Reconstructing relief surfaces - Oxford Brookes University
Reconstructing relief surfaces - Oxford Brookes University
Reconstructing relief surfaces - Oxford Brookes University
You also want an ePaper? Increase the reach of your titles
YUMPU automatically turns print PDFs into web optimized ePapers that Google loves.
404 G. Vogiatzis et al. / Image and Vision Computing 26 (2008) 397–404<br />
[8] W. Freeman, E. Pasztor, Learning to estimate scenes from images, in:<br />
M. Kearns, S. Solla, D. Cohn (Eds.), Advances in Neural Information<br />
Processing Systems, vol. 11, MIT Press, 1999.<br />
[9] W. Freeman, E. Pasztor, Learning to estimate scenes from images, in:<br />
M. Kearns, S. Solla, D. Cohn (Eds.), Advances in Neural Information<br />
Processing Systems, vol. 11, MIT Press, 1999.<br />
[10] P. Fua, Y.G. Leclerc, Object-centered surface reconstruction: combining<br />
multi-image stereo and shading, IJCV 16 (1995) 35–56.<br />
[11] D. Geiger, H. Ishikawa, Segmentation by grouping junctions, in:<br />
Proceedings of CVPR 1998, pp. 125–131.<br />
[12] J. Hailin, S. Soatto, A.J. Yezzi, Multi-view stereo beyond lambert, in:<br />
CVPR 2003, vol. 1, pp. 171–178.<br />
[13] H. Hoppe, T. De Rose, T. Duchamp, J. McDonald, W. Stuetzle,<br />
Mesh optimisation, in: Proceedings of SIGGRAPH 1993, pp. 19–26.<br />
[14] J. Isidoro, S. Sclaroff, Stochastic refinement of the visual hull to<br />
satisfy photometric and silhouette consistency constraints, in: Proceedings<br />
of International Conference on Computer Vision, 2003, pp.<br />
1335–1342.<br />
[15] V. Kolmogorov, R. Zabih, Multi-camera scene reconstruction via<br />
graph-cuts, in: ECCV 2002, vol. 3, pp. 82–96.<br />
[16] K.N. Kutulakos, S.M. Seitz, A theory of shape by space carving,<br />
International Journal of Computer Vision 38 (3) (2000) 199–218.<br />
[17] A. Lee, H. Moreton, H. Hoppe, Displaced subdivision <strong>surfaces</strong>, in:<br />
Siggraph 2000, Computer Graphics Proceedings, pp.85–94.<br />
[18] P.J. Narayanan, P.W. Rander, T. Kanade, Constructing virtual<br />
worlds using dense stereo, in: ICCV98, 1998, pp. 3–10.<br />
[19] S. Paris, F. Sillion, L. Quan, A surface reconstruction method using<br />
global graph cut optimization, in: Proceedings of Asian Conference<br />
on Computer Vision, January 2004.<br />
[20] S. Roy, I.J. Cox, A maximum-flow formulation of the n-camera<br />
stereo correspondence problem, in: Proceedings of ICCV 1998, pp.<br />
735–743.<br />
[21] D. Scharstein, R. Szeliski, A taxonomy and evaluation of dense twoframe<br />
stereo correspondence algorithms, International Journal of<br />
Computer Vision 47 (1–3) (2002) 7–42.<br />
[22] J.W. Shade, S.J. Gortler, L.-W. He, R. Szeliski, Layered depth<br />
images, Computer Graphics 32 (Annual Conference Series) (1998)<br />
231–242.<br />
[23] C. Strecha, R. Tuytelaars, L. Van Gool, Dense matching of multiple<br />
wide-baseline views, in: ICCV, 2003, pp. 1194–1201.<br />
[24] J. Sun, H,-Y Shum, N.-N. Zheng, Stereo matching using belief<br />
propagation, in: Proceedings of ECCV, 2002, pp. 510–524.<br />
[25] F.M. Tappen, W.T. Freeman, Comparison of graph cuts with belief<br />
propagation for stereo, using identical mrf parameters, in: ICCV,<br />
2003, vol. 2, pp. 900–907.<br />
[26] L. Zhang, S.M. Seitz. Image-based multiresolution shape recovery by<br />
surface deformation, in: Proceedings of SPIE: Videometrics and<br />
Optical Methods for 3D Shape Measurement, 2001, pp. 51–61.
Change language