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In mathematics, a Lissajous curve , 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 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/4). 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. Visually, the ratio ''a''/''b'' determines the number of "lobes" of the figure. For example, a ratio of 3/1 or 1/3 produces a figure with three major lobes (see image). Similarly, a ratio of 5/4 produces a figure with five horizontal lobes and four vertical lobes. Rational ratios produce closed (connected) or "still" figures, while irrational ratios produce figures that appear to rotate. The ratio ''A''/''B'' determines the relative width-to-height ratio of the curve. For example, a ratio of 2/1 produces a figure that is twice as wide as it is high. Finally, the value of ''δ'' determines the apparent "rotation" angle of the figure, viewed as if it were actually a three-dimensional curve. For example, ''δ''=0 produces ''x'' and ''y'' components that are exactly in phase, so the resulting figure appears as an apparent three-dimensional figure viewed from straight on (0°). In contrast, any non-zero ''δ'' produces a figure that appears to be rotated, either as a left/right or an up/down rotation (depending on the ratio ''a''/''b''). Lissajous figures where ''a'' = 1, ''b'' = ''N'' (''N'' is a natural number) and : are Chebyshev polynomials of the first kind of degree ''N''. This property is exploited to produce a set of points, called Padua points, at which a function may be sampled in order to compute either a bivariate interpolation or quadrature of the function over the domain ()×(). ==Examples== The animation 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. Image:Lissajous_curve_1by2.svg|''a'' = 1, ''b'' = 2 (1:2) Image:Lissajous_curve_3by2.svg|''a'' = 3, ''b'' = 2 (3:2) Image:Lissajous_curve_3by4.svg|''a'' = 3, ''b'' = 4 (3:4) Image:Lissajous_curve_5by4.svg|''a'' = 5, ''b'' = 4 (5:4) 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Lissajous curve」の詳細全文を読む スポンサード リンク
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