ADC700JH Burr-Brown Corporation, ADC700JH Datasheet - Page 8

ADC700JH

Manufacturer Part Number

ADC700JH

Description

16-bit Resolution With Microprocessor Interface A/D Converter

Manufacturer

Burr-Brown Corporation

Datasheet

1.ADC700JH.pdf (12 pages)

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supply plane. If it is used for offset adjustment, the series

resistor and potentiometer should be located as close to the

converter as possible.

The Gain Adjust (pin 4) is an input that has a relatively high

input impedance and is susceptible to noise pickup. The

Gain Adjust pin should be bypassed with a 0.01 F to 0.1 F

capacitor whether or not the gain adjust feature is used.

If the 20V Analog input range is used (pin 28), the 10V

Range input (pin 27) may need to be shielded with ground

plane to reduce noise pickup.

ANALOG SIGNAL SOURCE IMPEDANCE

The input impedance of the ADC700, typical of most suc-

cessive approximation A/D converters, is relatively low

(2.5k

approximation A/D converter changes rapidly during the

conversion algorithm as each bit current is compared to the

analog input current. Since the output impedance of a

closed-loop amplifier or a sample-hold amplifier increases

with frequency and, in addition, the amplifier must settle to

the required accuracy in time for the next comparison/

decision after such a disturbance, care must be taken to

select the proper driving amplifier.

Unfortunately, high-accuracy operational amplifiers tend to

have low bandwidth, while wide-band amplifiers tend to

have lower accuracy. One solution is to use a wide-band but

perhaps less precise amplifier. Another solution is to add a

wide-band buffer amplifier such as the Burr-Brown OPA633

inside the feedback loop of a slower (but precision) ampli-

fier, Figure 5. This reduces the output impedance at high

frequencies yet preserves the accuracy at low frequencies.

When a sample/hold is needed, a high-linearity, high-speed

sample/hold such as the Burr-Brown SHC76 should be used

to drive the ADC700.

ANALOG INPUT RANGES

The analog input circuits of the ADC700 can be connected

to accept unipolar or bipolar input signals. These ranges and

connections are tabulated in Table I. Circuit connections are

shown in Figures 6 and 7. Gain and offset adjustments are

described in the calibration section.

To operate the ADC700 with a range that gives other

convenient values for the LSB, the input resistor may be

increased or decreased slightly without seriously affecting

the Gain Drift of the converter. Since the input resistors of

the ADC700 are within 2% from unit to unit, this can be

FIGURE 5. Wideband Buffer Reduces Output Impedance at

to 10k ). The input current of a successive

High Frequencies.

Low Bandwidth

Precision

OPA111

Op Amp

OPA27

ADC700

Wideband

OPA633

Buffer

Common

Analog

Converter

A/D

consistently done with a fixed series or parallel resistor. The

ADC700 can then be calibrated using the Gain and Offset

adjustments described in the calibration section. For ex-

ample, using the 10V input range, one can decrease the

range slightly by paralleling the 10k input resistor (pin 28

to pin 1) with a 610k

300 V LSB instead of the nominal standard 305.17578 V

binary LSB.

OPTIONAL EXTERNAL GAIN AND OFFSET TRIM

Gain and Offset Error may be trimmed to zero using external

Gain and Offset trim potentiometers connected to the

ADC700 as shown in Figures 6 and Figure 7. A calibration

procedure in described in the Operating Instructions section.

Multiturn potentiometers with 100ppm/ C or better TCR are

recommended for minimum drift over temperature. These

potentiometers may be any value from 10k to 100k . All

resistors should be 20% carbon or better. Pin 1 (Comparator

In) and pin 4 (Gain Adjust) may be left open if no external

adjustment is planned; however, pin 4 should always be

bypassed with 0.01 F or larger to Analog Common.

OPERATING INSTRUCTIONS

CALIBRATION

Offset and Gain may be trimmed by external Offset and

Gain potentiometers. Offset is adjusted first and then Gain.

Calibration values are listed in Table II for all ADC700

input ranges. Offset and Gain calibration can be accom-

plished to a precision of about 1/2LSB using a static

adjustment procedure described below. By summing a small

sine or triangular wave voltage with the accurate calibration

voltage applied to the analog input, the output can be swept

through each of the calibration codes to more accurately

determine the transition points listed in Table II. NOTE: The

transition points are not the same as the code midpoints used

in the static calibration example.

OFFSET ADJUSTMENT,

14-BIT RESOLUTION EXAMPLE

Static Adjustment Procedure (At Code Midpoints)

0V to +10V Range—Set the analog input to +1LSB

0.00061V. Adjust the Offset potentiometer for a digital

output of 0004

2LSB

digital output of FFFC

set the analog input to +5.0000V and read a digital output

code of 8000

TABLE I. ADC700 Input Range Connections.

INPUT

SIGNAL

RANGE

0V to +5V

0V to +10V

0V to +20V

10V

2.5V

= +9.9987V. Adjust the Gain potentiometer for a

BTCEN = 1

BOB

USB

OUTPUT CODE

. Set the analog input to +Full Scale –

BTCEN = 0

BTC

. For a half-scale calibration check,

—

metal film resistor to achieve a

CONNECT

TO PIN

PIN 2

Input Signal

CONNECT

TO PIN

PIN 28

Open

Pin 1

Open

CONNECT

SIGNAL

TO PIN

ADC700JH Burr-Brown Corporation, ADC700JH Datasheet - Page 8

ADC700JH

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