Abstract
In very high-resolution (VHR) push-broom-type satellite sensor data, both destriping and denoising methods have become chronic problems and attracted major research advances in the remote sensing fields. Since the estimation of the original image from a noisy input is an ill-posed problem, a simple noise removal algorithm cannot preserve the radiometric integrity of satellite data. To solve these problems, we present a novel method to correct VHR data acquired by a push-broom-type sensor by combining wavelet-Fourier and multiscale non-local means (NLM) filters. After the wavelet-Fourier filter separates the stripe noise from the mixed noise in the wavelet low- and selected high-frequency sub-bands, random noise is removed using the multiscale NLM filter in both low- and high-frequency sub-bands without loss of image detail. The performance of the proposed method is compared to various existing methods on a set of push-broom-type sensor data acquired by Korean Multi-Purpose Satellite 3 (KOMPSAT-3) with severe stripe and random noise, and the results of the proposed method show significantly improved enhancement results over existing state-of-the-art methods in terms of both qualitative and quantitative assessments.
Highlights
The very high-resolution (VHR) satellite images acquired by a push-broom-type sensor are frequently contaminated by random and stripe noises
Push-broom-type sensors have been recently equipped in Korean Multi-Purpose Satellite 3 (KOMPSAT-3), WoldView-2, GeoEye-1 and QuickBird-2 and are subject to in-track striping without scan periodicity, since each line in the image is simultaneously acquired by a one-dimensional cross-track charge-coupled device (CCD) array
In order to preserve the radiometric integrity of satellite data, we present a novel image restoration framework that selectively combines destriping and denoising algorithms in the wavelet domain
Summary
The very high-resolution (VHR) satellite images acquired by a push-broom-type sensor are frequently contaminated by random and stripe noises. Push-broom-type sensors have been recently equipped in Korean Multi-Purpose Satellite 3 (KOMPSAT-3) (launched 2012), WoldView-2 (launched 2009), GeoEye-1 (launched 2008) and QuickBird-2 (launched 2001) and are subject to in-track striping without scan periodicity, since each line in the image is simultaneously acquired by a one-dimensional cross-track charge-coupled device (CCD) array. This type of sensor ensures a high signal-to-noise ratio (SNR) due to a longer dwell time than the whisk-broom-type sensor at the cost of random and stripe noises. In the past few decades, various denoising and/or destriping methods have been proposed to enhance satellite imagery
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