Lock in amplifier theory of operation, Mathematical description of a lock in amplifier – Gentec-EO T-Rad (DB-15) User Manual

T-RAD-DB15--USB Instruction Manual

Version 2.1

December. 2012

9

Data Displays

Real time, Strip chart, Tuning, Statistics

User input correction
factors

1 multiplier (transmission adjustment) (7 digits

floating point)

Positive External trigger

4.5 to 10 V @ 20 mA, optically isolated

External trigger pulse
width

80 ms

Analog-out

AC signal of the ADC input.

Internet Upgrades

Yes

PC Serial Commands

Yes

Dimensions

(connectors included)

147 (L) x 106 (W) x 34 (H) mm

Weight

0.424 kg

Power Over USB

Yes

T-RAD

1 Channel

1.2

Lock In Amplifier Theory of Operation

The operation of a Lock In Amplifier can seem mysterious given its ability to pull a useful signal
out of noise and interference, but the basics of operation are not complex. A lock in amplifier's
operation can be explained in three ways: mathematically, in the time domain, or in the frequency
domain. W hile all explanations are equally useful, the one that makes sense to the user is the
most useful, so a brief description of all three will be presented.

1.2.1

Mathematical Description of a Lock In Amplifier.

Fourier Theory tells us that all repetitive signals can be broken down into a series of sin

e’s and

cosines. Because of this fact, we can describe the lock in operation using a signal that is a pure
cosine wave. To go further, even if the input signal is not a pure cosine wave, the lock will extract
the pure cosine wave component of the signal anyway, so the approach is justified. Consider an
input signal, v (t), given by:

Now consider a second signal, the reference signal, given by:

This reference signal is at the same frequency as the input signal and is supplied by the lock in.