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The stretched exponential function : is obtained by inserting a fractional power law into the exponential function. In most applications, it is meaningful only for arguments ''t'' between 0 and +∞. With ''β'' = 1, the usual exponential function is recovered. With a ''stretching exponent'' ''β'' between 0 and 1, the graph of log ''f'' versus ''t'' is characteristically ''stretched'', whence the name of the function. The compressed exponential function (with ''β'' > 1) has less practical importance, with the notable exception of ''β'' = 2, which gives the normal distribution. In mathematics, the stretched exponential is also known as the complementary cumulative Weibull distribution. Furthermore, the stretched exponential is the characteristic function (basically the Fourier transform) of the Lévy symmetric alpha-stable distribution. In physics, the stretched exponential function is often used as a phenomenological description of relaxation in disordered systems. It was first introduced by Rudolf Kohlrausch in 1854 to describe the discharge of a capacitor;〔.〕 therefore it is also called the Kohlrausch function. In 1970, G. Williams and D.C. Watts used the Fourier transform of the stretched exponential to describe dielectric spectra of polymers;〔.〕 in this context, the stretched exponential or its Fourier transform are also called the Kohlrausch-Williams-Watts (KWW) function. In phenomenological applications, it is often not clear whether the stretched exponential function should apply to the differential or to the integral distribution function—or to neither. In each case one gets the same asymptotic decay, but a different power law prefactor, which makes fits more ambiguous than for simple exponentials. In a few cases it can be shown that the asymptotic decay is a stretched exponential, but the prefactor is usually an unrelated power. == Mathematical properties == 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「Stretched exponential function」の詳細全文を読む スポンサード リンク
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