Revision as of 17:05, 20 April 2011 edit Michael Hardy (talk \| contribs) Administrators 210,577 edits No edit summary ← Previous edit		Revision as of 17:05, 20 April 2011 edit undo Michael Hardy (talk \| contribs) Administrators 210,577 edits →Description Next edit →
Line 14: : <math>f(t) = a_0 + a_1 (t - t_i) + a_2(t - t_i)^2 + \cdots + a_h(t - t_i)^{h_i} \, </math> where <math> t </math> is close to <math> t_i </math> and <math> h_i </math> is a non-integer quantifying the local singularity. (Compare this to a [[~~Taylor_series~~Taylor series]], where in practice only a limited number of low-order terms are used to approximate a continuous function.) Generally, a [[continuous wavelet transform]] decomposes a signal as a function of time, rather than assuming the signal is stationary (For example, the Fourier transform). Any continuous wavelet can be used, though the first derivative of the [[Gaussian distribution]] and the [[~~Mexican_hat_wavelet~~Mexican hat wavelet]] (2nd derivative of Gaussian) are common. Choice of wavelet may depend on characteristics of the signal being investigated. Below we see one possible wavelet basis given by the first derivative of the Gaussian:

Wavelet transform modulus maxima method: Difference between revisions