AD AD844

a
FEATURES
Wide Bandwidth: 60 MHz at Gain of –1
Wide Bandwidth: 33 MHz at Gain of –10
Very High Output Slew Rate: Up to 2000 V/ms
20 MHz Full Power Bandwidth, 20 V pk-pk, RL = 500 V
Fast Settling: 100 ns to 0.1% (10 V Step)
Differential Gain Error: 0.03% at 4.4 MHz
Differential Phase Error: 0.158 at 4.4 MHz
High Output Drive: 650 mA into 50 Ω Load
Low Offset Voltage: 150 mV max (B Grade)
Low Quiescent Current: 6.5 mA
Available in Tape and Reel in Accordance with
EIA-481A Standard
60 MHz, 2000 V/ms
Monolithic Op Amp
AD844
CONNECTION DIAGRAMS
8-Pin Plastic (N),
and Cerdip (Q) Packages
16-Pin SOIC
(R) Package
APPLICATIONS
Flash ADC Input Amplifiers
High Speed Current DAC Interfaces
Video Buffers and Cable Drivers
Pulse Amplifiers
PRODUCT DESCRIPTION
The AD844 is a high speed monolithic operational amplifier fabricated using Analog Devices’ junction isolated complementary
bipolar (CB) process. It combines high bandwidth and very fast
large signal response with excellent dc performance. Although
optimized for use in current to voltage applications and as an
inverting mode amplifier, it is also suitable for use in many noninverting applications.
The AD844 can be used in place of traditional op amps, but its
current feedback architecture results in much better ac performance, high linearity and an exceptionally clean pulse response.
This type of op amp provides a closed-loop bandwidth which is
determined primarily by the feedback resistor and is almost independent of the closed-loop gain. The AD844 is free from the
slew rate limitations inherent in traditional op amps and other
current-feedback op amps. Peak output rate of change can be
over 2000 V/µs for a full 20 V output step. Settling time is typically 100 ns to 0.1%, and essentially independent of gain. The
AD844 can drive 50 Ω loads to ± 2.5 V with low distortion and
is short circuit protected to 80 mA.
The AD844 is available in four performance grades and three
package options. In the 16-pin SOIC (R) package, the AD844J
is specified for the commercial temperature range of 0°C to
+70°C. The AD844A and AD844B are specified for the industrial temperature range of –40°C to +85°C and are available in
the cerdip (Q) package. The AD844A is also available in an 8-pin
plastic mini-DIP (N). The AD844S is specified over the military
temperature range of –55°C to +125°C. It is available in the
8-pin cerdip (Q) package. “A” and “S” grade chips and devices
processed to MIL-STD-883B, REV. C are also available.
PRODUCT HIGHLIGHTS
1. The AD844 is a versatile, low cost component providing an
excellent combination of ac and dc performance. It may be
used as an alternative to the EL2020 and CLC400/1.
2. It is essentially free from slew rate limitations. Rise and fall
times are essentially independent of output level.
3. The AD844 can be operated from ± 4.5 V to ± 18 V power
supplies and is capable of driving loads down to 50 Ω, as
well as driving very large capacitive loads using an external
network.
4. The offset voltage and input bias currents of the AD844 are
laser trimmed to minimize dc errors; VOS drift is typically
1 µV/°C and bias current drift is typically 9 nA/°C.
5. The AD844 exhibits excellent differential gain and differential phase characteristics, making it suitable for a variety of
video applications with bandwidths up to 60 MHz.
6. The AD844 combines low distortion, low noise and low drift
with wide bandwidth, making it outstanding as an input amplifier for flash A/D converters.
