Block-sparse tensor recovery
Block-sparse tensor recovery
This work explores the fundamental problem of the recoverability of a sparse tensor being reconstructed from its compressed embodiment. We present a generalized model of block-sparse tensor recovery as a theoretical foundation, where concepts measuring holistic mutual incoherence property (MIP) of the measurement matrix set are defined. A representative algorithm based on the orthogonal matching pursuit (OMP) framework, called tensor generalized block OMP (T-GBOMP), is applied to the theoretical framework elaborated for analyzing both noiseless and noisy recovery conditions. Specifically, we present the exact recovery condition (ERC) and sufficient conditions for establishing it with consideration of different degrees of restriction. Reliable reconstruction conditions, in terms of the residual convergence, the estimated error and the signal-to-noise ratio bound, are established to reveal the computable theoretical interpretability based on the newly defined MIP, which we introduce. The flexibility of tensor recovery is highlighted, i.e., the reliable recovery can be guaranteed by optimizing MIP of the measurement matrix set. Analytical comparisons demonstrate that the theoretical results developed are tighter and less restrictive than the existing ones (if any). Further discussions provide tensor extensions for several classic greedy algorithms, indicating that the sophisticated results derived are universal and applicable to all these tensorized variants.
Lu, Liyang
2b4dbf33-9621-4a4d-96ff-1923b8d683d0
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Gao, Zhen
e0ab17e4-5297-4334-8b64-87924feb7876
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Poor, H. Vincent
ace801ca-0c45-451f-9509-217ea29e32e1
Lu, Liyang
2b4dbf33-9621-4a4d-96ff-1923b8d683d0
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Gao, Zhen
e0ab17e4-5297-4334-8b64-87924feb7876
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Poor, H. Vincent
ace801ca-0c45-451f-9509-217ea29e32e1
Lu, Liyang, Wang, Zhaocheng, Gao, Zhen, Chen, Sheng and Poor, H. Vincent
(2024)
Block-sparse tensor recovery.
IEEE Transactions on Information Theory.
(In Press)
Abstract
This work explores the fundamental problem of the recoverability of a sparse tensor being reconstructed from its compressed embodiment. We present a generalized model of block-sparse tensor recovery as a theoretical foundation, where concepts measuring holistic mutual incoherence property (MIP) of the measurement matrix set are defined. A representative algorithm based on the orthogonal matching pursuit (OMP) framework, called tensor generalized block OMP (T-GBOMP), is applied to the theoretical framework elaborated for analyzing both noiseless and noisy recovery conditions. Specifically, we present the exact recovery condition (ERC) and sufficient conditions for establishing it with consideration of different degrees of restriction. Reliable reconstruction conditions, in terms of the residual convergence, the estimated error and the signal-to-noise ratio bound, are established to reveal the computable theoretical interpretability based on the newly defined MIP, which we introduce. The flexibility of tensor recovery is highlighted, i.e., the reliable recovery can be guaranteed by optimizing MIP of the measurement matrix set. Analytical comparisons demonstrate that the theoretical results developed are tighter and less restrictive than the existing ones (if any). Further discussions provide tensor extensions for several classic greedy algorithms, indicating that the sophisticated results derived are universal and applicable to all these tensorized variants.
Text
Tensor-Block-Sparse-Recovery
- Accepted Manuscript
More information
Accepted/In Press date: 15 August 2024
Identifiers
Local EPrints ID: 493535
URI: http://eprints.soton.ac.uk/id/eprint/493535
ISSN: 0018-9448
PURE UUID: 9f20921f-7fea-4c89-bd00-e901379a7905
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Date deposited: 05 Sep 2024 17:00
Last modified: 05 Sep 2024 17:00
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Contributors
Author:
Liyang Lu
Author:
Zhaocheng Wang
Author:
Zhen Gao
Author:
Sheng Chen
Author:
H. Vincent Poor
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