AD660ARZ-REEL - Analog Devices

Monolithic 16-Bit

Serial/Byte DACPORT

AD660

Rev. B

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FEATURES

Complete 16-bit digital-to-analog function

On-chip output amplifier

On-chip buried Zener voltage reference

±1 LSB integral linearity

15-bit monotonic over temperature

Microprocessor compatible

Serial or byte input

Double-buffered latches

Fast (40 ns) write pulse

Asynchronous clear (to 0 V) function

Serial output pin facilitates daisy-chaining

Unipolar or bipolar output

Low glitch: 15 nV-s

Low THD + N: 0.009%

FUNCTIONAL BLOCK DIAGRAM

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN 10kΩ

10kΩ

10.05kΩ

REF OUT

DB7/

DB15

AD660

OUT

AGND

SPAN/

BIPOLAR

OFFSET

DGND

–V

10V REF

16-BIT LATCH

16-BIT DAC

16-BIT LATCH

1 2 3 4

121415

01813-001

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

Figure 1.

GENERAL DESCRIPTION

The AD660 DACPORT® is a complete 16-bit monolithic digital-

to-analog converter with an on-board voltage reference, double-

buffered latches, and an output amplifier. It is manufactured on

the Analog Devices, Inc., BiMOS II process. This process allows

the fabrication of low power CMOS logic functions on the same

chip as high precision bipolar linear circuitry.

The AD660 architecture ensures 15-bit monotonicity over time

and temperature. Integral and differential nonlinearity is main-

tained at ±0.003% maximum. The on-chip output amplifier

provides a voltage output settling time of 10 μs to within ½ LSB for

a full-scale step.

The AD660 has an extremely flexible digital interface. Data can

be loaded into the AD660 in serial mode or as two 8-bit bytes.

This is made possible by two digital input pins that have dual

functions. The serial mode input format is pin selectable to be

MSB or LSB first. The serial output pin allows the user to daisy-

chain several AD660 devices by shifting the data through the

input latch into the next DAC, thus minimizing the number of

control lines required to SIN, CS and LDAC. The byte mode input

format is also flexible in that the high byte or low byte data can

be loaded first. The double buffered latch structure eliminates

data skew errors and provides for simultaneous updating of DACs

in a multiDAC system.

The AD660 is available in five grades. AN and BN versions are

specified from −40°C to +85°C and are packaged in a 24-lead

300 mil plastic DIP. AR and BR versions are also specified from

−40°C to +85°C and are packaged in a 24-lead SOIC. The SQ

version is packaged in a 24-lead 300 mil CERDIP package and

is also available compliant to MIL-STD-883. Refer to the

AD660SQ/883B military data sheet for specifications and test

conditions.

PRODUCT HIGHLIGHTS

1. The AD660 is a complete 16-bit DAC, with a voltage

reference, double-buffered latches, and an output amplifier

on a single chip.

2. The internal buried Zener reference is laser trimmed to

10.000 V with a ±0.1% maximum error and a temperature

drift performance of ±15 ppm/°C. The reference is available

for external applications.

3. The output range of the AD660 is pin programmable and

can be set to provide a unipolar output range of 0 V to 10 V

or a bipolar output range of −10 V to +10 V. No external

components are required.

4. The AD660 is both dc and ac specified. DC specifications

include ±1 LSB INL and ±1 LSB DNL errors. AC specifica-

tions include 0.009% THD + N and 83 dB SNR.

5. The double-buffered latches on the AD660 eliminate data

skew errors and allow simultaneous updating of DACs in

multiDAC applications.

6. The clear function can asynchronously set the output

to 0 V regardless of whether the DAC is in unipolar or

bipolar mode.

7. The output amplifier settles within 10 μs to ±½ LSB for a

full-scale step and within 2.5 μs for a 1 LSB step over tempera-

ture. The output glitch is typically 15 nV-s when a full-scale

step is loaded.

AD660

Rev. B | Page 2 of 20

TABLE OF CONTENTS

Features .............................................................................................. 1

Functional Block Diagram .............................................................. 1

General Description ......................................................................... 1

Product Highlights ........................................................................... 1

Revision History ............................................................................... 2

Specifications ..................................................................................... 3

AC Performance Characteristics ................................................ 4

Timing Characteristics ................................................................ 5

Absolute Maximum Ratings ............................................................ 7

ESD Caution .................................................................................. 7

Pin Configuration and Function Descriptions ............................. 8

Terminology ...................................................................................... 9

Theory of Operation ...................................................................... 10

Analog Circuit Connections ..................................................... 10

Unipolar Configuration ............................................................. 10

Bipolar Configuration ................................................................ 11

Internal/External Reference Use .............................................. 11

Output Settling and Glitch ........................................................ 13

Digital Circuit Details ................................................................ 14

Microprocessor Interface ............................................................... 15

AD660 to MC68HC11 (SPI Bus) Interface ............................. 15

AD660 to MICROWIRE Interface ........................................... 15

AD660 to ADSP-210x Family Interface .................................. 15

AD660 to Z80 Interface ............................................................. 16

Noise ............................................................................................ 16

Board Layout ................................................................................... 17

Supply Decoupling ..................................................................... 17

Grounding ................................................................................... 17

Outline Dimensions ....................................................................... 18

Ordering Guide .......................................................................... 19

REVISION HISTORY

6/08—Rev. A to Rev. B

Updated Format .................................................................. Universal

Updated Pin Name MSB/LSB to DATADIR Throughout ........... 1

Updated Pin Name UNI/BIP CLEAR to CLEAR SELECT

Throughout ....................................................................................... 1

Changes to Table 1 ............................................................................ 3

Changes to Endnote 3 in Table 1 .................................................... 4

Changes to Figure 2 .......................................................................... 5

Changes to Figure 3 and Figure 5 ................................................... 6

Changes to Table 4 ............................................................................. 7

Added Pin Configuration and Function Descriptions Section ... 8

Changes to Internal/External Reference Use Section ................ 11

Changes to Figure 12 ...................................................................... 12

Changes to Figure 13, Figure 14, Figure 15, and Figure 16....... 13

Changes to Figure 17 and Figure 18............................................. 15

Changes to Figure 19 ...................................................................... 16

Updated Outline Dimensions ....................................................... 18

Changes to Ordering Guide .......................................................... 19

AD660

Rev. B | Page 3 of 20

SPECIFICATIONS

TA = 25°C, +VCC = 15 V, −VEE = −15 V, +VLL = 5 V unless otherwise noted.

