Lissajous curve

Not to be confused with spirographs, which are generally enclosed by a circular boundary, whereas Lissajous curves are enclosed by rectangular boundaries.

In mathematics, a Lissajous curve ( /ˈlɪsəʒuː/ and /ˈbaʊdɪtʃ/), also known as Lissajous figure or Bowditch curve, is the graph of a system of parametric equations

which describe complex harmonic motion. This family of curves was investigated by Nathaniel Bowditch in 1815, and later in more detail by Jules Antoine Lissajous (a French name pronounced [lisaˈʒu]) in 1857.

The appearance of the figure is highly sensitive to the ratio a/b. For a ratio of 1, the figure is an ellipse, with special cases including circles (A = B, δ = π/2 radians) and lines (δ = 0). Another simple Lissajous figure is the parabola (a/b = 2, δ = π/2). Other ratios produce more complicated curves, which are closed only if a/b is rational. The visual form of these curves is often suggestive of a three-dimensional knot, and indeed many kinds of knots, including those known as Lissajous knots, project to the plane as Lissajous figures.

Lissajous figure on an oscilloscope, displaying a 3:1 relationship between the frequencies of the vertical and horizontal sinusoidal inputs, respectively.

Lissajous figures where a = 1, b = N (N is a natural number) and

are Chebyshev polynomials of the first kind of degree N.

Examples

The 20s animation below shows the curve adaptation with continuously increasing fraction from 0 to 1 in steps of 0.01. (δ=0)

Below are examples of Lissajous figures with δ = π/2, an odd natural number a, an even natural number b, and |a − b| = 1.

• 

  a = 1, b = 2 (1:2)
• 

  a = 1, b = 2 (1:2)
• 

  a = 3, b = 2 (3:2)
• 

  a = 3, b = 4 (3:4)
• 

  a = 5, b = 4 (5:4)

Generation

Prior to modern computers, Lissajous curves could be generated mechanically by means of a harmonograph.

Practical application

Lissajous curves can also be generated using an oscilloscope(as illustrated). An octopus circuit can be used to demonstrate the waveform images on an oscilloscope. Two phase-shifted sinusoid inputs are applied to the oscilloscope in X-Y mode and the phase relationship between the signals is presented as a Lissajous figure.

On an oscilloscope, we suppose x is CH1 and y is CH2, A is amplitude of CH1 and B is amplitude of CH2, a is frequency of CH1 and b is frequency of CH2, so a/b is a ratio of frequency of two channels, finally, δ is the phase shift of CH1.

A purely mechanical application of a Lissajous curve with a=1, b=2 is in the driving mechanism of the Mars Light type of oscillating beam lamps popular with railroads in the mid-1900s. The beam in some versions traces out a lopsided figure-8 pattern with the "8" lying on its side.

Application for the case of a = b

In this figure both input frequencies are identical, but the phase variance between them creates the shape of an ellipse.

When the input to an LTI system is sinusoidal, the output is sinusoidal with the same frequency, but it may have a different amplitude and some phase shift. Using an oscilloscope that can plot one signal against another (as opposed to one signal against time) to plot the output of an LTI system against the input to the LTI system produces an ellipse that is a Lissajous figure for the special case of a = b. The aspect ratio of the resulting ellipse is a function of the phase shift between the input and output, with an aspect ratio of 1 (perfect circle) corresponding to a phase shift of and an aspect ratio of (a line) corresponding to a phase shift of 0 or 180 degrees. The figure below summarizes how the Lissajous figure changes over different phase shifts. The phase shifts are all negative so that delay semantics can be used with a causal LTI system (note that -270 degrees is equivalent to +90 degrees). The arrows show the direction of rotation of the Lissajous figure.

A pure phase shift affects the eccentricity of the Lissajous oval. Analysis of the oval allows phase shift from an LTI system to be measured.

Popular culture

• Lissajous figures are sometimes used in graphic design as logos. Examples include:
  • The Australian Broadcasting Corporation (a = 1, b = 3, δ = π/2)
  • The Lincoln Laboratory at MIT (a = 4, b = 3, δ = 0)^[1]
  • The University of Electro-Communications, Japan (a = 3, b = 4, δ = π/2).
• In computing, Lissajous figures are in some screen savers.

See also

• Rose curve
• Lissajous orbit
• Blackburn pendulum
• Lemniscate of Gerono

Notes

1. "Lincoln Laboratory Logo". MIT Lincoln Laboratory. 2008. http://www.ll.mit.edu/about/History/logo.html. Retrieved 2008-04-12. 

External links

• Interactive Java Tutorial: Lissajous Figures on Oscilloscope National High Magnetic Field Laboratory
• Lissajous Curve at Mathworld
• ECE 209: Lissajous Figures – a short wikified document that mathematically and graphically explains Lissajous curves for LTI systems and gives an oscilloscope procedure that uses them to find system phase shift
• HTML5 Canvas and Javascript based interactive version
• Animated Lissajous figures in Java
• About the Australian Broadcasting Corporation logo
• Free tool QLiss3D that displays Lissajous figures in three dimensions
• A free Javascript tool for generating Lissajous curves

• A 3D Java applet showing how a Lissajous figure can be traced.
• Lissajous 3D: animated textured 3D Lissajous patterns, also Lissajous screen saver for Windows
• http://jsxgraph.uni-bayreuth.de/wiki/index.php/Lissajous_curves: an interactive JavaScript-applet showing Lissajous curves in 2D. Neither Java nor Flash required, it uses the JSXGraph library.
• Another interactive Java applet; animated or can move figure with mouse.
• Lissajous Curves: Interactive simulation of graphical representations of musical intervals, beats, interference, vibrating strings
• Lissajous Curves: Interactive advanced Excel chart with infinite variation.