Fast algorithms for non-convex tensor completion problems Fast algorithms for non-convex tensor completion problems

Multi-dimensional image processing plays a pivotal role in diverse fields such as medicine, research, graphics, industry, remote sensing, virtual reality, and geospatial mapping, enabling advanced visualization and analysis. Traditional methods for processing multi-dimensional data, such as matrix-b...

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Vydané v:Afrika mathematica Ročník 36; číslo 2; s. 65
Hlavní autori: Kanwal, Asia, ur Rahman, Mati, Boulaaras, Salah
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Berlin/Heidelberg Springer Berlin Heidelberg 01.06.2025
Springer Nature B.V
Predmet:
Accuracy
Algorithms
Applications of Mathematics
Approximation
Complexity
Convex analysis
Convexity
Data recovery
Datasets
Decomposition
Fourier transforms
Gray scale
History of Mathematical Sciences
Hyperspectral imaging
Image processing
Machine learning
Mathematics
Mathematics and Statistics
Mathematics Education
Multidimensional data
Multidimensional methods
Optimization
Optimization techniques
Remote sensing
Singular value decomposition
Tensors
Video
Virtual reality
68U10
68W40
Randomized singular value decomposition (r-SVD)
Multi-dimensional image processing
Tensor singular value decomposition (t-SVD)
42B10
Surrogate functions
Alternating direction method of multipliers (ADMM)
ISSN:1012-9405, 2190-7668
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Popis
Shrnutí:Multi-dimensional image processing plays a pivotal role in diverse fields such as medicine, research, graphics, industry, remote sensing, virtual reality, and geospatial mapping, enabling advanced visualization and analysis. Traditional methods for processing multi-dimensional data, such as matrix-based singular value decomposition (SVD), often fail to capture the inherent multi-dimensional structure, leading to suboptimal performance in tasks like data recovery and feature extraction. To address these limitations, tensor singular value decomposition (t-SVD) has emerged as a powerful tool, specifically designed to handle the complex, multi-linear structures inherent in multi-dimensional data. Unlike matrix-based approaches, t-SVD operates directly on tensors, preserving the intrinsic relationships between dimensions and enabling more accurate representation and recovery of multi-dimensional data. Derived from t-SVD, surrogate functions such as the logDet function and Laplace function have been proposed to approximate the multi-rank of tensors, facilitating the recovery of the underlying structure of multi-dimensional images. However, real-world applications involving large-scale datasets (e.g., hyperspectral images, multispectral images, and grayscale videos) present significant computational challenges. Standard optimization algorithms, such as the alternating direction method of multipliers (ADMM), are often inefficient for solving the resulting large-scale non-convex optimization problems. To overcome these challenges, we propose efficient ADMM algorithms based on randomized singular value decomposition (r-SVD). These algorithms are specifically designed to handle the non-convexity and scalability issues associated with SVD-based optimization. We provide a detailed analysis of the computational complexity of the proposed algorithms, demonstrating their superiority over traditional methods in terms of efficiency and scalability. Extensive experiments on real-world datasets, including hyperspectral images, multispectral images, and grayscale videos, validate that our proposed algorithms achieve significant reductions in CPU time without compromising the quality of data recovery. By leveraging the strengths of r-SVD, our approach offers a robust and efficient solution for multi-dimensional image processing, addressing both theoretical and practical challenges in the field.
Bibliografia:ObjectType-Article-1
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ISSN:1012-9405
2190-7668
DOI:10.1007/s13370-025-01290-0