Abstract

Lifting schemes (LS) were found to be efficient tools for image coding purposes. Since LS-based decompositions depend on the choice of the prediction/update operators, many research efforts have been devoted to the design of adaptive structures. The most commonly used approaches optimize the prediction filters by minimizing the variance of the detail coefficients. In this article, we investigate techniques for optimizing sparsity criteria by focusing on the use of an l1 criterion instead of an l2 one. Since the output of a prediction filter may be used as an input for the other prediction filters, we then propose to optimize such a filter by minimizing a weighted l1 criterion related to the global rate-distortion performance. More specifically, it will be shown that the optimization of the diagonal prediction filter depends on the optimization of the other prediction filters and vice-versa. Related to this fact, we propose to jointly optimize the prediction filters by using an algorithm that alternates between the optimization of the filters and the computation of the weights. Experimental results show the benefits which can be drawn from the proposed optimization of the lifting operators.

Highlights

  • The discrete wavelet transform has been recognized to be an efficient tool in many image processing fields, including denoising [1] and compression [2]

  • Since the output of a prediction filter may be used as an input for other prediction filters, we propose to optimize such a filter by minimizing a weighted l1 criterion related to the global prediction error

  • In order to show the benefits of the proposed l1 optimization criterion, we provide the results for the following decompositions carried out over three resolution levels:

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Summary

Introduction

The discrete wavelet transform has been recognized to be an efficient tool in many image processing fields, including denoising [1] and compression [2] Such a success of wavelets is due to their intrinsic features: multiresolution representation, good energy compaction, and decorrelation properties [3,4]. LS guarantee a lossy-to-lossless reconstruction required in some specific applications such as remote sensing imaging for which any distortion in the decoded image may lead to an erroneous interpretation of the image [6]. They are suitable tools for scalable reconstruction, which is a key issue for telebrowsing applications [7,8]

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