AD7705 Analog Devices, AD7705 Datasheet - Page 25

AD7705

Manufacturer Part Number

AD7705

Description

3V/5V, 1 mW, 2-Channel Differential, 16-Bit Sigma-Delta ADC

Manufacturer

Analog Devices

Datasheet

1.AD7705.pdf (44 pages)

Specifications of AD7705

Resolution (bits)

16bit

# Chan

Sample Rate

n/a

Interface

Ser,SPI

Analog Input Type

Diff-Bip,Diff-Uni

Ain Range

Bip (Vref)/(PGA Gain),Uni (Vref)/(PGA Gain)

Adc Architecture

Sigma-Delta

Pkg Type

DIP,SOIC,SOP

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Current page: 25 of 44
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ANALOG FILTERING

The digital filter does not provide any rejection at integer multiples

of the modulator sample frequency, as outlined earlier. However,

due to the part’s high oversampling ratio, these bands occupy

only a small fraction of the spectrum, and most broadband

noise is filtered. Therefore, the analog filtering requirements in

front of the AD7705/AD7706 are considerably reduced vs. a

conventional converter without on-chip filtering. In addition,

because the parts’ common-mode rejection performance of

100 dB extends to several kHz, common-mode noise in this

frequency range is substantially reduced.

Depending on the application, however, it might be necessary to

provide attenuation of the signal before it reaches the AD7705/

AD7706 to eliminate unwanted frequencies that can pass through

the digital filter. It might also be necessary to provide analog

filtering in front of the AD7705/AD7706 to ensure that differential

noise signals outside the band of interest do not saturate the

analog modulator.

If passive components are placed in front of the AD7705/

AD7706 in unbuffered mode, care must be taken to ensure that

the source impedance is low enough not to introduce gain errors

in the system. This significantly limits the amount of passive

antialiasing filtering, which can be provided in front of the

AD7705/AD7706 when the parts are used in unbuffered mode.

However, when the parts are used in buffered mode, large source

impedances result in a small dc offset error (a 10 kΩ source

resistance causes an offset error of less than 10 μV). Therefore,

if the system requires significant source impedances to provide

passive analog filtering in front of the AD7705/AD7706, it is

recommended to operate the part in buffered mode.

CALIBRATION

The AD7705/AD7706 provide a number of calibration options

that can be programmed via the MD1 and MD0 bits of the setup

Setup Register (RS2, RS1, RS0 = 0, 0, 1); Power-On/Reset Status:

01 Hex, and Calibration Sequences sections. A calibration cycle

can be initiated at any time by writing to these bits of the setup

and gain errors from the devices. A calibration routine should

be initiated on these devices whenever there is a change in the

ambient operating temperature or supply voltage. It should also

be initiated if there is a change in the selected gain, filter notch,

or bipolar/unipolar input range.

The AD7705/AD7706 offer self-calibration and system calibration

facilities. For full calibration to occur on the selected channel,

the on-chip microcontroller must record the modulator output

for two input conditions: zero-scale point and full-scale point.

These points are derived by performing a conversion on the

different input voltages provided to the input of the modulator

during calibration. As a result, the accuracy of the calibration is

only as good as the noise level that it provides in normal mode.

Rev. C | Page 25 of 44

The result of the zero-scale calibration conversion is stored in

the zero-scale calibration register, and the result of the full-scale

calibration conversion is stored in the full-scale calibration register.

With these readings, the microcontroller can calculate the offset

and the gain slope for the input-to-output transfer function of

the converter. Internally, the part works with a resolution of

33 bits to determine the conversion result of 16 bits.

Self-Calibration

A self-calibration is initiated on the AD7705/AD7706 by writing

the appropriate values (0, 1) to the MD1 and MD0 bits of the

setup register. In self-calibration mode with a unipolar input

range, the zero-scale point used to determine the calibration

coefficients is with the inputs of the differential pair internally

shorted on the part (i.e., AIN(+) = AIN(−) = internal bias voltage

on the AD7705, and AIN = COMMON = internal bias voltage

on the AD7706). The PGA is set for the selected gain for this

zero-scale calibration conversion, as per the G1 and G0 bits in

the communication register. The full-scale calibration conversion

is performed at the selected gain on an internally generated

voltage of V

The duration time for the calibration is 6 × 1/output rate. This

is composed of 3 × 1/output rate for the zero-scale calibration

and 3 × 1/output rate for the full-scale calibration. Then, the

MD1 and MD0 bits in the setup register return to 0, 0. This

provides the earliest indication that the calibration sequence is

complete. The DRDY line goes high when calibration is initiated

and does not return low until there is a valid new word in the data

issued to DRDY going low is 9 × 1/output rate. This is composed

of 3 × 1/output rate for the zero-scale calibration, 3 × 1/output

rate for the full-scale calibration, 3 × 1/output rate for a conversion

on the analog input, and some overhead to set up the coeffi-

cients correctly. If DRDY is low before (or goes low during)

writing the calibration command to the setup register, it can

take up to one modulator cycle (MCLK IN/128) before DRDY

goes high to indicate that a calibration is in progress. Therefore,

DRDY should be ignored for one modulator cycle after the last

bit is written to the setup register in the calibration command.

For bipolar input ranges in the self-calibrating mode, the

sequence is very similar to that outlined in the previous

paragraph. In this case, the two points are the same as above,

but the shorted inputs point is midscale of the transfer function

because the part is configured for bipolar operation.

System Calibration

System calibration allows the AD7705/AD7706 to compensate

for system gain and offset errors, as well as their own internal

errors. System calibration performs the same slope factor

calculations as self-calibration, but uses voltage values presented

by the system to the AIN inputs for the zero- and full-scale points.

Full system calibration requires a two-step process, a zero-scale

system calibration followed by a full-scale system calibration.

REF

/selected gain.

AD7705/AD7706

AD7705 Analog Devices, AD7705 Datasheet - Page 25

AD7705

Specifications of AD7705

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