Table 1.

Parameter

AD660AN/AR/SQ AD660BN/BR

Unit Min Typ Max Min Typ Max

RESOLUTION 16 16 Bits

DIGITAL INPUTS (TMIN to TMAX)

VIH (Logic 1) 2.0 5.5 2.0 5.5 V

VIL (Logic 0) 0 0.8 0 0.8 V

IIH (VIH = 5.5 V) −10 +10 −10 +10 μA

IIL (VIL = 0 V) −10 +10 −10 +10 μA

TRANSFER FUNCTION CHARACTERISTICS1

Integral Nonlinearity

Bipolar Operation −2 +2 −1 +1 LSB

TMIN to TMAX −4 +4 −2 +2 LSB

Unipolar Operation −2 +2 −1 +1.5 LSB

TMIN to TMAX −4 +4 −2 +2 LSB

Differential Nonlinearity −2 +2 −1 +1 LSB

TMIN to TMAX −4 +4 −2 +2 LSB

Monotonicity Over Temperature 14 15 Bits

Gain Error2, 3 −0.1 +0.1 −0.1 +0.1 % of FSR

Gain Drift (TMIN to TMAX) 25 15 ppm/°C

DAC Gain Error4 −0.05 +0.05 −0.05 +0.05 % of FSR

DAC Gain Drift4 10 10 ppm/°C

Unipolar Offset −2.5 +2.5 −2.5 +2.5 mV

Unipolar Offset Drift (TMIN to TMAX) 3 3 ppm/°C

Bipolar Zero Error −7.5 +7.5 −7.5 +7.5 mV

Bipolar Zero Error Drift (TMIN to TMAX) 5 5 ppm/°C

REFERENCE INPUT

Input Resistance 7 10 13 7 10 13 kΩ

Bipolar Offset Input Resistance 7 10 13 7 10 13 kΩ

REFERENCE OUTPUT

Voltage 9.99 10.00 10.01 9.99 10.00 10.01 V

Drift 25 15 ppm/°C

External Current5 2 4 2 4 mA

Capacitive Load 1000 1000 pF

Short-Circuit Current 25 25 mA

OUTPUT CHARACTERISTICS

Output Voltage Range

Unipolar Configuration 0 +10 0 +10 V

Bipolar Configuration −10 +10 −10 +10 V

Output Current 5 5 mA

Capacitive Load 1000 1000 pF

Short-Circuit Current 25 25 mA

AD660

Rev. B | Page 4 of 20

Parameter

AD660AN/AR/SQ AD660BN/BR

Unit Min Typ Max Min Typ Max

POWER SUPPLIES

Voltage

+VCC6 +13.5 +16.5 +13.5 +16.5 V

−VEE6 −13.5 −16.5 −13.5 −16.5 V

+VLL +4.5 +5.5 +4.5 +5.5 V

Current (No Load)

ICC +12 +18 +12 +18 mA

IEE −12 −18 −12 −18 mA

ILL

@ VIH = 5 V, VIL = 0 V 0.3 2 0.3 2 mA

@ VIH = 2.4 V, VIL = 0.4 V 3 7.5 3 7.5 mA

Power Supply Sensitivity 1 2 1 2 ppm/%

Power Dissipation (Static, No Load) 365 625 365 625 mW

TEMPERATURE RANGE

Specified Performance (A, B) −40 +85 −40 +85 °C

Specified Performance (S) −55 +125 °C

1 For 16-bit resolution, 1 LSB = 0.0015% of FSR. For 15-bit resolution, 1 LSB = 0.003% of FSR. For 14-bit resolution, 1 LSB = 0.006% of FSR. FSR stands for full-scale range

and is 10 V in a unipolar mode and 20 V in bipolar mode.

2 Gain error and gain drift are measured using the internal reference. The internal reference is the main contributor to gain drift. If lower gain drift is required, the AD660

can be used with a precision external reference such as the AD587, AD586, or AD688.

3 Gain error is measured with fixed 50 Ω resistors as shown in the Theory of Operation section. Eliminating these resistors increases the gain error by 0.25% of FSR

(unipolar mode) or 0.50% of FSR (bipolar mode).

4 DAC gain error and drift are measured with an external voltage reference. They represent the error contributed by the DAC alone, for use with an external reference.

5 External current is defined as the current available in addition to that supplied to REF IN and SPAN/BIPOLAR OFFSET on the AD660.

6 Operation on ±12 V supplies is possible using an external reference such as the AD586 and reducing the output range. Refer to the Internal/External Reference Use

section.

AC PERFORMANCE CHARACTERISTICS

With the exception of total harmonic distortion + noise (THD + N) and signal-to-noise (SNR) ratio, these characteristics are included for

design guidance only and are not subject to test. THD + N and SNR are 100% tested.

TMIN ≤ TA ≤ TMAX, +VCC = 15 V, −VEE = −15 V, +VLL = 5 V except where noted.

Table 2.

Parameter Limit Unit Test Conditions/Comments

OUTPUT SETTLING TIME 13 μs max 20 V step, TA = 25°C

(Time to ±0.0008% FS 8 μs typ 20 V step, TA = 25°C

with 2 kΩ, 1000 pF Load) 10 μs typ 20 V step, TMIN ≤ TA ≤ TMAX

6 μs typ 10 V step, TA = 25°C

8 μs typ 10 V step, TMIN ≤ TA ≤ TMAX

2.5 μs typ 1 LSB step, TMIN ≤ TA ≤ TMAX

TOTAL HARMONIC DISTORTION + NOISE

A, B, S Grade 0.009 % max 0 dB, 990.5 Hz, sample rate = 96 kHz, TA = 25°C

A, B, S Grade 0.056 % max −20 dB, 990.5 Hz, sample rate = 96 kHz, TA = 25°C

A, B, S Grade 5.6 % max −60 dB, 990.5 Hz, sample rate = 96 kHz, TA = 25°C

SIGNAL-TO-NOISE RATIO 83 dB min TA = 25°C

DIGITAL-TO-ANALOG GLITCH IMPULSE 15 nV-s typ DAC alternately loaded with 0x8000 and 0x7FFF

DIGITAL FEEDTHROUGH 2 nV-s typ DAC alternately loaded with 0x0000 and 0xFFFF, CS high

OUTPUT NOISE VOLTAGE

Density (1 kHz to 1 MHz) 120 nV/√Hz typ Measured at VOUT, 20 V span, excludes reference

REFERENCE NOISE 125 nV/√Hz typ Measured at REF OUT

AD660

Rev. B | Page 5 of 20

TIMING CHARACTERISTICS

+VCC = 15 V, −VEE = −15 V, +VLL = 5 V, VHIGH = 2.4 V, VLOW = 0.4 V.

