AD8603AUJZ-R2 Analog Devices Inc, AD8603AUJZ-R2 Datasheet - Page 13
AD8603AUJZ-R2
Manufacturer Part Number
AD8603AUJZ-R2
Description
IC OPAMP GP R-R CMOS TSOT23-5
Manufacturer
Analog Devices Inc
Datasheet
1.AD8607ARMZ-REEL.pdf
(16 pages)
Specifications of AD8603AUJZ-R2
Slew Rate
0.1 V/µs
Design Resources
Generating a Negative Precision Voltage Reference Without Precision Resistors (CN0005) High Precision, Low Cost Current Sources Using AD8276 and AD8603 (CN0099) Measuring -48 V High-Side Current Using AD629, AD8603, AD780, and AD7453 (CN0100)
Amplifier Type
General Purpose
Number Of Circuits
1
Output Type
Rail-to-Rail
Gain Bandwidth Product
400kHz
Current - Input Bias
0.2pA
Voltage - Input Offset
12µV
Current - Supply
40µA
Current - Output / Channel
70mA
Voltage - Supply, Single/dual (±)
1.8 V ~ 5 V, ±0.9 V ~ 2.5 V
Operating Temperature
-40°C ~ 125°C
Mounting Type
Surface Mount
Package / Case
TSOT-23-5, TSOT-5, TSOP-5
Op Amp Type
Precision
No. Of Amplifiers
1
Bandwidth
400kHz
Supply Voltage Range
1.8V To 5V
Amplifier Case Style
TSOT-23
No. Of Pins
5
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
-3db Bandwidth
-
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
Other names
AD8603AUJZ-R2TR
PROXIMITY SENSORS
Proximity sensors can be capacitive or inductive and are used in
a variety of applications. One of the most common applications
is liquid level sensing in tanks. This is particularly popular in
pharmaceutical environments where a tank must know when to
stop filling or mixing a given liquid. In aerospace applications,
these sensors detect the level of oxygen used to propel engines.
Whether in a combustible environment or not, capacitive
sensors generally use low voltage. The precision and low voltage
of the AD8603/AD8607/AD8609 make the parts an excellent
choice for such applications.
COMPOSITE AMPLIFIERS
A composite amplifier can provide a very high gain in applications
where high closed-loop dc gains are needed. The high gain
achieved by the composite amplifier comes at the expense of a
loss in phase margin. Placing a small capacitor, C
in parallel with R2 (see Figure 45) improves the phase margin.
Picking C
values shown in Figure 45.
A composite amplifier can be used to optimize dc and ac
characteristics. Figure 46 shows an example using the AD8603
and the AD8541. This circuit offers many advantages. The band-
width is increased substantially, and the input offset voltage and
noise of the AD8541 become insignificant because they are divided
by the high gain of the AD8603.
The circuit in Figure 46 offers high bandwidth (nearly double
that of the AD8603), high output current, and very low power
consumption of less than 100 μA.
V
IN
F
= 50 pF yields a phase margin of about 45° for the
1kΩ
Figure 46. Low Power Composite Amplifier
R1
Figure 45. High Gain Composite Amplifier
1kΩ
R1
V
IN
V+
V–
AD8603
V
EE
V+
V
–
V
V
V
EE
CC
CC
AD8603
99kΩ
C
R2
F
1kΩ
R3
1kΩ
C2
R3
V
V
CC
EE
99kΩ
V+
V
R4
V
V
–
CC
EE
U5
100kΩ
V+
V
–
R2
AD8541
AD8541
F
, in the feedback
100Ω
R4
C3
Rev. C | Page 13 of 16
BATTERY-POWERED APPLICATIONS
The AD8603/AD8607/AD8609 are ideal for battery-powered
applications. The parts are tested at 5 V, 3.3 V, 2.7 V, and 1.8 V
and are suitable for various applications whether in single or
dual supply.
In addition to their low offset voltage and low input bias, the
AD8603/AD8607/AD8609 have a very low supply current of
40 μA, making the parts an excellent choice for portable electronics.
The TSOT package allows the AD8603 to be used on smaller
board spaces.
PHOTODIODES
Photodiodes have a wide range of applications from barcode
scanners to precision light meters and CAT scanners. The very
low noise and low input bias current of the AD8603/AD8607/
AD8609 make the parts very attractive amplifiers for I-V
conversion applications.
Figure 47 shows a simple photodiode circuit. The feedback
capacitor helps the circuit maintain stability. The signal band-
width can be increased at the expense of an increase in the total
noise; a low-pass filter can be implemented by a simple RC network
at the output to reduce the noise. The signal bandwidth can be
calculated by ½πR2C2, and the closed-loop bandwidth is the
intersection point of the open-loop gain and the noise gain.
The circuit shown in Figure 47 has a closed-loop bandwidth of
58 kHz and a signal bandwidth of 16 Hz. Increasing C2 to 50 pF
yields a closed-loop bandwidth of 65 kHz, but only 3.2 Hz of
signal bandwidth can be achieved.
1000MΩ
R1
Figure 47. Photodiode Circuit
10pF
C1
AD8603/AD8607/AD8609
V–
V+
AD8603
1000MΩ
V
V
10pF
EE
CC
C2
R2
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