality” ground for the AD667;
it should be connected directly to the analog reference point of
the system. The power ground at Pin 16 can be connected to
the most convenient ground point; analog power return is
preferred. If power ground contains high frequency noise beyond 200 mV, this noise may feed through the converter, thus
some caution will be required in applying these grounds.
c. Fine-Scale Settling, CF = 20 pF
It is also important to apply decoupling capacitors properly on
the power supplies for the AD667 and the output amplifier. The
correct method for decoupling is to connect a capacitor from
each power supply pin of the AD667 to the analog ground pin
of the AD667. Any load driven by the output amplifier should
also be referred to the analog ground pin.
d. Fine-Scale Settling, CF = 0 pF
OPTIMIZING SETTLING TIME
The dynamic performance of the AD667’s output amplifier can
be optimized by adding a small (20 pF) capacitor across the
feedback resistor. Figure 4 shows the improvement in both
large-signal and small-signal settling for the 10 V range. In Figure 4a, the top trace shows the data inputs (DB11–DB0 tied together), the second trace shows the CS pulse (A3–A0 tied low),
and the lower two traces show the analog outputs for CF = 0 pF
and 20 pF respectively.
Figures 4b and 4c show the settling time for the transition from
all bits on to all bits off. Note that the settling time to ± 1/2 LSB
for the 10 V step is improved from 2.4 microseconds to 1.6 microseconds by the addition of the 20 pF capacitor.
e. Fine-Scale Settling, CF = 20 pF
Figure 4. Settling Time Performance
DIGITAL CIRCUIT DETAILS
Figures 4d and 4e show the settling time for the transition from
all bits off to all bits on. The improvement in settling time
gained by adding CC = 20 pF is similar.
The bus interface logic of the AD667 consists of four independently addressable registers in two ranks. The first rank consists
of three four-bit registers which can be loaded directly from a
4-, 8-, 12-, or 16-bit microprocessor bus. Once the complete
12-bit data word has been assembled in the first rank, it can be
loaded into the 12-bit register of the second rank. This
double-buffered organization avoids the generation of spurious
analog output values. Figure 5 shows the block diagram of the
AD667 logic section.
The latches are controlled by the address inputs, A0–A3, and
the CS input. All control inputs are active low, consistent with
general practice in microprocessor systems. The four address
lines each enable one of the four latches, as indicated in Table II.
a. Large Scale Settling
All latches in the AD667 are level-triggered. This means that
data present during the time when the control signals are valid
will enter the latch. When any one of the control signals returns
high, the data is latched.
–6–
REV. A
AD667
The AD667 data and control inputs will float to a Logic 0 if left
open. It is recommended that any unused inputs be connected
to power ground to improve noise immunity.
Fanout for the AD667 is 100 when used with a standard low
power Schottky gate output device.
8-BIT MICROPROCESSOR INTERFACE
The AD667 interfaces easily to 8-bit microprocessor systems of
all types. The control logic makes possible the use of right- or
left-justified data formats.
Whenever a 12-bit DAC is loaded from an 8-bit bus, two bytes
are required. If the program considers the data to be a 12-bit
binary fraction (between 0 and 4095/4096), the data is leftjustified, with the eight most significant bits in one byte and the
remaining bits in the upper half of another byte. Right-justified
data calls for the eight least significant bits to occupy one byte,
with the 4 most significant bits residing in the lower half of another byte, simplifying integer arithmetic.
Figure 5. AD667 Block Diagram
It is permissible to enable more than one of the latches simultaneously. If a first rank latch is enabled coincident with the second rank latch, the data will reach the second rank correctly if
the “WRITE CYCLE #1” timing specifications are met.
Table II. AD667 Truth Table
CS A3 A2 A1 A0 Operation
1
X
0
0
0
0
0
X
1
1
1
1
0
0
X
1
1
1
0
1
0
X
1
1
0
1
1
0
X
1
0
1
1
1
0
No Operation
No Operation
Enable 4 LSBs of First Rank
Enable 4 Middle Bits of First Rank
Enable 4 MSBs of First Rank
Loads Second Rank from First Rank
All Latches Transparent
“X” = Don’t Care.
Figure 7. 12-Bit Data Formats for 8-Bit Systems
INPUT CODING
Figure 8 shows an addressing scheme for use with an AD667 set
up for left-justified data in an 8-bit system. The base address is
decoded from the high-order address bits and the resultant
active-low signal is applied to CS. The two LSBs of the address
bus are connected as shown to the AD667 address inputs. The
latches now reside in two consecutive locations, with location
X01 loading the four LSBs and location X10 loading the eight
MSBs and updating the output.
The AD667 uses positive-true binary input coding. Logic “1” is
represented by an input voltage greater than 2.0 V and Logic
“0” is defined as an input voltage less than 0.8 V.
Unipolar coding is straight binary, where all zeroes (000H) on
the data inputs yields a zero analog output and all ones (FFFH)
yields an analog output 1 LSB below full scale.
Bipolar coding is offset binary, where an input code of 000H
yields a minus full-scale output, an input of FFFH yields an output 1 LSB below positive full scale, and zero occurs for an input
code with only the MSB on (800H).
The AD667 can be used with twos complement input coding if
an inverter is used on the MSB (DB11).
DIGITAL INPUT CONSIDERATIONS
The threshold of the digital input circuitry is set at 1.4 volts and
does not vary with supply voltage. The input lines can thus interface with any type of 5 volt logic. The configuration of the input circuit is shown in Figure 6.
Figure 8. Left-Justified 8-Bit Bus Interface
Figure 6. Equivalent Digital Input Circuit
REV. A
–7–
AD667
Right-justified data can be similarly accommodated. The overlapping of data lines is reversed, and the address connections
are slightly different. The AD667 still occupies two adjacent
locations in the processor’s memory map. In the circuit of Figure 9, location X01 loads the 8 LSBs and location X10 loads
the 4 MSBs and updates the output.
This configuration uses the first and second rank registers
simultaneously. The CS input can be driven from an active-low
decoded address. It should be noted that any data bus activity
during the period when CS is low will cause activity at the
AD667 output. If data is not guaranteed stable during this
period, the second rank register can be used to provide double
buffering.
C842b–22–8/87
low, and the latch is enabled by CS going low. The AD667 thus
occupies a single memory location.
Figure 9. Right-Justified 8-Bit Bus Interface
USING THE AD667 WITH 12- AND 16-BIT BUSES
Figure 10. Connections for 12- and 16-Bit Bus Interface
The AD667 is easily interfaced to 12- and 16-bit data buses. In
this operation, all four address lines (A0 through A3) are tied
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
28-Pin Plastic DIP (N)
PRINTED IN U.S.A.
28-Terminal Plastic Leaded
Chip Carrier (P)
28-Contact LCC (E)
28-Pin Ceramic DIP (D)
–8–
REV. A