AD7706 Analog Devices, AD7706 Datasheet - Page 22
AD7706
Manufacturer Part Number
AD7706
Description
3V/5V, 1mW, 3-Channel Pseudo Differential, 16-Bit Sigma-Delta ADC
Manufacturer
Analog Devices
Datasheet
1.AD7705.pdf
(44 pages)
Specifications of AD7706
Resolution (bits)
16bit
# Chan
3
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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AD7705/AD7706
ANALOG INPUT
Ranges
The AD7705 contains two differential analog input pairs,
AIN1(+)/AIN1(−) and AIN2(+)/AIN2(−). These input pairs
provide programmable-gain, differential input channels that can
handle either unipolar or bipolar input signals. It should be noted
that the bipolar input signals are referenced to the respective
AIN(−) input of each input pair. The AD7706 contains three
pseudo differential analog input pairs, AIN1, AIN2, and AIN3,
which are referenced to the COMMON input.
In unbuffered mode, the common-mode range of the input is
from GND to V
input voltage lies between GND − 100 mV and V
Therefore, in unbuffered mode, the part can handle both unipolar
and bipolar input ranges for all gains. The AD7705 can tolerate
absolute analog input voltages down to GND − 200 mV, but the
leakage current increases at high temperatures. In buffered mode,
the analog inputs can handle much larger source impedances,
but the absolute input voltage range is restricted to between
GND + 50 mV and V
mode range. Therefore, in buffered mode, there are some
restrictions on the allowable gains for bipolar input ranges. Care
must be taken in setting up the common-mode voltage and
input voltage ranges so that the above limits are not exceeded;
otherwise, there is a degradation in linearity performance.
In unbuffered mode, the analog inputs look directly into the
7 pF input sampling capacitor, C
current in this unbuffered mode is 1 nA maximum. As a result,
the analog inputs see a dynamic load that is switched at the
input sample rate (see Figure 14). This sample rate depends on
master clock frequency and selected gain. C
AIN(+) and discharged to AIN(−) every input sample cycle.
The effective on resistance of the switch, R
C
impedances every input sample cycle. Therefore, in unbuffered
mode, source impedances mean a longer charge time for C
which might result in gain errors on the parts. Table 22 shows
the allowable external resistance-capacitance values for unbuffered
mode, such that no gain error to the 16-bit level is introduced in
the part. Note that these capacitances are total capacitances on
the analog input—external capacitance plus 10 pF capacitance
from the pins and lead frame of the devices.
SAMP
must be charged through R
AIN(+)
AIN(–)
Figure 14. Unbuffered Analog Input Structure
SWITCHING FREQUENCY DEPENDS ON
f
CLKIN
DD
, provided that the absolute value of the analog
AND SELECTED GAIN
DD
− 1.5 V, which also restricts the common-
R
SW
(7kΩ TYP)
C
SAMP
(7pF)
V
SAMP
BIAS
SW
and any external source
. The dc input leakage
HIGH
IMPEDANCE
>1G
SW
SAMP
, is typically 7 kΩ.
is charged to
DD
+ 30 mV.
SAMP
Rev. C | Page 22 of 44
,
Table 22. External Resistance-Capacitance Combination for
Unbuffered Mode (Without 16-Bit Gain Error)
Gain
1
2
4
8 to 128 16.7 kΩ
In buffered mode, the analog inputs look into the high impedance
inputs stage of the on-chip buffer amplifier. C
this buffer amplifier such that source impedances do not affect
the charging of C
current of 1 nA. In this buffered mode, large source impedances
result in a small dc offset voltage developed across the source
impedance, but not in a gain error.
Sample Rate
The modulator sample frequency for the AD7705/AD7706
remains at f
of the selected gain. However, gains greater than 1 are achieved
by a combination of multiple input samples per modulator cycle
and a scaling of the ratio of reference capacitor to input capacitor.
As a result of the multiple sampling, the input sample rate of
these devices varies with the selected gain (see Table 23). In
buffered mode, the input is buffered before the input sampling
capacitor. In unbuffered mode, where the analog input looks
directly into the sampling capacitor, the effective input impedance
is 1/C
and f
Table 23. Input Sampling Frequency vs. Gain
Gain
1
2
4
8 to 128
BIPOLAR/UNIPOLAR INPUT
The analog inputs on the AD7705/AD7706 can accept either
unipolar or bipolar input voltage ranges. Bipolar input ranges
do not imply that these parts can handle negative voltages on
their analog inputs; the analog inputs cannot go more negative
than −100 mV to ensure correct operation of these parts. The
input channels are fully differential. As a result, on the AD7705,
the voltage to which the unipolar and bipolar signals on the
AIN(+) input are referenced is the voltage on the respective
AIN(−) input.
S
SAMP
is the input sample rate.
152 kΩ
75.1 kΩ
34.2 kΩ
10
× f
Input Sampling Frequency (f
f
2 × f
4 × f
8 × f
CLKIN
CLKIN
S
, where C
/64 (38.4 kHz @ f
CLKIN
CLKIN
CLKIN
/128 (19.2 kHz @ f
SAMP
50
53.9 kΩ
26.6 kΩ
12.77 kΩ
5.95 kΩ
/64 (76.8 kHz @ f
/64 (76.8 kHz @ f
/64 (307.2 kHz @ f
. This buffer amplifier has an offset leakage
SAMP
External Capacitance (pF)
is the input sampling capacitance
100
31.4 kΩ
15.4 kΩ
7.3 kΩ
3.46 kΩ
CLKIN
CLKIN
CLKIN
CLKIN
= 2.4576 MHz)
CLKIN
500
8.4 kΩ
4.14 kΩ
1.95 kΩ
924 Ω
= 2.4576 MHz), regardless
= 2.4576 MHz)
= 2.4576 MHz)
= 2.4576 MHz)
S
)
SAMP
1000
4.76 kΩ
2.36 kΩ
1.15 kΩ
526 Ω
is charged via
1.36 kΩ
670 Ω
5000
320 Ω
150 Ω
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