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AD829ARZ-REEL

P1-P3P4-P6P7-P9P10-P12P13-P15P16-P18P19-P21
AD829 Data Sheet
Rev. I | Page 12 of 20
THEORY OF OPERATION
The AD829 is fabricated on the Analog Devices, Inc., proprietary
complementary bipolar (CB) process, which provides PNP and
NPN transistors with similar f
T
s of 600 MHz. As shown in
Figure 35, the AD829 input stage consists of an NPN differential
pair in which each transistor operates at a 600 µA collector current.
This gives the input devices a high transconductance, which in
turn gives the AD829 a low noise figure of 2 nV/√Hz at 1 kHz.
Figure 35. Simplified Schematic
The input stage drives a folded cascode that consists of a fast pair of
PNP transistors. These PNPs drive a current mirror that provides a
differential-input-to-single-ended-output conversion. The high
speed PNPs are also used in the current-amplifying output stage,
which provides a high current gain of 40,000. Even under heavy
loading conditions, the high f
T
s of the NPN and PNPs, produced
using the CB process, permit cascading two stages of emitter
followers while maintaining 60 phase margin at closed-loop
bandwidths greater than 50 MHz.
Two stages of complementary emitter followers also effectively
buffer the high impedance compensation node (at the C
COMP
pin)
from the output so that the AD829 can maintain a high dc open-
loop gain, even into low load impedances (92 dB into a 150 Ω
load and 100 dB into a 1 kΩ load). Laser trimming and PTAT
biasing ensure low offset voltage and low offset voltage drift,
enabling the user to eliminate ac coupling in many applications.
For added flexibility, the AD829 provides access to the internal
frequency compensation node. This allows users to customize the
frequency response characteristics for a particular application.
Unity-gain stability requires a compensation capacitance of 68 pF
(Pin 5 to ground), which yields a small signal bandwidth of
66 MHz and slew rate of 16 V/µs. The slew rate and gain
bandwidth product varies inversely with compensation
capacitance. Table 4 and Figure 37 show the optimum
compensation capacitance and the resulting slew rate for
a desired noise gain.
For gains between 1 and 20, choose C
COMP
to keep the small signal
bandwidth relatively constant. The minimum gain that will still
provide stability depends on the value of the external
compensation capacitance.
An RC network in the output stage (see Figure 35) completely
removes the effect of capacitive loading when the amplifier
compensates for closed-loop gains of 10 or higher. At low
frequencies, and with low capacitive loads, the gain from the
compensation node to the output is very close to unity. In this case,
C is bootstrapped and does not contribute to the compensation
capacitance of the device. As the capacitive load increases, a pole
forms with the output impedance of the output stage, which
reduces the gain, and subsequently, C is incompletely
bootstrapped. Therefore, some fraction of C contributes to the
compensation capacitance, and the unity-gain bandwidth falls.
As the load capacitance is further increased, the bandwidth
continues to fall, and the amplifier remains stable.
EXTERNALLY COMPENSATING THE AD829
The AD829 is stable with no external compensation for noise
gains greater than 20. For lower gains, two different methods of
frequency compensating the amplifier can be used to achieve
closed-loop stability: shunt and current feedback compensation.
SHUNT COMPENSATION
Figure 36 and Figure 37 show that shunt compensation has an
external compensation capacitor, C
COMP
, connected between the
compensation pin and ground. This external capacitor is tied in
parallel with approximately 3 pF of internal capacitance at the
compensation node. In addition, a small capacitance, C
LEAD
, in
parallel with resistor R2, compensates for the capacitance at the
inverting input of the amplifier.
Figure 36. Inverting Amplifier Connection Using External Shunt
Compensation
Figure 37. Noninverting Amplifier Connection Using External Shunt
Compensation
Table 4 gives the recommended C
COMP
and C
LEAD
values, as well
as the corresponding slew rates and bandwidth. The capacitor
values were selected to provide a small signal frequency response
with <1 dB of peaking and <10% overshoot. For Table 4, ±15 V
00880-035
–IN+IN
1.2mA
OFFSET NULL
C
12.5pF
R
500
OUTPUT
+V
S
–V
S
C
COMP
15
15
00880-036
2
3
7
6
4
+
AD829
+V
S
–V
S
0.1µF
0.1µF
5
C
COMP
50
50
COAX
CABLE
R1
C
LEAD
R2
V
OUT
1k
V
IN
00880-037
3
2
7
6
4
+
AD829
+V
S
–V
S
0.1µF
0.1µF
C
LEAD
5
C
COMP
50
50
CABLE
