[go: up one dir, main page]
More Web Proxy on the site http://driver.im/ skip to main content
10.1145/2818143.2818165acmotherconferencesArticle/Chapter ViewAbstractPublication Pagessiggraph-asiaConference Proceedingsconference-collections
abstract

Advances in geometry and reflectance acquisition (course notes)

Published: 02 November 2015 Publication History

Abstract

The demands for digital 3D content for numerous applications such as video games, movies, virtual prototyping, advertisement, virtual reality, augmented reality or even digital preservation of cultural heritage objects has led to a need for efficient and accurate automatic acquisition systems for both geometry and reflectance. This short course sheds light on the acquisition ecosystem with three of its most important components that consist in accurate acquisition methods for geometry and reflectance as well as strategies towards an efficient acquisition pipeline to fulfill the demands of industry with respect to mass digitization of 3D contents. In this context, this course provides a thorough overview of the standard methods for the acquisition of both geometry and reflectance of surfaces with different types of reflectance behavior ranging from diffuse over opaque to specular surfaces or even translucent and transparent surfaces. These standard acquisition techniques are - by design - only well-suited for a limited range of surface materials and, hence, not adequate if no prior information with respect to the surface reflectance behavior is available. For this reason, we also discuss recent advances towards an efficient, fully automatic acquisition in the scope of the concluding remarks.

