MAX9637AXA+T Maxim Integrated Products, MAX9637AXA+T Datasheet - Page 10

MAX9637AXA+T

Manufacturer Part Number

MAX9637AXA+T

Description

Op Amps 3V-5V Low-Power Op Amp

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX9637AXAT.pdf (16 pages)

Specifications of MAX9637AXA+T

Number Of Channels

Common Mode Rejection Ratio (min)

58 dB

Input Voltage Range (max)

5.5 V

Input Voltage Range (min)

2.1 V

Input Offset Voltage

3.5 mV

Output Voltage

0.04 V

Operating Supply Voltage

2.1 V to 5 V

Supply Current

36 uA

Maximum Power Dissipation

245 mW

Maximum Operating Temperature

+ 125 C

Mounting Style

SMD/SMT

Package / Case

SC-70-8

Lead Free Status / Rohs Status

Details

Current page: 10 of 16
Download datasheet (3Mb)

Figure 1. Using a Series Resistor to Isolate the Capacitive

Load from the Op Amp

3V/5V Low-Power, Low-Noise, CMOS,

Rail-to-Rail I/O Op Amps

The ICs have a high tolerance for capacitive loads.

In unity-gain configuration, the op amps can typically

drive up to 300pF pure capacitive load. Increasing the

gain enhances the amplifier’s ability to drive greater

capacitive loads. In unity-gain configurations, capacitive

load drive can be improved by inserting a small (5I to

30I) isolation resistor, R

as shown in Figure 1. This significantly reduces ringing

while maintaining DC performance for purely capaci-

tive loads. However, if the load also has a resistive

component then a voltage-divider is created, introduc-

ing a direct current (DC) error at the output. The error

introduced is proportional to the ratio RISO/RL, which

is usually negligible in most cases. Applications that

cannot tolerate this slight DC error can use an alterna-

tive approach of providing stability by placing a suitable

resistance in parallel with the capacitive load as shown

in Figure 2 (see the Typical Operating Characteristics

section for graphs of the stable operating region for

various capacitive loads vs. resistive loads). While this

approach of adding a resistor parallel to the load does

not introduce DC error, it nevertheless reduces the out-

put swing proportionally.

Figure 3. The MAX9636 in a Sensor Preamp Configuration

MAX9636/

MAX9637/

MAX9638

PHOTODIODE

Driving Capacitive Loads

+ R

ISO

, in series with the output,

≈ 1V/V

ISO

REF

IN+

IN-

MAX9636

OUT

Figure 2. Using a Parallel Resistor to Degenerate the Effect of

the Capacitive Load and Increase Stability

The ICs interface to both current-output sensors, such

as photodiodes (Figure 3), and high-impedance voltage

sources, such as piezoelectric sensors. For current-

output sensors, a transimpedance amplifier is the most

noise-efficient method for converting the input signal to

a voltage. High-value feedback resistors are commonly

chosen to create large gains, while feedback capacitors

help stabilize the amplifier by cancelling any poles intro-

duced in the feedback function by the highly capacitive

sensor or cabling. A combination of low-current noise

and low-voltage noise is important for these applications.

Take care to calibrate out photodiode dark current if DC

accuracy is important. The high bandwidth and slew

rate also allows AC signal processing in certain medical

photodiode sensor applications such as pulse oximetry.

For voltage-output sensors, a noninverting amplifier is

typically used to buffer and/or apply a small gain to the

input voltage signal. Due to the extremely high imped-

ance of the sensor output, a low input bias current with

minimal temperature variation is very important for these

applications.

CONDITIONING/

MAX9636/

MAX9637/

FILTERS

MAX9638

SIGNAL

MAX1286

Sensor Front-Ends

ADC

High-Impedance

MAX9637AXA+T Maxim Integrated Products, MAX9637AXA+T Datasheet - Page 10

MAX9637AXA+T

Specifications of MAX9637AXA+T

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