Table of Contents
Advertisement
Chapter 2
Lock-in Amplifier Basics
What is a Lock-in Amplifier?
Lock-in amplifiers are used to detect and measure very small ac signals — all the way
down to a few nanovolts. Accurate measurements may be made even when the small
signal is obscured by noise sources many thousands of times larger.
Lock-in amplifiers use a technique known as phase-sensitive detection to single out the
component of the signal at a specific reference frequency and phase. Noise signals at
frequencies other than the reference frequency are rejected and do not affect the
measurement.
Why use a lock-in?
Let's consider an example. Suppose the signal is a 10 nV sine wave at 10 kHz. Clearly
some amplification is required. A good low noise amplifier may have about 5 nV/√Hz of
input noise. If the amplifier bandwidth is 100 kHz and the gain is 1000, then we can
expect our output to be 10 μV of signal (10 nV × 1000) and 1.6 mV of broadband noise
(5 nV/√Hz × √100 kHz × 1000). We won't have much luck measuring the output signal
unless we single out the frequency of interest.
If we follow the amplifier with a band pass filter with a Q=100 (a very good filter)
centered at 10 kHz, any signal in a 100 Hz bandwidth will be detected (10 kHz/Q). The
noise in the filter pass band will be 50 μV (5 nV/√Hz × √100 Hz × 1000) and the signal
will still be 10 μV. The output noise is still much greater than the signal and an accurate
measurement cannot be made. Further gain will not help the signal to noise problem.
Now try following the amplifier with a phase-sensitive detector (PSD). The PSD can
detect the signal at 10 kHz with a bandwidth as narrow as 0.01 Hz! In this case, the noise
in the detection bandwidth will be only 0.5 μV (5 nV/√Hz × √.01 Hz × 1000) while the
signal is still 10 µV. The signal to noise ratio is now 20 and an accurate measurement of
the signal is possible.
What is phase-sensitive detection?
Lock-in measurements require a frequency reference. Typically an experiment is excited
at a fixed frequency (from an oscillator or function generator) and the lock-in detects the
response from the experiment at the reference frequency. In the diagram below, the
reference signal is a square wave at frequency f
function generator. If the sine output from the function generator is used to excite the
experiment, the response might be the signal waveform shown below. The signal is
sin(ω
V
sig
t + θ
) where ω
= 2πf
ref
sig
ref
. This might be the sync output from a
ref
and V
is the signal amplitude.
ref
sig
SR865A DSP Lock-in Amplifier
Basics
37
Advertisement
Table of Contents
