Datasheet
AD626
–9–
10
90
100
0%
TPC 25. Settling Time. V
S
= +5 V, G = 10
AD626
C1
5pF
+IN
–IN
R1
200k⍀
R2
200k⍀
R3
41k⍀
C2
5pF
R4
41k⍀
R5
4.2k⍀
R11
10k⍀
R6
500⍀
R7
500⍀
R8
10k⍀
R10
10k⍀
R14
555⍀
GND
GAIN = 100
R13
10k⍀
R15
10k⍀
R17
95k⍀
R9
10k⍀
R12
100k⍀
FILTER
OUT
+V
S
A1
A2
–V
S
Figure 4. Simplifi ed Schematic
10
90
100
0%
TPC 26. Settling Time. V
S
= +5 V, G = 100
10k⍀
10k⍀
10k⍀
INPUT
20V p–p
1k⍀
+V
S
AD626
–V
S
ERROR
OUT
2k⍀
Figure 3. Settling Time Test Circuit
THEORY OF OPERATION
The AD626 is a differential amplifi er con sist ing of a precision
bal anced attenuator, a very low drift preamplifi er (A1), and an
out put buffer amplifi er (A2). It has been designed so that small
differential signals can be accurately am pli fi ed and fi ltered in the
presence of large common -mode voltages (V
CM
), without the use
of any other active components.
Figure 4 shows the main elements of the AD626. The signal in puts
at Pins 1 and 8 are fi rst applied to dual resistive at ten u a tors R1
through R4 whose purpose is to reduce the peak com mon-mode
voltage at the input to the preamplifi er—a feed back stage based
on the very low drift op amp A1. This allows the dif feren tial
input voltage to be accurately amplifi ed in the pres ence of large
common-mode volt ag es six times greater than that which can be
tol er at ed by the actual input to A1. As a re sult, the in put CMR
ex tends to six times the quantity (V
S
– 1 V). The over all common -
mode error is min i mized by precise laser-trimming of R3 and R4,
thus giving the AD626 a common-mode re jec tion ra tio (CMRR)
of at least 10,000:1 (80 dB).
To minimize the effect of spurious RF signals at the inputs due to
rectifi cation at the input to A1, small fi lter capacitors C1 and C2
are included.
The output of A1 is connected to the in put of A2 via a 100 k⍀
(R12) resistor to facilitate the low-pass fi ltering of the sig nal of
in ter est (see Low-Pass Filtering section).
The 200 k⍀ input impedance of the AD626 requires that the source
re sis tance driving this amplifi er be low in val ue (<1 k⍀)—this is
REV. D