AD977ANZ Datasheet, PDF(6/24 Page) Analog Devices – 16-Bit, 100 kSPS/200 kSPS BiCMOS A/D Converter

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AD977ANZ Datasheet, PDF (6/24 Pages) Analog Devices – 16-Bit, 100 kSPS/200 kSPS BiCMOS A/D Converter

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AD977/AD977A

Pin No.

DIP/SOIC

1, 3, 4

Pin No.

SSOP

1, 3, 4

Mnemonic

R1IN, R2IN, R3IN

AGND1

CAP

REF

AGND2

SB/BTC

EXT/INT

DGND

SYNC

DATACLK

DATA

TAG

R/C

BUSY

PWRD

VANA

VDIG

PIN FUNCTION DESCRIPTIONS

Description

Analog Input. Refer to Table I, Table II for input range configuration.

Analog Ground. Used as the ground reference point for the REF pin.

Reference buffer output. Connect a 2.2 ÂµF tantalum capacitor between CAP and

Analog Ground.

Reference Input/Output. The internal 2.5 V reference is available at this pin.

Alternatively an external reference can be used to override the internal reference. In

either case, connect a 2.2 ÂµF tantalum capacitor between REF and Analog Ground.

Analog Ground.

This digital input is used to select the data format of a conversion result. With SB/BTC

tied LOW, conversion data will be output in Binary Twoâs Complement format. With

SB/BTC connected to a logic HIGH, data is output in Straight Binary format.

Digital select input for choosing the internal or an external data clock. With EXT/INT

tied LOW, after initiating a conversion, 16 DATACLK pulses transmit the previous

conversion result as shown in Figure 3. With EXT/INT set to a logic HIGH, output

data is synchronized to an external clock signal connected to the DATACLK input.

Data is output as indicated in Figure 4 through Figure 9.

Digital Ground.

Digital output frame synchronization for use with an external data clock

(EXT/INT = Logic HIGH). When a read sequence is initiated, a pulse one

DATACLK period wide is output synchronous to the external data clock.

Serial data clock input or output, dependent upon the logic state of the EXT/INT

pin. When using the internal data clock (EXT/INT = Logic LOW), a conversion

start sequence will initiate transmission of 16 DATACLK periods. Output data is

synchronous to this clock and is valid on both its rising and falling edges (Figure 3).

When using an external data clock (EXT/INT = Logic HIGH), the CS and R/C

signals control how conversion data is accessed.

The serial data output is synchronized to DATACLK. Conversion results are

stored in an on-chip register. The AD977 provides the conversion result, MSB first,

from its internal shift register. The DATA format is determined by the logic level of

SB/BTC. When using the internal data clock (EXT/INT = Logic LOW), DATA is

valid on both the rising and falling edges of DATACLK. Between conversions

DATA will remain at the level of the TAG input when the conversion was started.

Using an external data clock (EXT/INT = Logic HIGH) allows previous conversion

data to be accessed during a conversion (Figures 5, 7 and 9) or the conversion

result can be accessed after the completion of a conversion (Figures 4, 6 and 8).

This digital input can be used with an external data clock, (EXT/INT = Logic

HIGH) to daisy chain the conversion results from two or more AD977s onto a

single DATA line. The digital data level on TAG is output on DATA with a delay

of 16 or 17 external DATACLK periods after the initiation of the read sequence.

Dependent on whether a SYNC is not present or present.

Read/Convert Input. Is used to control the conversion and read modes of the

AD977. With CS LOW; a falling edge on R/C holds the analog input signal inter-

nally and starts a conversion, a rising edge enables the transmission of the conver-

sion result.

Chip Select Input. With R/C LOW, a falling edge on CS will initiate a conversion.

With R/C HIGH, a falling edge on CS will enable the serial data output sequence.

Busy Output. Goes LOW when a conversion is started, and remains LOW until the

conversion is completed and the data is latched into the on-chip shift register.

Power-Down Input. When set to a logic HIGH power consumption is reduced and

conversions are inhibited. The conversion result from the previous conversion is

stored in the onboard shift register.

Analog Power Supply. Nominally 5 V.

Digital Power Supply. Nominally 5 V.

â6â

REV. D

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