2.5 V
Q
ADC_V
CM
Q
2.6 V
ADC_ V
CM
=
5 ×
tr
•
À
tr
•
À
+ (R
1
//
tr
•
À
)
×
l
1 +
s
•
À
s
•
À
+ R
S
p
F
l
2.5 ×
s
•
À
s
•
À
+ R
S
p
ADC_ V
CM
=
5 × (
sr
•
À
//
tr
•
À
)
(
sr
•
À
//
tr
•
À
) + (R
1
//
tr
•
À
)
×
l
1 +
s
•
À
s
•
À
+ R
S
p
20k
Ÿ
280k
Ÿ
5.0V
20k
Ÿ
10k
Ÿ
OPA625_CM
OPA376
Gain = 1
J2
J1
R1
Analog Interface
7
SBAU268 – July 2016
Copyright © 2016, Texas Instruments Incorporated
ADS8910BEVM-PDK
Figure 2. Common-Mode Selection Jumpers
Table 3. J1 and J2 Configuration per Input Common Mode
J1 Setting
(R1 Comp)
J2 Setting
External Signal
Common-Mode
Differential Source Type
CLOSED
CLOSED
0 V
Bipolar: If R1 = 280 k
Ω
, R
S
range is 0
Ω
to 32
Ω
CLOSED
OPEN
2.5 V
Unipolar: must change R1 to match R
S
CLOSED
OPEN
Floating
AC-coupled bipolar: If R1 = 280 k
Ω
, no R
S
restriction
2.2.3
R1 Setting vs Source Impedance
The external source impedance (R
S
) adds up to the 1 k
Ω
of the input resistor, thereby moving the output
common-mode of the OPA625 amplifiers. To compensate for this change in output common-mode, R1
can be modified according to the particular external source impedance value used with the evaluation
board to allow full-scale input range without saturating the OPA625 amplifiers.
The board is shipped with R1 as 280 k
Ω
that allows an external source impedance (R
S
) range between
0
Ω
to 32
Ω
for a 0-V common-mode configuration (J1:closed and J2:closed). For floating or ac-coupled
signals, the input common-mode is set by the OPA625 amplifiers themselves and R1 must remain at 280
k
Ω
for any given source impedance. The ADC common-mode for 0-V input common-mode setting is
calculated using
.
(1)
In the case of unipolar input signals with a 2.5-V common-mode, the ADC common-mode is calculated
using
.
(2)
For
and
the value of R1 must be calculated to satisfy
(3)
