AD1580BRTZREEL7 - ANALOG DEVICES - Datasheet.Directory

Complete, High Speed

16-Bit A/D Converters

AD1376/AD1377

Rev. D

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Tel: 781.329.4700 www.analog.com

FEATURES

Complete 16-bit converters with reference and clock

±0.003% maximum nonlinearity

No missing codes to 14 bits over temperature

Fast conversion

17 µs to 16 bits (AD1376)

10 µs to 16 bits (AD1377)

Short cycle capability

Adjustable clock rate

Parallel outputs

Low power

645 mW typical (AD1376)

585 mW typical (AD1377)

Industry-standard pinout

GENERAL DESCRIPTION

The AD1376/AD1377 are high resolution, 16-bit analog-to-

digital converters with internal reference, clock, and laser-

trimmed thin-film applications resistors. The AD1376/AD1377

are excellent for use in high resolution applications requiring

moderate speed and high accuracy or stability over commercial

temperature ranges (0°C to 70°C). They are packaged in

compact 32-lead, ceramic seam-sealed (hermetic), dual in-line

packages (DIP). Thin-film scaling resistors provide bipolar

input ranges of ±2.5 V, ±5 V, and ±10 V and unipolar input

ranges of 0 V to +5 V, 0 V to +10 V, and 0 V to +20 V.

Digital output data is provided in parallel form with

corresponding clock and status outputs. All digital inputs and

outputs are TTL-compatible.

For the AD1376, the serial output function is no longer

available after date code 0111. For the AD1377, the serial output

function is no longer available after date code 0210. The option

of applying an external clock on the CONVERT START pin to

slow down the internally set conversion time is no longer

supported for either part.

PRODUCT HIGHLIGHTS

1. The AD1376/AD1377 provide 16-bit resolution with a

maximum linearity error of ±0.003% (1/2 LSB14) at 25°C.

2. The AD1376 conversion time is 14 µs (typical) short cycled

to 14 bits, and 16 µs to 16 bits.

3. The AD1377 conversion time is 8 µs (typical) short cycled

to 14 bits, and 9 µs to 16 bits.

4. Two binary codes are available on the digital output. They

are CSB (complementary straight binary) for unipolar input

voltage ranges and COB (complementary offset binary) for

bipolar input ranges. Complementary twos complement

(CTC) coding may be obtained by inverting Pin 1 (MSB).

5. The AD1376/AD1377 include internal reference and clock

with external clock rate adjust pin, and parallel digital outputs.

FUNCTIONAL BLOCK DIAGRAM

00699-001

(MSB) BIT 1

BIT 2

BIT 3

BIT 4

BIT 5

BIT 6

BIT 7

BIT 8

BIT 9

BIT 10

BIT 11

BIT 12

(LSB FOR 13 BITS) BIT 1

(LSB FOR 14 BITS) BIT 14

BIT 15

BIT 16

SHORT CYCL E

CONVERT START

+5V DC SUPPLY V

GAIN ADJUST

+15V DC SUPPLY V

CO M PARATOR I N

BIPOLAR OFFSET

+10V

+20V

CLK RAT E CTRL

ANALO G COMMON

–15V DC SUP P LY V

CLO CK OUT

DIGITAL COMMON

STATUS

16-BI T DAC

16-BIT SAR

CLOCK

REFERENCE

COMPARATOR

7.5kΩ

3.75kΩ3.75kΩ

AD1376/AD1377

Figure 1.

AD1376/AD1377

Rev. D | Page 2 of 12

TABLE OF CONTENTS

Specifications..................................................................................... 3

Absolute Maximum Ratings............................................................ 5

ESD Caution.................................................................................. 5

Description of Operation ................................................................ 6

Gain Adjustment .......................................................................... 6

Zero Offset Adjustment............................................................... 6

Timing............................................................................................ 7

Digital Output Data ..................................................................... 7

Input Scaling ..................................................................................7

Calibration (14-Bit Resolution Examples).................................8

Grounding, Decoupling, and Layout Considerations ..............9

Clock Rate Control........................................................................9