REV. C
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
AD844–SPECIFICATIONS (@ T = +258C and V = 615 V dc, unless otherwise noted)
A
Model
INPUT OFFSET VOLTAGE
TMIN–TMAX
vs. Temperature
vs. Supply
Initial
TMIN–TMAX
vs. Common Mode
Initial
TMIN–TMAX
Conditions
S
Min
1
AD844J/A
Typ Max
Min
AD844B
Typ
Max
AD844S
Min Typ Max
50
75
1
300
500
50
75
1
150
200
5
50
125
1
300
500
5
µV
µV
µV/°C
4
4
20
4
4
10
10
4
4
20
20
µV/V
µV/V
10
10
35
10
10
20
20
10
10
35
35
µV/V
µV/V
200
800
9
450
1500
150
750
9
250
1100
15
200
1900
20
450
2500
30
nA
nA
nA/°C
175
220
250
175
220
200
240
175
220
250
300
nA/V
nA/V
90
110
150
350
3
160
90
110
100
300
3
110
150
200
500
7
90
120
100
800
7
160
200
400
1300
15
nA/V
nA/V
nA
nA
nA/°C
5 V–18 V
VCM = +10 V
INPUT BIAS CURRENT
–Input Bias Current1
TMIN–TMAX
vs. Temperature
vs. Supply
Initial
TMIN–TMAX
vs. Common Mode
Initial
TMIN–TMAX
+Input Bias Current1
TMIN–TMAX
vs. Temperature
vs. Supply
Initial
TMIN–TMAX
vs. Common Mode
Initial
TMIN–TMAX
Units
5 V–18 V
VCM = +10 V
400
700
5 V–18 V
VCM = ± 10 V
INPUT CHARACTERISTICS
Input Resistance
–Input
+Input
Input Capacitance
–Input
+Input
Input Voltage Range
Common Mode
7
80
100
150
80
100
100
120
80
120
150
200
nA/V
nA/V
90
130
150
90
130
120
190
90
140
150
200
nA/V
nA/V
50
10
65
50
10
65
50
10
65
Ω
MΩ
7
2
2
7
2
2
± 10
± 10
2
2
± 10
pF
pF
V
INPUT VOLTAGE NOISE
f ≥ 1 kHz
2
2
2
nV/√Hz
INPUT CURRENT NOISE
–Input
+Input
f ≥ 1 kHz
f ≥ 1 kHz
10
12
10
12
10
12
pA/√Hz
pA/√Hz
OPEN LOOP TRANSRESISTANCE
VOUT = ± 10 V
RLOAD = 500 Ω
3.0
1.6
4.5
MΩ
MΩ
pF
TMIN–TMAX
Transcapacitance
DIFFERENTIAL GAIN ERROR2
DIFFERENTIAL PHASE ERROR
2
SETTLING TIME
10 V Output Step
Gain = –1, to 0.1%5
Gain = –10, to 0.1%6
2 V Output Step
Gain = –1, to 0.1%5
Gain = –10, to 0.1%6
3.0
2.0
4.5
2.8
1.6
3.0
2.0
4.5
2.2
1.3
f = 4.4 MHz
0.03
0.03
0.03
%
f = 4.4 MHz
0.15
0.15
0.15
Degree
60
33
60
33
60
33
MHz
MHz
0.005
0.005
0.005
%
100
100
100
100
100
100
ns
ns
110
100
110
100
110
100
ns
ns
FREQUENCY RESPONSE
Small Signal Bandwidth
3
Gain = –1
4
Gain = –10
TOTAL HARMOMIC DISTORTION
2.2
1.3
f = 100 kHz,
2 V rms5
± 15 V Supplies
± 5 V Supplies
–2–
REV. C
AD844
Model
Conditions
Min
OUTPUT SLEW RATE
Overdriven
Input
1200
FULL POWER BANDWIDTH
VOUT = 20 V p-p5
VOUT = 2 V p-p5
OUTPUT CHARACTERISTICS
Voltage
Short Circuit Current
TMIN–TMAX
Output Resistance
AD844J/A
Typ Max
VS = ± 15 V
VS = ± 5 V
THD = 3%
RLOAD = 500 Ω
2000
Min
AD844B
Typ
1200
2000
20
20
10
Open Loop
Max
AD844S
Min Typ Max
Units
1200 2000
V/µs
20
20
11
80
60
15
11
80
60
15
10
10
20
20
MHz
MHz
11
80
60
15
±V
mA
mA
Ω
POWER SUPPLY
± 4.5
Operating Range
Quiescent Current
TMIN–TMAX
6.5
± 18
7.5
7.5
8.5
± 4.5
6.5
± 18
7.5
7.5
8.5
6.5
± 18
7.5
V
mA
8.5
9.5
mA
+4.5
NOTES
1
Rated performance after a 5 minute warmup at T A = 25°C.
