AN-940 Datasheet, PDF(1/12 Page) Analog Devices – Low Noise Amplifier Selection Guide for Optimal Noise Performance

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AN-940 Datasheet, PDF (1/12 Pages) Analog Devices – Low Noise Amplifier Selection Guide for Optimal Noise Performance

AN-940

APPLICATION NOTE

One Technology Way â¢ P.O. Box 9106 â¢ Norwood, MA 02062-9106, U.S.A. â¢ Tel: 781.329.4700 â¢ Fax: 781.461.3113 â¢ www.analog.com

Low Noise Amplifier Selection Guide for Optimal Noise Performance

by Paul Lee

INTRODUCTION

When evaluating an amplifierâs performance for a low noise

application, both internal and external noise sources must be

considered. This application note briefly discusses the funda-

mentals of both internal and external noise and identifies the

tradeoffs associated in selecting the optimal amplifier for low

noise design.

EXTERNAL NOISE SOURCES

External noise includes any type of external influences, such

as external components and electrical/electromagnetic interfer-

ence. Interference is defined as any unwanted signals arriving

as either voltage or current, at any of the amplifierâs terminals

or induced in its associated circuitry. It can appear as spikes,

steps, sine waves, or random noise. Interference can come from

anywhere: machinery, nearby power lines, RF transmitters or

receivers, computers, or even circuitry within the same equip-

ment (that is, digital circuits or switching-type power supplies).

If all interference is eliminated by careful design and/or layout

of the board, there can still be random noise associated with the

amplifier and its circuit components.

Noise from surrounding circuit components must be accounted

for. At temperatures above absolute zero, all resistances act as

noise sources due to thermal movement of charge carriers called

Johnson noise or thermal noise. This noise increases with resis-

tance, temperature, and bandwidth. Voltage noise is shown in

Equation 1.

Vn ï½ 4kTBR

(1)

where:

Vn is voltage noise.

k is Boltzmannâs constant (1.38 Ã 10â23 J/K).

T is the temperature in Kelvin (K).

B is the bandwidth in hertz (Hz).

Current noise (noise associated with current flow) is shown in

Equation 2

In ï½

4kTB

(2)

where:

In is current noise.

k is Boltzmannâs constant (1.38 Ã 10â23 J/K).

T is the temperature in Kelvin (K).

B is the bandwidth in hertz (Hz).

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