Table 3.

Parameter Limit at TA = 25°C Limit at TA = −55°C to +125°C Unit

BYTE LOAD (see Figure 2)

tCS 40 50 ns min

tDS 40 50 ns min

tDH 0 10 ns min

tBES 40 50 ns min

tBEH 0 10 ns min

tLH 80 100 ns min

tLW 40 50 ns min

SERIAL LOAD (see Figure 3)

tCLK 80 100 ns min

tLOW 30 50 ns min

tHIGH 30 50 ns min

tSS 0 10 ns min

tDS 40 50 ns min

tDH 0 10 ns min

tSH 0 10 ns min

tLH 80 100 ns min

tLW 40 50 ns min

ASYNCHRONOUS CLEAR TO BIPOLAR

OR UNIPOLAR ZERO (see Figure 4)

tCLR 80 110 ns min

tSET 80 110 ns min

tHOLD 0 10 ns min

SERIAL OUT (see Figure 5)

tPROP 50 100 ns min

tDS 50 80 ns min

BEH

BES

DB0 TO DB7

HBE OR LBE

LDAC

01813-002

Figure 2. AD660 Byte Load Timing

AD660

Rev. B | Page 6 of 20

CLK

LOW

HIGH

DB0 VALID 1

1 = MSB FIRST, 0 = LSB FIRST

VALID 16

SER

LDAC

DB1

(DATADIR)

01813-003

Figure 3. AD660 Serial Load Timing

LBE

01813-004

CLR

HOLD

SET

1 = BIPOLAR 0, 0 = UNIPOLAR 0

Figure 4. Asynchronous Clear to Bipolar or Unipolar Zero

DB0

OUT

VALID 16 VALID 17

VALID S

OUT

SER

DB1

(

DATADIR)

01813-005

PROP

Figure 5. Serial Out Timing

AD660

Rev. B | Page 7 of 20

ABSOLUTE MAXIMUM RATINGS

Table 4.

Parameter Rating

+VCC to AGND −0.3 V to +17.0 V

−VEE to AGND +0.3 V to −17.0 V

+VLL to DGND −0.3 V to +7 V

AGND to DGND ±1 V

Digital Inputs (Pin 5 through Pin 23)

to DGND

−1.0 V to +7.0 V

REF IN to AGND ±10.5 V

SPAN/BIPOLAR OFFSET to AGND ±10.5 V

REF OUT, VOUT Indefinite short to AGND,

DGND, +VCC, −VEE, and +VLL

Power Dissipation (Any Package)

To +60°C 1000 mW

Derates Above +60°C 8.7 mW/°C

Storage Temperature −65°C to +150°C

Lead Temperature JEDEC industry standard

Soldering J-STD-020

Stresses above those listed under Absolute Maximum Ratings

may cause permanent damage to the device. This is a stress

rating only; functional operation of the device at these or any

other conditions above those indicated in the operational

section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect

device reliability.

ESD CAUTION

AD660

Rev. B | Page 8 of 20

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

–VEE 1

+VCC 2

+VLL 3

DGND 4

REF OUT24

REF IN

SPAN/BIPOLAR OFFSET

VOUT

DB7/DB15 5AGND20

DB6/DB14 6LDAC

DB5/DB13 7CLR18

DB4/DB12 8SER17

DB3/DB11 9HBE16

DB2/DB10 10 LBE/CLEAR SELECT15

DB1/DB9/DATADIR 11 CS

DB0/DB8/SIN 12 SOUT

AD660

TOP VIEW

(Not to Scale)

1813-006

Figure 6. Pin Configuration

Table 5. Pin Function Descriptions

Pin No. Mnemonic Description

1 −VEE Negative Analog Supply Pin

2 +VCC Positive Analog Supply Pin

3 +VLL Digital Supply Pin

4 DGND Digital Ground Reference Pin

5 DB7/DB15 DB7 and DB15 Byte Load Data Input Pin

6 DB6/DB14 DB6 and DB14 Byte Load Data Input Pin

7 DB5/DB13 DB5 and DB13 Byte Load Data Input Pin

8 DB4/DB12 DB4 and DB12 Byte Load Data Input Pin

9 DB3/DB11 DB3 and DB11 Byte Load Data Input Pin

10 DB2/DB10 DB2 and DB10 Byte Load Data Input Pin

11 DB1/DB9/DATADIR DB1 and DB9 Byte Load Data Input Pin/MSB or LSB First Data Direction Serial Input Select Pin

12 DB0/DB8/SIN DB0 and DB8 Byte Load Data Input Pin/Serial Data Input Pin

13 SOUT Serial Data Output Pin

14 CS Chip Select Pin

15 LBE/CLEAR SELECT Low Byte Enable Pin/Unipolar or Bipolar Clear Select Pin

16 HBE High Byte Enable Pin

17 SER Serial Input Enable Pin

18 CLR Output Clear Pin

19 LDAC Load DAC Pin

20 AGND Analog Ground Reference Pin

21 VOUT Voltage Output Pin

22 SPAN/BIPOLAR OFFSET Output Span Configuration Pin

23 REF IN External Reference Voltage Input Pin

24 REF OUT Internal Reference Voltage Output Pin

AD660

Rev. B | Page 9 of 20

TERMINOLOGY

Integral Nonlinearity

Integral nonlinearity is the maximum deviation of the actual,

adjusted DAC output from the ideal analog output (a straight

line drawn from 0 to FS − 1 LSB) for any bit combination. This

is also referred to as relative accuracy.