References

[1]
Ackermann, J., Fuhrmann, S., and Goesele, M. 2013. Geometric point light source calibration. In Proceedings of Vision, Modeling and Visualization (VMV), 161--168.
[2]
Adato, Y., Vasilyev, Y., Ben-Shahar, O., and Zickler, T. 2007. Towards a theory of shape from specular flow. In Proceedings of the International Conference on Computer Vision (ICCV), 1--8.
[3]
Adelson, E. H., and Bergen, J. R. 1991. The plenoptic function and the elements of early vision. In Computational Models of Visual Processing. 3--20.
[4]
Agarwal, S., Mallick, S. P., Kriegman, D., and Belongie, S. 2004. On refractive optical flow. In Proceedings of the European Conference on Computer Vision (ECCV), 483--494.
[5]
Agarwal, S., Snavely, N., Simon, I., Seitz, S. M., and Szeliski, R. 2009. Building Rome in a day. In Proceedings of the International Conference on Computer Vision (ICCV), 72--79.
[6]
Aittala, M., Weyrich, T., and Lehtinen, J. 2013. Practical svbrdf capture in the frequency domain. ACM Transactions on Graphics 32, 4, 110:1--110:12.
[7]
Aittala, M., Weyrich, T., and Lehtinen, J. 2015. Two-shot svbrdf capture for stationary materials. ACM Transactions on Graphics 34, 4, 110:1--110:13.
[8]
Ali, M. A., Sato, I., Okabe, T., and Sato, Y. 2013. Toward efficient acquisition of brdfs with fewer samples. In Proceedings of the Asian Conference on Computer Vision (ACCV), vol. 4, 54--67.
[9]
Aliaga, D. G., and Xu, Y. 2008. Photogeometric structured light: A self-calibrating and multi-viewpoint framework for accurate 3D modeling. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[10]
Aliaga, D. G., and Xu, Y. 2010. A self-calibrating method for photogeometric acquisition of 3D objects. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 32, 4, 747--754.
[11]
Alldrin, N., Zickler, T., and Kriegman, D. 2008. Photometric stereo with non-parametric and spatially-varying reflectance. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[12]
Allène, C., Pons, J.-P., and Keriven, R. 2008. Seamless image-based texture atlases using multi-band blending. In Proceedings of the International Conference on Pattern Recognition (ICPR), 1--4.
[13]
Aloimonos, J. 1988. Shape from texture. Biological Cybernetics 58, 345--360.
[14]
Ashikhmin, M., and Shirley, P. 2000. An anisotropic phong brdf model. Journal of Graphics Tools 5, 2, 25--32.
[15]
Aubreton, O., Eren, G., Bokhabrine, Y., Bajard, A., and Truchetet, F. 2012. Estimation of surface normal vectors based on 3d scanning from heating approach. In Proceedings of SPIE, vol. 8290, 82900X-1-82900X-6.
[16]
Bai, J., Chandraker, M., Ng, T.-T., and Ramamoorthi, R. 2010. A dual theory of inverse and forward light transport. In Proceedings of the European Conference on Computer Vision (ECCV), 1--8.
[17]
Balzer, J., and Werling, S. 2010. Principles of shape from specular reflection. Measurement 43, 1305--1317.
[18]
Balzer, J., Holer, S., and Beyerer, J. 2011. Multiview specular stereo reconstruction of large mirror surfaces. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 2537--2544.
[19]
Basri, R., Jacobs, D., and Kemelmacher, I. 2007. Photometric stereo with general, unknown lighting. International Journal of Computer Vision (IJCV) 72, 3, 239--257.
[20]
Baumberg, A. 2002. Blending images for texturing 3d models. In Proceedings of the British Machine Vision Conference (BMVC), 38.1--38.10.
[21]
Bay, H., Ess, A., Tuytelaars, T., and van Gool, L. 2008. Speeded-up robust features (SURF). Computer Vision and Image Understanding 110, 3, 346--359.
[22]
Beckmann, P., and Spizzichino, A. 1987. The Scattering of Electromagnetic Waves from Rough Surfaces. Artech House Publishers.
[23]
Beecroft, M. T., and Mattison, P. R. 1997. Design review of an in-situ bidirectional reflectometer. In Proceedings of SPIE, vol. 3141, 196--208.
[24]
Beljan, M., Ackermann, J., and Goesele, M. 2012. Consensus multi-view photometric stereo. In Pattern Recognition, vol. 7476 of Lecture Notes in Computer Science, 287--296.
[25]
Ben-Ezra, M., and Nayar, S. K. 2003. What does motion reveal about transparency? In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 1025--1032.
[26]
Ben-Ezra, M., Wang, J., Wilburn, B., Li, X., and Ma, L. 2008. An led-only brdf measurement device. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[27]
Bhandari, A., Feigin, M., Izadi, S., Rhemann, C., Schmidt, M., and Raskar, R. 2014. Resolving multipath interference in Kinect: An inverse problem approach. In Sensors, 614--617.
[28]
Birkbeck, N., Cobzas, D., Jagersand, M., and Sturm, P. 2006. Variational shape and reflectance estimation under changing light and viewpoints. In Proceedings of the European Conference on Computer Vision (ECCV), 536--549.
[29]
Blinn, J. F. 1977. Models of light reflection for computer synthesized pictures. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 192--198.
[30]
Bonfort, T., and Sturm, P. 2003. Voxel carving for specular surfaces. In Proceedings of the International Conference on Computer Vision (ICCV), 591--596.
[31]
Brady, M., and Yuille, A. 1984. An extremum principle for shape from contour. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 6, 288--301.
[32]
Callieri, M., Cignoni, P., Corsini, M., and Scopigno, R. 2008. Masked photo blending: Mapping dense photographic data set on high-resolution sampled 3d models. Computers & Graphics 32, 4, 464--473.
[33]
Chang, J. Y., Lee, K. M., and Lee, S. U. 2007. Multiview normal field integration using level set methods. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[34]
Chen, T., Goesele, M., and Seidel, H.-P. 2006. Mesostructure from specularity. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, 1825--1832.
[35]
Chen, T., Lensch, H., Fuchs, C., and Seidel, H.-P. 2007. Polarization and phase-shifting for 3d scanning of translucent objects. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[36]
Chen, T., Seidel, H.-P., and Lensch, H. 2008. Modulated phase-shifting for 3d scanning. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[37]
Chen, Z., Zhou, J., Chen, Y., and Wang, G. 2012. 3D texture mapping in multi-view reconstruction. In Advances in Visual Computing, vol. 7431 of Lecture Notes in Computer Science, 359--371.
[38]
Chen, G., Dong, Y., Peers, P., Zhang, J., and Tong, X. 2014. Reflectance scanning: Estimating shading frame and brdf with generalized linear light sources. ACM Transactions on Graphics 33, 4, 117:1--117:11.
[39]
Chung, H.-S., and Jia, J. 2008. Efficient photometric stereo on glossy surfaces with wide specular lobes. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[40]
Coleman, E. N., and Jain, R. 1982. Obtaining 3-dimensional shape of textured and specular surfaces using four-source photometry. Computer Graphics and Image Processing 18, 4, 309--328.
[41]
Comaniciu, D., and Meer, P. 2002. Mean shift: A robust approach toward feature space analysis. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 24, 5, 603--619.
[42]
Cook, R. L., and Torrance, K. E. 1982. A reflectance model for computer graphics. ACM Transactions on Graphics 1, 1, 7--24.
[43]
Cremers, D., and Kolev, K. 2011. Multiview stereo and silhouette consistency via convex functionals over convex domains. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 33, 6, 1161--1174.
[44]
Cula, O., Dana, K., Murphy, F., and Rao, B. 2004. Bidirectional imaging and modeling of skin texture. IEEE Transactions on Biomedical Engineering 51, 12, 2148--2159.
[45]
Curless, B. L. 1997. New methods for surface reconstruction from range images. PhD thesis, Stanford University, Stanford, USA.
[46]
Dai, Z., 2009. A Markov random field approach for multi-view normal integration. Master-Thesis, University of Hong Kong.
[47]
Dal Mutto, C., Zanuttigh, P., and Cortelazzo, G. M. 2012. Time-of-Flight Cameras and Microsoft Kinect™. Springer New York, USA.
[48]
Dana, K. J., and Wang, J. 2004. Device for convenient measurement of spatially varying bidirectional reflectance. Journal of the Optical Society of America A 21, 1, 1--12.
[49]
Dana, K. J., van Ginneken, B., Nayar, S. K., and Koenderink, J. J. 1997. Reflectance and texture of real world surfaces. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 151--157.
[50]
Dana, K. J. 2001. BRDF/BTF measurement device. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 460--466.
[51]
Darrell, T., and Wohn, K. 1988. Pyramid based depth from focus. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 504--509.
[52]
Debevec, P., Hawkins, T., Tchou, C., Duiker, H.-P., Sarokin, W., and Sagar, M. 2000. Acquiring the reflectance field of a human face. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 145--156.
[53]
Debevec, P., Wenger, A., Tchou, C., Gardner, A., Waese, J., and Hawkins, T. 2002. A lighting reproduction approach to live-action compositing. Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH) 21, 3, 547--556.
[54]
Debevec, P. E. 1996. Modeling and rendering architecture from photographs. PhD thesis, University of California, Berkeley, USA.
[55]
Delaunoy, A., and Prados, E. 2011. Gradient flows for optimizing triangular mesh-based surfaces: Applications to 3d reconstruction problems dealing with visibility. International Journal of Computer Vision (IJCV), 100--123.
[56]
Delaunoy, A., Prados, E., and Belhumeur, P. N. 2010. Towards full 3D Helmholtz stereovision algorithms. In Proceedings of the Asian Conference on Computer Vision (ACCV), vol. 1, 39--52.
[57]
Dellepiane, M., Corsini, M., Callieri, M., and Scopigno, R. 2006. High quality ptm acquisition: Reflection transformation imaging for large objects. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 179--186.
[58]
Dellepiane, M., Marroquim, R., Callieri, M., Cignoni, P., and Scopigno, R. 2012. Flow-based local optimization for image-to-geometry projection. IEEE Transactions on Visualization and Computer Graphics (TVCG) 18, 3, 463--474.
[59]
den Brok, D., Steinhausen, H. C., Hullin, M. B., and Klein, R. 2014. Patch-based sparse reconstruction of material btfs. Journal of WSCG 22, 2, 83--90.
[60]
den Brok, D., Steinhausen, H. C., Hullin, M. B., and Klein, R. 2015. Multiplexed acquisition of bidirectional texture functions for materials. In Proceedings of SPIE, vol. 9398, 93980F-1-93980F-9.
[61]
DeYoung, J., and Fournier, A. 1997. Properties of tabulated bidirectional reflectance distribution functions. In Proceedings of Graphics Interface, 47--55.
[62]
Dong, Y., Wang, J., Pellacini, F., Tong, X., and Guo, B. 2010. Fabricating spatially-varying subsurface scattering. ACM Transactions on Graphics 29, 4, 62:1--62:10.
[63]
Dong, Y., Wang, J., Tong, X., Snyder, J., Lan, Y., Ben-Ezra, M., and Guo, B. 2010. Manifold bootstrapping for svbrdf capture. ACM Transactions on Graphics 29, 4, 98:1--98:10.
