research-article

Public Access

Practical multiple scattering for rough surfaces

Authors:

Daniel S. Jeon,

Diego Gutierrez,

Min H. KimAuthors Info & Claims

ACM Transactions on Graphics (TOG), Volume 37, Issue 6

Article No.: 275, Pages 1 - 12

https://doi.org/10.1145/3272127.3275016

Published: 04 December 2018 Publication History

Abstract

Microfacet theory concisely models light transport over rough surfaces. Specular reflection is the result of single mirror reflections on each facet, while exact computation of multiple scattering is either neglected, or modeled using costly importance sampling techniques. Practical but accurate simulation of multiple scattering in microfacet theory thus remains an open challenge. In this work, we revisit the traditional V-groove cavity model and derive an analytical, cost-effective solution for multiple scattering in rough surfaces. Our kaleidoscopic model is made up of both real and virtual V-grooves, and allows us to calculate higher-order scattering in the microfacets in an analytical fashion. We then extend our model to include nonsymmetric grooves, allowing for additional degrees of freedom on the surface geometry, improving multiple reflections at grazing angles with backward compatibility to traditional normal distribution functions. We validate the accuracy of our model against ground-truth Monte Carlo simulations, and demonstrate its flexibility on anisotropic and textured materials. Our model is analytical, does not introduce significant cost and variance, can be seamless integrated in any rendering engine, preserves reciprocity and energy conservation, and is suitable for bidirectional methods.

Supplementary Material

ZIP File (a275-lee.zip)

Supplemental files.

Download
9.45 MB

References

[1]

M. Ashikmin, S. Premoze, and P. Shirley. 2000. A Microfacet-based BRDF Generator. In SIGGRAPH. 65--74.

Digital Library

[2]

S.-H. Baek, D. S. Jeon, X. Tong, and M. H. Kim. 2018. Simultaneous Acquisition of Polarimetric SVBRDF and Normals. ACM Trans. Graph. 37, 6 (2018).

Digital Library

[3]

P. Beckmann and A. Spizzichino. 1963. The scattering of electromagnetic waves from rough surfaces. Int Ser. Monographs. Electomagn Waves 4 (1963).

[4]

C. Bosch, X. Pueyo, S. Merillou, and D. Ghazanfarpour. 2004. A Physically Based Model for Rendering Realistic Scratches. Comput. Graph. Forum 23, 3 (2004), 361--370.

[5]

C. Bourlier and G. Berginc. 2004. Multiple scattering in the high-frequency limit with second-order shadowing function from 2D anisotropic rough dielectric surfaces: I. Theoretical study. Wave. Random Media 14, 3 (2004), 253--276.

[6]

C. Bourlier, G. Berginc, and J. Saillard. 2002. Monostatic and bistatic statistical shadowing functions from a one-dimensional stationary randomly rough surface: II. Multiple scattering. Wave. Random Media 12, 2 (2002), 175--200.

[7]

R. L. Cook and K. E. Torrance. 1982. A Reflectance Model for Computer Graphics. ACM Trans. Graph. 1, 1 (1982), 7--24.

Digital Library

[8]

Z. Dong, B. Walter, S. Marschner, and D. P. Greenberg. 2015. Predicting appearance from measured microgeometry of metal surfaces. ACM Trans. Graph. 35, 1 (2015), 9.

Digital Library

[9]

J. Dupuy, E. Heitz, and E. d'Eon. 2016. Additional Progress Towards the Unification of Microfacet and Microflake Theories. In Proc. Eurograph. Symp. Rendering. 55--63.

Digital Library

[10]

B. W. Hapke. 1963. A theoretical photometric function for the lunar surface. J. Geophy. Re. 68, 15 (1963), 4571--4586.

[11]

E. Heitz. 2014. Understanding the Masking-Shadowing Function in Microfacet-Based BRDFs. J. Comput. Graph. Techn. 3, 2 (2014), 48--107.

[12]

E. Heitz and E. d'Eon. 2014. Importance Sampling Microfacet-Based BSDFs using the Distribution of Visible Normals. Comput. Graph. Forum 33, 4 (2014), 103--112.

Digital Library

[13]

E. Heitz, J. Hanika, E. d'Eon, and C. Dachsbacher. 2016. Multiple-scattering Microfacet BSDFs with the Smith Model. ACM Trans. Graph. 35, 4 (2016), 58:1--58:14.

Digital Library

[14]

N. Holzschuch and R. Pacanowski. 2017. A two-scale microfacet reflectance model combining reflection and diffraction. ACM Trans. Graph. 36, 4 (2017), 66.

Digital Library

[15]

W. Jakob. 2010. Mitsuba renderer. http://www.mitsuba-renderer.org.

[16]

W. Jakob, E. d'Eon, O. Jakob, and S. Marschner. 2014. A Comprehensive Framework for Rendering Layered Materials. ACM Trans. Graph. 33, 4 (2014), 118:1--118:14.

