Presentation is loading. Please wait.

Presentation is loading. Please wait.

Characteristic Point Maps Hongzhi Wu Julie Dorsey Holly Rushmeier (presented by Patrick Paczkowski) Computer Graphics Lab Yale University.

Published byRalph Matthews Modified over 8 years ago

Similar presentations

Presentation on theme: "Characteristic Point Maps Hongzhi Wu Julie Dorsey Holly Rushmeier (presented by Patrick Paczkowski) Computer Graphics Lab Yale University."— Presentation transcript:

1 Characteristic Point Maps Hongzhi Wu Julie Dorsey Holly Rushmeier (presented by Patrick Paczkowski) Computer Graphics Lab Yale University

2 Outline Introduction Previous Work Characteristic Point Maps – Derivation – Preprocessing – Usage Results Conclusions Future Work

3 Motivation Challenging to Render – Highly complex geometry + materials – High sampling rate to avoid aliasing – Viewed at multiple scales

4 Introduction We present Characteristic Point Maps (CPMs) – A hierarchy of points on the original model Preserves appearance (i.e. 6D filtered SV-BRDF) at multiple scales – Precomputed object-space adaptive sampling

5 Introduction …… Mesh Hierarchy Preprocess Original Model + Characteristic Point Maps …… level 0 level 1 level n original modelsimplified meshes Render Output Image

6 Previous Work Texture Mipmap [Wil83] – Pre-filtering textures Mesh Simplification [GH98, LT00, SSGH01] – Minimizing texture-mapping distortion Appearance-Preserving Mesh Simplification [COM98] – Missing small-scale shadowing and masking effects – For textures, not general BRDFs BTF LOD representation [MCT*05] – Dense sampling of 6D BTF for high-frequency effects

7 Previous Work Arbitrary BRDFArbitrary Geometry Shadowing and Masking Effects Small footprint Reflectance Filtering [TLQ*08] XXO√ Normal Map Filtering [HSRG07] XXX√ BTF [DvGNK99]√√√X Ours [WDR09]√√√√

8 Derivations Reflected radiance at x incident radiance visibility term BRDF cosine term reflected radiance L i (x, ω i ) dL(x, ω o ) x ωiωi ωoωo

9 Average reflected radiance A A vis ωiωi ωoωo a vis

10 Derivations After a sequence of transformations, where apparent reflectance function

11 Derivations Average reflectance function – 6D function – Brute-force precomputation is impossible! No analytical model => huge storage – E.g. 64 2 for A, 6x64 2 for both ω i and ω o – 64 2 x(6x64 2 )x(6x64 2 ) = 2473 Billion! Difficult to compress numerically

12 Derivations Discretize integration into summation

13 Derivations Visible Projected Area Term – a 2D spherical function – Precompute on GPU and compress using Haar wavelets Visible projected area term

14 Derivations Summation term Summation Term – Want to reduce the number of items (i.e. find the characteristic points) – Use Randomized Matrix Column Sampling

15 Illustration …… x 1 x 2 …... ω i1,ω o1 ω i2,ω o2 ω id, ω od

16 Illustration …… x 1 x 2 …... x1x1 ω i1,ω o1 ω i2,ω o2 ω id, ω od x2x2 …... …

17 … Illustration … …… x 1 x 2 …... x1x1 ω i1,ω o1 ω i2,ω o2 ω id, ω od x2x2 …... … …

18 Illustration …… × × × + + x 1 x 2 …... ω i1,ω o1 ω i2,ω o2 ω id, ω od α1α1 α2α2 α3α3 α1α1 α2α2 α3α3 …

19 Randomized Matrix Column Sampling Use [DMM06] to sample columns (i.e. to find characteristic points) 1.Compute a prob. distribution for choosing a column from the matrix 2.Randomly select m columns according to the prob. distribution 3.Compute the weights for these m columns

20 Randomized Matrix Column Sampling – Measure error as L2 norm – Iterate to “boost” the probability of getting the optimal result – Exploit spatial coherence in apparent reflectance functions Determine the number of CPs as the minimum number to achieve certain approximation quality – High spatial coherence => small number of CPs – Low spatial coherence => large number of CPs

21 Preprocessing Build a mesh hierarchy – Simplify geometry using existing techniques [GH97] – Establish a mapping from each simplified mesh to CPM u-v space Preprocess …… Mesh Hierarchy original modelsimplified meshes Original Model

22 Preprocessing Build a CPM hierarchy – For each texel in CPM, we store References to characteristic points Corresponding weights Wavelet coefficients for a vis – Bottom-up construction × × × + + α1α1 α2α2 α3α3 Preprocess Original Model + …… Mesh Hierarchy original modelsimplified meshes Characteristic Point Maps …… level 0 level 1 level n

23 Using CPMs Select a simplified mesh Select CPM mip level Look up a particular texel Evaluate at characteristic points ONLY!

24 Results: Cylinder Multi-sampled Normal Map Ground TruthCPMsEqual-time Budget ωiωi ωoωo

25 Results: Bolts Multi-sampled Normal Map Ground TruthCPMsEqual-time Budget

26 Results: Wall Multi-sampled Normal Map Ground TruthCPMsEqual-time Budget

27 Results: Gargoyles Close-up viewGround TruthCPMsEqual-time Budget

28 Results Precomputed object-space adaptive sampling – CP density adapts to the complexity of filtered SV- BRDFs 46 0

29 Conclusions A general framework for efficiently computing and representing 6D spatially-varying average reflectance functions – No assumptions on geometry or BRDFs – Accelerates rendering A precomputed object-space adaptive sampling method

30 Future Work Apply a low-pass filter Incorporate indirect illumination Apply to deformable objects

31 Acknowledgements National Science Foundation Grant #0528204 Yale Graphics Group Sumanta Pattanaik (UCF) Li-Yi Wei (Microsoft) Ping Tan (NUS)

32 Thank you Questions? Contact: hongzhi.wu@yale.eduhongzhi.wu@yale.edu

33 Back-up slides

34 Ground Truth Characteristic Point Maps Multi-sampled Normal Map ωiωi ωoωo (a) (b) (c) (d) (e) (f)

Download ppt "Characteristic Point Maps Hongzhi Wu Julie Dorsey Holly Rushmeier (presented by Patrick Paczkowski) Computer Graphics Lab Yale University."

