TR2006-104

Inverse Shade Trees for Non-Parametric Material Representation and Editing


    •  Lawrence, J., Ben-Artzi, A., DeCoro, C., Matusik, W., Pfister, H., Ramamoorthi, R., Rusinkiewicz, S., "Inverse Shade Trees for Non-Parametric Material Representation and Editing", ACM Transactions on Graphics (TOG), Vol. 25, No. 3, pp. 735-745, July 2006.
      BibTeX TR2006-104 PDF
      • @article{Lawrence2006jul,
      • author = {Lawrence, J. and Ben-Artzi, A. and DeCoro, C. and Matusik, W. and Pfister, H. and Ramamoorthi, R. and Rusinkiewicz, S.},
      • title = {Inverse Shade Trees for Non-Parametric Material Representation and Editing},
      • journal = {ACM Transactions on Graphics (TOG)},
      • year = 2006,
      • volume = 25,
      • number = 3,
      • pages = {735--745},
      • month = jul,
      • issn = {0730-0301},
      • url = {https://www.merl.com/publications/TR2006-104}
      • }
  • Research Area:

    Computer Vision

Abstract:

Recent progress in the measurement of surface reflectance has created a demand for non-parametric appearance representations that are accurate, compact, and easy to use for rendering. Another crucial goal, which has so far received little attention, is editability: for practical use, we must be able to change both the directional and spatial behavior of surface reflectance (e.g., making one material shinier, another more anisotropic, and changing the spatial \"texture maps\" indicating where each material appears). We introduce an Inverse Shade Tree framework that provides a general approach to estimating the \"leaves\" of a user-specified shade tree from high-dimensional measured datasets of appearance. These leaves are sampled 1- and 2-dimensional functions that capture both the directional behavior of individual materials and their spatial mixing patterns. In order to compute these shade trees automatically, we map the problem to matrix factorization and introduce a flexible new algorithm that allows for constraints such as non-negativity, sparsity, and energy conservation. Although we cannot infer every type of shade tree, we demonstrate the ability to reduce multi-gigabyte measured datasets of the Spatially-Varying Bidirectional Reflectance Distribution Function (SVBRDF) into a compact representation that may be edited in real time.

 

  • Related News & Events

    •  NEWS    ACM Transactions on Graphics (TOG): 7 publications by Amit Agrawal, Ramesh Raskar and others
      Date: July 15, 2006
      Where: ACM Transactions on Graphics (TOG)
      Research Area: Computer Vision
      Brief
      • The articles "Coded Exposure Photography: Motion Deblurring Using Fluttered Shutter" by Raskar, R., Agrawal, A. and Tumblin, J., "Fast Separation of Direct and Global Components of a Scene Using High Frequency Illumination" by Nayar, S.K., Krishnan, G., Grossberg, M.D. and Raskar, R., "Analysis of Human Faces using a measurement-Based Skin Reflectance Model" by Weyrich, T., Matusik, W., Pfister, H., Bickel, B., Donner, C., Tu, C., McAndless, J., Lee, J., Ngan, A., Jensen, H. and Gross, M., "Inverse Shade Trees for Non-Parametric Material Representation and Editing" by Lawrence, J., Ben-Artzi, A., DeCoro, C., Matusik, W., Pfister, H., Ramamoorthi, R. and Rusinkiewicz, S., "A Compact Factored Representation of Heterogeneous Subsurface Scattering" by Peers, P., Berge, K., Matusik, W., Ramamoorthi, R., Lawrence, J., Rusinkiewicz, S. and Dutre, P., "Time-Varying Surface Appearance: Acquisition, Modeling and Rendering" by Gu, J., Tu, C., Ramamoorthi, R., Belhumeur, P., Matusik, W. and Nayar, S. and "A Statistical Model for Synthesis of Detailed Facial Geometry" by Golovinskiy, A., Matusik, W., Pfister, H., Rusinkiewicz, S. and Funkhouser, T. were published in ACM Transactions on Graphics (TOG).
    •