Optical flow estimation using steered-L1 norm

Motion is a very important part of understanding the visual picture of the surrounding environment. In image processing it involves the estimation of displacements for image points in an image sequence. In this context dense optical flow estimation is concerned with the computation of pixel displace...

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Main Author: Zayouna, Ammar
Published: Middlesex University 2016
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Online Access:http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.703081
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spelling ndltd-bl.uk-oai-ethos.bl.uk-7030812018-06-12T03:18:48ZOptical flow estimation using steered-L1 normZayouna, Ammar2016Motion is a very important part of understanding the visual picture of the surrounding environment. In image processing it involves the estimation of displacements for image points in an image sequence. In this context dense optical flow estimation is concerned with the computation of pixel displacements in a sequence of images, therefore it has been used widely in the field of image processing and computer vision. A lot of research was dedicated to enable an accurate and fast motion computation in image sequences. Despite the recent advances in the computation of optical flow, there is still room for improvements and optical flow algorithms still suffer from several issues, such as motion discontinuities, occlusion handling, and robustness to illumination changes. This thesis includes an investigation for the topic of optical flow and its applications. It addresses several issues in the computation of dense optical flow and proposes solutions. Specifically, this thesis is divided into two main parts dedicated to address two main areas of interest in optical flow. In the first part, image registration using optical flow is investigated. Both local and global image registration has been used for image registration. An image registration based on an improved version of the combined Local-global method of optical flow computation is proposed. A bi-lateral filter was used in this optical flow method to improve the edge preserving performance. It is shown that image registration via this method gives more robust results compared to the local and the global optical flow methods previously investigated. The second part of this thesis encompasses the main contribution of this research which is an improved total variation L1 norm. A smoothness term is used in the optical flow energy function to regularise this function. The L1 is a plausible choice for such a term because of its performance in preserving edges, however this term is known to be isotropic and hence decreases the penalisation near motion boundaries in all directions. The proposed improved L1 (termed here as the steered-L1 norm) smoothness term demonstrates similar performance across motion boundaries but improves the penalisation performance along such boundaries.621.36Middlesex Universityhttp://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.703081http://eprints.mdx.ac.uk/21273/Electronic Thesis or Dissertation
collection NDLTD
sources NDLTD
topic 621.36
spellingShingle 621.36
Zayouna, Ammar
Optical flow estimation using steered-L1 norm
description Motion is a very important part of understanding the visual picture of the surrounding environment. In image processing it involves the estimation of displacements for image points in an image sequence. In this context dense optical flow estimation is concerned with the computation of pixel displacements in a sequence of images, therefore it has been used widely in the field of image processing and computer vision. A lot of research was dedicated to enable an accurate and fast motion computation in image sequences. Despite the recent advances in the computation of optical flow, there is still room for improvements and optical flow algorithms still suffer from several issues, such as motion discontinuities, occlusion handling, and robustness to illumination changes. This thesis includes an investigation for the topic of optical flow and its applications. It addresses several issues in the computation of dense optical flow and proposes solutions. Specifically, this thesis is divided into two main parts dedicated to address two main areas of interest in optical flow. In the first part, image registration using optical flow is investigated. Both local and global image registration has been used for image registration. An image registration based on an improved version of the combined Local-global method of optical flow computation is proposed. A bi-lateral filter was used in this optical flow method to improve the edge preserving performance. It is shown that image registration via this method gives more robust results compared to the local and the global optical flow methods previously investigated. The second part of this thesis encompasses the main contribution of this research which is an improved total variation L1 norm. A smoothness term is used in the optical flow energy function to regularise this function. The L1 is a plausible choice for such a term because of its performance in preserving edges, however this term is known to be isotropic and hence decreases the penalisation near motion boundaries in all directions. The proposed improved L1 (termed here as the steered-L1 norm) smoothness term demonstrates similar performance across motion boundaries but improves the penalisation performance along such boundaries.
author Zayouna, Ammar
author_facet Zayouna, Ammar
author_sort Zayouna, Ammar
title Optical flow estimation using steered-L1 norm
title_short Optical flow estimation using steered-L1 norm
title_full Optical flow estimation using steered-L1 norm
title_fullStr Optical flow estimation using steered-L1 norm
title_full_unstemmed Optical flow estimation using steered-L1 norm
title_sort optical flow estimation using steered-l1 norm
publisher Middlesex University
publishDate 2016
url http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.703081
work_keys_str_mv AT zayounaammar opticalflowestimationusingsteeredl1norm
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