2
Input signal 285 mV p-p carrier (40 IRE) riding on 0 mV to 642 mV (90 IRE) ramp. R L= 100 Ω; R1, R2 = 300 Ω.
3
Input signal 0 dBm, C L = 10 pF, R L = 500 Ω, R1 = 500 Ω, R2 = 500 Ω in Figure 26.
4
Input signal 0 dBm, C L =10 pF, R L = 500 Ω, R1 = 500 Ω, R2 = 50 Ω in Figure 26.
5
CL = 10 pF, R L = 500 Ω, R1 = 1 kΩ, R2 = 1 kΩ in Figure 26.
6
CL = 10 pF, R L = 500 Ω, R1 = 500 Ω, R2 = 50 Ω in Figure 26.
Specifications subject to change without notice. All min and max specifications are guaranteed.
Specifications shown in boldface are tested on all production units at final electrical test.
ABSOLUTE MAXIMUM RATINGS 1
NOTES
1
Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device at these or any other conditions above those
indicated in the operational sections of this specification is not implied. Exposure
to absolute maximum rating conditions for extended periods may affect device
reliability.
2
28-Pin Plastic Package: θJA = 100°C/Watt
8-Pin Cerdip Package: θJA = 110°C/Watt
16-Pin SOIC Package: θJA = 100°C/Watt
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .± 18 V
Power Dissipation2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1 W
Output Short Circuit Duration . . . . . . . . . . . . . . . . . Indefinite
Common-Mode Input Voltage . . . . . . . . . . . . . . . . . . . . . . ± VS
Differential Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . 6 V
Inverting Input Current
Continuous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 mA
Transient . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 mA
Storage Temperature Range (Q) . . . . . . . . . . –65°C to +150°C
Storage Temperature Range (N, R) . . . . . . . . –65°C to +125°C
Lead Temperature Range (Soldering 60 sec) . . . . . . . . +300°C
ESD Rating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1000 V
METALIZATION PHOTOGRAPH
Contact factory for latest dimensions.
Dimension shown in inches and (mm).
ORDERING GUIDE
Model
Temperature
Range
Package
Option*
AD844JR
AD844JR-REEL
AD844AN
AD844AQ
AD844BQ
AD844SQ
AD844SQ/883B
5962-8964401PA
AD844A Chips
AD844S Chips
0°C to +70°C
0°C to +70°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–40°C to +85°C
–55°C to +125°C
R-16
Tape and Reel
N-8
Q-8
Q-8
Q-8
Q-8
Q-8
Die
Die
*N = Plastic DIP; Q = Cerdip; R = Small Outline IC (SOIC).
REV. C
–3–
AD844–Typical Characteristics (T = +258C and V = 615 V, unless otherwise noted)
A
Figure 1. –3 dB Bandwidth vs.
Supply Voltage R1 = R2 = 500 Ω
Figure 4. Noninverting Input Voltage
Swing vs. Supply Voltage
Figure 7. Inverting Input Bias Current (IBN) and Noninverting Input
Bias Current (IBP) vs. Temperature
S
Figure 2. Harmonic Distortion
vs. Frequency, R1 = R2 = 1 kΩ
Figure 5. Output Voltage Swing
vs. Supply Voltage
Figure 8. Output Impedance vs.
Frequency, Gain = –1, R1 = R2 = 1 kΩ
–4–
Figure 3. Transresistance
vs. Temperature
Figure 6. Quiescent Supply Current
vs. Temperature and Supply Voltage
Figure 9. –3 dB Bandwidth vs.
