Presentation is loading. Please wait.

Presentation is loading. Please wait.

Interactive Virtual Relighting and Remodelling of Real Scenes C. Loscos 1, MC. Frasson 1,2,G. Drettakis 1, B. Walter 1, X. Granier 1, P. Poulin 2 (1) iMAGIS*

Published bySheena West Modified over 8 years ago

Similar presentations

Presentation on theme: "Interactive Virtual Relighting and Remodelling of Real Scenes C. Loscos 1, MC. Frasson 1,2,G. Drettakis 1, B. Walter 1, X. Granier 1, P. Poulin 2 (1) iMAGIS*"— Presentation transcript:

1 Interactive Virtual Relighting and Remodelling of Real Scenes C. Loscos 1, MC. Frasson 1,2,G. Drettakis 1, B. Walter 1, X. Granier 1, P. Poulin 2 (1) iMAGIS* - GRAVIR/IMAG - INRIA Rhône-Alpes * iMAGIS is a joint project of CNRS/INRIA/UJF/INPG * iMAGIS is a joint project of CNRS/INRIA/UJF/INPG (2) Département d ’informatique et de recherche opérationnelle, Université de Montréal Université de Montréal

2 MAGIS i Motivation Interior design Geometric modificationChanges in lighting

3 MAGIS i Motivation ü Goal: interactive system simple capture process simple capture process interactive ( ~ 1 sec. per frame) interactive ( ~ 1 sec. per frame) modification of lighting modification of lighting modification of geometry modification of geometry

4 MAGIS i Motivation ü We have to: create a simple model of the real scene create a simple model of the real scene  geometry  approximate reflectance represent real global illumination represent real global illumination develop interactive methods for modifications develop interactive methods for modifications ü Goal is to be convincing, not highly accurate

5 MAGIS i Previous Work ü Geometric reconstruction vision methods [Faugeras et al. 97,...] (Realise) vision methods [Faugeras et al. 97,...] (Realise) constraint-based systems [Debevec et al. 96, Poulin et al. 98] constraint-based systems [Debevec et al. 96, Poulin et al. 98] software: Photomodeler, etc. software: Photomodeler, etc. ü Reflectance recovery e.g., [Sato et al. 97, Ward92, Debevec98, Yu et al. 98, etc]. e.g., [Sato et al. 97, Ward92, Debevec98, Yu et al. 98, etc].

6 MAGIS i Previous Work ü Real-time direct shadows real point light source [State et al. 96] real point light source [State et al. 96] ü Common global illumination non-interactive non-interactive  [Nakamae et al. 86, Fournier et al. 93, Jancène et al. 95, Debevec 98, Yu et al. 98, Yu et al. 99] interactive interactive  [Drettakis et al. 97, Loscos et al. 98]

7 MAGIS i Algorithm Overview ü Input ü Pre-process ü Interactive modification

8 MAGIS i Algorithm Overview - Assumptions ü Single viewpoint ü Diffuse assumption ü Lighting: direct lighting: ray casting direct lighting: ray casting indirect lighting: hierarchical radiosity indirect lighting: hierarchical radiosity radiosity = reflectance x ( direct light + indirect light )

9 MAGIS i Simple Input Process ü Geometric reconstruction several (4-5) images from different viewpoints several (4-5) images from different viewpoints geometric modelling using “Rekon” [Poulin et al. 98] geometric modelling using “Rekon” [Poulin et al. 98] ü Reflectance reconstruction several (5-7) images from a single viewpoint several (5-7) images from a single viewpoint different lighting conditions: single light source at different positions different lighting conditions: single light source at different positions “radiance images” “radiance images”

10 MAGIS i Input ü Radiance images from single viewpoint combining multiple images reduces artefacts of estimation combining multiple images reduces artefacts of estimation different lighting conditions

11 MAGIS i Pre-process ü Computation of approximate diffuse reflectance pixel by pixel compute individual reflectance images compute individual reflectance images merge reflectance images using confidence values merge reflectance images using confidence values ü Initialise lighting system data structure data structure hierarchical radiosity system hierarchical radiosity system

12 MAGIS i Reflectance Computation ü For each radiance image photographreflectance reflectance = radiosity / ( direct light + indirect light )

13 MAGIS i Confidence Images ü Estimate confidence confidence ~ quality of reflectance estimate confidence ~ quality of reflectance estimate create a confidence image per light source position create a confidence image per light source position ü Begin with confidence = Visibility low in shadow regions low in shadow regions ü Filtering process to remove unwanted effects low for outliers (specular effects, light tripod) low for outliers (specular effects, light tripod)

14 MAGIS i Merged Reflectance Computation x x avg. reflectanceconfidence merged reflectance

15 MAGIS i Interactive Modification: Shadow Reprojection ü Direct illumination: pixel by pixel ü Indirect illumination: optimised radiosity solution a pixel Reflectance Indirect lighting Direct lighting

16 MAGIS i Shadow Re-projection photograph simulated

17 MAGIS i Add/move/remove object (virtual or real) ü Visible surface changes: pixel by pixel local update project bounding box of dynamic object project bounding box of dynamic object  localise directly affected pixels original object insertion

18 MAGIS i Add/move/remove object (virtual or real) ü Direct lighting updates: shaft structure localisation of visibility changes (shadows) localisation of visibility changes (shadows) accelerate visibility computation (blocker lists) accelerate visibility computation (blocker lists) original object insertion