Similar presentations

All-Frequency PRT for Glossy Objects Xinguo Liu, Peter-Pike Sloan, Heung-Yeung Shum, John Snyder Microsoft.

All-Frequency PRT for Glossy Objects Xinguo Liu, Peter-Pike Sloan, Heung-Yeung Shum, John Snyder Microsoft.
Hongzhi Wu 1,2, Li-Yi Wei 1, Xi Wang 1, and Baining Guo 1 Microsoft Research Asia 1 Fudan University 2 Silhouette Texture.

Hongzhi Wu 1,2, Li-Yi Wei 1, Xi Wang 1, and Baining Guo 1 Microsoft Research Asia 1 Fudan University 2 Silhouette Texture.
Hongzhi Wu Julie Dorsey Holly Rushmeier Yale University

Hongzhi Wu Julie Dorsey Holly Rushmeier Yale University
Real-time Shading with Filtered Importance Sampling

Real-time Shading with Filtered Importance Sampling
03/16/2009Dinesh Manocha, COMP770 Texturing Surface’s texture: its look & feel Graphics: a process that takes a surface and modifies its appearance using.

03/16/2009Dinesh Manocha, COMP770 Texturing Surface’s texture: its look & feel Graphics: a process that takes a surface and modifies its appearance using.
Environment Mapping CSE 781 – Roger Crawfis

Environment Mapping CSE 781 – Roger Crawfis
Zhao Dong 1, Jan Kautz 2, Christian Theobalt 3 Hans-Peter Seidel 1 Interactive Global Illumination Using Implicit Visibility 1 MPI Informatik Germany 2.

Zhao Dong 1, Jan Kautz 2, Christian Theobalt 3 Hans-Peter Seidel 1 Interactive Global Illumination Using Implicit Visibility 1 MPI Informatik Germany 2.
Spherical Harmonic Lighting of Wavelength-dependent Phenomena Clifford Lindsay, Emmanuel Agu Worcester Polytechnic Institute (USA)

Spherical Harmonic Lighting of Wavelength-dependent Phenomena Clifford Lindsay, Emmanuel Agu Worcester Polytechnic Institute (USA)
Photon Mapping. How did I use it 10 years ago? Why might you want to use it tomorrow?

Photon Mapping. How did I use it 10 years ago? Why might you want to use it tomorrow?
Frequency Domain Normal Map Filtering Charles Han Bo Sun Ravi Ramamoorthi Eitan Grinspun Columbia University.

Frequency Domain Normal Map Filtering Charles Han Bo Sun Ravi Ramamoorthi Eitan Grinspun Columbia University.
Real-Time Rendering TEXTURING Lecture 02 Marina Gavrilova.

Real-Time Rendering TEXTURING Lecture 02 Marina Gavrilova.
ATEC 6351.001 Procedural Animation Introduction to Procedural Methods in 3D Computer Animation Dr. Midori Kitagawa.

ATEC Procedural Animation Introduction to Procedural Methods in 3D Computer Animation Dr. Midori Kitagawa.
Computer Graphics Bing-Yu Chen National Taiwan University.

Computer Graphics Bing-Yu Chen National Taiwan University.
Scalability with many lights II (row-column sampling, visibity clustering) Miloš Hašan.

Scalability with many lights II (row-column sampling, visibity clustering) Miloš Hašan.
Rendering with Environment Maps Jaroslav Křivánek, KSVI, MFF UK

Rendering with Environment Maps Jaroslav Křivánek, KSVI, MFF UK
Preserving Realism in real-time Rendering of Bidirectional Texture Functions Jan Meseth, Gero Müller, Reinhard Klein Bonn University Computer Graphics.

Preserving Realism in real-time Rendering of Bidirectional Texture Functions Jan Meseth, Gero Müller, Reinhard Klein Bonn University Computer Graphics.
Real-Time Rendering Paper Presentation Imperfect Shadow Maps for Efficient Computation of Indirect Illumination T. Ritschel T. Grosch M. H. Kim H.-P. Seidel.

Real-Time Rendering Paper Presentation Imperfect Shadow Maps for Efficient Computation of Indirect Illumination T. Ritschel T. Grosch M. H. Kim H.-P. Seidel.
Master Thesis Lighting and materials for real-time game engines

Master Thesis Lighting and materials for real-time game engines
Advanced Computer Graphics (Spring 2005) COMS 4162, Lectures 18, 19: Monte Carlo Integration Ravi Ramamoorthi Acknowledgements.

Advanced Computer Graphics (Spring 2005) COMS 4162, Lectures 18, 19: Monte Carlo Integration Ravi Ramamoorthi Acknowledgements.
An Efficient Representation for Irradiance Environment Maps Ravi Ramamoorthi Pat Hanrahan Stanford University.

An Efficient Representation for Irradiance Environment Maps Ravi Ramamoorthi Pat Hanrahan Stanford University.

Similar presentations

Ads by Google