Temperature, Gain = –1,
R1 = R2 = 1 kΩ
REV. C
AD844
Inverting Gain of 1 AC Characteristics
Figure 10. Inverting Amplifier,
Gain of –1 (R1 = R2)
Figure 11. Gain vs. Frequency for
Gain = –1, RL = 500 Ω, CL = 0 pF
Figure 13. Large Signal Pulse
Response, Gain = –1, R1 = R2 = 1 kΩ
Figure 12. Phase vs. Frequency
Gain = –1, RL = 500 Ω, CL = 0 pF
Figure 14. Small Signal Pulse
Response, Gain = –1, R1 = R2 = 1 kΩ
Inverting Gain of 10 AC Characteristics
Figure 15. Gain of –10 Amplifier
REV. C
Figure 16. Gain vs. Frequency,
Gain = –10
–5–
Figure 17. Phase vs. Frequency,
Gain = –10
AD844
Inverting Gain of 10 Pulse Response
Figure 19. Small Signal Pulse
Response, Gain = –10, RL = 500 Ω
Figure 18. Large Signal Pulse
Response, Gain = –10, RL = 500 Ω
Noninverting Gain of 10 AC Characteristics
Figure 20. Noninverting Gain of
+10 Amplifier
Figure 21. Gain vs. Frequency,
Gain = +10
Figure 23. Noninverting Amplifier Large Signal
Pulse Response, Gain = +10, RL = 500 Ω
Figure 22. Phase vs. Frequency,
Gain = +10
Figure 24. Small Signal Pulse
Response, Gain = +10, RL = 500 Ω
–6–
REV. C
AD844
UNDERSTANDING THE AD844
The closed loop transresistance is simply the parallel sum of R1
and Rt. Since R1 will generally be in the range 500 Ω to 2 kΩ
and Rt is about 3 MΩ the closed loop transresistance will be
only 0.02% to 0.07% lower than R1. This small error will often
be less than the resistor tolerance.
The AD844 can be used in ways similar to a conventional op
amp while providing performance advantages in wideband applications. However, there are important differences in the internal structure which need to be understood in order to optimize
the performance of the AD844 op amp.
When R1 is fairly large (above 5 kΩ) but still much less than
Rt, the closed loop HF response is dominated by the time constant R1Ct. Under such conditions the AD844 is over-damped
and will provide only a fraction of its bandwidth potential. Because of the absence of slew rate limitations under these conditions, the circuit will exhibit a simple single pole response even
under large signal conditions.
Open Loop Behavior
Figure 25 shows a current feedback amplifier reduced to essentials. Sources of fixed dc errors such as the inverting node bias
current and the offset voltage are excluded from this model and
are discussed later. The most important parameter limiting the
dc gain is the transresistance, Rt, which is ideally infinite. A finite value of Rt is analogous to the finite open loop voltage gain
in a conventional op amp.
In Figure 26, R3 is used to properly terminate the input if desired. R3 in parallel with R2 gives the terminated resistance. As
R1 is lowered, the signal bandwidth increases, but the time
constant R1Ct becomes comparable to higher order poles in the
closed loop response. Therefore, the closed loop response becomes complex, and the pulse response shows overshoot. When
R2 is much larger than the input resistance, RIN, at Pin 2, most
of the feedback current in R1 is delivered to this input; but as
R2 becomes comparable to RIN, less of the feedback is absorbed
at Pin 2, resulting in a more heavily damped response. Consequently, for low values of R2 it is possible to lower R1 without
causing instability in the closed loop response. Table I lists
combinations of R1 and R2 and the resulting frequency response for the circuit of Figure 26. Figure 13 shows the very
clean and fast ± 10 V pulse response of the AD844.
The current applied to the inverting input node is replicated by
the current conveyor so as to flow in resistor Rt. The voltage
developed across Rt is buffered by the unity gain voltage follower.
Voltage gain is the ratio Rt/ RIN. With typical values of Rt = 3 MΩ
and RIN = 50 Ω, the voltage gain is about 60,000. The open loop
current gain is another measure of gain and is determined by the
beta product of the transistors in the voltage follower stage (see
Figure 28); it is typically 40,000.
