analyze signals and images in the wavelet domain
wavelet transforms are mathematical tools for analyzing data where features vary over different scales. for signals, features can be frequencies varying over time, transients, or slowly varying trends. for images, features include edges and textures. wavelet transforms were primarily created to address limitations of the fourier transform.
while fourier analysis consists of decomposing a signal into sine waves of specific frequencies, wavelet analysis is based on decomposing signals into shifted and scaled versions of a wavelet. a wavelet, unlike a sine wave, is a rapidly decaying, wave-like oscillation. this enables wavelets to represent data across multiple scales. different wavelets can be used depending on the application. wavelet toolbox™ for use with matlab® supports used in wavelet analysis.
audio signals, time-series financial data, and biomedical signals typically exhibit piecewise smooth behavior punctuated by transients. similarly, images typically include homogenous, piecewise smooth regions separated by transients, which appear as edges. for both signals and images, the smooth regions and transients can be sparsely represented with wavelet transforms.
wavelet transforms can be classified into two broad classes: the continuous wavelet transform (cwt) and the discrete wavelet transform (dwt).
the continuous wavelet transform is a time-frequency transform, which is ideal for analysis of non-stationary signals. a signal being nonstationary means that its frequency-domain representation changes over time. cwt is similar to the short-time fourier transform (stft). the stft uses a fixed window to create a local frequency analysis, while cwt tiles the time-frequency plane with variable-sized windows. the window widens in time, making it suitable for low-frequency phenomena, and narrows for high-frequency phenomena. the continuous wavelet transform can be used to analyze transient behavior, rapidly changing frequencies, and slowly varying behavior.
with the discrete wavelet transform scales are discretized more coarsely than with cwt. this makes dwt useful for compressing and denoising signals and images while preserving important features. you can use discrete wavelet transforms to perform multiresolution analysis and split signals into physically meaningful and interpretable components.
for more information on applying wavelet techniques and selecting the right wavelets for your application in matlab, see wavelet toolbox.
examples and how to
software reference
see also: signal processing toolbox, dsp system toolbox, , empirical mode decomposition, denoising