High Resolution Data Acquisition System.............................. 10

Applications..................................................................................... 11

Outline Dimensions ....................................................................... 12

Ordering Guide .......................................................................... 12

REVISION HISTORY

6/05—Rev. C to Rev. D

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

Updated Outline Dimensions....................................................... 12

6/03—Rev. B to Rev. C

Removed Serial Output Function and

Adjustable Clock Rate........................................................Universal

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

Changes to General Description .................................................... 1

Changes to Product Highlights....................................................... 1

Changes to Functional Block Diagram.......................................... 1

Inserted ESD Warning ..................................................................... 3

Change to Ordering Guide.............................................................. 3

Change to Figure 7 ........................................................................... 5

Deleted text from Digital Output Data.......................................... 5

Deleted Figure 9 and Renumbered Remainder of Figures.......... 5

Deleted the ‘Using the AD1376 or AD1377 at

Slower Conversion Times’ Section............................................... 8

Deleted Figure 16.............................................................................. 8

Change to Figure 13 ......................................................................... 9

Change to Figure 14 ......................................................................... 9

Updated Outline Dimensions....................................................... 10

AD1376/AD1377

Rev. D | Page 3 of 12

SPECIFICATIONS

Typical at TA = 25°C, VS = ±15 V, +5 V, unless otherwise noted.

Table 1.

AD1376JD/AD1377JD AD1376KD/AD1377KD

Model Min Typ Max Min Typ Max Unit

RESOLUTION 16 16 Bits

ANALOG INPUTS

Voltage Ranges

Bipolar ±2.5 ±2.5 V

±5 ±5 V

±10 ±10 V

Unipolar 0 to 5 0 to 5 V

0 to 10 0 to 10 V

0 to 20 0 to 20 V

Impedance (Direct Input) V

0 V to +5 V, ±2.5 V 1.88 1.88 kΩ

0 V to +10 V, ±5.0 V 3.75 3.75 kΩ

0 V to +20 V, ±10 V 7.50 7.50 kΩ

DIGITAL INPUTS1

Convert Command Trailing edge of positive 50 ns (min) pulse

Logic Loading 1 1 LS TTL Load

TRANSFER CHARACTERISTICS2

(ACCURACY)