Figure 25. Equivalent Schematic
The important parameters defining ac behavior are the transcapacitance, Ct, and the external feedback resistor (not shown).
The time constant formed by these components is analogous to
the dominant pole of a conventional op amp, and thus cannot
be reduced below a critical value if the closed loop system is to
be stable. In practice, Ct is held to as low a value as possible
(typically 4.5 pF) so that the feedback resistor can be maximized
while maintaining a fast response. The finite RIN also affects the
closed loop response in some applications as will be shown.
Figure 26. Inverting Amplifier
Table I.
The open loop ac gain is also best understood in terms of the
transimpedance rather than as an open loop voltage gain. The
open loop pole is formed by Rt in parallel with Ct. Since Ct is
typically 4.5 pF, the open loop corner frequency occurs at about
12 kHz. However, this parameter is of little value in determining
the closed loop response.
Response as an Inverting Amplifier
Figure 26 shows the connections for an inverting amplifier. Unlike a conventional amplifier the transient response and the
small signal bandwidth are determined primarily by the value of
the external feedback resistor, R1, rather than by the ratio of
R1/R2 as is customarily the case in an op amp application. This
is a direct result of the low impedance at the inverting input. As
with conventional op amps, the closed loop gain is –R1/R2.
REV. C
–7–
Gain
R1
R2
BW (MHz)
GBW (MHz)
–1
–1
–2
–2
–5
–5
–10
–10
–20
–100
+100
1 kΩ
500 Ω
2 kΩ
1 kΩ
5 kΩ
500 Ω
1 kΩ
500 Ω
1 kΩ
5 kΩ
5 kΩ
1 kΩ
500 Ω
1 kΩ
500 Ω
1 kΩ
100 Ω
100 Ω
50 Ω
50 Ω
50 Ω
50 Ω
35
60
15
30
5.2
49
23
33
21
3.2
9
35
60
30
60
26
245
230
330
420
320
900
AD844
Response as an I-V Converter
The AD844 works well as the active element in an operational
current to voltage converter, used in conjunction with an external scaling resistor, R1, in Figure 27. This analysis includes the
stray capacitance, CS, of the current source, which might be a
high speed DAC. Using a conventional op amp, this capacitance forms a “nuisance pole” with R1 which destabilizes the
closed loop response of the system. Most op amps are internally compensated for the fastest response at unity gain, so the
pole due to R1 and CS reduces the already narrow phase margin
of the system. For example, if R1 were 2.5 kΩ a CS of 15 pF
would place this pole at a frequency of about 4 MHz, well
within the response range of even a medium speed operational
amplifier. In a current feedback amp this nuisance pole is no
longer determined by R1 but by the input resistance, RIN. Since
this is about 50 Ω for the AD844, the same 15 pF forms a pole
212 MHz and causes little trouble. It can be shown that the
response of this system is:
VOUT = – Isig
K R1
(1 + sTd )(1 + sTn )
where K is a factor very close to unity and represents the finite
dc gain of the amplifier, Td is the dominant pole and Tn is the
nuisance pole:
K =
Rt
Rt + R1
Td = KR1Ct
Tn = RINCS
age, ensured by the close matching of like polarity transistors
operating under essentially identical bias conditions. Laser trimming nulls the residual offset voltage, down to a few tens of microvolts. The inverting input is the common emitter node of a
complementary pair of grounded base stages and behaves as a
current summing node. In an ideal current feedback op amp the
input resistance would be zero. In the AD844 it is about 50 Ω.
(assuming RIN << R1)
Using typical values of R1 = 1 kΩ and Rt = 3 MΩ, K is 0.9997;
in other words, the “gain error” is only 0.03%. This is much
less than the scaling error of virtually all DACs and can be
absorbed, if necessary, by the trim needed in a precise system.
In the AD844, Rt is fairly stable with temperature and supply
voltages, and consequently the effect of finite “gain” is negligible unless high value feedback resistors are used. Since that
would result in slower response times than are possible, the
relatively low value of Rt in the AD844 will rarely be a significant source of error.