[64]
Dong, Y., Lin, S., and Guo, B. 2013. Material appearance modeling: A data-coherent approach. Springer Berlin Heidelberg, Germany.
[65]
Dong, B., Moore, K. D., Zhang, W., and Peers, P. 2014. Scattering parameters and surface normals from homogeneous translucent materials using photometric stereo. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 2299--2306.
[66]
Donner, C., and Jensen, H. W. 2005. Light diffusion in multi-layered translucent materials. ACM Transactions on Graphics 24, 3, 1032--1039.
[67]
Donner, C., Weyrich, T., d'Eon, E., Ramamoorthi, R., and Rusinkiewicz, S. 2008. A layered, heterogeneous reflectance model for acquiring and rendering human skin. In ACM SIGGRAPH Asia 2008 Papers, 140:1--140:12.
[68]
Dorrington, A. A., Godbaz, J. P., Cree, M. J., Payne, A. D., and Streeter, L. V. 2011. Separating true range measurements from multi-path and scattering interference in commercial range cameras. Proceedings of SPIE 7864, 786404--1-786404-10.
[69]
Droeschel, D., Holz, D., and Behnke, S. 2010. Multi-frequency phase unwrapping for time-of-flight cameras. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems, 1463--1469.
[70]
Durou, J.-D., Falcone, M., and Sagona, M. 2008. Numerical methods for shape-from-shading: A new survey with benchmarks. Computer Vision and Image Understanding 109, 1, 22--43.
[71]
Eren, G., Aubreton, O., Meriaudeau, F., Secades, L. A. S., Fofi, D., Naskali, A. T., Truchetet, F., and Ercil, A. 2009. Scanning from heating: 3d shape estimation of transparent objects from local surface heating. Optics Express 17, 14, 11457--11468.
[72]
Esteban, C. H., and Schmitt, F. 2004. Silhouette and stereo fusion for 3d object modeling. Computer Vision and Image Understanding 96, 367--392.
[73]
Esteban, C. H., Vogiatzis, G., and Cipolla, R. 2008. Multiview photometric stereo. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 30, 3, 548--554.
[74]
Filip, J., and Haindl, M. 2009. Bidirectional texture function modeling: A state of the art survey. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 31, 11, 1921--1940.
[75]
Filip, J., Vávra, R., Haindl, M., Žid, P., Krupička, M., and Havran, V. 2013. BRDF slices: Accurate adaptive anisotropic appearance acquisition. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR). 1468--1473.
[76]
Foo, S. C. 1997. A gonioreflectometer for measuring the bidirectional reflectance of material for use in illumination computation. PhD thesis, Cornell University, Ithaca, USA.
[77]
Frahm, J.-M., Fite-Georgel, P., Gallup, D., Johnson, T., Raguram, R., Wu, C., Jen, Y.-H., Dunn, E., Clipp, B., Lazebnik, S., and Pollefeys, M. 2010. Building Rome on a cloudless day. In Proceedings of the European Conference on Computer Vision (ECCV), 368--381.
[78]
Francken, Y., Cuypers, T., Mertens, T., Gielis, J., and Bekaert, P. 2008. High quality mesostructure acquisition using specularities. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--7.
[79]
Freedman, D., Smolin, Y., Krupka, E., Leichter, I., and Schmidt, M. 2014. SRA: Fast removal of general multipath for ToF sensors. In Computer Vision - ECCV 2014, D. Fleet, T. Pajdla, B. Schiele, and T. Tuytelaars, Eds., vol. 8689 of Lecture Notes in Computer Science. Springer International Publishing, 234--249.
[80]
Fuchs, C., Goesele, M., Chen, T., and Seidel, H.-P. 2005. An empirical model for translucent objects. SIGGRAPH Sketches 2005.
[81]
Fuchs, M., Blanz, V., Lensch, H. P. A., and Seidel, H.-P. 2007. Adaptive sampling of reflectance fields. ACM Transactions on Graphics 26, 2, 10:1--10:18.
[82]
Furukawa, R., Kawasaki, H., Ikeuchi, K., and Sakauchi, M. 2002. Appearance based object modeling using texture database: Acquisition, compression and rendering. In Proceedings of the Eurographics Workshop on Rendering, 257--266.
[83]
Gal, R., Wexler, Y., Ofek, E., Hoppe, H., and Cohen-Or, D. 2010. Seamless montage for texturing models. Computer Graphics Forum 29, 2, 479--486.
[84]
Garcia-Dorado, I., Demir, I., and Aliaga, D. G. 2013. Automatic urban modeling using volumetric reconstruction with surface graph cuts. Computers & Graphics 37, 7, 896--910.
[85]
Garg, G., Talvala, E.-V., Levoy, M., and Lensch, H. P. A. 2006. Symmetric photography: Exploiting data-sparseness in reflectance fields. In Proceedings of the Eurographics Symposium on Rendering (EGSR). 251--262.
[86]
Geiges, M. L. 2009. Traces of Marion B. Sulzberger in the museum of wax moulages in Zurich and their importance for the history of dermatology. Journal of the American Academy of Dermatology 60, 6, 980--984.
[87]
Georghiades, A. S. 2003. Incorporating the torrance and sparrow model of reflectance in uncalibrated photometric stereo. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 816--823.
[88]
Ghosh, A., Achutha, S., Heidrich, W., and O'Toole, M. 2007. Brdf acquisition with basis illumination. In Proceedings of the International Conference on Computer Vision (ICCV), 1--8.
[89]
Ghosh, A., Hawkins, T., Peers, P., Frederiksen, S., and Debevec, P. 2008. Practical modeling and acquisition of layered facial reflectance. ACM Transactions on Graphics 27, 5, 139:1--139:10.
[90]
Ghosh, A., Chen, T., Peers, P., Wilson, C. A., and Debevec, P. 2009. Estimating specular roughness and anisotropy from second order spherical gradient illumination. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 1161--1170.
[91]
Ghosh, A., Chen, T., Peers, P., Wilson, C. A., and Debevec, P. 2010. Circularly polarized spherical illumination reflectometry. ACM Transactions on Graphics 29, 6, 162:1--162:12.
[92]
Gibson, J. J. 1950. The perception of the visual world. Houghton Mifflin, Boston, USA.
[93]
Glassner, A. S. 1995. Principles of digital image synthesis. Morgan Kaufmann Publishers Inc., San Francisco, CA, USA.
[94]
Goddyn, L., and Gvozdjak, P. 2003. Binary gray codes with long bit runs. The Electronic Journal of Combinatorics 10, 1--10. R27.
[95]
Goesele, M., Lensch, H. P. A., Lang, J., Fuchs, C., and Seidel, H.-P. 2004. Disco: Acquisition of translucent objects. ACM Transactions on Graphics 23, 3, 835--844.
[96]
Goldlucke, B., Ihrke, I., Linz, C., and Magnor, M. 2007. Weighted minimal hypersurface reconstruction. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 29, 7, 1194--1208.
[97]
Goldman, D. B., Curless, B., Hertzmann, A., and Seitz, S. M. 2005. Shape and spatially-varying brdfs from photometric stereo. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 1, 341--348.
[98]
Gortler, S. J., Grzeszczuk, R., Szeliski, R., and Cohen, M. F. 1996. The lumigraph. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 43--54.
[99]
Grammatikopoulos, L., Kalisperakis, I., Karras, G., and Petsa, E. 2007. Automatic multi-view texture mapping of 3d surface projections. In 3D Virtual Reconstruction & Visualization of Complex Architectures (3D Arch).
[100]
Guenther, J., Chen, T., Goesele, M., Wald, I., and Seidel, H.-P. 2005. Efficient acquisition and realistic rendering of car paint. Proceedings of Vision, Modeling, and Visualization (VMV), 487--494.
[101]
Gupta, M., Agrawal, A., Veeraraghavan, A., and Narasimhan, S. G. 2011. Structured light 3d scanning in the presence of global illumination. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 713--720.
[102]
Haber, T., Fuchs, C., Bekaert, P., Seidel, H.-P., Goesele, M., and Lensch, H. P. A. 2009. Relighting objects from image collections. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 627--634.
[103]
Haindl, M., and Filip, J. 2011. Advanced textural representation of materials appearance. In SIGGRAPH Asia 2011 Courses. 1:1--1:84.
[104]
Haindl, M., and Filip, J. 2013. Visual texture: Accurate material appearance measurement, representation and modeling. Advances in Computer Vision and Pattern Recognition. Springer, New York, USA.
[105]
Han, J. Y., and Perlin, K. 2003. Measuring bidirectional texture reflectance with a kaleidoscope. ACM Transactions on Graphics 22, 3, 741--748.
[106]
Hanrahan, P., and Krueger, W. 1993. Reflection from layered surfaces due to subsurface scattering. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 165--174.
[107]
Hartley, R. I., and Zisserman, A. 2004. Multiple view geometry in computer vision (2nd edition). Cambridge University Press, Cambridge, UK.
[108]
Hata, S., Saitoh, Y., Kumamura, S., and Kaida, K. 1996. Shape extraction of transparent object using genetic algorithm. In Proceedings of the International Conference on Pattern Recognition (ICPR), vol. 4, 684--688.
[109]
Hawkins, T., Cohen, J., and Debevec, P. 2001. A photometric approach to digitizing cultural artifacts. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 333--342.
[110]
Hawkins, T., Einarsson, P., and Debevec, P. 2005. A dual light stage. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 91--98.
[111]
He, X. D., Torrance, K. E., Sillion, F. X., and Greenberg, D. P. 1991. A comprehensive physical model for light reflection. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 175--186.
[112]
Herbort, S., and Wöhler, C. 2011. An introduction to image-based 3d surface reconstruction and a survey of photometric stereo methods. 3D Research 2, 3, 40:1--40:17.
[113]
Hertzmann, A., and Seitz, S. M. 2005. Example-based photometric stereo: Shape reconstruction with general, varying brdfs. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 27, 1254--1264.
[114]
Higo, T., Matsushita, Y., Joshi, N., and Ikeuchi, K. 2009. A hand-held photometric stereo camera for 3-d modeling. In Proceedings of the International Conference on Computer Vision (ICCV), 1234--1241.
[115]
Higo, T., Matsushita, Y., and Ikeuchi, K. 2010. Consensus photometric stereo. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1157--1164.
[116]
Holroyd, M., Lawrence, J., and Zickler, T. 2010. A coaxial optical scanner for synchronous acquisition of 3D geometry and surface reflectance. ACM Transactions on Graphics 29, 4, 99:1--99:12.
[117]
Höpe, A., Atamas, T., Hünerhoff, D., Teichert, S., and Hauer, K.-O. 2012. ARGon3: 3d appearance robot-based gonioreflectometer at ptb. The Review of Scientific Instruments 83, 4, 11--16.
[118]
Horn, B. K. P., and Schunck, B. G. 1981. Determining optical flow. Artificial Intelligence 17, 185--203.
[119]
Horn, B. K. P. 1970. Shape from shading: A method for obtaining the shape of a smooth opaque object from one view. Tech. rep., Massachusetts Institute of Technology, Cambridge, MA, USA.
[120]
Hornung, A., and Kobbelt, L. 2006. Hierarchical volumetric multi-view stereo reconstruction of manifold surfaces based on dual graph embedding. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 503--510.
[121]
