MAX412CSA-T Maxim Integrated Products, MAX412CSA-T Datasheet - Page 9

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MAX412CSA-T

Manufacturer Part Number
MAX412CSA-T
Description
Op Amps Dual 28MHz Low-V Low-Noise Precision
Manufacturer
Maxim Integrated Products
Datasheet

Specifications of MAX412CSA-T

Number Of Channels
2
Voltage Gain Db
122 dB
Common Mode Rejection Ratio (min)
115 dB
Input Offset Voltage
0.25 mV
Operating Supply Voltage
5 V or 9 V
Supply Current
5.4 mA
Maximum Power Dissipation
471 mW
Maximum Operating Temperature
+ 70 C
Mounting Style
SMD/SMT
Package / Case
SOIC-8 Narrow
Maximum Dual Supply Voltage
+/- 5.25 V
Minimum Operating Temperature
0 C
Figure 5. Current-Noise Test Circuit
Tech measures input-referred noise. For the circuit in
Figure
and the measurement is taken with the Quan Tech
model 5173, the equation simplifies to:
To protect amplifier inputs from excessive differential
input voltages, most modern op amps contain input
protection diodes and current-limiting resistors. These
resistors increase the amplifier’s input-referred noise.
They have not been included in the MAX410/MAX412/
MAX414, to optimize noise performance. The MAX410/
MAX412/MAX414 do contain back-to-back input pro-
tection diodes which will protect the amplifier for differ-
ential input voltages of ±0.1V. If the amplifier must be
protected from higher differential input voltages, add
external current-limiting resistors in series with the op
amp inputs to limit the potential input current to less
than 20mA.
Driving large capacitive loads increases the likelihood
of oscillation in amplifier circuits. This is especially true
for circuits with high loop gains, like voltage followers.
The output impedance of the amplifier and a capacitive
load form an RC network that adds a pole to the loop
response. If the pole frequency is low enough, as when
driving a large capacitive load, the circuit phase mar-
gin is degraded.
In voltage follower circuits, the MAX410/MAX412/
MAX414 remain stable while driving capacitive loads
as great as 3900pF (see
100Ω
i
n
5, assuming R
=
e
no
10kΩ
10kΩ
2
R
R
-
n
p
[
_______________________________________________________________________________________
(1.64 10
(20 10 )
909Ω
p
+5V
×
-5V
Capacitive-Load Driving
Figures 6a and
is approximately equal to R
D.U.T
×
Single/Dual/Quad, 28MHz, Low-Noise,
-20
3
)(20 10 )
0.022µF
0.022µF
Input Protection
×
Low-Voltage, Precision Op Amps
3
6b).
MAX410
MAX412
MAX414
]
A
/
e
no
Hz
n
When driving capacitive loads greater than 3900pF,
add an output isolation resistor to the voltage follower
circuit, as shown in
load capacitance from the amplifier output and restores
the phase margin.
response of a MAX410/MAX412/MAX414 driving a
0.015µF load with a 10Ω isolation resistor
The capacitive-load driving performance of the
MAX410/MAX412/MAX414 is plotted for closed-loop
gains of -1V/V and -10V/V in the % Overshoot vs.
Capacitive Load graph in the Typical Operating
Characteristics.
Feedback around the isolation resistor RI increases the
accuracy at the capacitively loaded output (see
The MAX410/MAX412/MAX414 are stable with a 0.01µF
load for the values of R
decreased closed-loop gain, increase R
larger capacitive loads, increase the value of C
Figure 6a. Voltage Follower Circuit with 3900pF Load
Figure 6b. Driving 3900pF Load as Shown in Figure 6a
OUTPUT
INPUT
1V/div
1V/div
V
IN
D.U.T
Figure
Figure 7b
499Ω
R
I
f
and C
1µs/div
7a. This resistor isolates the
is a photograph of the
F
shown. In general, for
MAX410
MAX412
MAX414
V
T
A
S
= ±5V
= +25°C
3900pF
I
or C
V
OUT
GND
GND
F
F
. To drive
.
Figure
8).
9

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