AD548 Analog Devices, AD548 Datasheet - Page 7

AD548

Manufacturer Part Number

AD548

Description

Precision/ Low Power BiFET Op Amp

Manufacturer

Analog Devices

Datasheet

1.AD548.pdf (8 pages)

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Current page: 7 of 8
Download datasheet (199Kb)

PHOTODIODE PREAMP

The performance of the photodiode preamp shown in Figure 27

is enhanced by the AD548’s low input current, input voltage

offset and offset voltage drift. The photodiode sources a current

proportional to the incident light power on its surface. R

the photodiode current to an output voltage equal to R

An error budget illustrating the importance of low amplifier

input current, voltage offset and offset voltage drift to minimize

output voltage errors can be developed by considering the equi-

valent circuit for the small (0.2 mm

Figure 27. The input current results in an error proportional to

the feedback resistance used. The amplifier’s offset will produce

an error proportional to the preamp’s noise gain (I + R

where R

input current will double with every 10 C rise in temperature,

and the photodiode’s shunt resistance halves with every 10 C

rise. The error budget in Figure 28 assumes a room temperature

photodiode R

and input offset voltage specs of an AD548C.

TEMP

–

+25

+50

+75

+85

The capacitance at the amplifier’s negative input (the sum of the

photodiode’s shunt capacitance, the op amp’s differential input

capacitance, stray capacitance due to wiring, etc.) will cause a

rise in the preamp’s noise gain over frequency. This can result in

excess noise over the bandwidth of interest. C

noise gain “peaking” at the expense of bandwidth.

INSTRUMENTATION AMPLIFIER

The AD548C’s maximum input current of 10 pA makes it an

excellent building block for the high input impedance instru-

mentation amplifier shown in Figure 29. Total current drain for

this circuit is under 600 A. This configuration is optimal for

conditioning differential voltages from high impedance sources.

The overall gain of the circuit is controlled by R

the following transfer function:

REV. C

Figure 28. Photo Diode Pre-Amp Errors Over Temperature

15,970

2,830

500

88.5

15.6

7.8

(M )

is the photodiode shunt resistance. The amplifier’s

of 500 M , and the maximum input current

150

200

250

300

350

370

( V) (1+ R

OUT

Figure 27.

151 V

207 V

300 V

640 V

2.6 mV

5.1 mV

) V

area) photodiode shown in

0.30

2.26

10.00

56.6

320

640

)

(pA)

reduces the

, resulting in

30 V

262 V 469 V

1.0 mV 1.30 mV

5.6 mV 6.24 mV

32 mV 34.6 mV

64 mV 69.1 mV

converts

TOTAL

181 V

–7–

Gains of 1 to 100 can be accommodated with gain nonlinearities

of less than 0.01%. Referred to input errors, which contribute

an output error proportional to in amp gain, include a maxi-

mum untrimmed input offset voltage of 0.5 mV and an input

offset voltage drift over temperature of 4 V/ C. Output errors,

which are independent of gain, will contribute an additional

0.5 mV offset and 4 V/ C drift. The maximum input current is

15 pA over the common-mode range, with a common-mode

impedance of over 1 10

should be ratio matched to 0.01% to take full advantage of the

AD548’s high common-mode rejection. Capacitors C1 and C1

compensate for peaking in the gain over frequency caused by

input capacitance when gains of 1 to 3 are used.

The –3 dB small signal bandwidth for this low power instru-

mentation amplifier is 700 kHz for a gain of 1 and 10 kHz for a

gain of 100. The typical output slew rate is 1.8 V/ s.

LOG RATIO AMPLIFIER

Log ratio amplifiers are useful for a variety of signal condition-

ing applications, such as linearizing exponential transducer out-

puts and compressing analog signals having a wide dynamic

range. The AD548’s picoamp level input current and low input

offset voltage make it a good choice for the front-end amplifier

of the log ratio circuit shown in Figure 30. This circuit produces

an output voltage equal to the log base 10 of the ratio of the in-

put currents I

for voltage inputs.

Input currents I

a matched pair of logging transistors. Voltages at points A and

B are developed according to the following familiar diode

equation:

In this equation, k is Boltzmann’s constant, T is absolute tem-

perature, q is an electron charge, and I

current of the logging transistors. The difference of these two

voltages is taken by the subtractor section and scaled by a factor

of approximately 16 by resistors R9, R10, and R8. Temperature

Figure 29. Low Power Instrumentation Amplifier

and I

Application Hints–AD548

. Resistive inputs R1 and R2 are provided

set the collector currents of Q1 and Q2,

(kT/q) ln (I

. Resistor pairs R3/R5 and R4/R6

is the reverse saturation

)

AD548 Analog Devices, AD548 Datasheet - Page 7

AD548

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