Hu, Y., Qi, Y., and Shen, F. 2010. Modeling spatially-varying reflectance based on kernel nyström. In Proceedings of the ACM Symposium on Virtual Reality Software and Technology (VRST). 91--92.
[122]
Hu, Y., Wang, S., and Qi, Y. 2013. Efficient reconstruction, decomposition and editing for spatially-varying reflectance data. In Proceedings of the Graphics Interface Conference (GI). 55--62.
[123]
Hullin, M. B., Fuchs, M., Ihrke, I., Seidel, H.-P., and Lensch, H. P. A. 2008. Fluorescent immersion range scanning. ACM Transactions on Graphics 27, 3, 87:1--87:10.
[124]
Hünerhoff, D., Grusemann, U., and Höpe, A. 2006. New robot-based gonioreflectometer for measuring spectral diffuse reflection. Metrologia 43, 2, 11--16.
[125]
Ihrke, I., and Magnor, M. 2006. Adaptive grid optical tomography. In Graphical Models, vol. 68, 484--495.
[126]
Ihrke, I., Kutulakos, K. N., Lensch, H. P. A., Magnor, M., and Heidrich, W. 2010. Transparent and specular object reconstruction. Computer Graphics Forum 29, 8, 2400--2426.
[127]
Ihrke, I., Reshetouski, I., Manakov, A., Tevs, A., Wand, M., and Seidel, H.-P. 2012. A kaleidoscopic approach to surround geometry and reflectance acquisition. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition Workshops (CVPRW). 29--36.
[128]
Ikeuchi, K., and Horn, B. K. P. 1981. Numerical shape from shading and occluding boundaries. Artificial Intelligence 17, 1, 141--184.
[129]
Ikeuchi, K. 1981. Determining surface orientations of specular surfaces by using the photometric stereo method. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 3, 6, 661--669.
[130]
Inoshita, C., Mukaigawa, Y., Matsushita, Y., and Yagi, Y. 2014. Surface normal deconvolution: Photometric stereo for optically thick translucent objects. In Proceedings of the European Conference on Computer Vision (ECCV), vol. 2, 346--359.
[131]
Jensen, H. W., Marschner, S. R., Levoy, M., and Hanrahan, P. 2001. A practical model for subsurface light transport. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 511--518.
[132]
Jin, H., Cremers, D., Yezzi, A. J., and Soatto, S. 2004. Shedding light on stereoscopic segmentation. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 1, I--36 -- I--42.
[133]
Jutzi, B. 2009. Investigations on ambiguity unwrapping of range images. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XXXVIII-3/W8, 265--270.
[134]
Jutzi, B. 2012. Extending the range measurement capabilities of modulated range imaging devices by time-frequency-multiplexing. Allgemeine Vermessungs-Nachrichten 2/2012, 54--62.
[135]
Kajiya, J. T. 1985. Anisotropic reflection models. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 15--21.
[136]
Kamal, M. H., Golbabaee, M., and Vandergheynst, P. 2012. Light field compressive sensing in camera arrays. In Proceedings of the International Conference on Acoustics, Speech, and Signal Processing.
[137]
Kanitsar, A., Theussl, T., Mroz, L., Sramek, M., Bartroli, A. V., Csebfalvi, B., Hladuvka, J., Fleischmann, D., Knapp, M., Wegenkittl, R., Felkel, P., Rottger, S., Guthe, S., Purgathofer, W., and Groller, M. E. 2002. Christmas tree case study: Computed tomography as a tool for mastering complex real world objects with applications in computer graphics. In Proceedings of the Conference on Visualization, 489--492.
[138]
Karner, K. F., Mayer, H., and Gervautz, M. 1996. An image based measurement system for anisotropic reflection. Computer Graphics Forum 15, 3, 119--128.
[139]
Kautz, J., Sattler, M., Sarlette, R., Klein, R., and Seidel, H.-P. 2004. Decoupling brdfs from surface mesostructures. In Proceedings of Graphics Interface, 177--182.
[140]
Ke, L. 1999. A method of light reflectance measurement. PhD thesis, University of British Columbia, Vancouver, Canada.
[141]
Kim, D. B., Kim, K. Y., Park, K. S., Seo, M. K., and Lee, K. H. 2008. A fast and accurate image-based measuring system for isotropic reflection materials. In Proceedings of SPIE, vol. 7065, 70650I1--70650I12.
[142]
Kimachi, A., Tanaka, N., and Tominaga, S. 2006. Development and calibration of a gonio-spectral imaging system for measuring surface reflection. IEICE - Transactions on Information and Systems E89-D, 1994--2003.
[143]
Koenderink, J. J., and van Doorn, A. J. 1998. Phenomenological description of bidirectional surface reflection. Journal of the Optical Society of America A 15, 11, 2903--2912.
[144]
Köhler, J., Nöll, T., Reis, G., and Stricker, D. 2013. A full-spherical device for simultaneous geometry and reflectance acquisition. In Proceedings of the IEEE Workshop on Applications of Computer Vision (WACV). 355--362.
[145]
Kolb, A., Barth, E., Koch, R., and Larsen, R. 2010. Time-of-flight cameras in computer graphics. Computer Graphics Forum 29, 1, 141--159.
[146]
Kolev, K., Pock, T., and Cremers, D. 2010. Anisotropic minimal surfaces integrating photoconsistency and normal information for multiview stereo. In Proceedings of the European Conference on Computer Vision (ECCV), 538--551.
[147]
Kolev, K., Kirchgeíner, N., Houben, S., Csiszár, A., Rubner, W., Palm, C., Eiben, B., Merkel, R., and Cremers, D. 2011. A variational approach to vesicle membrane reconstruction from fluorescence imaging. Pattern Recognition 44, 12, 2944--2958.
[148]
Koninckx, T. P., Peers, P., Dutre, P., and Van Gool, L. 2005. Scene-adapted structured light. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, 611--618.
[149]
Koudelka, M., Belhumeur, P., Magda, S., and Kriegman, D. 2001. Image-based modeling and rendering of surfaces with arbitrary brdfs. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 1, 568--575.
[150]
Koudelka, M. L., Magda, S., Belhumeur, P. N., and Kriegman, D. J. 2003. Acquisition, compression, and synthesis of bidirectional texture functions. In Proceedings of the ICCV Workshop on Texture Analysis and Synthesis, 47--52.
[151]
Krotkov, E. 1987. Focusing. International Journal of Computer Vision (IJCV) 1, 3, 223--237.
[152]
Kutulakos, K. N., and Steger, E. 2005. A theory of refractive and specular 3d shape by light-path triangulation. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 1448--1455.
[153]
Kutulakos, K. N., and Steger, E. 2008. A theory of refractive and specular 3d shape by light-path triangulation. International Journal of Computer Vision (IJCV) 76, 1, 13--29.
[154]
labsphere. Spectralonc diffuse reflectance targets. http://www.labsphere.com/uploads/pb13025Targets.pdf (accessed on 19 March 2014).
[155]
Ladikos, A., Benhimane, S., and Navab, N. 2008. Multi-view reconstruction using narrow-band graph-cuts and surface normal optimization. In Proceedings of the British Machine Vision Conference (BMVC), 15.1--15.10.
[156]
Lafortune, E. P. F., Foo, S.-C., Torrance, K. E., and Greenberg, D. P. 1997. Non-linear approximation of reflectance functions. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 117--126.
[157]
Lalonde, P., and Fournier, A. 1997. A wavelet representation of reflectance functions. IEEE Transactions on Visualization and Computer Graphics (TVCG) 3, 4, 329--336.
[158]
Lan, Y., Dong, Y., Wang, J., Tong, X., and Guo, B. 2010. Condenser-based instant reflectometry. In Computer Graphics Forum (Proceedings of Pacific Graphics), vol. 29, 117--126.
[159]
Lang, J., Seidel, H.-P., and Lensch, H. P. A. 2003. View planning for brdf acquisition. In ACM SIGGRAPH 2003 Sketches and Applications.
[160]
Laurentini, A. 1994. The visual hull concept for silhouette-based image understanding. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 16, 150--162.
[161]
Lawrence, J., Ben-Artzi, A., DeCoro, C., Matusik, W., Pfister, H., Ramamoorthi, R., and Rusinkiewicz, S. 2006. Inverse shade trees for non-parametric material representation and editing. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 735--745.
[162]
Lehtinen, J. 2007. A framework for precomputed and captured light transport. ACM Transactions on Graphics 26, 4, 13:1--13:22.
[163]
Leloup, F. B., Forment, S., Dutr, P., Pointer, M. R., and Hanselaer, P. 2008. Design of an instrument for measuring the spectral bidirectional scatter distribution function. Applied Optics 47, 29, 5454--5467.
[164]
Lempitsky, V., and Ivanov, D. 2007. Seamless mosaicing of image-based texture maps. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--6.
[165]
Lensch, H. P. A., Kautz, J., Goesele, M., Heidrich, W., and Seidel, H.-P. 2001. Image-based reconstruction of spatially varying materials. Rendering Techniques, 103--114.
[166]
Lensch, H. P. A., Kautz, J., Goesele, M., Heidrich, W., and Seidel, H.-P. 2003. Image-based reconstruction of spatial appearance and geometric detail. ACM Transactions on Graphics 22, 234--257.
[167]
Lensch, H. P. A., Lang, J., Sá, A. M., and Seidel, H.-P. 2003. Planned sampling of spatially varying brdfs. Computer Graphics Forum 22, 3, 473--482.
[168]
Levenberg, K. 1944. A method for the solution of certain non-linear problems in least squares. Quarterly Journal of Applied Mathematics II, 2, 164--168.
[169]
Levoy, M., and Hanrahan, P. 1996. Light field rendering. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 31--42.
[170]
Levoy, M., Chen, B., Vaish, V., Horowitz, M., McDowall, I., and Bolas, M. 2004. Synthetic aperture confocal imaging. Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH) 23, 3, 825--834.
[171]
Liang, C.-K., Lin, T.-H., Wong, B.-Y., Liu, C., and Chen, H. H. 2008. Programmable aperture photography: Multiplexed light field acquisition. ACM Transactions on Graphics 27, 3, 55:1--55:10.
[172]
Liu, M., Wong, K.-Y. K., Dai, Z., and Chen, Z. 2010. Specular surface recovery from reflections of a planar pattern undergoing an unknown pure translation. In Proceedings of the Asian Conference on Computer Vision (ACCV), vol. 2, 137--147.
[173]
Lloyd, S. P. 1957. Least squares quantization in PCM. Tech. rep., Bell Laboratories.
[174]
Lourakis, M. I. A., and Argyros, A. A. 2009. SBA: A software package for generic sparse bundle adjustment. ACM Transactions on Mathematical Software 36, 1, 1--30.
[175]
Lowe, D. G. 2004. Distinctive image features from scale-invariant keypoints. International Journal of Computer Vision (IJCV) 60, 91--110.
[176]
Lu, J., and Little, J. 1995. Reflectance function estimation and shape recovery from image sequence of a rotating object. In Proceedings of the International Conference on Computer Vision (ICCV), 80--86.
[177]
Lu, R., Koenderink, J. J., and Kappers, A. M. 1998. Optical properties (bidirectional reflection distribution functions) of velvet. Applied Optics 37, 25, 5974--5984.
[178]
Lu, Z., Tai, Y.-W., Ben-Ezra, M., and Brown, M. S. 2010. A framework for ultra high resolution 3d imaging. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1205--1212.
[179]
