Abstract
Structured sparsity approaches have recently received much attention in the statistics, machine learning, and signal processing communities. A common strategy is to exploit or assume prior information about structural dependencies inherent in the data; the solution is encouraged to behave as such by the inclusion of an appropriate regularisation term which enforces structured sparsity constraints over sub-groups of data. An important variant of this idea considers the tree-like dependency structures often apparent in wavelet decompositions. However, both the constituent groups and their associated weights in the regularisation term are typically defined a priori. We here introduce an adaptive wavelet denoising framework whereby a sparsity-inducing regulariser is modified based on information extracted from the signal itself. In particular, we use the same wavelet decomposition to detect the location of salient features in the signal, such as jumps or sharp bumps. Given these locations, the weights in the regulariser associated to the groups of coefficients that cover these time locations are modified in order to favour retention of those coefficients. Denoising experiments show that, not only does the adaptive method preserve the salient features better than the non-adaptive constraints, but it also delivers significantly better shrinkage over the signal as a whole.
Highlights
A key attraction of wavelets is their compressive representation of data
Methods based on these models proved successful in many applications such as denoising, compression, and classification, some concerns remained about the preservation of salient features in the signal, such as jumps or sharp bumps [10]
The ability of shift-invariant complex wavelet transforms to detect salient features in the signal is exploited to design a penalisation term which favours estimated jumps or sharp bumps during the optimisation process. We show that this results in a denoising approach with better preservation of salient features
Summary
A key attraction of wavelets is their compressive representation of data. This is fundamental to powerful nonlinear processing methods such as wavelet shrinkage [1,2,3]. Methods based on these models proved successful in many applications such as denoising, compression, and classification, some concerns remained about the preservation of salient features in the signal, such as jumps or sharp bumps [10] This work builds upon two main ideas: the use of mixed-norm regularisers to obtain structured sparse estimates and the use of the DTCWT as a signal analysis tool to induce sparsity and locate salient features in the signal, while retaining desirable properties such as shiftinvariance and low redundancy We briefly examine these two ingredients . The strategy can be stated as the solution of the convex optimisation problem θb 1⁄4
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