Differential Nonlinearity

Differential nonlinearity is the measure of the change in the

analog output, normalized to full scale, associated with a 1 LSB

change in the digital input code. Monotonic behavior requires

that the differential linearity error be greater than or equal to

−1 LSB over the temperature range of interest.

Monotonicity

A DAC is monotonic if the output either increases or remains

constant for increasing digital inputs with the result that the

output is always a single-valued function of the input.

Gain Error

Gain error is a measure of the output error between an ideal

DAC and the actual device output with all 1s loaded after offset

error has been adjusted out.

Offset Error

Offset error is a combination of the offset errors of the voltage-

mode DAC and the output amplifier and is measured with all 0s

loaded in the DAC.

Bipolar Zero Error

When the AD660 is connected for bipolar output and 10…000

is loaded in the DAC, the deviation of the analog output from

the ideal midscale value of 0 V is called the bipolar zero error.

Drift

Drift is the change in a parameter (such as gain, offset, and bipolar

zero) over a specified temperature range. The drift temperature

coefficient, specified in ppm/°C, is calculated by measuring the

parameter at TMIN, 25°C, and TMAX, and dividing the change in

the parameter by the corresponding temperature change.

Total Harmonic Distortion + Noise

Total harmonic distortion + noise (THD + N) is defined as the

ratio of the square root of the sum of the squares of the values of

the harmonics and noise to the value of the fundamental input

frequency. It is usually expressed in percent (%).

THD + N is a measure of the magnitude and distribution of

linearity error, differential linearity error, quantization error,

and noise. The distribution of these errors may be different,

depending upon the amplitude of the output signal. Therefore,

to be the most useful, THD + N should be specified for both

large and small signal amplitudes.

Signal-To-Noise Ratio

The signal-to-noise ratio is the ratio of the amplitude of the output

when a full-scale signal is present to the output with no signal

present. The signal-to-noise ratio is measured in decibels (dB).

Digital-To-Analog Glitch Impulse

Digital-to-analog glitch impulse is the amount of charge

injected from the digital inputs to the analog output when the

inputs change state. This is measured at half scale when the DAC

switches around the MSB and as many as possible switches

change state, that is, from 011…111 to 100…000.

Digital Feedthrough

When the DAC is not selected (that is, CS is held high), high

frequency logic activity on the digital inputs is capacitively

coupled through the device to show up as noise on the VOUT pin.

This noise is digital feedthrough.

AD660

Rev. B | Page 10 of 20

THEORY OF OPERATION

The AD660 uses an array of bipolar current sources with MOS

current steering switches to develop a current proportional to the

applied digital word, ranging from 0 mA to 2 mA. A segmented

architecture is used, where the most significant four data bits

are thermometer decoded to drive 15 equal current sources.

The lesser bits are scaled using a R-2R ladder, then applied

together with the segmented sources to the summing node of

the output amplifier. The internal span/bipolar offset resistor

can be connected to the DAC output to provide a 0 V to 10 V

span, or it can be connected to the reference input to provide a

−10 V to +10 V span.

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN 10kΩ

10kΩ

10.05kΩ

REF OUT

DB0/

DB8/

SIN

DB1/DB9/

DATADIR

DB7/

DB15

AD660

SOUT

VOUT

AGND

SPAN/

BIPOLAR

OFFSET

DGND

–VEE +VCC +VLL

10V REF

16-BIT LATCH

16-BIT DAC

16-BIT LATCH

1 2 3 4

11121415

01813-007

LBE/

CLEAR SELECT

Figure 7. Functional Block Diagram

ANALOG CIRCUIT CONNECTIONS

Internal scaling resistors provided in the AD660 can be connected

to produce a unipolar output range of 0 V to 10 V or a bipolar

output range of −10 V to +10 V. Gain and offset drift are mini-

mized in the AD660 because of the thermal tracking of the

scaling resistors with other device components.

UNIPOLAR CONFIGURATION

The configuration shown in Figure 8 provides a unipolar 0 V to

10 V output range. In this mode, 50 Ω resistors are tied between

the SPAN/BIPOLAR OFFSET terminal (Pin 22) and VOUT (Pin 21),

and between REF OUT (Pin 24) and REF IN (Pin 23). It is possible

to use the AD660 without any external components by tying Pin 24

directly to Pin 23 and Pin 22 directly to Pin 21. Eliminating

these resistors increases the gain error by 0.25% of FSR.

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN

REF OUT

AD660

SOUT

VOUT

AGND

OUTPUT

50Ω

SPAN/

BIPOLAR

OFFSET

DGND

–VEE +VCC +VLL

10V REF

16-BIT LATCH

16-BIT DAC

1 2 3 4

01813-008

10kΩ

10.05kΩ

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

DB7/

DB15

51214

16-BIT LATCH

Figure 8. 0 V to 10 V Unipolar Voltage Output

If it is desired to adjust the gain and offset errors to zero, this

can be accomplished using the circuit shown in Figure 9. The

adjustment procedure is as follows:

1. Zero adjust.

Turn all bits off and adjust the zero trimmer, R4, until the

output reads 0.000000 V (1 LSB = 153 μV).

2. Gain adjust.

Turn all bits on and adjust the gain trimmer, R1, until the

output is 9.999847 V. (Full scale is adjusted to 1 LSB less

than the nominal full scale of 10.000000 V.)

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN

REF OUT

AD660

OUT

AGND

OUTPUT

50Ω

16k R4

10k

100Ω

SPAN/

BIPOLAR

OFFSET

DGND

–V

10V REF

16-BIT LATCH

16-BIT DAC

1 2 3 4

01813-009

10kΩ

10.05kΩ

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

DB7/

DB15

51214

16-BIT LATCH

Figure 9. 0 V to 10 V Unipolar Voltage Output with Gain and Offset

Adjustment

AD660

Rev. B | Page 11 of 20

BIPOLAR CONFIGURATION

The circuit shown in Figure 10 provides a bipolar output voltage

from −10.000000 V to +9.999694 V with positive full scale occur-

ring with all bits on. As in the unipolar mode, Resistor R1 and

Resistor R2 can be eliminated altogether to provide AD660 bipolar

operation without any external components. Eliminating these

resistors increases the gain error by 0.50% of FSR in bipolar mode.