Figure 27. Current to Voltage Converter
Circuit Description of the AD844
A simplified schematic is shown in Figure 28. The AD844 differs from a conventional op amp in that the signal inputs have
radically different impedance. The noninverting input (Pin 3)
presents the usual high impedance. The voltage on this input is
transferred to the inverting input (Pin 2) with a low offset volt-
Figure 28. Simplified Schematic
A current applied to the inverting input is transferred to a
complementary pair of unity-gain current mirrors which deliver
the same current to an internal node (Pin 5) at which the full
output voltage is generated. The unity-gain complementary voltage follower then buffers this voltage and provides the load driving power. This buffer is designed to drive low impedance loads
such as terminated cables, and can deliver ± 50 mA into a 50 Ω
load while maintaining low distortion, even when operating at
supply voltages of only ± 6 V. Current limiting (not shown) ensures safe operation under short circuited conditions.
It is important to understand that the low input impedance at
the inverting input is locally generated, and does not depend on
feedback. This is very different from the “virtual ground” of a
conventional operational amplifier used in the current summing
mode which is essentially an open circuit until the loop settles.
In the AD844, transient current at the input does not cause
voltage spikes at the summing node while the amplifier is settling. Furthermore, all of the transient current is delivered to the
slewing (TZ) node (Pin 5) via a short signal path (the grounded
base stages and the wideband current mirrors).
The current available to charge the capacitance (about 4.5 pF)
at TZ node, is always proportional to the input error current, and
the slew rate limitations associated with the large signal response
of op amps do not occur. For this reason, the rise and fall times
are almost independent of signal level. In practice, the input
current will eventually cause the mirrors to saturate. When using
± 15 V supplies, this occurs at about 10 mA (or ± 2200 V/µs).
Since signal currents are rarely this large, classical “slew rate”
limitations are absent.
This inherent advantage would be lost if the voltage follower
used to buffer the output were to have slew rate limitations. The
AD844 has been designed to avoid this problem, and as a result
the output buffer exhibits a clean large signal transient response,
free from anomalous effects arising from internal saturation.
–8–
REV. C
Applying the AD844
Response as a Noninverting Amplifier
Since current feedback amplifiers are asymmetrical with regard
to their two inputs, performance will differ markedly in noninverting and inverting modes. In noninverting modes, the large
signal high speed behavior of the AD844 deteriorates at low
gains because the biasing circuitry for the input system (not
shown in Figure 28) is not designed to provide high input voltage slew rates.
However, good results can be obtained with some care. The
noninverting input will not tolerate a large transient input; it
must be kept below ±1 V for best results. Consequently this mode
is better suited to high gain applications (greater than ×10).
Figure 20 shows a noninverting amplifier with a gain of 10 and a
bandwidth of 30 MHz. The transient response is shown in Figures 23 and 24. To increase the bandwidth at higher gains, a capacitor can be added across R2 whose value is approximately the
ratio of R1 and R2 times Ct.
Figure 30. AC Response for Gain = 100, Configuration
Shown in Figure 29
USING THE AD844
Board Layout
As with all high frequency circuits considerable care must be
used in the layout of the components surrounding the AD844.
A ground plane, to which the power supply decoupling capacitors are connected by the shortest possible leads, is essential
to achieving clean pulse response. Even a continuous ground
plane will exhibit finite voltage drops between points on the
plane, and this must be kept in mind in selecting the grounding
points. Generally speaking, decoupling capacitors should be
taken to a point close to the load (or output connector) since
the load currents flow in these capacitors at high frequencies.
The +In and –In circuits (for example, a termination resistor
and Pin 3) must be taken to a common point on the ground
plane close to the amplifier package.
Use low impedance capacitors (AVX SR305C224KAA or
equivalent) of 0.22 µF wherever ac coupling is required. Include
either ferrite beads and/or a small series resistance (approximately 4.7 Ω) in each supply line.