V
OUT
R2
R1
1k
V
IN
Data Sheet AD829
Rev. I | Page 13 of 20
supply voltages should be used. Figure 38 is a graphical extension
of Table 4, which shows the slew rate/gain trade-off for lower
closed-loop gains, when using the shunt compensation scheme.
Figure 38. Value of C
COMP
and Slew Rate vs. Noise Gain
CURRENT FEEDBACK COMPENSATION
Bipolar, nondegenerated, single-pole, and internally
compensated amplifiers have their bandwidths defined as
COMP
COMP
e
T
C
q
kT
I
Cr
f
π
=
π
=
2
2
1
where:
f
T
is the unity-gain bandwidth of the amplifier.
I is the collector current of the input transistor.
C
COMP
is the compensation capacitance.
r
e
is the inverse of the transconductance of the input transistors.
kT/q approximately equals 26 mV at 27°C.
Because both f
T
and slew rate are functions of the same variables,
the dynamic behavior of an amplifier is limited. Because
COMP
C
I
RateSlew
2
=
then
q
kT
f
RateSlew
T
π= 4
This shows that the slew rate is only 0.314 V/µs for every mega-
hertz of bandwidth. The only way to increase the slew rate is to
increase the f
T
, and that is difficult because of process limitations.
Unfortunately, an amplifier with a bandwidth of 10 MHz can
only slew at 3.1 V/µs, which is barely enough to provide a full
power bandwidth of 50 kHz.
The AD829 is especially suited to a form of current feedback
compensation that allows for the enhancement of both the full
power bandwidth and the slew rate of the amplifier. The voltage
gain from the inverting input pin to the compensation pin is
large; therefore, if a capacitance is inserted between these pins,
the bandwidth of the amplifier becomes a function of its feed-
back resistor and the capacitance. The slew rate of the amplifier
is now a function of its internal bias (2I) and the compensation
capacitance.
Table 4. Component Selection for Shunt Compensation
Follower Gain Inverter Gain R1 (Ω) R2 (Ω) C
LEAD
(pF) C
COMP
(pF) Slew Rate (V/µs) 3 dB Small Signal Bandwidth (MHz)
1 Open 100 0 68 16 66
2 −1 1 k 1 k 5 25 38 71
5 −4 511 2.0 k 1 7 90 76
10 −9 226 2.05 k 0 3 130 65
20 −19 105 2 k 0 0 230 55
25
−24
105
2.49
0
0
230
39
100 −99 20 2 k 0 0 230 7.5
00880-038
NOISE GAIN
C
COMP
(pF)
SLEW RATE (V/µs)
1 10
1
10
100
10
100
1k
100
SLEW RATE
C
COMP
V
S
= ±15V
AD829 Data Sheet
Rev. I | Page 14 of 20
Because the closed-loop bandwidth is a function of R
F
and
C
COMP
(see Figure 39), it is independent of the amplifier closed-
loop gain, as shown in Figure 41. To preserve stability, the time
constant of R
F
and C
COMP
needs to provide a bandwidth of
<65 MHz. For example, with C
COMP
= 15 pF and R
F
= 1 kΩ, the
small signal bandwidth of the AD829 is 10 MHz. Figure 40
shows that the slew rate is in excess of 60 V/µs. As shown in
Figure 41, the closed-loop bandwidth is constant for gains of
−1 to −4; this is a property of the current feedback amplifiers.
Figure 39. Inverting Amplifier Connection Using Current Feedback
Compensation
Figure 40. Large Signal Pulse Response of Inverting Amplifier Using Current
Feedback Compensation, C
COMP
= 15 pF, C1 = 15 pF R
F
= 1 kΩ, R1 = 1 kΩ
Figure 41. Closed-Loop Gain vs. Frequency for the Circuit of Figure 38
Figure 42 is an oscilloscope photo of the pulse response of a unity-
gain inverter that has been configured to provide a small signal
bandwidth of 53 MHz and a subsequent slew rate of 180 V/µs;
R
F
= 3 kΩ and C
COMP
= 1 pF. Figure 43 shows the excellent pulse
response as a unity-gain inverter, this using component values
of R
F
= 1 kΩ and C
COMP
= 4 pF.
Figure 42. Large Signal Pulse Response of the Inverting Amplifier Using
Current Feedback Compensation, C
COMP
= 1 pF, R
F
= 3 kΩ, R1 = 3 kΩ
Figure 43. Small Signal Pulse Response of Inverting Amplified Using Current
Feedback Compensation, C
COMP
= 4 pF, R
F
= 1 kΩ, R1 = 1 kΩ
00880-039
2
3
7
6
4
+
AD829
+V
S
–V
S
0.1µF
5
0.1µF
C1*
50
50
COAX
CABLE
R1
C
COMP
R
F
V
OUT
R
L
1k
V
IN
IN4148
*RECOMMENDED VALUE
OF C
COMP
FOR C1
<7pF 0pF
7pF 15pF
C
COMP
SHOULD NEVER EXCEED
15pF FOR THIS CONNECTION
00880-040
5V 200ns
0%
10
90
100%
00880-041
FREQUENCY (Hz)
CLOSED-LOOP GAIN (dB)
100k 1M 10M
–15
–12
–9
–6
–3
0
3
6
9
12
15
100M
GAIN = –4
–3dB @ 8.2MHz
GAIN = –2
–3dB @ 9.6MHz
GAIN = –1
–3dB @ 10.2MHz
V
IN
= –30dBm
V
S
= ±15V
R
L
= 1k
R
F
= 1k
C
COMP
= 15pF
C1 = 15pF
00880-042
5V 200ns
0%
10
90
100%
00880-043
20mV
10ns
0%
10
90
100%
P1-P3P4-P6P7-P9P10-P12P13-P15P16-P18P19-P21

AD829ARZ-REEL

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Manufacturer:
Analog Devices Inc.
Description:
Video Amplifiers IC HIGH Speed Low Noise
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