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN

50Ω

REF OUT

AD660

OUT

AGND

SPAN/

BIPOLAR

OFFSET

DGND

–V

10V REF

16-BIT LATCH

16-BIT DAC

1 2 3 4

01813-010

OUTPUT

10kΩ

10.05kΩ

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

DB7/

DB15

51214

16-BIT LATCH

Figure 10. ±10 V Bipolar Voltage Output

Gain offset and bipolar zero errors can be adjusted to zero using

the circuit shown in Figure 11 as follows:

1. Offset adjust.

Turn off all bits. Adjust the trimmer, R2, to give 10.000000 V

output.

2. Gain adjust.

Turn all bits on and adjust R1 to give a reading of 9.999694 V.

3. Bipolar zero adjust (optional).

In applications where an accurate zero output is required, set

the MSB on, all other bits off, and readjust R2 for 0 V output.

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN

50Ω

REF OUT

AD660

OUT

AGND

SPAN/

BIPOLAR

OFFSET

DGND

–V

10V REF

16-BIT LATCH

16-BIT DAC

1 2 3 4

01813-011

OUTPUT

100Ω

10kΩ

10.05kΩ

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

DB7/

DB15

51214

16-BIT LATCH

Figure 11. ±10 V Bipolar Voltage Output with Gain and Offset Adjustment

Note that using external resistors introduces a small temperature

drift component beyond that inherent in the AD660. The inter-

nal resistors are trimmed to ratio-match and temperature-track

other resistors on-chip, even though their absolute tolerances are

±20% and absolute temperature coefficients are approximately

−50 ppm/°C. In the case that external resistors are used, the

temperature coefficient mismatch between internal and external

resistors, multiplied by the sensitivity of the circuit to variations

in the external resistor value, is the resultant additional tempera-

ture drift.

INTERNAL/EXTERNAL REFERENCE USE

The AD660 has an internal low noise buried Zener diode

reference that is trimmed for absolute accuracy and temperature

coefficient. This reference is buffered and optimized for use in a

high speed DAC and gives long-term stability equal or superior to

the best discrete Zener diode references. The performance of

the AD660 is specified with the internal reference driving the

DAC and with the DAC alone (for use with a precision external

reference).

The internal reference has sufficient buffering to drive external

circuitry in addition to the reference currents required for the

DAC (typically 1 mA to REF IN and 1 mA to SPAN/BIPOLAR

OFFSET). A minimum of 2 mA is available for driving external

loads. The AD660 reference output should be buffered with an

external op amp if it is required to supply more than 4 mA total

current. The reference is tested and guaranteed to ±0.2%

maximum error.

AD660

Rev. B | Page 12 of 20

It is also possible to use external references other than 10 V with

slightly degraded linearity specifications. The recommended

range of reference voltages is 5 V to 10.24 V, which allows 5 V,

8.192 V, and 10.24 V ranges to be used. For example, by using

the AD586 5 V reference, outputs of 0 V to 5 V unipolar or ±5 V

bipolar can be realized. Using the AD586 voltage reference

makes it possible to operate the AD660 with ±12 V supplies

with 10% tolerances.

Figure 12 shows the AD660 using the AD586 precision 5 V

reference in the bipolar configuration. The highest grade

AD586MN is specified with a drift of 2 ppm/°C, which is a

7.5× improvement over the AD660 internal reference. This

circuit includes two optional potentiometers and one optional

resistor that can be used to adjust the gain, offset, and bipolar

zero errors in a manner similar to that described in the Bipolar

Configuration section. Use −5.000000 V and +4.999847, as the

output values.

The AD660 can also be used with the AD587 10 V reference,

using the same configuration shown in Figure 12 to produce a

±10 V output. The highest grade AD587UQ is specified at

5 ppm/°C, which is a 3× improvement over the AD660 internal

reference.

Figure 13 shows the AD660 using the AD688 precision

±10 V reference, in the unipolar configuration. The highest

grade AD688BQ is specified with a temperature coefficient of

1.5 ppm/°C. The ±10 V output is also ideal for providing precise

biasing for the offset trim resistor, R4.

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN

GND

TRIM

OUT

50Ω

10kΩ

50Ω

REF OUT

AD660

AD586

OUT

AGND

SPAN/

BIPOLAR

OFFSET

DGND

–V

10V REF

16-BIT LATCH

16-BIT DAC

1 2 3 4

01813-012

OUTPUT

10kΩ

10.05kΩ

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

DB7/

DB15

51214

16-BIT LATCH

Figure 12. Using the AD660 with the AD586 5 V Reference

AD660

Rev. B | Page 13 of 20

HBE

CONTROL

LOGIC

SER

CLR

LDAC

REF IN

50Ω

REF OUT

AD660

AD688

OUT

AGND

SPAN/

BIPOLAR

OFFSET

DGND

–V

10V REF

16-BIT LATCH

16-BIT DAC

1 2 3 4

01813-013

OUTPUT

0V TO 10V

100Ω

10kΩR4

10kΩ

–V

13111281095

467 3

10kΩ

10.05kΩ

DB1/DB9/

DATADIR

LBE/

CLEAR SELECT

DB0/

DB8/

SIN

DB7/

DB15

51214

16-BIT LATCH

Figure 13. Using the AD660 with the AD688 High Precision ±10 V Reference

OUTPUT SETTLING AND GLITCH

The AD660 output buffer amplifier typically settles to within

0.0008% FS (1/2 LSB) of its final value in 8 μs for a full-scale

step. Figure 14 and Figure 15 show settling for a full-scale and

an LSB step, respectively, with a 2 kΩ, 1000 pF load applied.

The guaranteed maximum settling time at 25°C for a full-scale

step is 13 μs with this load. The typical settling time for a 1 LSB

step is 2.5 μs.

The digital-to-analog glitch impulse is specified as 15 nV-s

typical. Figure 16 shows the typical glitch impulse characteristic

at the 011…111 to 100…000 code transition when loading the

second rank register from the first rank register.