Figure 29. Noninverting Amplifier Gain = 100, Optional
Offset Trim Is Shown
Noninverting Gain of 100
Input Impedance
The AD844 provides very clean pulse response at high noninverting gains. Figure 29 shows a typical configuration providing
a gain of 100 with high input resistance. The feedback resistor is
kept as low as practicable to maximize bandwidth, and a peaking
capacitor (CPK) can optionally be added to further extend the
bandwidth. Figure 30 shows the small signal response with
CPK = 3 nF, RL = 500 Ω and supply voltages of either ± 5 V or
± 15 V. Gain bandwidth products of up to 900 MHz can be achieved
in this way.
At low frequencies, negative feedback keeps the resistance at the
inverting input close to zero. As the frequency increases, the impedance looking into this input will increase from near zero to
the open loop input resistance, due to bandwidth limitations,
making the input seem inductive. If it is desired to keep the input impedance flatter, a series RC network can be inserted
across the input. The resistor is chosen so that the parallel sum
of it and R2 equals the desired termination resistance. The capacitance is set so that the pole determined by this RC network
is about half the bandwidth of the op amp. This network is not
important if the input resistor is much larger than the termination used, or if frequencies are relatively low. In some cases, the
small peaking that occurs without the network can be of use in
extending the –3 dB bandwidth.
The offset voltage of the AD844 is laser trimmed to the 50 µV
level and exhibits very low drift. In practice, there is an additional offset term due to the bias current at the inverting input
(IBN) which flows in the feedback resistor (R1). This can optionally be nulled by the trimming potentiometer shown in Figure 29.
REV. C
–9–
AD844
Driving Large Capacitive Loads
Capacitive drive capability is 100 pF without an external network. With the addition of the network shown in Figure 31, the
capacitive drive can be extended to over 10,000 pF, limited by
internal power dissipation. With capacitive loads, the output
speed becomes a function of the overdriven output current
limit. Since this is roughly ± 100 mA, under these conditions,
the maximum slew rate into a 1000 pF load is ± 100 V/µs. Figure 32 shows the transient response of an inverting amplifier
(R1 = R2 = 1 kΩ) using the feed forward network shown in
Figure 31, driving a load of 1000 pF.
Figure 33. Settling Time Test Fixture
DC Error Calculation
Figure 31. Feed Forward Network for Large Capacitive
Loads
Figure 34 shows a model of the dc error and noise sources for
the AD844. The inverting input bias current, IBN, flows in the
feedback resistor. IBP, the noninverting input bias current, flows
in the resistance at Pin 3 (RP), and the resulting voltage (plus
any offset voltage) will appear at the inverting input. The total
error, VO, at the output is:

R1 
VO = (IBP RP + VOS + IBN RIN )1 +
 + I BN R1

R2 
Since IBN and IBP are unrelated both in sign and magnitude, inserting a resistor in series with the noninverting input will not
necessarily reduce dc error and may actually increase it.
Figure 32. Driving 1000 pF CL with Feed Forward Network
of Figure 31
Settling Time
Settling time is measured with the circuit of Figure 33. This circuit employs a false summing node, clamped by the two
Schottky diodes, to create the error signal and limit the input
signal to the oscilloscope. For measuring settling time, the ratio
of R6/R5 is equal to R1/R2. For unity gain, R6 = R5 = 1 kΩ,
and RL = 500 Ω. For the gain of –10, R5 = 50 Ω, R6 = 500 Ω
and RL was not used since the summing network loads the output with approximately 275 Ω. Using this network in a unitygain configuration, settling time is 100 ns to 0.1% for a –5 V to
+5 V step with CL = 10 pF.
Figure 34. Offset Voltage and Noise Model for the AD844
Noise
Noise sources can be modeled in a manner similar to the dc bias
currents, but the noise sources are Inn, Inp, Vn, and the
amplifier induced noise at the output, VON, is:
2
R1 
2
2 
2
VON = ((Inp RP ) + Vn )1 +
 + (Inn R1)
R2 

Overall noise can be reduced by keeping all resistor values to a
minimum. With typical numbers, R1 = R2 = 1k, RP = 0, Vn =
2 nV/√Hz, Inp = 10 pA/√Hz, Inn = 12 pA/√Hz, VON calculates
to 12 nV/√Hz. The current noise is dominant in this case, as it
will be in most low gain applications.