Lucas, B. D., and Kanade, T. 1981. An iterative image registration technique with an application to stereo vision. In Proceedings of the International Joint Conference on Artificial Intelligence (IJCAI), vol. 2, 674--679.
[180]
Ma, W.-C., Hawkins, T., Peers, P., Chabert, C.-F., Weiss, M., and Debevec, P. 2007. Rapid acquisition of specular and diffuse normal maps from polarized spherical gradient illumination. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 183--194.
[181]
MacQueen, J. B. 1967. Some methods for classification and analysis of multivariate observations. In Proceedings of the Berkeley Symposium on Mathematical Statistics and Probability, vol. 1, 281--297.
[182]
Maki, A., and Cipolla, R. 2009. Obtaining the shape of a moving object with a specular surface. In Proceedings of the British Machine Vision Conference (BMVC), 39.1--39.10.
[183]
Mallick, S. P., Zickler, T. E., Kriegman, D., and Belhumeur, P. N. 2005. Beyond lambert: reconstructing specular surfaces using color. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, 619--626.
[184]
Malzbender, T., Gelb, D., and Wolters, H. 2001. Polynomial texture maps. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 519--528.
[185]
Malzbender, T., Wilburn, B., Gelb, D., and Ambrisco, B. 2006. Surface enhancement using real-time photometric stereo and reflectance transformation. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 245--250.
[186]
Marschner, S. R., Westin, S. H., Lafortune, E. P. F., Torrance, K. E., and Greenberg, D. P. 1999. Image-based brdf measurement including human skin. In Proceedings of the Eurographics Workshop on Rendering, 131--144.
[187]
Marschner, S. R., Westin, S. H., Lafortune, E. P. F., and Torrance, K. E. 2000. Image-based bidirectional reflectance distribution function measurement. Applied Optics 39, 2592--2600.
[188]
Marschner, S. R., Westin, S. H., Arbree, A., and Moon, J. T. 2005. Measuring and modeling the appearance of finished wood. ACM Transactions on Graphics 24, 3, 727--734.
[189]
Marwah, K., Wetzstein, G., Bando, Y., and Raskar, R. 2013. Compressive light field photography using overcomplete dictionaries and optimized projections. ACM Transactions on Graphics 32, 4, 46:1--46:12.
[190]
Matusik, W., Pfister, H., Ngan, A., Beardsley, P., Ziegler, R., and McMillan, L. 2002. Image-based 3D photography using opacity hulls. Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH) 21, 3, 427--437.
[191]
Matusik, W., Pfister, H., Ziegler, R., Ngan, A., and McMillan, L. 2002. Acquisition and rendering of transparent and refractive objects. In Proceedings of the Eurographics Workshop on Rendering. 267--278.
[192]
Matusik, W., Pfister, H., Brand, M., and McMillan, L. 2003. A data-driven reflectance model. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 759--769.
[193]
Matusik, W., Pfister, H., Brand, M., and McMillan, L. 2003. Efficient isotropic brdf measurement. In Proceedings of the Eurographics Workshop on Rendering, 241--247.
[194]
McAllister, D. K. 2002. A Generalized Surface Appearance Representation for Computer Graphics. PhD thesis, University of North Carolina at Chapel Hill, Chapel Hill, USA.
[195]
Meister, G., Wiemker, R., Bienlein, J., and Spitzer, H. 1996. In situ BRDF measurements of selected surface materials to improve analysis of remotely sensed multispectral imagery. In International Archives for Photogrammetry and Remote Sensing, vol. 31-B7, 493--498.
[196]
Meriaudeau, F., Sanchez Secades, L. A., Eren, G., Ercil, A., Truchetet, F., Aubreton, O., and Fofi, D. 2010. 3-d scanning of nonopaque objects by means of imaging emitted structured infrared patterns. IEEE Transactions on Instrumentation and Measurement 59, 11, 2898--2906.
[197]
Meriaudeau, F., Rantoson, R., Adal, K., Fofi, D., and Stolz, C. 2012. Non-conventional imaging systems for 3D digitization of transparent objects: Shape from polarization in the IR and shape from visible fluorescence induced UV. In Proceedings of the International Topical Meeting on Optical Sensing and Artificial Vision (OSAV), 34--40.
[198]
Moons, T., Van Gool, L., and Vergauwen, M. 2010. 3D reconstruction from multiple images part 1: Principles. Foundations and Trends in Computer Graphics and Vision 4, 4, 287--404.
[199]
Morris, N. J. W., and Kutulakos, K. N. 2005. Dynamic refraction stereo. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 1573--1580.
[200]
Morris, N. J. W., and Kutulakos, K. N. 2007. Reconstructing the surface of inhomogeneous transparent scenes by scatter-trace photography. In Proceedings of the International Conference on Computer Vision (ICCV), 1--8.
[201]
Mudge, M., Voutaz, J.-P., Schroer, C., and Lum, M. 2005. Reflection transformation imaging and virtual representations of coins from the hospice of the grand st. bernard. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 29--39.
[202]
Mudge, M., Malzbender, T., Schroer, C., and Lum, M. 2006. New reflection transformation imaging methods for rock art and multiple-viewpoint display. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 195--202.
[203]
Mudge, M., Malzbender, T., Chalmers, A., Scopigno, R., Davis, J., Wang, O., Gunawardane, P., Ashley, M., Doerr, M., Proenca, A., and Barbosa, J. 2008. Image-based empirical information acquisition, scientific reliability, and long-term digital preservation for the natural sciences and cultural heritage. Eurographics Tutorials.
[204]
Mukaigawa, Y., Sumino, K., and Yagi, Y. 2007. Multiplexed illumination for measuring brdf using an ellipsoidal mirror and a projector. In Computer Vision ACCV 2007, vol. 4844 of Lecture Notes in Computer Science, 246--257.
[205]
Mukaigawa, Y., Tagawa, S., Kim, J., Raskar, R., Matsushita, Y., and Yagi, Y. 2011. Hemispherical confocal imaging using turtleback reflector. In Computer Vision ACCV 2010, vol. 6492 of Lecture Notes in Computer Science. 336--349.
[206]
Müller, G., Meseth, J., Sattler, M., Sarlette, R., and Klein, R. 2004. Acquisition, synthesis and rendering of bidirectional texture functions. In Eurographics 2004 State of the Art Reports, 69--94.
[207]
Müller, G., Bendels, G. H., and Klein, R. 2005. Rapid synchronous acquisition of geometry and appearance of cultural heritage artefacts. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 13--20.
[208]
Murase, H. 1990. Surface shape reconstruction of an undulating transparent object. In Proceedings of the International Conference on Computer Vision (ICCV), 313--317.
[209]
Murase, H. 1992. Surface shape reconstruction of a nonrigid transport object using refraction and motion. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 14, 10, 1045--1052.
[210]
Murray-Coleman, F., and Smith, A. M. 1990. The automated measurement of brdfs and their application to luminaire modeling. 87--99.
[211]
Naik, N., Zhao, S., Velten, A., Raskar, R., and Bala, K. 2011. Single view reflectance capture using multiplexed scattering and time-of-flight imaging. ACM Transactions on Graphics 30, 6, 171:1--171:10.
[212]
Nair, H. N., and Stewart, C. V. 1992. Robust focus ranging. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 309--314.
[213]
Nayar, S. K., and Nakagawa, Y. 1994. Shape from focus. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 16, 8, 824--831.
[214]
Nayar, S. K., Weiss, L. E., Simon, D. A., and Sanderson, A. C. 1990. Specular surface inspection using structured highlight and Gaussian images. IEEE Transactions on Robotics and Automation 6, 2, 208--218.
[215]
Nayar, S. K., Watanabe, M., and Noguchi, M. 1996. Real-time focus range sensor. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 18, 12, 1186--1198.
[216]
Nayar, S. K., Fang, X.-S., and Boult, T. 1997. Separation of reflection components using color and polarization. Proceedings of the International Conference on Computer Vision (ICCV) 21, 3, 163--186.
[217]
Nayar, S. K., Krishnan, G., Grossberg, M. D., and Raskar, R. 2006. Fast separation of direct and global components of a scene using high frequency illumination. ACM Transactions on Graphics 25, 935--944.
[218]
Nehab, D., Rusinkiewicz, S., Davis, J., and Ramamoorthi, R. 2005. Efficiently combining positions and normals for precise 3d geometry. ACM Transactions on Graphics 24, 536--543.
[219]
Nehab, D., Weyrich, T., and Rusinkiewicz, S. 2008. Dense 3D reconstruction from specularity consistency. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1--8.
[220]
Neubeck, A., Zalesny, A., and Van Gool, L. 2005. 3D texture reconstruction from extensive btf data. In Proceedings of the Texture 2005 Workshop, 13--19.
[221]
Neubeck, A., Zalesny, A., and Van Gool, L. 2006. Light source calibration for IBR and BTF acquisition setups. In Proceedings of the International Symposium on 3D Data Processing, Visualisation and Transmission (3DPVT). 272--278.
[222]
Ngan, A., and Durand, F. 2006. Statistical acquisition of texture appearance. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 31--40.
[223]
Nicodemus, F. E., Richmond, J. C., Hsia, J. J., Ginsberg, I. W., and Limperis, T. 1977. Geometrical considerations and nomenclature for reflectance. National Bureau of Standards Monograph #160, U.S. Department of Commerce.
[224]
Nishino, K. 2009. Directional statistics brdf model. In Proceedings of the International Conference on Computer Vision (ICCV), 476--483.
[225]
Nöll, T., J., K., Reis, G., and Stricker, D. 2013. Faithful, compact and complete digitization of cultural heritage using a full-spherical scanner. In Proceedings of the International Congress on Digital Heritage, 15--22.
[226]
Nöll, T., Köhler, J., Reis, G., and Stricker, D. 2015. Fully automatic, omnidirectional acquisition of geometry and appearance in the context of cultural heritage preservation. ACM Journal on Computing and Cultural Heritage (JOCCH) 8, 1, 2:1--2:28.
[227]
Pacanowski, R., Salazar-Celis, O., Schlick, C., Granier, X., Pierre, P., and Annie, C. 2012. Rational BRDF. IEEE Transactions on Visualization and Computer Graphics (TVCG) 18, 11, 1824--1835.
[228]
Padfield, J., Saunders, D., and Malzbender, T. 2006. Polynomial texture mapping: a new tool for examining the surface of paintings. In Triennial Meeting of the ICOM Committee for Conservation, vol. 1, 504--510.
[229]
Pak, A. 2012. Recovering shapes of specular objects in motion via normal vector map consistency. In Proceedings of SPIE, vol. 8493, 84930T--1-84930T--8.
[230]
Pak, A. 2013. Reconstruction of specular surfaces via probabilistic voxel carving. In Proceedings of SPIE, vol. 8791, 87911B--1-87911B--8.
[231]
Palma, G., Corsini, M., Cignoni, P., Scopigno, R., and Mudge, M. 2010. Dynamic shading enhancement for reflectance transformation imaging. ACM Journal on Computing and Cultural Heritage (JOCCH) 3, 6:1--6:20.
[232]
