Presentation is loading. Please wait.

Presentation is loading. Please wait.

Image-Based Modeling of Complex Surfaces Todd Zickler DEAS, Harvard University.

Published byClarissa Lester Modified over 8 years ago

Similar presentations

Presentation on theme: "Image-Based Modeling of Complex Surfaces Todd Zickler DEAS, Harvard University."— Presentation transcript:

1 Image-Based Modeling of Complex Surfaces Todd Zickler DEAS, Harvard University

2 Image-Based Modeling of Complex Surfaces Appearance

3 Image-Based Modeling of Complex Surfaces Modeling Appearance: Face Recognition [Harvard Face Database]

4 Image-Based Modeling of Complex Surfaces Modeling Appearance: Tracking Spacetime Faces [Zhang et al., 2004] Detection/tracking of facial features [Colmenarez et al., 1999]

5 Image-Based Modeling of Complex Surfaces Modeling Appearance: Applications  Object recognition  Face recognition  Visual tracking  Human-computer interfaces  Compression  Navigation  Surveillance  Metrology  Inspection  Vision for Graphics

6 Image-Based Modeling of Complex Surfaces Appearance

7 Image-Based Modeling of Complex Surfaces Non-parametric Appearance: Uniform Sampling? 5 º sampling 1,000,000 images >1x10 6 Mb 1 º sampling 625,000,000 images >1x10 9 Mb

8 Image-Based Modeling of Complex Surfaces Appearance = Shape + Reflectance SHAPEREFLECTANCE

9 Image-Based Modeling of Complex Surfaces Reflectance

10 Image-Based Modeling of Complex Surfaces Outline I = f ( shape, reflectance, illumination ) 1. SHAPE f -1 ( I ) = ?

11 Image-Based Modeling of Complex Surfaces Outline 1. SHAPE I = f ( shape, reflectance, illumination )

12 Image-Based Modeling of Complex Surfaces Outline 1. SHAPE + 2. REFLECTANCE

13 Image-Based Modeling of Complex Surfaces Shape: Restrictive Reflectance Assumptions Shape from shading [Tsai and Shaw, 1994] Variational Stereo [Faugeras and Keriven, 1998] Space Carving [Kutulakos and Seitz, 1998] Multiple-window stereo [Fusiello et al., 1997]

14 Image-Based Modeling of Complex Surfaces Simple (and Common!) Reflectance Model LAMBERTIAN: IDEALLY DIFFUSE

15 Image-Based Modeling of Complex Surfaces Example: Conventional Stereo

16 Image-Based Modeling of Complex Surfaces Example: Conventional Stereo

17 Image-Based Modeling of Complex Surfaces Reflectance: BRDF

18 Image-Based Modeling of Complex Surfaces Reflectance: BRDF

19 Image-Based Modeling of Complex Surfaces Helmholtz Reciprocity [Helmholtz 1925; Minnaert 1941; Nicodemus et al. 1977]

20 Image-Based Modeling of Complex Surfaces Stereo vs. Helmholtz Stereo STEREOHELMHOLTZ STEREO

21 Image-Based Modeling of Complex Surfaces Stereo vs. Helmholtz Stereo STEREOHELMHOLTZ STEREO

22 Image-Based Modeling of Complex Surfaces Reciprocal Images  Specularities “fixed” to surface IlIl IrIr  Relation between I l and I r independent of BRDF

23 Image-Based Modeling of Complex Surfaces Reciprocity Constraint ^ n vlvl ^ vrvr ^ p olol oror = vlvl ^ vrvr ^ p olol oror ^ n

24 Image-Based Modeling of Complex Surfaces Reciprocity Constraint ^ n vlvl ^ vrvr ^ p olol oror = vlvl ^ vrvr ^ p olol oror ^ n  Arbitrary reflectance  Surface normal

25 Image-Based Modeling of Complex Surfaces Reciprocal Acquisition CAMERA LIGHT SOURCE

26 Image-Based Modeling of Complex Surfaces Recovered Normals [ECCV 2002]

27 Image-Based Modeling of Complex Surfaces Recovered Surface [ECCV 2002]

28 Image-Based Modeling of Complex Surfaces Helmholtz Stereopsis: Recent Work Uncalibrated Helmholtz Stereopsis Binocular Helmholtz Stereopsis [CVPR 2003][ICCV 2003]

29 Image-Based Modeling of Complex Surfaces Outline 1. SHAPE + 2. REFLECTANCE

30 Image-Based Modeling of Complex Surfaces Spatially-varying Reflectance 5 º sampling: 1,000,000 images; >1x10 6 Mb 1 º sampling: 625,000,000 images; >1x10 9 Mb x 

31 Image-Based Modeling of Complex Surfaces Point-wise Reflectance Measurement (& Light Fields) Stanford Computer Graphics LaboratoryUSC Institute for Creative Technologies Graphics Lab Mitsubishi Electric Research LaboratoriesUniversity of Illinois Beckman Institute

32 Image-Based Modeling of Complex Surfaces Reflectance Sharing = Scattered Data Interpolation )()θ,(qfxf     q  x θ  

33 Image-Based Modeling of Complex Surfaces Application: Human Face

34 Image-Based Modeling of Complex Surfaces Application: Human Face DIFFUSESPECULAR          N i iikkk qqqplxaqf 1 λ)()()( ~ 

35 Image-Based Modeling of Complex Surfaces PREDICTED Application: Human Face ACTUALPREDICTED

36 Image-Based Modeling of Complex Surfaces Predicting Appearance in Real Time

37 Image-Based Modeling of Complex Surfaces Conclusion SHAPEREFLECTANCE

38 Image-Based Modeling of Complex Surfaces Future Work 1. Face/object recognition 2. Surface structure at shape/reflectance interface, transparency 3. Appearance over time  weathering, aging 4. Dynamic appearance  Reflectance under deformation

39 zickler@eecs.harvard.edu http://www.eecs.harvard.edu/~zickler

Download ppt "Image-Based Modeling of Complex Surfaces Todd Zickler DEAS, Harvard University."

