Hyperspectral image denoising using the robust low-rank tensor recovery

Chang Li; Yong Ma; Jun Huang; Xiaoguang Mei; Jiayi Ma

doi:10.1364/JOSAA.32.001604

Journal of the Optical Society of America A
Vol. 32,
Issue 9,
pp. 1604-1612
(2015)
•https://doi.org/10.1364/JOSAA.32.001604

Hyperspectral image denoising using the robust low-rank tensor recovery

Chang Li, Yong Ma, Jun Huang, Xiaoguang Mei, and Jiayi Ma

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Chang Li, Yong Ma, Jun Huang, Xiaoguang Mei, and Jiayi Ma, "Hyperspectral image denoising using the robust low-rank tensor recovery," J. Opt. Soc. Am. A 32, 1604-1612 (2015)

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Related Topics
Table of Contents Category
- Image Processing
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.
Previously assigned OCIS codes
- Multispectral and hyperspectral imaging (110.4234)
- Spectroscopy, visible (300.6550)

About this Article
History
- Original Manuscript: April 16, 2015
- Revised Manuscript: June 19, 2015
- Manuscript Accepted: July 2, 2015
- Published: August 7, 2015

Abstract

Denoising is an important preprocessing step to further analyze the hyperspectral image (HSI), and many denoising methods have been used for the denoising of the HSI data cube. However, the traditional denoising methods are sensitive to outliers and non-Gaussian noise. In this paper, by utilizing the underlying low-rank tensor property of the clean HSI data and the sparsity property of the outliers and non-Gaussian noise, we propose a new model based on the robust low-rank tensor recovery, which can preserve the global structure of HSI and simultaneously remove the outliers and different types of noise: Gaussian noise, impulse noise, dead lines, and so on. The proposed model can be solved by the inexact augmented Lagrangian method, and experiments on simulated and real hyperspectral images demonstrate that the proposed method is efficient for HSI denoising.

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	VBM3D	LRTA	PARAFAC	LRMR	RLRTR
MPSNR	32.490	25.108	32.187	33.968	34.128
MSSIM	0.8918	0.7082	0.9044	0.9506	0.9605
MFSIM	0.9427	0.8581	0.9468	0.9699	0.9731

	#Samples	Methods
Class	Training/Total	SVM	VBM3D	LRTA	PARAFAC	LRMR	RLRTR
Alfalfa	15/46	88.45	93.23	88.10	84.71	93.77	94.97
Corn-no till	100/1428	74.07	80.66	74.31	78.30	77.01	80.53
Corn-min till	100/830	71.33	78.20	71.10	72.29	78.60	80.46
Corn	50/237	87.27	91.82	87.41	87.19	92.56	92.89
Grass-pasture	50/483	90.22	93.62	90.38	91.95	91.40	90.98
Grass-tree	100/730	97.19	99.18	97.08	98.38	98.61	99.32
Grass-pasture-mowed	15/28	92.46	98.23	92.38	91.15	93.46	99.92
Hay-windrowed	50/478	97.79	98.84	97.76	98.42	99.54	97.79
Oats	15/20	96.20	99.80	95.80	96.40	98.80	100.00
Soybeans-no till	100/972	78.76	84.94	78.55	82.48	83.81	87.41
Soybeans-min till	150/2455	76.31	83.22	76.63	81.58	84.69	84.53
Soybeans-clean till	50/593	74.90	83.20	75.30	78.35	79.80	78.48
Wheat	50/205	98.28	99.06	98.57	98.96	98.77	98.65
Woods	100/1265	94.71	96.38	94.53	97.06	97.60	97.02
Buildings-Grass-Trees-Drives	50/386	59.74	70.37	60.29	72.26	77.24	85.43
Stone-Steel-Towers	50/93	98.16	98.79	98.12	98.47	98.07	99.35
Overall accuracy		$81.32 \pm 0.99$	$86.70 \pm 0.64$	$81.42 \pm 1.05$	$84.82 \pm 0.92$	$86.56 \pm 1.00$	$87.63 \pm 0.64$

	VBM3D	LRTA	PARAFAC	LRMR	RLRTR
MPSNR	32.490	25.108	32.187	33.968	34.128
MSSIM	0.8918	0.7082	0.9044	0.9506	0.9605
MFSIM	0.9427	0.8581	0.9468	0.9699	0.9731

	#Samples	Methods
Class	Training/Total	SVM	VBM3D	LRTA	PARAFAC	LRMR	RLRTR
Alfalfa	15/46	88.45	93.23	88.10	84.71	93.77	94.97
Corn-no till	100/1428	74.07	80.66	74.31	78.30	77.01	80.53
Corn-min till	100/830	71.33	78.20	71.10	72.29	78.60	80.46
Corn	50/237	87.27	91.82	87.41	87.19	92.56	92.89
Grass-pasture	50/483	90.22	93.62	90.38	91.95	91.40	90.98
Grass-tree	100/730	97.19	99.18	97.08	98.38	98.61	99.32
Grass-pasture-mowed	15/28	92.46	98.23	92.38	91.15	93.46	99.92
Hay-windrowed	50/478	97.79	98.84	97.76	98.42	99.54	97.79
Oats	15/20	96.20	99.80	95.80	96.40	98.80	100.00
Soybeans-no till	100/972	78.76	84.94	78.55	82.48	83.81	87.41
Soybeans-min till	150/2455	76.31	83.22	76.63	81.58	84.69	84.53
Soybeans-clean till	50/593	74.90	83.20	75.30	78.35	79.80	78.48
Wheat	50/205	98.28	99.06	98.57	98.96	98.77	98.65
Woods	100/1265	94.71	96.38	94.53	97.06	97.60	97.02
Buildings-Grass-Trees-Drives	50/386	59.74	70.37	60.29	72.26	77.24	85.43
Stone-Steel-Towers	50/93	98.16	98.79	98.12	98.47	98.07	99.35
Overall accuracy		$81.32 \pm 0.99$	$86.70 \pm 0.64$	$81.42 \pm 1.05$	$84.82 \pm 0.92$	$86.56 \pm 1.00$	$87.63 \pm 0.64$

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Journal of the Optical Society of America A

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