2020
DOI: 10.3390/app10030797
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Image Completion with Hybrid Interpolation in Tensor Representation

Abstract: The issue of image completion has been developed considerably over the last two decades, and many computational strategies have been proposed to fill-in missing regions in an incomplete image. When the incomplete image contains many small-sized irregular missing areas, a good alternative seems to be the matrix or tensor decomposition algorithms that yield low-rank approximations. However, this approach uses heuristic rank adaptation techniques, especially for images with many details. To tackle the obstacles o… Show more

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Cited by 8 publications
(6 citation statements)
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“…By representing visual as tensors, models addressing inverse problems exploit low-rank tensor decompositions (Section IV-B), or rely on robust variants (Sections IV-C IV-E) to estimate a low-rank tensor which forms a basis from which missing data can be imputed or denoised. Along this line of research, several methods for image and video inpainting and/or denoising have been developed by estimating the low-rank tensor using either nuclear norm-based regularizers, or by assuming an explicit low-rank tensor structure described by decompositions such CP, Tucker, Tensor Ring, or TT decomposition [218], [219], [220], [221], [92], [99], [100], [101], [98]. For the same task, methods based on tensor-structured separable dictionary learning (Section IV-E) have also been proposed [4], [115], [11].…”
Section: Tensor Methods In Inverse Problemsmentioning
confidence: 99%
“…By representing visual as tensors, models addressing inverse problems exploit low-rank tensor decompositions (Section IV-B), or rely on robust variants (Sections IV-C IV-E) to estimate a low-rank tensor which forms a basis from which missing data can be imputed or denoised. Along this line of research, several methods for image and video inpainting and/or denoising have been developed by estimating the low-rank tensor using either nuclear norm-based regularizers, or by assuming an explicit low-rank tensor structure described by decompositions such CP, Tucker, Tensor Ring, or TT decomposition [218], [219], [220], [221], [92], [99], [100], [101], [98]. For the same task, methods based on tensor-structured separable dictionary learning (Section IV-E) have also been proposed [4], [115], [11].…”
Section: Tensor Methods In Inverse Problemsmentioning
confidence: 99%
“…The incomplete images can contain many missing pixels distributed over the entire image. In the paper entitled 'Image Completion with Hybrid Interpolation in Tensor Representation', Rafał Zdunek and Tomasz Sadowski [18] proposes an interpolation algorithm for a wide spectrum of image-completion problems. Their algorithm outperforms other conventional methods with a considerably shorter computational runtime.…”
Section: Compression Completion and Correctionmentioning
confidence: 99%
“…D. Thanh et al [10] proposed an adaptive image inpainting using adaptive parameters estimation, parameters can be estimated based on the information of the image, such as discrete gradient. R. Zdunek et al [11] use hybrid interpolation in tensor representation for inpainting image, it only It can only repair a small area. In order to get similar patch for filling image, S. Yang et al [12] proposed multi-patch match with adaptive size, this method improves the accuracy of image matching and saves time.…”
Section: Introductionmentioning
confidence: 99%