Similar presentations

A Projective Framework for Radiometric Image Analysis CVPR 2009 Date: 2010/3/9 Reporter : Annie lin.

A Projective Framework for Radiometric Image Analysis CVPR 2009 Date: 2010/3/9 Reporter : Annie lin.
Computer graphics & visualization Global Illumination Effects.

Computer graphics & visualization Global Illumination Effects.
Computer Vision Spring 2006 15-385,-685 Instructor: S. Narasimhan Wean 5403 T-R 3:00pm – 4:20pm Lecture #12.

Computer Vision Spring ,-685 Instructor: S. Narasimhan Wean 5403 T-R 3:00pm – 4:20pm Lecture #12.
Lecture 35: Photometric stereo CS4670 / 5670 : Computer Vision Noah Snavely.

Lecture 35: Photometric stereo CS4670 / 5670 : Computer Vision Noah Snavely.
3D Modeling from a photograph https://research.microsoft.com/vision/cambridge/3d/3dart.htm.

3D Modeling from a photograph
Spherical Convolution in Computer Graphics and Vision Ravi Ramamoorthi Columbia Vision and Graphics Center Columbia University SIAM Imaging Science Conference:

Spherical Convolution in Computer Graphics and Vision Ravi Ramamoorthi Columbia Vision and Graphics Center Columbia University SIAM Imaging Science Conference:
Measuring BRDFs. Why bother modeling BRDFs? Why not directly measure BRDFs? True knowledge of surface properties Accurate models for graphics.

Measuring BRDFs. Why bother modeling BRDFs? Why not directly measure BRDFs? True knowledge of surface properties Accurate models for graphics.
Vision Sensing. Multi-View Stereo for Community Photo Collections Michael Goesele, et al, ICCV 2007 Venus de Milo.

Vision Sensing. Multi-View Stereo for Community Photo Collections Michael Goesele, et al, ICCV 2007 Venus de Milo.
Robust Object Tracking via Sparsity-based Collaborative Model

Robust Object Tracking via Sparsity-based Collaborative Model
1. What is Lighting? 2 Example 1. Find the cubic polynomial or that passes through the four points and satisfies 1.As a photon Metal Insulator.

1. What is Lighting? 2 Example 1. Find the cubic polynomial or that passes through the four points and satisfies 1.As a photon Metal Insulator.
Illumination Model How to compute color to represent a scene As in taking a photo in real life: – Camera – Lighting – Object Geometry Material Illumination.

Illumination Model How to compute color to represent a scene As in taking a photo in real life: – Camera – Lighting – Object Geometry Material Illumination.
Advanced Computer Graphics CSE 190 [Spring 2015], Lecture 14 Ravi Ramamoorthi

Advanced Computer Graphics CSE 190 [Spring 2015], Lecture 14 Ravi Ramamoorthi
Project 3 extension: Wednesday at noon Final project proposal extension: Friday at noon >consult with Steve, Rick, and/or Ian now! Project 2 artifact winners...

Project 3 extension: Wednesday at noon Final project proposal extension: Friday at noon >consult with Steve, Rick, and/or Ian now! Project 2 artifact winners...
Course Review CS/ECE 181b Spring 2004. Topics since Midterm Stereo vision Shape from shading Optical flow Face recognition project.

Course Review CS/ECE 181b Spring Topics since Midterm Stereo vision Shape from shading Optical flow Face recognition project.
Capturing light Source: A. Efros. Review Pinhole projection models What are vanishing points and vanishing lines? What is orthographic projection? How.

Capturing light Source: A. Efros. Review Pinhole projection models What are vanishing points and vanishing lines? What is orthographic projection? How.
Advanced Computer Graphics (Fall 2010) CS 283, Lecture 16: Image-Based Rendering and Light Fields Ravi Ramamoorthi

Advanced Computer Graphics (Fall 2010) CS 283, Lecture 16: Image-Based Rendering and Light Fields Ravi Ramamoorthi
Measurement, Inverse Rendering COMS 6998-3, Lecture 4.

Measurement, Inverse Rendering COMS , Lecture 4.
Image-Based Modeling and Rendering CS 6998 Lecture 6.

Image-Based Modeling and Rendering CS 6998 Lecture 6.
Multi-view stereo Many slides adapted from S. Seitz.

Multi-view stereo Many slides adapted from S. Seitz.
Visibility Subspaces: Uncalibrated Photometric Stereo with Shadows Kalyan Sunkavalli, Harvard University Joint work with Todd Zickler and Hanspeter Pfister.

Visibility Subspaces: Uncalibrated Photometric Stereo with Shadows Kalyan Sunkavalli, Harvard University Joint work with Todd Zickler and Hanspeter Pfister.

Similar presentations

Ads by Google