Palma, G., Callieri, M., Dellepiane, M., and Scopigno, R. 2012. A statistical method for SVBRDF approximation from video sequences in general lighting conditions. Computer Graphics Forum (Proceedings of the Eurographics Symposium on Rendering) 31, 4, 1491--1500.
[233]
Palma, G., Desogus, N., Cignoni, P., and Scopigno, R. 2013. Surface light field from video acquired in uncontrolled settings. In Proceedings of the International Congress on Digital Heritage, 31--38.
[234]
Peers, P., and Dutré, P. 2005. Inferring reflectance functions from wavelet noise. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 173--182.
[235]
Peers, P., vom Berge, K., Matusik, W., Ramamoorthi, R., Lawrence, J., Rusinkiewicz, S., and Dutré, P. 2006. A compact factored representation of heterogeneous subsurface scattering. ACM Transactions on Graphics 25, 3, 746--753.
[236]
Peers, P., Mahajan, D. K., Lamond, B., Ghosh, A., Matusik, W., Ramamoorthi, R., and Debevec, P. 2009. Compressive light transport sensing. ACM Transactions on Graphics 28, 1, 3:1--3:18.
[237]
Penner, E., and Borshukov, G. 2011. Pre-integrated skin shading. In GPU Pro 2, vol. 2. 41--55.
[238]
Peters, C., Klein, J., Hullin, M. B., and Klein, R. 2015. Solving trigonometric moment problems for fast transient imaging. In ACM SIGGRAPH Asia 2015 Papers (conditionally accepted).
[239]
Phong, B. T. 1975. Illumination for computer generated pictures. Communications of the ACM 18, 6, 311--317.
[240]
Ramamoorthi, R., and Hanrahan, P. 2001. A signal-processing framework for inverse rendering. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 117--128.
[241]
Rantoson, R., Stolz, C., Fofi, D., and Meriaudeau, F. 2010. 3d reconstruction of transparent objects exploiting surface fluorescence caused by UV irradiation. In Proceedings of the IEEE International Conference on Image Processing (ICIP), 2965--2968.
[242]
Rantoson, R., Stolz, C., Fofi, D., and Meriaudeau, F. 2010. Non contact 3d measurement scheme for transparent objects using UV structured light. In Proceedings of the International Conference on Pattern Recognition (ICPR), 1646--1649.
[243]
Remondino, F., and Stoppa, D. 2013. TOF range-imaging cameras. Springer, Berlin, Germany.
[244]
Ren, P., Wang, J., Snyder, J., Tong, X., and Guo, B. 2011. Pocket reflectometry. ACM Transactions on Graphics 30, 4, 45:1--45:10.
[245]
Ritz, M., Scholz, M., Goesele, M., and Stork, A. 2010. High resolution acquisition of detailed surfaces with lens-shifted structured light. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 1--8.
[246]
Riviere, J., Peers, P., and Ghosh, A. 2014. Mobile surface reflectometry. In ACM SIGGRAPH 2014 Posters, 68:1--68:1.
[247]
Roth, S., and Black, M. J. 2006. Specular flow and the recovery of surface structure. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, 1869--1876.
[248]
Ruiters, R., and Klein, R. 2009. Heightfield and spatially varying brdf reconstruction for materials with interreflections. Computer Graphics Forum (Proceedings of Eurographics) 28, 2, 513--522.
[249]
Ruiters, R., Schwartz, C., and Klein, R. 2012. Data driven surface reflectance from sparse and irregular samples. Computer Graphics Forum 31, 2, 315--324.
[250]
Ruiters, R. A. 2013. Data-driven analysis and interpolation of optical material properties. PhD thesis, Rheinische Friedrich-Wilhelms-Universität Bonn, Bonn, Germany.
[251]
Rump, M., Sarlette, R., and Klein, R. 2010. Groundtruth data for multispectral bidirectional texture functions. In Proceedings of the European Conference on Colour in Graphics, Imaging, and Vision (CGIV), 326--330.
[252]
Salvi, J., Pagès, J., and Batlle, J. 2004. Pattern codification strategies in structured light systems. Pattern Recognition 37, 827--849.
[253]
Sanderson, A. C., Weiss, L. E., and Nayar, S. K. 1988. Structured highlight inspection of specular surfaces. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 10, 1, 44--55.
[254]
Sankaranarayanan, A. C., Veeraraghavan, A., Tuzel, O., and Agrawal, A. K. 2010. Specular surface reconstruction from sparse reflection correspondences. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1245--1252.
[255]
Sansoni, G., Trebeschi, M., and Docchio, F. 2009. State-of-the-art and applications of 3d imaging sensors in industry, cultural heritage, medicine, and criminal investigation. Sensors 9, 1, 568--601.
[256]
Santos, P., Ritz, M., Tausch, R., Schmedt, H., Monroy, R., De Stefano, A., Posniak, O., Fuhrmann, C., and Fellner, D. W. 2014. CultLab3D - On the Verge of 3D Mass Digitization. In Eurographics Workshop on Graphics and Cultural Heritage.
[257]
Sato, Y., Wheeler, M. D., and Ikeuchi, K. 1997. Object shape and reflectance modeling from observation. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 379--387.
[258]
Sattler, M., Sarlette, R., and Klein, R. 2003. Efficient and realistic visualization of cloth. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 167--177.
[259]
Savarese, S., Chen, M., and Perona, P. 2005. Local shape from mirror reflections. International Journal of Computer Vision (IJCV) 64, 1, 31--67.
[260]
Scharstein, D., and Szeliski, R. 2002. A taxonomy and evaluation of dense two-frame stereo correspondence algorithms. International Journal of Computer Vision (IJCV) 47, 7--42.
[261]
Scharstein, D., and Szeliski, R. 2003. High-accuracy stereo depth maps using structured light. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 1, 195--202.
[262]
Schilling, A. 1997. Towards real-time photorealistic rendering: Challenges and solutions. In Proceedings of the ACM SIGGRAPH/EUROGRAPHICS Workshop on Graphics Hardware (HWWS), 7--15.
[263]
Schlick, C. 1994. An inexpensive brdf model for physically-based rendering. Computer Graphics Forum 13, 3, 233--246.
[264]
Schröder, P., and Sweldens, W. 1995. Spherical wavelets: Efficiently representing functions on the sphere. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 161--172.
[265]
Schwartz, C., Weinmann, M., Ruiters, R., and Klein, R. 2011. Integrated high-quality acquisition of geometry and appearance for cultural heritage. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 25--32.
[266]
Schwartz, C., Ruiters, R., Weinmann, M., and Klein, R. 2011. WebGL-based streaming and presentation framework for bidirectional texture functions. In Proceedings of the International Symposium on Virtual Reality, Archaeology and Intelligent Cultural Heritage (VAST), 113--120.
[267]
Schwartz, C., Sarlette, R., Weinmann, M., and Klein, R. 2013. DOME II: A parallelized BTF acquisition system. In Proceedings of the Eurographics Workshop on Material Appearance Modeling: Issues and Acquisition, 25--31.
[268]
Schwartz, C., Sarlette, R., Weinmann, M., Rump, M., and Klein, R. 2014. Design and implementation of practical bidirectional texture function measurement devices focusing on the developments at the University of Bonn. Sensors 14, 5, 7753--7819.
[269]
Schwartz, J. C. 2014. Acquisition, transmission and rendering of objects with optically complicated material appearance. PhD thesis, Rheinische Friedrich-Wilhelms-Universität Bonn, Bonn, Germany.
[270]
Seitz, S. M., Curless, B., Diebel, J., Scharstein, D., and Szeliski, R. 2006. A comparison and evaluation of multi-view stereo reconstruction algorithms. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 1, 519--528.
[271]
Sen, P., and Darabi, S. 2009. Compressive dual photography. Computer Graphics Forum 28, 2, 609--618.
[272]
Shafer, S. A. 1985. Using color to separate reflection components. Color Research & Application 10, 4, 210--218.
[273]
Sinha, S. N., and Pollefeys, M. 2005. Multi-view reconstruction using photo-consistency and exact silhouette constraints: A maximum-flow formulation. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 1, 349--356.
[274]
Sinha, S. N., Steedly, D., Szeliski, R., Agrawala, M., and Pollefeys, M. 2008. Interactive 3d architectural modeling from unordered photo collections. ACM Transactions on Graphics 27, 5, 159:1--159:10.
[275]
Skocaj, D., and Leonardis, A. 2000. Range image acquisition of objects with non-uniform albedo using structured light range sensor. In Proceedings of the International Conference on Pattern Recognition (ICPR), vol. 1, 778--781.
[276]
Smith, T., and Guild, J. 1931. The C.I.E. colorimetric standards and their use. Transactions of the Optical Society 33, 3, 73--134.
[277]
SphereOptics. Reflectance coatings and materials -- technical information. http://www.laser2000.fr/fileadmin/Produktgruppenkataloge/SPO_MaterialsCoatingsExtendedGuide2009.pdf (accessed on 19 March 2014).
[278]
Steinhaus, H. 1957. Sur la division des corps matériels en parties. Bulletin de l'Académie Polonaise des Sciences, Classe III 4, 801--804.
[279]
Stilla, U., and Jutzi, B. 2009. Waveform analysis for small-footprint pulsed laser systems. In Topographic Laser Ranging and Scanning: Principles and Processing, CRC Press, Boca Raton, USA, 215--234.
[280]
Strang, G. 1983. Maximal flow through a domain. Mathematical Programming 26, 2, 123--143.
[281]
Strang, G. 2010. Maximum flows and minimum cuts in the plane. Journal of Global Optimization 47, 3, 527--535.
[282]
Sturm, J., Bylow, E., Kahl, F., and Cremers, D. 2013. CopyMe3D: Scanning and printing persons in 3D. In Proceedings of the German Conference on Pattern Recognition (GCPR), 405--414.
[283]
Sun, B., Sunkavalli, K., Ramamoorthi, R., Belhumeur, P., and Nayar, S. 2006. Time-varying BRDFs. In Proceedings of the Eurographics Workshop on Natural Phenomena, 15--23.
[284]
Szeliski, R. 2011. Computer vision: Algorithms and applications. Springer, London, UK.
[285]
Tagawa, S., Mukaigawa, Y., and Yagi, Y. 2012. 8-d reflectance field for computational photography. In Proceedings of the International Conference on Pattern Recognition (ICPR). 2181--2185.
[286]
Tan, R., and Ikeuchi, K. 2003. Separating reflection components of textured surfaces using a single image. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 870--877.
[287]
Tan, R., and Ikeuchi, K. 2005. Separating reflection components of textured surfaces using a single image. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 27, 2, 178--193.
[288]
Tan, P., Lin, S., Quan, L., and Shum, H.-Y. 2003. Highlight removal by illumination-constrained inpainting. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 1, 164--169.
[289]
Tarini, M., Lensch, H. P. A., Goesele, M., and Seidel, H.-P. 2005. 3d acquisition of mirroring objects using striped patterns. Graphical Models 67, 4, 233--259.
[290]
Tariq, S., Gardner, A., Llamas, I., Jones, A., Debevec, P., and Turk, G. 2006. Efficient estimation of spatially varying subsurface scattering parameters. In Proceedings of the International Fall Workshop on Vision, Modeling and Visualization, 129--136.
[291]