Gain Error ±0.053±0.2 ± 0.053 ± 0.2 %

Offset Error

Unipolar ±0.053 ±0.1 ±0.053 ±0.1 % of FSR4

Bipolar ±0.053 ±0.2 ±0.053 ±0.2 % of FSR

Linearity Error (Max) ±0.006 ±0.003 % of FSR

Inherent Quantization Error ±1/2 ±1/2 LSB

Differential Linearity Error ±0.003 ±0.003 % of FSR

POWER SUPPLY SENSITIVITY

±15 V DC (±0.75 V) 0.0015 0.0015 % of FSR/% ∆VS

+5 V DC (±0.25 V) 0.001 0.001 % of FSR/% ∆VS

CONVERSION TIME5

12 Bits (AD1376) 11.5 13 11.5 13 µs

14 Bits (AD1376) 13.5 15 13.5 15 µs

16 Bits (AD1376) 15.5 17 15.5 17 µs

14 Bits (AD1377) 8.75 8.75 µs

16 Bits (AD1377) 10 10 µs

POWER SUPPLY REQUIREMENTS

Analog Supplies +14.5 +15 +15.5 +14.5 +15 +15.5 V dc

−14.5 −15 −15.5 −14.5 −15 −15.5 V dc

Digital Supply +4.75 +5 +5.25 +4.75 +5 +5.25 V dc

AD1376 Power Consumption 600 800 600 800 mW

+15 V Supply Drain +10 +10 mA

−15 V Supply Drain −23 −23 mA

+5 V Supply Drain +18 +18 mA

AD1377 Power Consumption 600 800 600 800 mW

+15 V Supply Drain +10 +10 mA

−15 V Supply Drain −23 −23 mA

+5 V Supply Drain +18 +18 mA

WARM-UP TIME 1 1 Minutes

AD1376/AD1377

Rev. D | Page 4 of 12

AD1376JD/AD1377JD AD1376KD/AD1377KD

Model Min Typ Max Min Typ Max Unit

DRIFT6

Gain ±15 ±5 ±15 ppm/°C

Offset

Unipolar ±2 ±4 ±2 ±4 ppm of FSR/°C

Bipolar ±10 ±3 ±10 ppm of FSR/°C

Linearity ±2 ±3 ±0.3 ±2 ppm of FSR/°C

Guaranteed No Missing Code

Temperature Range 0 to 70 (13 Bits) 0 to 70 (14 Bits) °C

DIGITAL OUTPUT1

(All Codes Complementary)

Parallel Output Codes7

Unipolar CSB CSB

Bipolar COB, CTC8 COB, CTC8

Output Drive 5 5 LSTTL Loads

Status

Logic 1 During

Conversion

Logic 1 During

Conversion

Status Output Drive 5 5 LSTTL Loads

Internal Clock9

Clock Output Drive 5 5 LSTTL Loads

Frequency 1040/1750 1040/1750 kHz

TEMPERATURE RANGE

Specification 0 to 70 0 to 70 °C

Operating −25 to +85 −25 to +85 °C

Storage −55 to +125 −55 to +125 °C

1 Logic 0 = 0.8 V max; Logic 1 = 2.0 V min for inputs. For digital outputs, Logic 0 = 0.4 V max. Logic 1 = 2.4 V min.

2 Tested on ±10 V and 0 V to +10 V ranges.

3 Adjustable to zero.

4 Full-scale range.

5 Conversion time may be shortened with “short cycle” set for lower resolution.

6 Guaranteed but not 100% production tested.

7 CSB–Complementary Straight Binary. COB–Complementary Offset Binary. CTC–Complementary Twos Complement.

8 CTC coding obtained by inverting MSB (Pin 1).

9 With Pin 23, clock rate controls tied to digital ground.

AD1376/AD1377

Rev. D | Page 5 of 12

ABSOLUTE MAXIMUM RATINGS

Table 2.

Parameter Rating

Supply Voltage ±18 V

Logic Supply Voltage +7 V

Analog Inputs (Pin 24 and Pin 25) ±25 V

Analog Ground to Digital Ground ±0.3 V

Digital Inputs −0.3 V to VDD + 0.3 V

Junction Temperature 175°C

Storage Temperature 150°C

Lead Temperature (10 sec) 300°C

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 listed in the operational sections

of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect

device reliability.

ESD CAUTION

ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the

human body and test equipment and can discharge without detection. Although this product features

proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy

electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance

degradation or loss of functionality.

AD1376/AD1377

Rev. D | Page 6 of 12

DESCRIPTION OF OPERATION

0.0135

0.0080

0.0195

0.0120

–0.0120

–0.0195

0.0060

0.0030

–0.0030

–0.0060

–0.0080

–0.0135

025 70

00699-002

TEMPERATURE (°C)

LINEARITY ERROR (% FSR)

AD1376/AD1377KD

±2ppm/°C,

±0.003%, @ 25°C

AD1376/AD1377JD

±3ppm/°C,

±0.006%, @ 25°C

Figure 2. Linearity Error vs. Temperature

0.100

AD1376

0.001

0.003

0.006

0.010

5 10152

00699-003

CONVERSION TIME (µs)

LINEARITY AND DIFFERENTIAL LINEARITY

ERROR (% OF FSR)

SHORT CYCLED TO 12 BITS

1/2LSB 12-BIT

1/2LSB 13-BIT

1/2LSB 14-BIT

SHORT CYCLED TO 13 BITS

SHORT CYCLED TO 14 BITS

Figure 3. AD1376 Nonlinearity vs. Conversion Time

0.100

0.038

–0.038

–0.068

0.068

–0.100

0605040302010

00699-004

GAIN DRIFT ERROR (% FSR)

Figure 4. Gain Drift Error vs. Temperature

On receipt of a CONVERT START command, the AD1376/

AD1377 convert the voltage at the analog input into an

equivalent 16-bit binary number. This conversion is

accomplished as follows: the 16-bit successive approximation

device bit output pins and to the corresponding bit inputs of the

feedback DAC. The analog input is successively compared to

the feedback DAC output, one hit at a time (MSB first, LSB

last). The decision to keep or reject each bit is then made at the

completion of each bit comparison period, depending on the

state of the comparator at that time.

