Local Signal-Dependent Noise Variance Estimation From Hyperspectral Textural Images

A maximum-likelihood method for estimating hyperspectral sensors random noise components, both dependent and independent from the signal, is proposed. A hyperspectral image is locally jointly processed in the spatial and spectral dimensions within a multicomponent scanning window (MSW), as small as...

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Bibliographic Details
Published in:IEEE journal of selected topics in signal processing 2011-06, Vol.5 (3), p.469-486
Main Authors: Uss, Mikhail L, Vozel, Benoît, Lukin, Vladimir V, Chehdi, Kacem
Format: Article
Language:English
Subjects:
Additives
Airborne Visible/Infrared Imaging Spectrometer (AVIRIS)
Band spectra
Calibration
Correlation
Cramér-Rao lower bound (CRLB)
Estimates
fractal Brownian motion (fBm) model
Fractals
hyperspectral imagery
Hyperspectral imaging
Image texture
maximum-likelihood (ML) estimation
Noise
noise variance estimation
Random noise
signal-dependent noise
Spectra
Texture
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Summary:A maximum-likelihood method for estimating hyperspectral sensors random noise components, both dependent and independent from the signal, is proposed. A hyperspectral image is locally jointly processed in the spatial and spectral dimensions within a multicomponent scanning window (MSW), as small as 7 × 7 × 7 spatial-spectral pixels. Each MSW is regarded as an additive mixture of spectrally correlated fractal Brownian motion (fBm)-samples and random noise. The main advantage of the proposed method is its ability to accurately estimate band noise variances locally by using spatial and spectral texture correlations from a single textural MSW. For each spectral band, both additive and signal-dependent band noise components are estimated by linear fit of local noise variances obtained from many MSWs distributed over the whole band intensity range. CRLB-based analysis of the estimator performance shows that a good compromise is to jointly process seven adjacent spectral bands. The proposed method performance is assessed first on synthetic fBm-data and on real images with synthesized noise. Finally, four different AVIRIS datasets from 1997 flying season are considered. Good coincidence between additive and signal-dependent AVIRIS random noise components estimates obtained by our method and the estimates retrieved from AVIRIS calibration data is demonstrated. These experiments suggest that it is worth taking into account noise signal-dependency hypothesis for processing AVIRIS data.
ISSN:1932-4553
1941-0484
DOI:10.1109/JSTSP.2010.2104312