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OPA365 Datasheet, PDF (12/16 Pages) Burr-Brown (TI) – 2.2V, 50MHz, Low-Noise, Single-Supply Rail-to-Rail OPERATIONAL AMPLIFIERS
OPA365
OPA2365
SBOS365A − JUNE 2006 − REVISED JULY 2006
One method for driving an ADC that negates the need
for an output swing down to 0V uses a slightly com-
pressed ADC full-scale input range (FSR). For exam-
ple, the 16-bit ADS8361 (shown in Figure 11) has a
maximum FSR of 0V to 5V, when powered by a +5V
supply and VREF of 2.5V. The idea is to match the ADC
input range with the op amp full linear output swing
range; for example, an output range of +0.1 to +4.9V.
The reference output from the ADS8361 ADC is divided
down from 2.5V to 2.4V using a resistive divider. The
ADC FSR then becomes 4.8VPP centered on a com-
mon-mode voltage of +2.5V. Current from the ADS8361
reference pin is limited to about ±10µA. Here, 5µA was
used to bias the divider. The resistors must be precise
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to maintain the ADC gain accuracy. An additional bene-
fit of this method is the elimination of the negative sup-
ply voltage; it requires no additional power-supply cur-
rent.
An RC network, consisting of R1 and C1, is included be-
tween the op amp and the ADS8361. It not only pro-
vides a high-frequency filter function, but more impor-
tantly serves as a charge reservoir used for charging
the converter internal hold capacitance. This capability
assures that the op amp output linearity is maintained
as the ADC input characteristics change throughout the
conversion cycle. Depending on the particular applica-
tion and ADC, some optimization of the R1 and C1 val-
ues may be required for best transient performance.
R2
10kΩ
+5V
VIN
0.1V to 4.9V
R1
10kΩ
C1
100nF
V+
OPA365
R3(1)
100Ω
V−
+5V
−IN
C2(1)
1nF +IN
ADS8361
16−Bit
100kSPS
REF OUT REF IN
+2.5V
NOTE: (1) Suggested value; may require adjustment
based on specific application.
R4
20kΩ
+2.4V
R5
C3
480kΩ
1µF
Figure 11. Driving the ADS8361
12