+10

600

400

200

–200

–400

–600

–10

01020

01813-014

OUTPUT VOLTAGE (V)

OUTPUT VOLTAGE (µV)

TIME (µs)

Figure 14. −10 V to +10 V Full-Scale Step Settling

01 2345

01813-015

OUTPUT VOLTAGE (µV)

TIME (µs)

600

400

200

–200

–400

–600

Figure 15. LSB Step Settling

+10

–10

01813-016

OUTPUT VOLTAGE (mV)

TIME (µs)

01 2345

Figure 16. Output Characteristics

AD660

Rev. B | Page 14 of 20

DIGITAL CIRCUIT DETAILS

The AD660 has several dual-use pins that allow flexible opera-

tion while maintaining the lowest possible pin count and

consequently the smallest package size. The user should,

therefore, pay careful attention to the following information

when applying the AD660.

Data can be loaded into the AD660 in serial or byte mode,

described as follows.

Serial mode operation is enabled by bringing SER (Pin 17) low.

This changes the function of DB0 (Pin 12) to that of the serial

input pin, SIN. It also changes the function of DB1 (Pin 11) to

a control input that tells the AD660 whether the serial data is

going to be loaded MSB or LSB first.

In serial mode, HBE and LBE are effectively disabled except

for the dual function of LBE, which is to control whether the

asynchronous clear function goes to unipolar or bipolar zero.

(A low on LBE, when CLR is strobed, sends the DAC output

to unipolar zero, a high to bipolar zero.) The AD660 does not

recognize the status of HBE when in serial mode.

Data is clocked into the input register on the rising edge of CS,

as shown in Figure 3. The data then resides in the first rank latch

and can be loaded into the DAC latch by taking LDAC high.

This causes the DAC to change to the appropriate output value.

It should be noted that the CLR function clears the DAC latch

but does not clear the first rank latch. Therefore, the data that

was previously residing in the first rank latch can be reloaded

simply by bringing LDAC high after the event that necessitated

CLR to be strobed has ended. Alternatively, new data can be

loaded into the first rank latch if desired.

The serial out pin (SOUT) can be used to daisy-chain several DACs

together in multiDAC applications to minimize the number of

isolators being used to cross an intrinsic safety barrier. The first

rank latch acts like a 16-bit shift register, and repeated strobing

of CS shifts the data out through SOUT and into the next DAC.

Each DAC in the chain requires its own LDAC signal unless all

of the DACs are to be updated simultaneously.

Byte mode operation is enabled simply by keeping SER high,

which configures DB0 to DB7 as data inputs. In this mode, HBE

and LBE are used to identify the data as either the high byte or

the low byte of the 16-bit input word. (The user can load the

data, in any order, into the first rank latch.) As in the serial mode

case, the status of LBE, when CLR is strobed, determines whether

the AD660 clears to unipolar or bipolar zero. Therefore, when in

byte mode, the user must take care to set LBE to the desired

status before strobing CLR. (In serial mode the user can simply

hardware LBE to the desired state.)

Note that CS is edge triggered. HBE, LBE, and LDAC are level

triggered.

AD660

Rev. B | Page 15 of 20

MICROPROCESSOR INTERFACE

AD660 TO MC68HC11 (SPI BUS) INTERFACE

The AD660 interface to the Motorola SPI (serial peripheral

interface) is shown in Figure 17. The MOSI, SCK, and SS pins

of the 68HC11 are respectively connected to the DB0/DB8/SIN,

CS, and LDAC pins of the AD660. The SER pin of the AD660 is

tied low causing the first rank latch to be transparent. The

majority of the interfacing issues are taken care of in the

software initialization. A typical routine such as the one shown

in the Software Initialization Example begins by initializing the

state of the various SPI data and control registers.

The most significant data byte (MSBY) is then retrieved from

memory and processed by the SENDAT subroutine. The SS pin

is driven low by indexing into the PORTD data register and

clearing Bit 5. This causes the 2nd rank latch of the AD660 to

become transparent. The MSBY is then set to the SPI data

The HC11 generates the requisite eight clock pulses with data

valid on the rising edges. After the most significant byte is

transmitted, the least significant byte (LSBY) is loaded from

memory and transmitted in a similar fashion. To complete the

transfer, the LDAC pin is driven high, latching the complete

16-bit word into the AD660.

Software Initialization Example

INIT LDAA #$2F ; SS = I; SCK = 0; MOSI

= I

STAA PORTD ;SEND TO SPI OUTPUTS

LDAA #$38 ; SS, SCK,MOSI = OUTPUTS

STAA DDRD ;SEND DATA DIRECTION

INFO

LDAA #$50 ;DABL INTRPTS,SPI IS

MASTER & ON

STAA SPCR ;CPOL = 0, CPHA = 0,1MHZ

BAUD RATE

NEXTPT LDAA MSBY ;LOAD ACCUM WITH UPPER 8

BITS

BSR SENDAT ;JUMP TO DAC OUTPUT

ROUTINE

JMP NEXTPT ;INFINITE LOOP

SENDAT LDY #$1000 ;POINT AT ON-CHIP

REGISTERS

BCLR $08,Y,$20 ;DRIVE SS (LDAC) LOW

STAA SPDR ;SEND MS-BYTE TO SPI

DATA REG

WAIT1 LDAA SPSR ;CHECK STATUS OF SPIE

BPL WAIT1 ;POLL FOR END OF X-

MISSION

LDAA LSBY ;GET LOW 8 BITS FROM

MEMORY

STAA SPDR ;SEND LS-BYTE TO SPI

DATA REG

WAIT2 LDAA SPSR ;CHECK STATUS OF SPIE

BPL WAIT2 ;POLL FOR END OF X-

MISSION

BSET $08,Y,$20 ;DRIV SS HIGH TO LATCH

DATA

RTS

DB0/DB8/SIN

LDAC

MDSI

SCK

AD660

68HC11

SER

01813-017

Figure 17. AD660 to 68HC11 (SPI) Interface

AD660 TO MICROWIRE INTERFACE

The flexible serial interface of the AD660 is also compatible

with the National Semiconductor MICROWIRE™ interface.

The MICROWIRE interface is used on microcontrollers, such

as the COP400 and COP800 series of processors. A generic

interface to the MICROWIRE interface is shown in Figure 18.

