AD844ANZ Analog Devices Inc, AD844ANZ Datasheet - Page 15
AD844ANZ
Manufacturer Part Number
AD844ANZ
Description
IC OPAMP CF 60MHZ 80MA 8DIP
Manufacturer
Analog Devices Inc
Datasheet
1.AD844ANZ.pdf
(20 pages)
Specifications of AD844ANZ
Slew Rate
2000 V/µs
Amplifier Type
Current Feedback
Number Of Circuits
1
-3db Bandwidth
60MHz
Current - Input Bias
200pA
Voltage - Input Offset
50µV
Current - Supply
6.5mA
Current - Output / Channel
80mA
Voltage - Supply, Single/dual (±)
±4.5 V ~ 18 V
Operating Temperature
-40°C ~ 85°C
Mounting Type
Through Hole
Package / Case
8-DIP (0.300", 7.62mm)
Op Amp Type
High Speed
No. Of Amplifiers
1
Bandwidth
60MHz
Supply Voltage Range
± 4.5V To ± 18V
Amplifier Case Style
DIP
No. Of Pins
8
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Output Type
-
Gain Bandwidth Product
-
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Part Number:
AD844ANZ
Manufacturer:
ADI/亚德诺
Quantity:
20 000
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 capaci-
tors are connected by the shortest possible leads, is essential to
achieving clean pulse response. Even a continuous ground plane
exhibits finite voltage drops between points on the plane, and
this must be kept in mind when selecting the grounding points.
In general, decoupling capacitors should be taken to a point
close to the load (or output connector) because 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 0.22 μF capacitors (AVX SR305C224KAA
or equivalent) wherever ac coupling is required. Include either
ferrite beads and/or a small series resistance (approximately
4.7 Ω) in each supply line.
INPUT IMPEDANCE
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 increases 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 capacit-
ance 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.
DRIVING LARGE CAPACITIVE LOADS
Capacitive drive capability is 100 pF without an external net-
work. With the addition of the network shown in Figure 34,
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.
Because this is roughly ±100 mA, under these conditions, the
maximum slew rate into a 1000 pF load is ±100 V/μs. Figure 35
shows the transient response of an inverting amplifier (R1 =
R2 = 1 kΩ) using the feedforward network shown in Figure 34,
driving a load of 1000 pF.
Rev. F | Page 15 of 20
SETTLING TIME
Settling time is measured with the circuit of Figure 36. 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
R
was not used because the summing network loads the output
with approximately 275 Ω. Using this network in a unity-gain
configuration, settling time is 100 ns to 0.1% for a –5 V to +5 V
step with C
L
= 500 Ω. For the gain of −10, R5 = 50 Ω, R6 = 500 Ω, and R
Figure 35. Driving 1000 pF C
V
NOTES
1. D1, D2 IN6263 OR EQUIVALENT SCHOTTKY DIODE.
IN
100
90
10
Figure 34. Feedforward Network for Large Capacitive Loads
0
AD844
L
= 10 pF.
5V
R3
5
R5
Figure 36. Settling Time Test Fixture
D1
6
750Ω
R2
L
TO SCOPE
(TEK 7A11 FET PROBE)
with Feedforward Network of Figure 34
D2
22pF
500ns
AD844
R6
R1
R
L
C
L
V
OUT
C
V
AD844
L
OUT
L
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