GAIN ADJUSTMENT

The gain adjustment circuit consists of a 100 ppm/°C poten-

tiometer connected across ±VS with its slider connected

through a 300 kΩ resistor to Pin 29 (GAIN ADJ) as shown in

Figure 5.

If no external trim adjustment is desired, Pin 27

(COMPARATOR IN) and Pin 29 can be left open.

00699-005

AD1376/AD1377

0.01µF

300kΩ

+15V

10kΩ

100kΩ

100ppm/°C

–15V

Figure 5. Gain Adjustment Circuit (±0.2% FSR)

ZERO OFFSET ADJUSTMENT

The zero offset adjustment circuit consists of a 100 ppm/°C

potentiometer connected across ±VS with its slider connected

through a 1.8 MΩ resistor to Pin 27 for all ranges. As shown in

Figure 6, the tolerance of this fixed resistor is not critical; a carbon

composition type is generally adequate. Using a carbon compo-

sition resistor having a −1200 ppm/°C temperature coefficient

contributes a worst-case offset temperature coefficient of 32 LSB14

× 61 ppm/LSB14 × 1200 ppm/°C = 2.3 ppm/°C of FSR, if the offset

adjustment potentiometer is set at either end of its adjustment

range. Since the maximum offset adjustment required is typically

no more than ±16 LSB14, use of a carbon composition offset

summing resistor typically contributes no more than 1 ppm/°C of

FSR offset temperature coefficient.

00699-006

AD1376/AD1377

1.8MΩ

+15V

10kΩ

100kΩ

–15V

Figure 6. Zero Offset Adjustment Circuit (±0.3% FSR)

An alternate offset adjustment circuit, which contributes a

negligible offset temperature coefficient if metal film resistors

(temperature coefficient <100 ppm/°C) are used, is shown in

Figure 7.

00699-007

AD1376/AD1377

22kΩ M.F.

180kΩM.F. 180kΩM.F.

+15V

10kΩ

100kΩ

OFFSET

ADJ

–15V

Figure 7. Low Temperature Coefficient Zero Adjustment Circuit

AD1376/AD1377

Rev. D | Page 7 of 12

In either adjustment circuit, the fixed resistor connected to

Pin 27 should be located close to this pin to keep the pin

connection short. Pin 27 is quite sensitive to external noise

pickup and should be guarded by ANALOG COMMON.

TIMING

The timing diagram is shown in Figure 8. Receipt of a

CONVERT START signal sets the STATUS flag, indicating

conversion in progress. This in turn removes the inhibit applied

to the gated clock, permitting it to run through 17 cycles. All

the SAR parallel bits, the STATUS flip-flops, and the gated clock

inhibit signal are initialized on the trailing edge of the

CONVERT START signal. At time t0, B1 is reset and B2–B16 are

set unconditionally. At t1, the Bit 1 decision is made (keep) and

Bit 2 is reset unconditionally. This sequence continues until the

Bit 16 (LSB) decision (keep) is made at t16. The STATUS flag is

reset, indicating that the conversion is complete and that the

parallel output data is valid. Resetting the STATUS flag restores

the gated clock inhibit signal, forcing the clock output to the

low Logic 0 state. Note that the clock remains low until the next

conversion.

Corresponding parallel data bits become valid on the same

positive-going clock edge.

00699-008

(3)

(2)

(1)

0110011101111010

100

110

MSB

STATUS

INTERNAL

CLOCK

CONVERT

START

BIT 2

BIT 3

BIT 4

BIT 5

BIT 6

BIT 7

BIT 8

BIT 9

BIT 10

BIT 11

BIT 12

BIT 13

BIT 14

BIT 15

LSB LSBMSB

MAXIMUM THROUGHPUT TIME

CONVERSION TIME (2)

NOTES:

1. THE CONVERT START PULSEWIDTH IS 50ns MIN AND MUST REMAIN LOW DURING A

CONVERSION. THE CONVERSION IS INITIATED BY THE TRAILING EDGE OF THE

CONVERT COMMAND.

