AD7796 Analog Devices, AD7796 Datasheet - Page 21

AD7796

Manufacturer Part Number

AD7796

Description

Low Power 16-Bit Sigma-Delta A/D Converter for Bridge Sensors

Manufacturer

Analog Devices

Datasheet

1.AD7796.pdf (24 pages)

Specifications of AD7796

Resolution (bits)

16bit

# Chan

Sample Rate

n/a

Interface

Ser,SPI

Analog Input Type

Diff-Bip,Diff-Uni

Ain Range

± (Vref/128)

Adc Architecture

Sigma-Delta

Pkg Type

SOP

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RESET

The circuitry and serial interface of the AD7796/AD7797 can

be reset by writing 32 consecutive 1s to the device. This resets

the logic, the digital filter, and the analog modulator, while all

on-chip registers are reset to their default values. A reset is

automatically performed on power-up. When a reset is initiated,

the user must allow a period of 500 μs before accessing any of

the on-chip registers. A reset is useful if the serial interface

becomes asynchronous because of noise on the SCLK line.

BURNOUT CURRENTS

The AD7796/AD7797 contain two 100 nA constant current

generators, one sourcing current from AV

sinking current from AIN(–) to GND. Both currents are either

on or off, depending on the burnout current enable (BO) bit in

the configuration register. These currents can be used to verify

that an external transducer is still operational before attempting

to take measurements. When the burnout currents are turned

on, they flow in the external transducer circuit, and a measure-

ment of the input voltage on the analog input channel can be

taken. If the resulting voltage is full scale, the user needs to

verify why this is the case. A full-scale reading could mean that

the front-end sensor is open circuit. It could also mean that the

front-end sensor is overloaded and is justified in outputting full

scale, or that the reference could be absent, thus clamping the

data to all 1s.

When reading all 1s from the output, the user needs to check

these three cases before making a judgment. If the voltage

measured is 0 V, it could indicate that the transducer has short

circuited. For normal operation, these burnout currents are

turned off by writing a 0 to the BO bit in the configuration

Along with converting external voltages, the ADC can be used

to monitor the voltage on the AV

Bit CH0 equal 1, the voltage on the AV

attenuated by 6. The resulting voltage is applied to the

Σ-Δ modulator using an internal 1.17 V reference for analog-to-

digital conversion. This is useful because variations in the

power supply voltage can be monitored.

MONITOR

pin. When Bit CH2 to

pin is internally

to AIN(+) and one

Rev. A | Page 21 of 24

TEMPERATURE MONITOR

The AD7796/AD7797 have an embedded temperature sensor

that is accessed when Bit CH2 to Bit CH0 are equal to 1, 1, 0,

respectively. When the internal temperature sensor is selected,

the AD7796/AD7797 use an internal 1.17 V reference for

the conversions. The temperature sensor has a sensitivity of

0.81 mV/°C. However, a two-point calibration is required to

optimize the accuracy. The temperature sensor is not factory

calibrated; a user calibration is required. Following a

calibration, the accuracy is 2°C.

CALIBRATION

The AD7796/AD7797 provide three calibration modes that can

be programmed via the mode bits in the mode register. These

are internal zero-scale calibration, system zero-scale calibration,

and system full-scale calibration, which effectively reduces the

offset error and full-scale error to the order of the noise. After

each conversion, the ADC conversion result is scaled using the

ADC calibration registers before being written to the data

result prior to multiplication by the full-scale coefficient.

To start a calibration, write the relevant value to the MD2 to

MD0 bits in the mode register. DOUT/ RDY goes high when the

calibration is initiated. After the calibration is complete, the

contents of the corresponding calibration registers are updated,

the RDY bit in the status register is set, the DOUT/ RDY pin goes

low (if CS is low), and the AD7796/AD7797 revert to idle mode.

During an internal zero-scale calibration, the zero input is

automatically connected internally to the ADC input pins. A

system calibration, however, expects the system zero-scale and

system full-scale voltages to be applied to the ADC pins before

the calibration mode is initiated. In this way, external ADC

errors are removed.

From an operational point of view, a calibration should be

treated like another ADC conversion. A zero-scale calibration

(if required) should always be performed before a full-scale

calibration. System software should monitor the RDY bit in the

status register or the DOUT/ RDY pin to determine the end of

calibration via a polling sequence or an interrupt-driven routine.

Both an internal offset calibration and system offset calibration

takes two conversion cycles. An internal offset calibration is not

needed because the ADC itself removes the offset continuously.

A system full-scale calibration takes two conversion cycles to

complete. The measured full-scale coefficient is placed in the

full-scale register. If system offset calibrations are being

performed along with system full-scale calibrations, the offset

calibration should be performed before the system full-scale

calibration is initiated.

AD7796/AD7797

AD7796 Analog Devices, AD7796 Datasheet - Page 21

AD7796

Specifications of AD7796

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