LMC7101_05 MICREL [Micrel Semiconductor], LMC7101_05 Datasheet - Page 9

LMC7101_05

Manufacturer Part Number

LMC7101_05

Description

Low-Power Operational Amplifier

Manufacturer

MICREL [Micrel Semiconductor]

Datasheet

1.LMC7101_05.pdf (12 pages)

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Application Information

Input Common-Mode Voltage

Some amplifiers exhibit undesirable or unpredictable perfor-

mance when the inputs are driven beyond the common-mode

voltage range, for example, phase inversion of the output

signal. The LMC7101 tolerates input overdrive by at least

200mV beyond either rail without producing phase inversion.

If the absolute maximum input voltage (700mV beyond either

rail) is exceeded, the input current should be limited to ±5mA

maximum to prevent reducing reliability. A 10kΩ series input

resistor, used as a current limiter, will protect the input

structure from voltages as large as 50V above the supply or

below ground. See Figure 1.

Output Voltage Swing

Sink and source output resistances of the LMC7101 are

equal. Maximum output voltage swing is determined by the

load and the approximate output resistance. The output

resistance is:

stage. V

(output swing) portion of the appropriate Electrical Character-

istics table. I

minus V+/2 and divided by R

Electrical Characteristics DC (5V) table, the typical output

high voltage using a 2kΩ load (connected to V+/2) is 4.989V,

which produces an I

Voltage drop in the amplifier output stage is:

Because of output stage symmetry, the corresponding typical

output low voltage (0.011V) also equals V

February 2005

LMC7101

DROP

1 245

DROP

OUT

is the voltage dropped within the amplifier output

Figure 1. Input Current-Limit Protection

DROP

LOAD

= 5.0V – 4.989V

= 0.011V

and I







10kΩ

LOAD

4 989

is equal to the typical output high voltage

DROP

LOAD

V –

can be determined from the V

Ω

LOAD

2 5

. For example, using the



 =



1 245

DROP

OUT

. Then:

Driving Capacitive Loads

Driving a capacitive load introduces phase-lag into the output

signal, and this in turn reduces op-amp system phase margin.

The application that is least forgiving of reduced phase

margin is a unity gain amplifier. The LMC7101 can typically

drive a 100pF capacitive load connected directly to the output

when configured as a unity-gain amplifier.

Using Large-Value Feedback Resistors

A large-value feedback resistor (> 500kΩ) can reduce the

phase margin of a system. This occurs when the feedback

resistor acts in conjunction with input capacitance to create

phase lag in the fedback signal. Input capacitance is usually

a combination of input circuit components and other parasitic

capacitance, such as amplifier input capacitance and stray

printed circuit board capacitance.

Figure 2 illustrates a method of compensating phase lag

caused by using a large-value feedback resistor. Feedback

capacitor C

the phase lag caused by feedback resistor R

capacitance C

estimating C

Since a significant percentage of C

layout, it is important to note that the correct value of C

change when changing from a breadboard to the final circuit

layout.

Figure 2. Cancelling Feedback Phase Lag

OUT

introduces sufficient phase lead to overcome

and then applying the following formula:

0 001245

. The value of C

≤

0 011

8 8

may be caused by board

≈

is determined by first

Ω

OUT

Micrel, Inc.

LMC7101

and input

may

LMC7101_05 MICREL [Micrel Semiconductor], LMC7101_05 Datasheet - Page 9

LMC7101_05

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