2. MSB DECISION.

3. CLOCK REMAINS LOW AFTER LAST BIT DECISION.

Figure 8. Timing Diagram (Binary Code 0110011101111010)

DIGITAL OUTPUT DATA

Parallel data from TTL storage registers is in negative true form

(Logic 1 = 0 V and Logic 0 = 2.4 V). Parallel data output coding

is complementary binary for unipolar ranges and complement-

tary offset binary for bipolar ranges. Parallel data becomes valid

at least 20 ns before the STATUS flag returns to Logic 0,

permitting parallel data transfer to be clocked on the 1 to 0

transition of the STATUS flag (see Figure 9). Parallel data

output changes state on positive going clock edges.

00699-009

BIT 16

VALID

BUSY

(STATUS)

20ns MIN TO 90ns

Figure 9. LSB Valid to Status Low

Short Cycle Input

Pin 32 (SHORT CYCLE) permits the timing cycle shown in

Figure 8 to be terminated after any number of desired bits has

been converted, allowing somewhat shorter conversion times in

applications not requiring full 16-bit resolution. When 10-bit

resolution is desired, Pin 32 is connected to Bit 11 output

Pin 11. The conversion cycle then terminates and the STATUS

flag resets after the Bit 10 decision (Figure 8). Short cycle

connections and associated 8-, 10-, 12-, 13-, 14-, and 15-bit

conversion times are summarized in Table 3 for a 1.6 MHz

clock (AD1377) or 933 kHz clock (AD1376).

Table 3. Short Cycle Connections

Resolution

Maximum

Conversion Time (µs)

Bits

FSR) AD1377 AD1376

Status

Flag

Reset

Connect

Short Cycle

Pin 32 to

16 0.0015 10 17.1 t16 NC (Open)

15 0.003 9.4 16.1 t15 Pin 16

14 0.006 8.7 15.0 t1Pin 15

13 0.012 8.1 13.9 t13 Pin 14

12 0.024 7.5 12.9 t12 Pin 13

10 0.100 6.3 10.7 t10 Pin 11

8 0.390 5.0 8.6 t8Pin 9

INPUT SCALING

The ADC inputs should be scaled as close to the maximum

input signal range as possible to use the maximum signal

resolution of the ADC. Connect the input signal as shown in

Table 4. See Figure 10 for circuit details.

AD1376/AD1377

Rev. D | Page 8 of 12

Table 4. Input Scaling Connections

Input Signal Line Output Code Connect Pin 26 to Connect Pin 24 to Connect Input Signal to

±10 V COB Pin 271Input Signal Pin 24

±5 V COB Pin 271Open Pin 25

±2.5 V COB Pin 271Pin 271Pin 25

0 V to +5 V CSB Pin 22 Pin 271Pin 25

0 V to +10 V CSB Pin 22 Open Pin 25

0 V to +20 V CSB Pin 22 Input Signal Pin 24

1 Pin 27 is extremely sensitive to noise and should be guarded by ANALOG COMMON.

00699-010

ANALOG

COMMON

BIPOLAR

OFFSET

COMP IN

7.5kΩ

3.75kΩ

10V SPAN

20V SPAN R1

3.75kΩ

FROM DAC

COMPARATOR

SAR

REF

Figure 10. Input Scaling Circuit

CALIBRATION (14-BIT RESOLUTION EXAMPLES)

External zero adjustment and gain adjustment potentiometers,

connected as shown in Figure 5 and Figure 6, are used for

device calibration. To prevent interaction of these two

adjustments, zero is always adjusted first and then gain. Zero is

adjusted with the analog input near the most negative end of the

analog range (0 for unipolar and minus full scale for bipolar

input ranges). Gain is adjusted with the analog input near the

most positive end of the analog range.