The G1, SK, and SO pins of the MICROWIRE interface are respec-

tively connected to the LDAC, CS and DB0/DB8/SIN pins of

the AD660.

DB0/DB8/SIN

LDAC

AD660

MICROWIRE™

SER

01813-018

Figure 18. AD660 to MICROWIRE Interface

AD660 TO ADSP-210x FAMILY INTERFACE

The serial mode of the AD660 minimizes the number of control

and data lines required to interface to digital signal processors

(DSPs) such as the ADSP-210x family. The application in

Figure 19 shows the interface between an ADSP-210x and the

AD660. Both the TFS pin and the DT pins of the ADSP-210x

should be connected to the SER and DB0 pins of the AD660,

respectively. An inverter is required between the SCLK output

and the CS input of the AD660 to ensure that data transmitted

to the DB0 pin is valid on the rising edge of CS.

The serial port (SPORT) of the DSP should be configured for

alternate framing mode so that TFS complies with the word

length framing requirement of SER. Note that the INVTFS bit

in the SPORT control register should be set to invert the TFS

signal so that SER is the correct polarity. The LDAC signal,

which must meet the minimum hold specification of tHIGH, is

easily generated by delaying the rising edge of SER with a

74HC74 flip-flop. The CS signal clocks the flip-flop, resulting

in a delay of approximately one CS clock cycle.

AD660

Rev. B | Page 16 of 20

In applications such as waveform generation, accurate timing of

the output samples is important to avoid noise that is induced

by jitter on the LDAC signal. In this example, the ADSP-210x

is set up to use the internal timer to interrupt the processor at

the precise and desired sample rate. When the timer interrupt

occurs, the 16-bit data word of the processor is written to the

transmit register (TXn). This causes the DSP to automatically

generate the TFS signal and begin transmission of the data.

DB0/DB8/SIN

LDAC

SCLK

TFS

AD660

ADSP-210x 74HC04

74HC74

SER

01813-019

Figure 19. AD660 to ADSP-210x Interface

AD660 TO Z80 INTERFACE

Figure 20 shows a Zilog Z80 8-bit microprocessor connected to

the AD660 using the byte mode interface. The double-buffered

capability of the AD660 allows the microprocessor to indepen-

dently write to the low and high byte registers, and update the

DAC output. Processor speeds up to 6 MHz on the Z80 require

no extra wait states to interface with the AD660 when using a

74ALS138 as the address decoder.

The address decoder analyzes the input-output address produced

by the processor to select the function to be performed by the

AD660, qualified by the coincidence of the input/output request

(IORQ) and write (WR) pins. The least significant address bit

(A0) determines if the low or high byte register of the AD660 is

active. More significant address bits select between input register

loading, DAC output update, and unipolar or bipolar clear.

A typical Z80 software routine begins by writing the low byte of

the desired 16-bit DAC data to Address 0, followed by the high

byte to Address 1. The DAC output is then updated by activating

LDAC with a write to Address 2 (or Address 3). A clear to unipolar

zero occurs on a write to Address 4, and a clear to bipolar zero

is performed by a write to Address 5. The actual data written to

Address 2 through Address 5 is irrelevant. The decoder can easily

be expanded to control as many AD660 devices as required.

DB0 TO DB7 +V

CLR

LDAC

AD660

Z80

A1 TO A15

A0 TO A15

D0 TO D7

IORQ

SER

HBE DGND

01813-020

ADDRESS

DECODE

LBE

Figure 20. Connections for 8-Bit Bus Interface

NOISE

In high resolution systems, noise is often the limiting factor. A

16-bit DAC with a 10 V span has an LSB size of 153 μV (−96 dB).

Therefore, the noise floor must remain below this level in the

frequency range of interest. The noise spectral density of the

AD660 is shown in Figure 21 and Figure 22. Figure 21 shows

the DAC output noise voltage spectral density for a 20 V span

excluding the reference. This figure shows the 1/f corner frequency

at 100 Hz and the wideband noise to be below 120 nV/√Hz.

Figure 22 shows the reference noise voltage spectral density and

shows the reference wideband noise to be below 125 nV/√Hz.

100

11 10 100 1k 10k 100k 1M 10M

NOISE VOLTAGE (nV/ Hz)

FREQUENCY (Hz)

01813-021

Figure 21. DAC Output Noise Voltage Spectral Density

100

11 10 100 1k 10k 100k 1M 10M

NOISE VOLTAGE (nV/ Hz)

FREQUENCY (Hz)

01813-022

Figure 22. Reference Noise Voltage Spectral Density

AD660

Rev. B | Page 17 of 20

BOARD LAYOUT

Designing with high resolution data converters requires careful

attention to board layout. Trace impedance is the first issue. A

306 μA current through a 0.5 Ω trace develops a voltage drop of

153 μV, which is 1 LSB at the 16-bit level for a 10 V full-scale

span. In addition to ground drops, inductive and capacitive

coupling need to be considered, especially when high accuracy

analog signals share the same board with digital signals. Finally,

power supplies need to be decoupled to filter out ac noise.

Analog and digital signals should not share a common path.

Each signal should have an appropriate analog or digital return

routed close to it. Using this approach, signal loops enclose a

small area, minimizing the inductive coupling of noise. Wide

PC tracks, large gauge wire, and ground planes are highly

recommended to provide low impedance signal paths. Separate

analog and digital ground planes should also be used, with a

single interconnection point to minimize ground loops. Analog

signals should be routed as far as possible from digital signals

and should cross them at right angles.

One feature that the AD660 incorporates to help the user layout

is that the analog pins (+VCC, −VEE, REF OUT, REF IN, SPAN/

BIPOLAR OFFSET, VOUT and AGND) are adjacent to help

isolate analog signals from digital signals.

SUPPLY DECOUPLING

The AD660 power supplies should be well filtered, well regulated,

and free from high frequency noise. Switching power supplies

are not recommended due to their tendency to generate spikes,

which can induce noise in the analog system.

Decoupling capacitors should be used in very close layout

proximity between all power supply pins and ground. A 10 μF

tantalum capacitor in parallel with a 0.1 μF ceramic capacitor

provides adequate decoupling. VCC and VEE should be bypassed

to analog ground, while VLL should be decoupled to digital ground.

