Lissajous Lab

To operate: Select the Preset buttons at the left to see sample patterns. To generate your own patterns, use the digital readouts at the right. Adjust the readouts by clicking on the digits: clicking near the top of a digit increases its value; clicking near the bottom decreases its value.


Download screen saver Download the screen saver: Click on the button at the left to download the Lissajous screen saver. This displays the same patterns full-screen as a screen saver. The screen saver is only for PC's running Windows 95/98/NT.
Download this Web page Download this Web page: Click on the button at the left to download a WinZip archive of this Web page.  You are welcome to put this page on your own site; just unzip the archive and upload all of the files to a single directory.

Lissajous Figures

Lissajous (pronounced LEE-suh-zhoo) figures were discovered by the French physicist Jules Antoine Lissajous. He would use sounds of different frequencies to vibrate a mirror. A beam of light reflected from the mirror would trace patterns which depended on the frequencies of the sounds. Lissajous' setup was similar to the apparatus which is used today to project laser light shows.

Before the days of digital frequency meters and phase-locked loops, Lissajous figures were used to determine the frequencies of sounds or radio signals. A signal of known frequency was applied to the horizontal axis of an oscilloscope, and the signal to be measured was applied to the vertical axis. The resulting pattern was a function of the ratio of the two frequencies.

Lissajous figures often appeared as props in science fiction movies made during the 1950's. One of the best examples can be found in the opening sequence of The Outer Limits TV series. ("Do not attempt to adjust your picture--we are controlling the transmission.") The pattern of criss-cross lines is actually a Lissajous figure.

The Lissajous Lab provides you with a virtual oscilloscope which you can use to generate these patterns. (You will control the horizontal. You will control the vertical.) The applet also allows you to apply a signal to modulate the hue of the trace, so you can create colorful designs.

Explanation of Readout Values
xFreq This is the number of horizontal cycles for each frame of the plot.
yFreq This is the number of vertical cycles for each frame of the plot.
hueFreq This is the number of hue cycles for each frame of the plot. Each hue cycle represents a complete spectrum of colors.
Samples This is the number of line segments which will be used to draw each frame of the plot. Increasing this number will make the curves appear smoother. Decreasing this number will exacerbate the aliasing in the plot (making it look more like string art than a mathematical curve).

Best experienced with
Microsoft Internet Explorer
Click here to start.