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Quantum Mechanics-Based Signal and Image Representation: Application to Denoising

Sayantan Dutta, Adrian Basarab, Bertrand Georgeot, Denis Kouame

2021IEEE Open Journal of Signal Processing48 citationsDOIOpen Access PDF

Abstract

Decomposition of digital signals and images into other basis or dictionaries than time or space domains is a very common approach in signal and image processing and analysis. Such a decomposition is commonly obtained using fixed transforms (e.g., Fourier or wavelet) or dictionaries learned from example databases or from the signal or image itself. In this work, we investigate in detail a new approach of constructing such a signal or image-dependent bases inspired by quantum mechanics tools, i.e., by considering the signal or image as a potential in the discretized Schroedinger equation. To illustrate the potential of the proposed decomposition, denoising results are reported in the case of Gaussian, Poisson, and speckle noise and compared to the state of the art algorithms based on wavelet shrinkage, total variation regularization or patch-wise sparse coding in learned dictionaries, non-local means image denoising, and graph signal processing.

Topics & Concepts

Noise reductionMathematicsArtificial intelligenceTotal variation denoisingWaveletAlgorithmImage processingSignal processingSIGNAL (programming language)Fourier transformSpeckle patternComputer scienceComputer visionWavelet transformMultidimensional signal processingPattern recognition (psychology)Discrete-time signalQuantization (signal processing)Basis (linear algebra)GraphRegularization (linguistics)Basis functionSparse approximationNoise (video)Fourier analysisDiscretizationMultiplicative noiseImage restorationImage (mathematics)Speckle noiseIterative reconstructionTime–frequency analysisDigital imageNeural codingImage and Signal Denoising MethodsMathematical Analysis and Transform MethodsMedical Image Segmentation Techniques
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