An effort should be made to minimize the trace length between

the capacitor leads and the respective converter power supply

and common pins. The circuit layout should attempt to locate

the AD660, associated analog circuitry, and interconnections as

far as possible from logic circuitry. A solid analog ground plane

around the AD660 will isolate large switching ground currents.

For these reasons, the use of wire wrap circuit construction is

not recommended; careful printed circuit construction is

preferred.

GROUNDING

The AD660 has two ground pins, designated analog ground

(AGND) and digital ground (DGND.) The analog ground pin is

the high quality ground reference point for the device. Any

external loads on the output of the AD660 should be returned

to analog ground. If an external reference is used, this should

also be returned to the analog ground.

If a single AD660 is used with separate analog and digital ground

planes, connect the analog ground plane to AGND and the digital

ground plane to DGND keeping lead lengths as short as possible.

Then connect AGND and DGND together at the AD660. If

multiple AD660 devices are used or the AD660 shares analog

supplies with other components, connect the analog and digital

returns together once at the power supplies rather than at each

chip. This single interconnection of grounds prevents large

ground loops and consequently prevents digital currents from

flowing through the analog ground.

AD660

Rev. B | Page 18 of 20

OUTLINE DIMENSIONS

CONTROLLING DIMENSIONS ARE IN INCHES; MILLIMETER DIMENSIONS

(IN PARENTHESES) ARE ROUNDED-OFF INCH EQUIVALENTS FOR

REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.

CORNER LEADS MAY BE CONFIGURED AS WHOLE OR HALF LEADS.

COMPLIANT TO JEDEC STANDARDS MS-001

071006-A

0.022 (0.56)

0.018 (0.46)

0.014 (0.36)

0.150 (3.81)

0.130 (3.30)

0.115 (2.92)

0.070 (1.78)

0.060 (1.52)

0.045 (1.14)

112

0.100 (2.54)

BSC

1.280 (32.51)

1.250 (31.75)

1.230 (31.24)

0.210 (5.33)

MAX

SEATING

PLANE

0.015

(0.38)

MIN

0.005 (0.13)

MIN

0.280 (7.11)

0.250 (6.35)

0.240 (6.10)

0.060 (1.52)

MAX

0.430 (10.92)

MAX

0.014 (0.36)

0.010 (0.25)

0.008 (0.20)

0.325 (8.26)

0.310 (7.87)

0.300 (7.62)

0.015 (0.38)

GAUGE

PLANE

0.195 (4.95)

0.130 (3.30)

0.115 (2.92)

Figure 23. 24-Lead Plastic Dual In-Line Package [PDIP]

Narrow Body

(N-24-1)

Dimensions shown in inches and (millimeters)

CONTROLLING DIMENSIONS ARE IN INCHES; MILLIMETER DIMENSIONS

(IN PARENTHESES) ARE ROUNDED-OFF INCH EQUIVALENTS FOR

REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.

112

0.310 (7.87)

0.220 (5.59)

0.005 (0.13)

MIN

0.098 (2.49)

MAX

15°

0°

0.320 (8.13)

0.290 (7.37)

0.015 (0.38)

0.008 (0.20)

SEATING

PLANE

0.200 (5.08)

MAX 1.280 (32.51) MAX

0.150 (3.81)

MIN

0.200 (5.08)

0.125 (3.18)

0.023 (0.58)

0.014 (0.36)

0.100

(2.54)

BSC

0.070 (1.78)

0.030 (0.76)

0.060 (1.52)

0.015 (0.38)

PIN 1

Figure 24. 24-Lead Ceramic Dual In-Line Package [CERDIP]

(Q-24)

Dimensions shown in inches and (millimeters)

AD660

Rev. B | Page 19 of 20

COMPLIANT TO JEDEC STANDARDS MS-013-AD

CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS

(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR

REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.

15.60 (0.6142)

15.20 (0.5984)

0.30 (0.0118)

0.10 (0.0039)

2.65 (0.1043)

2.35 (0.0925)

10.65 (0.4193)

10.00 (0.3937)

7.60 (0.2992)

7.40 (0.2913)

0.75 (0.0295)

0.25 (0.0098)

45°

1.27 (0.0500)

0.40 (0.0157)

COPLANARITY

0.10 0.33 (0.0130)

0.20 (0.0079)

0.51 (0.0201)

0.31 (0.0122)

SEATING

PLANE

8°

0°

24 13

1.27 (0.0500)

BSC

060706-A

Figure 25. 24-Lead Standard Small Outline Package [SOIC_W]

Wide Body

(RW-24)

Dimensions shown in millimeters and (inches)

ORDERING GUIDE

Model Temperature Range Gain TC Max ppm/°C Package Description Package Option

AD660AN −40°C to +85°C 25 24-Lead PDIP N-24-1

AD660ANZ1 −40°C to +85°C 25 24-Lead PDIP N-24-1

AD660AR −40°C to +85°C 25 24-Lead SOIC_W RW-24

AD660AR-REEL −40°C to +85°C 25 24-Lead SOIC_W RW-24

AD660ARZ1 −40°C to +85°C 25 24-Lead SOIC_W RW-24

AD660ARZ-REEL1 −40°C to +85°C 25 24-Lead SOIC_W RW-24

AD660BN −40°C to +85°C 15 24-Lead PDIP N-24-1

AD660BNZ1 −40°C to +85°C 15 24-Lead PDIP N-24-1

AD660BR −40°C to +85°C 15 24-Lead SOIC_W RW-24

AD660BR-REEL −40°C to +85°C 15 24-Lead SOIC_W RW-24

AD660BRZ1 −40°C to +85°C 15 24-Lead SOIC_W RW-24

AD660BRZ-REEL1 −40°C to +85°C 15 24-Lead SOIC_W RW-24

AD660SQ −55°C to +125°C 25 24-Lead CERDIP Q-24

AD660SQ/883B2 −55°C to +125°C

1 Z = RoHS Compliant Part.

2 For further details, refer to the AD660SQ/883B military data sheet.

AD660

Rev. B | Page 20 of 20

NOTES

registered trademarks are the property of their respective owners.

D01813-0-6/08(B)