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Complexity-constrained best-basis wavelet packet algorithm for image compression

Complexity-constrained best-basis wavelet packet algorithm for image compression

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  • Author(s): D. Marpe 1 ; H.L. Cycon 2 ; W. Li 3
    • View affiliations
    • Affiliations: 1: Heinrich-Hertz-Institut für Nachrichtentechnik, Berlin, Germany
      2: Fachhochschule für Technik und Wirtschaft, Berlin, Germany
      3: Department of Mathematics and Statistics, Old Dominion University, Norfolk, USA
  • Source: Volume 145, Issue 6, December 1998, p. 391 – 398
    DOI:  10.1049/ip-vis:19982457 , Print ISSN 1350-245X, Online ISSN 1359-7108
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The concept of adapted waveform analysis using a best-basis selection out of a predefined library of wavelet packet (WP) bases allows an efficient image representation for the purpose of compression. Image coding methods based on the best-basis WP representation have shown significant coding gains for some image classes compared with methods using a fixed dyadic structured wavelet basis, at the expense however, of considerably higher computational complexity. A modification of the best-basis method, the so-called complexity constrained best-basis algorithm (CCBB), is proposed which parameterises the complexity gap between the fast (standard) wavelet transform and the best wavelet packet basis of a maximal WP library. This new approach allows a ‘suboptimal’ best basis to be found with respect to a given budget of computational complexity or, in other words, it offers an instrument to control the trade-off between compression speed and coding efficiency. Experimental results are presented for image coding applications showing a highly nonlinear relationship between the rate-distortion (RD) performance and the computational complexity in such a way that a relatively small increase in complexity with respect to the standard wavelet basis results in a relatively high RD gain.

Inspec keywords: image coding; rate distortion theory; discrete wavelet transforms; transform coding; data compression; computational complexity; image representation

Other keywords: compression speed; image coding; coding efficiency; rate-distortion performance; wavelet packet basis; image compression; suboptimal best basis; adapted waveform analysis; image representation; computational complexity; wavelet transform; best-basis wavelet packet algorithm; complexity constrained best-basis algorithm

Subjects: Integral transforms in numerical analysis; Computational complexity; Integral transforms in numerical analysis; Image and video coding; Computer vision and image processing techniques

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