0 V to 10 V Range

Set analog input to +1 LSB14 = 0.00061 V. Adjust zero for digital

output = 11111111111110. Zero is now calibrated. Set analog

input to +FSR − 2 LSB = 9.99878 V. Adjust gain for

00000000000001 digital output code; full scale (gain) is now

calibrated. Half-scale calibration check: set analog input to

5.00000 V; digital output code should be 01111111111111.

−10 V to +10 V Range

Set analog input to −9.99878 V; adjust zero for 1111111111110

digital output (complementary offset binary) code. Set analog

input to 9.99756 V; adjust gain for 00000000000001 digital

output (complementary offset binary) code. Half-scale

calibration check: set analog input to 0.00000 V; digital output

(complementary offset binary) code should be 01111111111111.

00699-011

–15V

+15V A

16-BIT SUCCESSIVE

APPROMIXATION REGISTER

16-BIT DAC

REF

CONTROL

3.75kΩ3.75kΩ

24262319

(0V TO +10V)

KEEP/

REJECT

7.5kΩ

+15V

–15V

ZERO

ADJ

10kΩ

100kΩ

= 1.3mA

AD1376/

AD1377

1.8MΩ

1µF

+5V +

1µF

+15V

–15V

GAIN

ADJ

10kΩ

100

Ω

300kΩ

0.01µF

NOTE:

NALOG ( ) AND DIGITAL ( ) GROUNDS ARE NOT TIED INTERNALLY AND MUST BE CONNECTED EXTERNALLY

Figure 11. Analog and Power Connections

for Unipolar 0 V to 10 V Input Range

00699-012

–15V

+15V A

16-BIT SUCCESSIVE

APPROMIXATION REGISTER

16-BIT DAC

REF

CONTROL

3.75kΩ3.75kΩ

24262319

(–10V TO +10V)

KEEP/

REJECT

7.5kΩ

+15V

–15V

ZERO

ADJ

10kΩ

100kΩ

= 1.3mA

AD1376/

AD1377

1.8MΩ

1µF

+5V +

1µF

+15V

–15V

GAIN

ADJ

10kΩ

100kΩ

300kΩ

0.01µF

NOTE:

NALOG ( ) AND DIGITAL ( ) GROUNDS ARE NOT TIED INTERNALLY AND MUST BE CONNECTED EXTERNALL

Figure 12. Analog and Power Connections

for Bipolar −10 V to +10 V Input Range

Other Ranges

Representative digital coding for 0 V to +10 V and −10 V to

+10 V ranges is given in the 0 V to 10 V Range section and

−10 V to +10 V Range section. Coding relationships and

calibration points for 0 V to +5 V, −2.5 V to +2.5 V, and −5 V to

+5 V ranges can be found by halving proportionally the

corresponding code equivalents listed for the 0 V to +10 V and

−10 V to +10 V ranges, respectively, as indicated in Table 5.

