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Proceedings Paper

Research on system modeling and data reconstruction for spatial coding compressive spectral imaging
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Paper Abstract

Compressive spectral imaging is a kind of novel spectral imaging technique that combines traditional spectral imaging method with new concept of compressive sensing. Spatial coding compressive spectral imaging realizes snapshot imaging and the dimension reduction of the acquisition data cube by successive modulation, dispersion and stacking of the light signal. It reduces acquisition data amount, increases imaging signal-to-noise ratio, realizes snapshot imaging for large field of view and has already been applied in the occasions such as high-speed imaging, fluorescent imaging and so on. In this paper, the physical model for single dispersion spatial coding compressive spectral imaging is reviewed on which the data flow procession is analyzed and its reconstruction issue is concluded. The existing sparse reconstruction methods are investigated and specific module based on the two-step iterative shrinkage/thresholding algorithm is built so as to execute the imaging data reconstruction. A regularizer based on the total-variation form is included in the unconstrained minimization problem so that the smooth extent of the restored data cube can be controlled by altering its tuning parameter. To verify the system modeling and data reconstruction method, a simulation imaging experiment is carried out, for which a specific imaging scenery of both spatial and spectral features is firstly built. The root-mean-square error of the whole-band reconstructed spectral images under different regularization tuning parameters are calculated so that the relation between data fidelity and the tuning parameter is revealed. The imaging quality is also evaluated by visual observation and comparison on resulting image and spectral curve.

Paper Details

Date Published: 21 November 2012
PDF: 6 pages
Proc. SPIE 8558, Optoelectronic Imaging and Multimedia Technology II, 855819 (21 November 2012); doi: 10.1117/12.981385
Show Author Affiliations
Yuheng Chen, Soochow Univ. (China)
Key Lab. of Advanced Optical Manufacturing Technologies (China)
Key Lab. of Modern Optical Technologies of Jiangsu Province and of Ministry of Education (China)
Xinhua Chen, Soochow Univ. (China)
Key Lab. of Advanced Optical Manufacturing Technologies (China)
Key Lab. of Modern Optical Technologies of Jiangsu Province and of Ministry of Education (China)
Yiqun Ji, Soochow Univ. (China)
Key Lab. of Advanced Optical Manufacturing Technologies (China)
Key Lab. of Modern Optical Technologies of Jiangsu Province and of Ministry of Education (China)
Jiankang Zhou, Soochow Univ. (China)
Key Lab. of Advanced Optical Manufacturing Technologies (China)
Key Lab. of Modern Optical Technologies of Jiangsu Province and of Ministry of Education (China)
Weimin Shen, Soochow Univ. (China)
Key Lab. of Advanced Optical Manufacturing Technologies (China)
Key Lab. of Modern Optical Technologies of Jiangsu Province and of Ministry of Education (China)


Published in SPIE Proceedings Vol. 8558:
Optoelectronic Imaging and Multimedia Technology II
Tsutomu Shimura; Guangyu Xu; Linmi Tao; Jesse Zheng, Editor(s)

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