Depth Image Super-Resolution Construction Combined with High-Resolution Color Image of the Same Scene

Yu Wang; Yan Piao; Rongchun Sun

doi:10.3788/AOS201737.0810002

[1] Wang Qilong, Li Jianyong, Shen Haikuo. Target tracking system of binocular vision and laser range sensor[J]. Acta Optica Sinica, 36, 0912002(2016).

[2] Li Xi, Tang Rufeng, Li Zhulian et al. Laser ranging data processing based on the analysis of the binary image[J]. Chinese J Lasers, 41, 1208005(2014).

[3] Schuon S, Theobalt C, Davis J et al. High-quality scanning using time-of-flight depth super-resolution[C]. IEEE Computer Society Conference on Computer Vision and Pattern Recognition, 1-7(2008).

[4] Yang Y, Wang Z. Range image super-resolution via guided image filter[C]. International Conference on Internet Multimedia Computing and Service, 200-203(2012).

[5] Di Weiwei, Zhang Xudong, Hu Liangmei et al. Depth image super-resolution based on second-order total generalized variation constrained by color image[J]. Journal of Image and Graphics, 19, 1162-1167(2014).

[6] Cui Y, Schuon S, Chan D et al. 3D shape scanning with a time-of-flight camera[C]. Computer Vision and Pattern Recognition, 1173-1180(2010).

[7] Schuon S, Theobalt C, Davis J et al. LidarBoost: depth superresolution for ToF 3d shape scanning[C]. Computer Vision and Pattern Recognition, 343-350(2009).

[8] Yang Q, Yang R, Davis J et al. Spatial-depth super resolution for range images[C]. Computer Vision and Pattern Recognition, 1-8(2007).

[9] Diebel J, Thrun S. An application of markov random fields to range sensing[C]. Advances in Neural Information Processing Systems, 291-298(2005).

[10] Lu J, Min D, Pahwa R S et al. A revisit to MRF-based depth map super-resolution and enhancement[C]. IEEE International Conference on Acoustics, Speech and Signal Processing, 985-988(2011).

[11] Park J, Kim H, Tai Y W et al. High quality depth map upsampling for 3D-TOF cameras[C]. IEEE International Conference on Computer Vision, 1623-1630(2012).

[12] Kopf J, Cohen M F, Lischinski D et al. Joint bilateral upsampling[C]. ACM Transactions on Graphics(2007).

[13] He K, Sun J, Tang X. Guided image filtering[C]. European Conference on Computer Vision, 1-14(2010).

[14] Ferstl D, Reinbacher C, Ranftl R et al. Image guided depth upsampling using anisotropic total generalized variation[C]. IEEE International Conference on Computer Vision, 993-1000(2013).

[15] Torralba A, Freeman W. Properties and applications of shape recipes[C]. Computer Vision & Pattern Recognition(2003).

[16] Zhang Lihong, Liang Yingbo, Wu Dingyun et al. Strip steel surface defects imaging edge inspection based on improved multi-scale morphology[J]. Laser & Infrared, 44, 330-334(2014).

[17] Chambolle A, Pock T. A first-order primal-dual algorithm for convex problems with applications toimaging[J]. Journal of Mathematical Imaging and Vision, 40, 120-145(2011).

[18] Esser E, Zhang X, Chan T. A general framework for a class of first order primal-dual algorithms for convex optimization in imagingscience[J]. Siam Journal on Imaging Sciences, 3, 1015-1046(2010).

[19] Pock T, Chambolle A. Diagonal preconditioning for first order primal-dual algorithms in convex optimization[C]. IEEE International Conference on Computer Vision, 1762-1769(2011).

[20] Hirschmuller H, Scharstein D. Evaluation of cost functions for stereo matching[C]. Computer Vision and Pattern Recognition, 1-8(2007).

[21] Scharstein D, Pal C. Learning conditional random fields for stereo[C]. Computer Vision and Pattern Recognition, 1-8(2007).

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