AD1376/AD1377

Rev. D | Page 9 of 12

Table 5. Transition Values vs. Calibration Codes

Output Code

MSB LSB1Range ±10 V ±5 V ±2.5 V 0 V to +10 V 0 V to +5 V

000 ………0002+Full Scale +10 V +5 V +2.5 V +10 V +5 V

−3/2 LSB −3/2 LSB −3/2 LSB −3/2 LSB −3/2 LSB

011………111 Midscale 0 V 0 V 0 V +5 V +2.5 V

–1/2 LSB –1/2 LSB –1/2 LSB –1/2 LSB –1/2 LSB

111………110 −Full Scale −10 V −5 V −2.5 V 0 V 0 V

+1/2 LSB +1/2 LSB +1/2 LSB +1/2 LSB +1/2 LSB

1 For LSB value for range and resolution used, see Ta . ble 6

Table 6. Input Voltage Range and LSB Values

2 Voltages given are the nominal value for transition to the code specified.

Analog Input Voltage Range ±10 V ±5 V ±2.5 V 0 V to +10 V 0 V to +5 V

Code Designation COB1 or CTC2COB1 or CTC2 COB1 or CTC2 CSB3CSB3

One Least Significant Bit (LSB) n

FSR n

V20 n

V10 n

V5 n

V10 n

n = 8 78.13 mV 39.06 mV 19.53 mV 39.06 mV 19.53 mV

n = 10 19.53 mV 9.77 mV 4.88 mV 9.77 mV 4.88 mV

n = 12 4.88 mV 2.44 mV 1.22 mV 2.44 mV 1.22 mV

n = 13 2.44 mV 1.22 mV 0.61 mV 1.22 mV 0.61 mV

n = 14 1.22 mV 0.61 mV 0.31 mV 0.61 mV 0.31 mV

n = 15 0.61 mV 0.31 mV 0.15 mV 0.31 mV 0.15 mV

1 COB = complementary offset binary.

2 CTC = complementary twos complement—achieved by using an inverter to complement the most significant bit to produce MSB.

3 CSB = complementary straight binary

Zero- and full-scale calibration can be accomplished to a

precision of approximately ±1/2 LSB using the static adjustment

procedure described previously. By summing a small sine or

triangular wave voltage with the signal applied to the analog

input, the output can be cycled through each of the calibration

codes of interest to more accurately determine the center (or

end points) of each discrete quantization level. A detailed

description of this dynamic calibration technique is presented

in Analog-Digital Conversion Handbook, edited by D. H.

Sheingold, Prentice Hall, Inc., 1986.

GROUNDING, DECOUPLING, AND LAYOUT

CONSIDERATIONS

Many data acquisition components have two or more ground

pins that are not connected together within the device. These

grounds are usually referred to as DIGITAL COMMON (logic

power return), ANALOG COMMON (analog power return), or

analog signal ground. These grounds (Pin 19 and Pin 22) must

be tied together at one point as close as possible to the

converter. Ideally, a single solid analog ground plane under the

converter would be desirable. Current flows through the wires

and etch stripes of the circuit cards, and since these paths have

resistance and inductance, hundreds of millivolts can be

generated between the system analog ground point and the

ground pins of the ADC. Separate wide conductor stripe

ground returns should be provided for high resolution

converters to minimize noise and IR losses from the current

flow in the path from the converter to the system ground point.

In this way, ADC supply currents and other digital logic-gate

return currents are not summed into the same return path as

analog signals where they would cause measurement errors.

Each of the ADC supply terminals should be capacitively

decoupled as close to the ADC as possible. A large value (such

as 1 µF) capacitor in parallel with a 0.1 µF capacitor is usually

sufficient. Analog supplies are to be bypassed to the ANALOG

COMMON (analog power return) Pin 22 and the logic supply is

bypassed to DIGITAL COMMON (logic power return) Pin 19.

The metal cover is internally grounded with respect to the

power supplies, grounds, and electrical signals. Do not

externally ground the cover.

CLOCK RATE CONTROL

The AD1376/AD1377 can be operated at faster conversion

times by connecting the clock rate control (Pin 23) to an

external multiturn trim potentiometer (TCR <100 ppm/°C) as

shown in Figure 13.

00699-013

AD1376/AD1377

2.25MHz @ 5V

1750kHz @ DGND

15V DC

5kΩ

Figure 13. Clock Rate Control Circuit

AD1376/AD1377

Rev. D | Page 10 of 12

HIGH RESOLUTION DATA ACQUISITION SYSTEM

The essential details of a high resolution data acquisition system

using a 16-bit sample-and-hold amplifier (SHA) and the

AD1376/AD1377 are shown in Figure 14. Conversion is

initiated by the falling edge of the CONVERT START pulse.

This edge drives the device’s STATUS line high. The inverter

then drives the SHA into hold mode. STATUS remains high

throughout the conversion and returns low once the conversion

is completed. This allows the SHA to re-enter track mode.

This circuit can exhibit nonlinearities arising from transients

produced at the ADC’s input by the falling edge of CONVERT

START. This edge resets the ADC’s internal DAC; the resulting

transient depends on the SHA’s present output voltage and the

ADC’s prior conversion result. In the circuit of Figure 15, the

falling edge of CONVERT START also places the SHA into hold

mode (via the ADC’s STATUS output), causing the reset

transient to occur at the same moment as the SHA’s track-and-

hold transition. Timing skews and capacitive coupling can cause

some of the transient signal to add to the signal being acquired

by the SHA, introducing nonlinearity.