–10–
REV. C
Applications–AD844
Video Cable Driver Using ± 5 Volt Supplies
load. The –3 dB bandwidth of this circuit is typically 30 MHz.
Figure 35b shows a differential gain and phase test setup. In
video applications, differential-phase and differential-gain
characteristics are often important. Figure 35c shows the variation in phase as the load voltage varies. Figure 35d shows the
gain variation.
The AD844 can be used to drive low impedance cables. Using
± 5 V supplies, a 100 Ω load can be driven to ± 2.5 V with low
distortion. Figure 35a shows an illustrative application which
provides a noninverting gain of 2, allowing the cable to be
reverse-terminated while delivering an overall gain of +1 to the
Figure 35a. The AD844 as a Cable Driver
Figure 35b. Differential Gain/Phase Test Setup
Figure 35c. Differential Phase for the Circuit of Figure 35a
Figure 35d. Differential Gain for the Circuit of Figure 35a
High Speed DAC Buffer
The AD844 performs very well in applications requiring
current-to-voltage conversion. Figure 36 shows connections for
use with the AD568 current output DAC. In this application
the bipolar offset is used so that the full-scale current is
± 5.12 mA, which generates an output of ± 5.12 V using the
1 kΩ application resistor on the AD568. Figure 37 shows the
full-scale transient response. Care is needed in power supply
decoupling and grounding techniques to achieve the full 12-bit
accuracy and realize the fast settling capabilities of the system.
The unmarked capacitors in this figure are 0.1 µF ceramic (for
example, AVX Type SR305C104KAA), and the ferrite inductors should be about 2.5 µH (for example, Fair-Rite Type
2743002122). The AD568 data sheet should be consulted for
more complete details about its use.
Figure 36. High Speed DAC Amplifier
REV. C
Figure 37. DAC Amplifier Full-Scale Transient Response
–11–
20 MHz Variable Gain Amplifier
The AD844 is an excellent choice as an output amplifier for the
AD539 multiplier, in all of its connection modes. (See AD539
data sheet for full details.) Figure 38 shows a simple multiplier
providing the output:
VW = –
VX VY
2V
where VX is the “gain control” input, a positive voltage of from
0 V to +3.2 V (max) and VY is the “signal voltage”, nominally
± 2 V FS but capable of operation up to ± 4.2 V. The peak output in this configuration is thus ± 6.7 V. Using all four of the
internal application resistors provided on the AD539 in parallel
results in a feedback resistance of 1.5 kΩ, at which value the
bandwidth of the AD844 is about 22 MHz, and is essentially independent of VX. The gain at VX = 3.16 V is +4 dB.
Figure 38. 20 MHz VGA Using the AD539
Figure 39 shows the small signal response for a 50 dB gain control range (VX = +10 mV to +3.16 V). At small values of VX,
capacitive feedthrough on the PC board becomes troublesome,
and very careful layout techniques are needed to minimize this
problem. A ground strip between the pins of the AD539 will be
helpful in this regard. Figure 40 shows the response to a 2 V
pulse on VY for VX = +1 V, +2 V and +3 V. For these results, a
load resistor of 500 Ω was used and the supplies were ± 9 V.
The multiplier will operate from supplies between ± 4.5 V and
± 16.5 V.
Disconnecting Pins 9 and 16 on the AD539 alters the denominator in the above expression to 1 V, and the bandwidth will be
approximately 10 MHz, with a maximum gain of 10 dB. Using
only Pin 9 or Pin 16 results in a denominator of 0.5 V, a bandwidth of 5 MHz and a maximum gain of 16 dB.
Figure 39. VGA AC Response
C1258b–5–9/90
AD844
Figure 40. VGA Transient
Response with VX = 1 V, 2 V, and 3 V
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
Cerdip (Q) Package
16-Pin SOIC (R) Package
PRINTED IN U.S.A.
Mini-DIP (N) Package
–12–
REV. C