1-Bit Tensor Completion

Higher-order tensor structured data arise in many imaging scenarios, including hyperspectral imaging and color video. The recovery of a tensor from an incomplete set of its entries, known as tensor completion, is crucial in applications like compression. Furthermore, in many cases observations are n...

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Veröffentlicht in:Electronic Imaging Jg. 30; H. 13; S. 261-1 - 261-6
Hauptverfasser: Aidini, Anastasia, Tsagkatakis, Grigorios, Tsakalides, Panagiotis
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Society for Imaging Science and Technology 28.01.2018
Schlagworte:
1-Bit Matrix Completion
Higher-Order Tensor
Low-Rank Tensor Completion
Quantization
ISSN:2470-1173, 2470-1173
Online-Zugang:Volltext
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Zusammenfassung:Higher-order tensor structured data arise in many imaging scenarios, including hyperspectral imaging and color video. The recovery of a tensor from an incomplete set of its entries, known as tensor completion, is crucial in applications like compression. Furthermore, in many cases observations are not only incomplete, but also highly quantized. Quantization is a critical step for high dimensional data transmission and storage in order to reduce storage requirements and power consumption, especially for energy-limited systems. In this paper, we propose a novel approach for the recovery of low-rank tensors from a small number of binary (1-bit) measurements. The proposed method, called 1-bit Tensor Completion, relies on the application of 1-bit matrix completion over different matricizations of the underlying tensor. Experimental results on hyperspectral images demonstrate that directly operating with the binary measurements, rather than treating them as real values, results in lower recovery error.
Bibliographie:2470-1173(20180128)2018:13L.2611;1-
ISSN:2470-1173
2470-1173
DOI:10.2352/ISSN.2470-1173.2018.13.IPAS-261