Compressive scanning of an object signature

Jonathan I. Tamir; Dan E. Tamir; Wilhelmus J. Geerts; Shlomi Dolev

doi:10.1007/s11047-014-9460-7

Compressive scanning of an object signature

Jonathan I. Tamir, Dan E. Tamir, Wilhelmus J. Geerts, Shlomi Dolev

Department of Computer Science

Research output: Contribution to journal › Article › peer-review

Abstract

In this paper we explore the utility of compressive sensing for object signature generation in the optical domain. In the data acquisition stage we use laser scanning to obtain a small (sub-Nyquist) number of points of an object’s boundary. This is used to construct the signature, thereby enabling object identification, reconstruction, and, image data compression. We refer to this framework as compressive scanning of objects’ signatures. The main contributions of the paper are the following: (1) we use this framework to replace parts of the digital processing with optical processing and present one possible implementation, (2) the use of compressive scanning reduces laser data obtained and maintains high reconstruction accuracy, and (3) we show that using compressive sensing can lead to a reduction in the amount of stored data without significantly affecting the utility of this data for image recognition and image compression.

Original language	English
Pages (from-to)	457-467
Number of pages	11
Journal	Natural Computing
Volume	14
Issue number	3
DOIs	https://doi.org/10.1007/s11047-014-9460-7
State	Published - 21 Sep 2015

Keywords

Compressive sensing
Digital signal processing
Object signature
Optical signal processing
Optical superComputing
Shape representation

ASJC Scopus subject areas

Computer Science Applications

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10.1007/s11047-014-9460-7

Cite this

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title = "Compressive scanning of an object signature",

abstract = "In this paper we explore the utility of compressive sensing for object signature generation in the optical domain. In the data acquisition stage we use laser scanning to obtain a small (sub-Nyquist) number of points of an object{\textquoteright}s boundary. This is used to construct the signature, thereby enabling object identification, reconstruction, and, image data compression. We refer to this framework as compressive scanning of objects{\textquoteright} signatures. The main contributions of the paper are the following: (1) we use this framework to replace parts of the digital processing with optical processing and present one possible implementation, (2) the use of compressive scanning reduces laser data obtained and maintains high reconstruction accuracy, and (3) we show that using compressive sensing can lead to a reduction in the amount of stored data without significantly affecting the utility of this data for image recognition and image compression.",

keywords = "Compressive sensing, Digital signal processing, Object signature, Optical signal processing, Optical superComputing, Shape representation",

author = "Tamir, {Jonathan I.} and Tamir, {Dan E.} and Geerts, {Wilhelmus J.} and Shlomi Dolev",

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AU - Tamir, Jonathan I.

AU - Tamir, Dan E.

AU - Geerts, Wilhelmus J.

AU - Dolev, Shlomi

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Y1 - 2015/9/21

N2 - In this paper we explore the utility of compressive sensing for object signature generation in the optical domain. In the data acquisition stage we use laser scanning to obtain a small (sub-Nyquist) number of points of an object’s boundary. This is used to construct the signature, thereby enabling object identification, reconstruction, and, image data compression. We refer to this framework as compressive scanning of objects’ signatures. The main contributions of the paper are the following: (1) we use this framework to replace parts of the digital processing with optical processing and present one possible implementation, (2) the use of compressive scanning reduces laser data obtained and maintains high reconstruction accuracy, and (3) we show that using compressive sensing can lead to a reduction in the amount of stored data without significantly affecting the utility of this data for image recognition and image compression.

AB - In this paper we explore the utility of compressive sensing for object signature generation in the optical domain. In the data acquisition stage we use laser scanning to obtain a small (sub-Nyquist) number of points of an object’s boundary. This is used to construct the signature, thereby enabling object identification, reconstruction, and, image data compression. We refer to this framework as compressive scanning of objects’ signatures. The main contributions of the paper are the following: (1) we use this framework to replace parts of the digital processing with optical processing and present one possible implementation, (2) the use of compressive scanning reduces laser data obtained and maintains high reconstruction accuracy, and (3) we show that using compressive sensing can lead to a reduction in the amount of stored data without significantly affecting the utility of this data for image recognition and image compression.

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KW - Digital signal processing

KW - Object signature

KW - Optical signal processing

KW - Optical superComputing

KW - Shape representation

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Compressive scanning of an object signature

Abstract

Keywords

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