00699-014

SHA

AD1376/

AD1377

30 21 28

18 31

BITS

1–16

CONVERT

START

–10V TO + 10V

10µF+

10µF

+15

–15V

+5V

ANALOG

INPUT

–

10V TO + 10

Figure 14. Basic Data Acquisition System Interconnections 16-Bit SHA

A much safer approach is to add a flip-flop, as shown in

Figure 15. The rising edge of CONVERT START places the

track-and-hold device into hold mode before the ADC reset

transients begin. The falling edge of STATUS places the SHA

back into track mode. System throughput will be reduced if a

long CONVERT START pulse is used. Throughput can be

calculated from

CSCONVACQ TTT

Throughput ++

where:

TACQ is the track-and-hold acquisition time.

TCONV is the time required for the ADC conversion.

TCS is the duration of CONVERT START.

The combination of the AD1376 and a 16-bit SHA can provide

greater than 50 kHz throughput. No significant track-and-hold

droop error will be introduced, provided the width of

CONVERT START is small compared with the ADC’s

conversion time.

0699-015

SHA

AD1376/

AD1377

30 21 28

19 18 31

BITS

1–16

–10V TO +10V

10µF+

10µF

+15V

–15V

+5V

ANALOG

INPUT

–10V T O +10V

CONVERT

START

HC112

+5V

Figure 15. Improved Data Acquisition System

AD1376/AD1377

Rev. D | Page 11 of 12

APPLICATIONS

The AD1376/AD1377 are excellent for use in high resolution

applications requiring moderate speed and high accuracy or

stability over commercial (0°C to 70°C) temperature ranges.

Typical applications include medical and analytic instrumen-

tation, precision measurement for industrial robotics, automatic

test equipment (ATE), multichannel data acquisition systems,

servo control systems, or anywhere wide dynamic range is

required. A proprietary monolithic DAC and laser-trimmed

thin-film resistors guarantee a maximum nonlinearity of

±0.003% (1/2 LSB14). The converters may be short cycled to

achieve faster conversion times—15 µs to 14 bits for the

AD1376 or 8 µs to 14 bits for the AD1377.

AD1376/AD1377

Rev. D | Page 12 of 12

OUTLINE DIMENSIONS

NOTES:

1. INDEX AREA IS INDICATED BY A NOTCH OR LEAD ONE

IDENTIFICATION MARK LOCATED ADJACENT TO LEAD ONE.

2. 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.

0.023 (0.58)

0.014 (0.36)

0.910 (23.11)

0.890 (22.61)

116

1732

1.728 (43.89) MAX

0.225 (5.72)

MAX

0.025 (0.64)

0.015 (0.38)

0.008 (0.20)

1.102 (27.99)

1.079 (27.41)

0.100 (2.54)

BSC 0.070 (1.78)

0.030 (0.76)

0.120 (3.05)

MAX

PIN 1

INDICATOR

(NOTE 1)

0.192 (4.88)

0.152 (3.86) 0.206 (5.23)

0.186 (4.72)

0.025 (0.64)

MIN

Figure 16. 32 Lead Bottom-Brazed Ceramic DIP for Hybrid [BBDIP_H]

(DH-32E)

Dimensions shown in inches and (millimeters)

ORDERING GUIDE

Model Temperature Range Maximum Linearity Error Conversion Time (16 Bits) Package Option1

AD1376JD 0°C to 70°C ±0.006% 17 µs DH-32E

AD1376KD 0°C to 70°C ±0.003% 17 µs DH-32E

AD1377JD 0°C to 70°C ±0.006% 10 µs DH-32E

AD1377KD 0°C to 70°C ±0.003% 10 µs DH-32E

1 DH-32E = Ceramic DIP.

registered trademarks are the property of their respective owners.

C00699–0–6/05(D)