AD8651/AD8652 Data Sheet
Rev. D | Page 16 of 20
Input Capacitance
Along with bypassing and grounding, high speed amplifiers can be
sensitive to parasitic capacitance between the inputs and ground. A
few picofarads of capacitance reduces the input impedance at high
frequencies, which in turn increases the amplifier gain, causing
peaking in the frequency response or oscillations. With the
AD865x, additional input damping is required for stability with
capacitive loads greater than 47 pF with direct input to output
feedback (see the Output Capacitance section).
Output Capacitance
When using high speed amplifiers, it is important to consider
the effects of the capacitive loading on amplifier stability.
Capacitive loading interacts with the output impedance of the
amplifier, causing reduction of the BW as well as peaking and
ringing of the frequency response. To reduce the effects of the
capacitive loading and allow higher capacitive loads, there are
two commonly used methods.
• As shown in Figure 56, place a small value resistor (R
S
) in
series with the output to isolate the load capacitor from the
amplifier output. Heavy capacitive loads can reduce the
phase margin of an amplifier and cause the amplifier
response to peak or become unstable. The AD865x is able
to drive up to 47 pF in a unity gain buffer configuration
without oscillation or external compensation. However, if
an application requires a higher capacitive load drive when
the AD865x is in unity gain, the use of external isolation
networks can be used. The effect produced by this resistor
is to isolate the op amp output from the capacitive load.
The required amount of series resistance has been
tabulated in Table 5 for different capacitive loads. While
this technique improves the overall capacitive load drive
for the amplifier, its biggest drawback is that it reduces the
output swing of the overall circuit.
V
IN
0
0
0
3
2
U1
R
L
C
L
R
S
V
OUT
V
CC
03301-055
+
–
AD865x
V
+
V
–
Figure 56. Driving Large Capacitive Loads
Table 5. Optimum Values for Driving Large Capacitive Loads
C
L
R
S
100 pF 50 Ω
500 pF 35 Ω
1.0 nF 25 Ω
• Another way to stabilize an op amp driving a large capacitive
load is to use a snubber network, as shown in Figure 57. Because
there is not any isolation resistor in the signal path, this method
has the significant advantage of not reducing the output swing.
The exact values of R
S
and C
S
are derived experimentally. In
Figure 57, an optimum R
S
and C
S
combination for a capacitive
load drive ranging from 50 pF to 1 nF was chosen. For this,
R
S
= 3 Ω and C
S
= 10 nF were chosen.
200m
V
R
L
C
L
R
S
C
S
V
O
U
T
V
+
V
–
03301-056
+
–
AD
865
x
V
+
V
–
Figure 57. Snubber Network
Settling Time
The settling time of an amplifier is defined as the time it takes
for the output to respond to a step change of input and enter
and remain within a defined error band, as measured relative to
the 50% point of the input pulse. This parameter is especially
important in measurements and control circuits where amplifi-
ers are used to buffer A/D inputs or DAC outputs. The design of
the AD865x family combines a high slew rate and a wide gain
bandwidth product to produce an amplifier with very fast
settling time. The AD865x is configured in the noninverting
gain of 1 with a 2 V p-p step applied to its input. The AD865x
family has a settling time of about 130 ns to 0.01% (2 mV). The
output is monitored with a 10×, 10 M, 11.2 pF scope probe.
THD Readings vs. Common-Mode Voltage
Total harmonic distortion of the AD865x family is well below
0.0004% with any load down to 600 Ω. The distortion is a
function of the circuit configuration, the voltage applied, and
the layout, in addition to other factors. The AD865x family
outperforms its competitor for distortion, especially at
frequencies below 20 kHz, as shown in Figure 58.
THD + NOISE (%)
0.0001
0.0002
0.0005
0.001
0.002
0.005
0.01
0.02
0.05
0.1
FREQUENCY (Hz)
V
SY
= +3.5V/–1.5V
V
OUT
= 2.0V p-p
20 50 100 500 20k5k
2k1k
OPA350
AD8651
03301-057
Figure 58. Total Harmonic Distortion