Thomas, D., and Sugimoto, A. 1991. Range image registration of specular objects under complex illumination. Proceedings of the International Conference on 3D Data Processing, Visualization and Transmission 13, 7, 635--657.
[292]
Tong, X., Wang, J., Lin, S., Guo, B., and Shum, H.-Y. 2005. Modeling and rendering of quasi-homogeneous materials. ACM Transactions on Graphics 24, 3, 1054--1061.
[293]
Torrance, K. E., and Sparrow, E. M. 1967. Theory for off-specular reflection from roughened surfaces. Journal of the Optical Society of America 57, 9, 1105--1112.
[294]
Trifonov, B., Bradley, D., and Heidrich, W. 2006. Tomographic reconstruction of transparent objects. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 51--60.
[295]
Triggs, B., McLauchlan, P. F., Hartley, R. I., and Fitzgibbon, A. W. 2000. Bundle adjustment - a modern synthesis. In Proceedings of the International Workshop on Vision Algorithms: Theory and Practice, 298--372.
[296]
Tsuchida, M., Arai, H., Nishiko, M., Sakaguchi, Y., Uchiyama, T., Yamaguchi, M., Haneishi, H., and Ohyama, N. 2005. Development of BRDF and BTF measurement and computer-aided design systems based on multispectral imaging. In AIC Colour 05 - 10th Congress of the International Colour Association. 129--132.
[297]
Tsuchida, M., Sakaguchi, Y., Arai, H., Nishiko, M., Fujikawa, N., Yamaguchi, M., Haneishi, H., and Ohyama, N. 2005. High-fidelity color reproduction based on multi-channel BTF/BRDF acquisition, rendering and display. In ACM SIGGRAPH 2005 Sketches.
[298]
Tunwattanapong, B., Fyffe, G., Graham, P., Busch, J., Yu, X., Ghosh, A., and Debevec, P. 2013. Acquiring reflectance and shape from continuous spherical harmonic illumination. ACM Transactions on Graphics 32, 4, 109:1--109:12.
[299]
Tuytelaars, T., and Mikolajczyk, K. 2008. Local invariant feature detectors: A survey. Foundations and Trends in Computer Graphics and Vision 3, 3, 177--280.
[300]
Velho, L., and Sossai Jr., J. 2007. Projective texture atlas construction for 3d photography. The Visual Computer 23, 9-11, 621--629.
[301]
Vogiatzis, G., Hernández, C., Torr, P. H. S., and Cipolla, R. 2007. Multi-view stereo via volumetric graph-cuts and occlusion robust photo-consistency. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 29, 12, 2241--2246.
[302]
Waechter, M., Moehrle, N., and Goesele, M. 2014. Let there be color! Large-scale texturing of 3d reconstructions. In Proceedings of the European Conference on Computer Vision (ECCV), 836--850.
[303]
Wang, J., and Dana, K. 2006. Relief texture from specularities. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 28, 3, 446--457.
[304]
Wang, Z., and Inokuchi, S. 1993. Determining shape of specular surfaces. In Proceedings of the Scandinavian Conference on Image Analysis (SCIA), 1187--1194.
[305]
Wang, J., Zhao, S., Tong, X., Snyder, J., and Guo, B. 2008. Modeling anisotropic surface reflectance with example-based microfacet synthesis. ACM Transactions on Graphics 27, 3, 41:1--41:9.
[306]
Wang, H., Liao, M., Zhang, Q., Yang, R., and Turk, G. 2009. Physically guided liquid surface modeling from videos. ACM Transactions on Graphics 28, 3, 90:1--90:11.
[307]
Ward, G. J. 1992. Measuring and modeling anisotropic reflection. Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH) 26, 2, 265--272.
[308]
Weinmann, M., and Klein, R. 2015. Material recognition for efficient acquisition of geometry and reflectance. In Proceedings of the ECCV 2014 Workshops, 321--333.
[309]
Weinmann, M., and Klein, R. 2015. A short survey on optical material recognition. In Proceedings of the Eurographics Workshop on Material Appearance Modeling, 35--42.
[310]
Weinmann, M., Schwartz, C., Ruiters, R., and Klein, R. 2011. A multi-camera, multi-projector super-resolution framework for structured light. In Proceedings of the International Conference on 3D Imaging, Modeling, Processing, Visualization and Transmission (3DIMPVT), 397--404.
[311]
Weinmann, M., Ruiters, R., Osep, A., Schwartz, C., and Klein, R. 2012. Fusing structured light consistency and Helmholtz normals for 3d reconstruction. In Proceedings of the British Machine Vision Conference (BMVC), 1--12.
[312]
Weinmann, M., Osep, A., Ruiters, R., and Klein, R. 2013. Multi-view normal field integration for 3d reconstruction of mirroring objects. In Proceedings of the International Conference on Computer Vision (ICCV), 2504--2511.
[313]
Weinmann, M., Leitloff, J., Hoegner, L., Jutzi, B., Stilla, U., and Hinz, S. 2014. Thermal 3d mapping for object detection in dynamic scenes. ISPRS Annals of the Photogrammetry, Remote Sensing and Spatial Information Sciences II-1, 53--60.
[314]
Weinmann, M. 2013. Visual features -- from early concepts to modern computer vision. In Advanced Topics in Computer Vision, Advances in Computer Vision and Pattern Recognition. Springer London, 1--34.
[315]
Weistroffer, R. P., Walcott, K. R., Humphreys, G., and Lawrence, J. 2007. Efficient basis decomposition for scattered reflectance data. In Proceedings of the Eurographics Symposium on Rendering (EGSR), 207--218.
[316]
Wenger, A., Gardner, A., Tchou, C., Unger, J., Hawkins, T., and Debevec, P. 2005. Performance relighting and reflectance transformation with time-multiplexed illumination. ACM Transactions on Graphics 24, 3, 756--764.
[317]
Westin, S. H., Arvo, J. R., and Torrance, K. E. 1992. Predicting reflectance functions from complex surfaces. Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH) 26, 2.
[318]
Weyrich, T., Matusik, W., Pfister, H., Ngan, A., and Gross, M. 2005. Measuring skin reflectance and subsurface scattering. Tech. rep., Mitsubishi Electric Research Laboratories, TR2005--046.
[319]
Weyrich, T., Matusik, W., Pfister, H., Bickel, B., Donner, C., Tu, C., McAndless, J., Lee, J., Ngan, A., Jensen, H. W., and Gross, M. 2006. Analysis of human faces using a measurement-based skin reflectance model. ACM Transactions on Graphics 25, 1013--1024.
[320]
Weyrich, T., Lawrence, J., Lensch, H., Rusinkiewicz, S., and Zickler, T. 2007. Principles of appearance acquisition and representation. In ICCV 2007 Short Course.
[321]
White, D. R., Saunders, P., Bonsey, S. J., van de Ven, J., and Edgar, H. 1998. Reflectometer for measuring the bidirectional reflectance of rough surfaces. Applied Optics 37, 16, 3450--3454.
[322]
Wilburn, B., Joshi, N., Vaish, V., Talvala, E.-V., Antunez, E., Barth, A., Adams, A., Horowitz, M., and Levoy, M. 2005. High performance imaging using large camera arrays. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 765--776.
[323]
Witkin, A. P. 1980. Shape from contour. Tech. rep., Massachusetts Institute of Technology, Cambridge, MA, USA.
[324]
Witkin, A. P. 1981. Recovering surface shape and orientation from texture. Artificial Intelligence 17, 17--45.
[325]
Wolff, L. B., and Boult, T. E. 1991. Constraining object features using a polarization reflectance model. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 13, 7, 635--657.
[326]
Wolff, L. 1989. Using polarization to separate reflection components. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 363--369.
[327]
Wood, D. N., Azuma, D. I., Aldinger, K., Curless, B., Duchamp, T., Salesin, D. H., and Stuetzle, W. 2000. Surface light fields for 3D photography. In Proceedings of the Annual Conference on Computer Graphics and Interactive Techniques (SIGGRAPH), 287--296.
[328]
Woodham, R. J. 1980. Photometric method for determining surface orientation from multiple images. Optical Engineering 19, 1, 139--144.
[329]
Wu, C., Liu, Y., Dai, Q., and Wilburn, B. 2011. Fusing multiview and photometric stereo for 3d reconstruction under uncalibrated illumination. IEEE Transactions on Visualization and Computer Graphics (TVCG) 17, 8, 1082--1095.
[330]
Wu, L., Ganesh, A., Shi, B., Matsushita, Y., Wang, Y., and Ma, Y. 2011. Robust photometric stereo via low-rank matrix completion and recovery. In Proceedings of the Asian Conference on Computer Vision (ACCV), 703--717.
[331]
Xiong, Y., and Shafer, S. A. 1997. Moment and hypergeometric filters for high precision computation of focus, stereo and optical flow. International Journal of Computer Vision (IJCV) 22, 1, 25--59.
[332]
Yamazaki, M., Iwata, S., and Xu, G. 2007. Dense 3d reconstruction of specular and transparent objects using stereo cameras and phase-shift method. In Proceedings of the Asian Conference on Computer Vision (ACCV), 570--579.
[333]
Yeung, S.-K., Wu, T.-P., Tang, C.-K., Chan, T. F., and Osher, S. 2011. Adequate reconstruction of transparent objects on a shoestring budget. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 2513--2520.
[334]
Yoshiyasu, Y., and Yamazaki, N. 2011. Topology-adaptive multi-view photometric stereo. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 1001--1008.
[335]
Yu, T., Ahuja, N., and Chen, W. C. 2006. Sdg cut: 3d reconstruction of non-lambertian objects using graph cuts on surface distance grid. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), vol. 2, 2269--2276.
[336]
Yuan, J., Bae, E., and Tai, X.-C. 2010. A study on continuous max-flow and min-cut approaches. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (CVPR), 2217--2224.
[337]
Zhang, R., Tsai, P., Cryer, J. E., and Shah, M. 1999. Shape from shading: A survey. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 21, 8, 690--706.
[338]
Zhang, W., Wang, F., Wang, Z., and Wang, H. 2010. Measuring of spectral BRDF using fiber optic spectrometer. In Proceedings of SPIE, vol. 7658, 76582P--1-76582P--8.
[339]
Zheng, J. Y., and Murata, A. 2000. Acquiring a complete 3d model from specular motion under the illumination of circular-shaped light sources. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 22, 8, 913--920.
[340]
Zheng, Z., Ma, L., Li, Z., and Chen, Z. 2010. An extended photometric stereo algorithm for recovering specular object shape and its reflectance properties. Computer Science and Information Systems 7, 1, 1--12.
[341]
Zickler, T. E., Belhumeur, P. N., and Kriegman, D. J. 2002. Helmholtz stereopsis: Exploiting reciprocity for surface reconstruction. International Journal of Computer Vision (IJCV) 49, 2-3, 215--227.
[342]
Zickler, T. E., Ho, J., Kriegman, D. J., Ponce, J., and Belhumeur, P. N. 2003. Binocular Helmholtz stereopsis. In Proceedings of the International Conference on Computer Vision (ICCV), vol. 2, 1411--1417.
[343]
Zickler, T., Ramamoorthi, R., Enrique, S., and Belhumeur, P. N. 2006. Reflectance sharing: Predicting appearance from a sparse set of images of a known shape. IEEE Transactions on Pattern Analysis and Machine Intelligence (PAMI) 28, 8, 1287--1302.
[344]
Zisserman, A., Giblin, P., and Blake, A. 1989. The information available to a moving observer from specularities. Image and Vision Computing 7, 1, 38--42.

