Context-adaptive matching for optical flow

Modern sparse-to-dense optical flow estimation algorithms usually achieve state-of-art performance. Those algorithms need two steps: matching and interpolation. Matching is often unreliable for very large displacement optical flow due to illumination changes, deformations and occlusion etc. Moreover...

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Veröffentlicht in:	Multimedia tools and applications 2019, Vol.78 (1), p.641-659
Hauptverfasser:	Zu, Yueran, Tang, Wenzhong, Bao, Xiuguo, Wang, Yanyang, Gao, Ke
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Sprache:	eng
Schlagworte:	Algorithms Computer Communication Networks Computer Science Computer terminals Data Structures and Information Theory Deformation Displacement Feature extraction Interpolation Matching Multimedia Information Systems Occlusion Optical flow (image analysis) Pedestrians Propagation Special Purpose and Application-Based Systems
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creator	Zu, Yueran Tang, Wenzhong Bao, Xiuguo Wang, Yanyang Gao, Ke
description	Modern sparse-to-dense optical flow estimation algorithms usually achieve state-of-art performance. Those algorithms need two steps: matching and interpolation. Matching is often unreliable for very large displacement optical flow due to illumination changes, deformations and occlusion etc. Moreover, conspicuous errors around motion discontinuities still keep serious as most methods consider edge only at interpolation step. The context-adaptive matching (CAM) is proposed for optical flow which is better at large displacement and edge preserving. The CAM is selective in feature extraction, adaptive in flow propagation and search radius adjusting. Selective features are proposed to consider edge preserving in matching step. Except for the usually used SIFT descriptor, the local directional pattern flow (LDPF) is introduced to keep more edge structure, and the oriented fast and rotated brief (ORB) is utilized to select out several most similar candidates. Unlike coarse-to-fine matching, which proposed a propagation step with only neighbors, we propose adaptive propagation to extend the matching candidates in order to improve the possibility of getting right correspondences. Furthermore, guided by prior knowledge and taking advantage of upper layers results, adaptive radius instead of constrained radius are proposed at finer layers. The CAM interpolated by EpicFlow is fast and robust for large displacements especially for fast moving objects and also preserves the edge structure well. Extensive experiments show that our algorithm is on par with the state-of-art optical flow methods on MPI-Sintel, KITTI and Middlebury.
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subjects	Algorithms Computer Communication Networks Computer Science Computer terminals Data Structures and Information Theory Deformation Displacement Feature extraction Interpolation Matching Multimedia Information Systems Occlusion Optical flow (image analysis) Pedestrians Propagation Special Purpose and Application-Based Systems
title	Context-adaptive matching for optical flow
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