19 MAGIS i Add/move/remove object (virtual or real) ü Indirect illumination computed by a radiosity solution (optimised by the shaft structure) ü Example: moving object Position 1Position 2

20 MAGIS i Real Object Removal

21 MAGIS i Removing Real Objects ü Use of the reflectance image (lighting effects removed) to generate new textures reflectance images

22 MAGIS i Light Source Modification ü Insertion of a virtual light source computation for every pixel computation for every pixel  new form-factors  new visibility ü Indirect illumination: radiosity solution

23 MAGIS i Lighting Modification Insertion of virtual light Original virtual lighting

24 MAGIS i Video

25 MAGIS i Conclusion ü Input data simple to acquire data simple to acquire ü Pre-process data structures optimised for fast updates data structures optimised for fast updates ü Interactive modification add and move virtual objects add and move virtual objects remove real objects remove real objects relighting relighting

26 MAGIS i Future Work ü Improve reflectance computation use of high dynamic range images (instead of RGB) use of high dynamic range images (instead of RGB) better control of indirect illumination better control of indirect illumination ü Allow motion of real objects ü Faster: parallel computation

27 MAGIS i Future Work ü Remove restrictions diffuse reflectance [Yu et al. 99] diffuse reflectance [Yu et al. 99] fixed view-point fixed view-point

Download ppt "Interactive Virtual Relighting and Remodelling of Real Scenes C. Loscos 1, MC. Frasson 1,2,G. Drettakis 1, B. Walter 1, X. Granier 1, P. Poulin 2 (1) iMAGIS*"

Similar presentations

Computer graphics & visualization Global Illumination Effects.

Computer graphics & visualization Global Illumination Effects.
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.
Interactive Rendering using the Render Cache Bruce Walter, George Drettakis iMAGIS*-GRAVIR/IMAG-INRIA Steven Parker University of Utah *iMAGIS is a joint.

Interactive Rendering using the Render Cache Bruce Walter, George Drettakis iMAGIS*-GRAVIR/IMAG-INRIA Steven Parker University of Utah *iMAGIS is a joint.
Chunhui Yao 1 Bin Wang 1 Bin Chan 2 Junhai Yong 1 Jean-Claude Paul 3,1 1 Tsinghua University, China 2 The University of Hong Kong, China 3 INRIA, France.

Chunhui Yao 1 Bin Wang 1 Bin Chan 2 Junhai Yong 1 Jean-Claude Paul 3,1 1 Tsinghua University, China 2 The University of Hong Kong, China 3 INRIA, France.
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?
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.
Rendering with Environment Maps Jaroslav Křivánek, KSVI, MFF UK

Rendering with Environment Maps Jaroslav Křivánek, KSVI, MFF UK
Paper Presentation - An Efficient GPU-based Approach for Interactive Global Illumination- Rui Wang, Rui Wang, Kun Zhou, Minghao Pan, Hujun Bao Presenter.

Paper Presentation - An Efficient GPU-based Approach for Interactive Global Illumination- Rui Wang, Rui Wang, Kun Zhou, Minghao Pan, Hujun Bao Presenter.
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.
Copyright  Philipp Slusallek Cs448.98.fall IBR: Model-based Methods Philipp Slusallek.

Copyright  Philipp Slusallek Cs fall IBR: Model-based Methods Philipp Slusallek.
Photon Tracing with Arbitrary Materials Patrick Yau.

Photon Tracing with Arbitrary Materials Patrick Yau.
Measurement, Inverse Rendering COMS 6998-3, Lecture 4.

Measurement, Inverse Rendering COMS , Lecture 4.
1 Image-Based Visual Hulls Paper by Wojciech Matusik, Chris Buehler, Ramesh Raskar, Steven J. Gortler and Leonard McMillan [http://graphics.lcs.mit.edu/~wojciech/vh/]

1 Image-Based Visual Hulls Paper by Wojciech Matusik, Chris Buehler, Ramesh Raskar, Steven J. Gortler and Leonard McMillan [
Final Gathering on GPU Toshiya Hachisuka University of Tokyo Introduction Producing global illumination image without any noise.

Final Gathering on GPU Toshiya Hachisuka University of Tokyo Introduction Producing global illumination image without any noise.
Flexible Bump Map Capture From Video James A. Paterson and Andrew W. Fitzgibbon University of Oxford Calibration Requirement:

Flexible Bump Map Capture From Video James A. Paterson and Andrew W. Fitzgibbon University of Oxford Calibration Requirement:
Everything on Global Illumination Xavier Granier - IMAGER/UBC.

Everything on Global Illumination Xavier Granier - IMAGER/UBC.
The Radiosity Method Donald Fong February 10, 2004.

The Radiosity Method Donald Fong February 10, 2004.
Paper by Alexander Keller

Paper by Alexander Keller
CSCE 641: Computer Graphics Image-based Rendering Jinxiang Chai.

CSCE 641: Computer Graphics Image-based Rendering Jinxiang Chai.
Convergence of vision and graphics Jitendra Malik University of California at Berkeley Jitendra Malik University of California at Berkeley.

Convergence of vision and graphics Jitendra Malik University of California at Berkeley Jitendra Malik University of California at Berkeley.

Similar presentations

Ads by Google