Cited By

View all
  • (2024)Deep SVBRDF Acquisition and Modelling: A SurveyComputer Graphics Forum10.1111/cgf.1519943:6Online publication date: 16-Sep-2024
  • (2024)Efficient Reflectance Capture With a Deep Gated Mixture-of-ExpertsIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2023.326187230:7(4246-4256)Online publication date: Jul-2024
  • (2023)OpenSVBRDF: A Database of Measured Spatially-Varying ReflectanceACM Transactions on Graphics10.1145/361835842:6(1-14)Online publication date: 5-Dec-2023
  • Show More Cited By

Recommendations

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image ACM Other conferences
SA '15: SIGGRAPH Asia 2015 Courses
November 2015
1137 pages
ISBN:9781450339247
DOI:10.1145/2818143
Permission to make digital or hard copies of part or all of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for third-party components of this work must be honored. For all other uses, contact the Owner/Author.

In-Cooperation

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 02 November 2015

Check for updates

Author Tags

  1. digital content creation
  2. geometry and appearance acquisition
  3. measured materials and applications

Qualifiers

  • Abstract

Conference

SA'15
SA'15: SIGGRAPH Asia 2015
November 2 - 6, 2015
Kobe, Japan

Acceptance Rates

Overall Acceptance Rate 178 of 869 submissions, 20%

Contributors

Other Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

  • Downloads (Last 12 months)34
  • Downloads (Last 6 weeks)0
Reflects downloads up to 20 Jan 2025

Other Metrics

Citations

Cited By

View all
  • (2024)Deep SVBRDF Acquisition and Modelling: A SurveyComputer Graphics Forum10.1111/cgf.1519943:6Online publication date: 16-Sep-2024
  • (2024)Efficient Reflectance Capture With a Deep Gated Mixture-of-ExpertsIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2023.326187230:7(4246-4256)Online publication date: Jul-2024
  • (2023)OpenSVBRDF: A Database of Measured Spatially-Varying ReflectanceACM Transactions on Graphics10.1145/361835842:6(1-14)Online publication date: 5-Dec-2023
  • (2023)Neural Reflectance Capture in the View-Illumination DomainIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2021.311737029:2(1450-1462)Online publication date: 1-Feb-2023
  • (2023)An attention-embedded GAN for SVBRDF recovery from a single imageComputational Visual Media10.1007/s41095-022-0289-19:3(551-561)Online publication date: 22-Mar-2023
  • (2022)Shape, light, and material decomposition from images using Monte Carlo rendering and denoisingProceedings of the 36th International Conference on Neural Information Processing Systems10.5555/3600270.3601931(22856-22869)Online publication date: 28-Nov-2022
  • (2022)Differentiable Appearance Acquisition from a Flash/No-flash RGB-D Pair2022 IEEE International Conference on Computational Photography (ICCP)10.1109/ICCP54855.2022.9887646(1-12)Online publication date: 1-Aug-2022
  • (2022)Extracting Triangular 3D Models, Materials, and Lighting From Images2022 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)10.1109/CVPR52688.2022.00810(8270-8280)Online publication date: Jun-2022
  • (2022)A multiresolution network architecture for deferred neural lightingComputer Animation and Virtual Worlds10.1002/cav.206033:3-4Online publication date: 13-Jun-2022
  • (2021)Free-form scanning of non-planar appearance with neural trace photographyACM Transactions on Graphics10.1145/3476576.347669440:4(1-13)Online publication date: Aug-2021
  • Show More Cited By

View Options

Login options

View options

PDF

View or Download as a PDF file.

PDF

eReader

View online with eReader.

eReader

Media

Figures

Other

Tables

Share

Share

Share this Publication link

Share on social media