Digital Library

[17]

C. Kelemen and L. Szirmay-Kalos. 2001. A Microfacet Based Coupled Specular-Matte BRDF Model with Importance Sampling. In Proc. Eurograph. Short Presentations, Vol. 2. 4.

[18]

J. J. Koenderink, A. J. Van Doorn, K. J. Dana, and S. Nayar. 1999. Bidirectional reflection distribution function of thoroughly pitted surfaces. Int. J. Comput. Vis. 31, 2--3 (1999), 129--144.

Digital Library

[19]

C. Kulla and A. Conty. 2017. Revisiting Physically Based Shading at Imageworks. In Physically Based Shading in Theory and Practice, SIGGRAPH 2017 Courses.

[20]

S. Merillou, J.M. Dischler, and D. Ghazanfarpour. 2001. Surface scratches: measuring, modeling and rendering. Vis. Comput. 17, 1 (2001), 30--45.

[21]

G. Nam, J. H. Lee, D. Gutierrez, and M. H. Kim. 2018. Practical SVBRDF Acquisition of 3D Objects with Unstructured Flash Photography. ACM Trans. Graph. 37, 6 (2018).

Digital Library

[22]

G. Nam, J. H. Lee, H. Wu, D. Gutierrez, and M. H. Kim. 2016. Simultaneous Acquisition of Microscale Reflectance and Normals. ACM Trans. Graph. 35, 6 (2016), 185:1--185:11.

Digital Library

[23]

M. Oren and S. K. Nayar. 1994. Generalization of Lambert's Reflectance Model. In SIGGRAPH. 239--246.

Digital Library

[24]

P. Poulin and A. Fournier. 1990. A Model for Anisotropic Reflection. SIGGRAPH Comput. Graph. 24, 4 (1990), 273--282.

Digital Library

[25]

B. Raymond, G. Guennebaud, and P. Barla. 2016. Multi-scale rendering of scratched materials using a structured SV-BRDF model. ACM Trans. Graph. 35, 4 (2016), 57.

Digital Library

[26]

S. Rusinkiewicz. 1998. A New Change of Variables for Efficient BRDF Representation. In Rendering Techniques '98 (Proceedings of Eurographics Rendering Workshop '98), G. Drettakis and N. Max (Eds.). Springer Wien, 11--22.

[27]

D. Saint-Pierre, R. Deeb, D. Muselet, L. Simonot, and M. Hébert. 2018. Light interreflections and shadowing effects in a Lambertian V-cavity under diffuse illumination. J. Electron. Imag. (2018).

[28]

B. Smith. 1967. Geometrical shadowing of a random rough surface. IEEE Trans. Antennas Propag. 15, 5 (1967), 668--671.

[29]

K. E. Torrance and E. M. Sparrow. 1967. Theory for Off-Specular Reflection From Roughened Surfaces. J. Opt. Soc. Am. 57, 9 (1967), 1105--1114.

[30]

B. Walter, S. R. Marschner, H. Li, and K. E. Torrance. 2007. Microfacet Models for Refraction Through Rough Surfaces. In Proc. Eurograph. Symp. Rendering. 195--206.

Digital Library

[31]

R. B. Zipin. 1966. The apparent thermal radiation properties of an isothermal V-groove with specularly reflecting walls. J. Res. NBS C 70 (1966), 275--280.

Cited By

Yi SHong SQin YWang HLiu N(2025)Virtual Machine Placement in Edge Computing Based on Multi-Objective Reinforcement LearningElectronics10.3390/electronics1403063314:3(633)Online publication date: 6-Feb-2025
https://doi.org/10.3390/electronics14030633
Kang KGu TKwon T(2025)Learning Climbing Controllers for Physics‐Based CharactersComputer Graphics Forum10.1111/cgf.15284Online publication date: 30-Jan-2025
https://doi.org/10.1111/cgf.15284
Tamisier ERibardière MMeneveaux DHorna SPoulin P(2025)Visibility Evaluation in Microfacet TheoryIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2024.336365931:2(1422-1434)Online publication date: 1-Feb-2025
https://dl.acm.org/doi/10.1109/TVCG.2024.3363659
Show More Cited By

Index Terms

Practical multiple scattering for rough surfaces
1. Computing methodologies
  1. Computer graphics
    1. Rendering
      1. Reflectance modeling

Recommendations

Multiple scattering from distributions of specular v-grooves

Microfacet-based reflection models are the most common way to represent reflection from rough surfaces. However, a major current limitation of these models is that they only account for single scattering. Unfortunately, single scattering models do not ...
Multiple-scattering microfacet BSDFs with the Smith model

Modeling multiple scattering in microfacet theory is considered an important open problem because a non-negligible portion of the energy leaving rough surfaces is due to paths that bounce multiple times. In this paper we derive the missing multiple-...
Simulating multiple scattering in hair using a photon mapping approach

Simulating multiple scattering correctly is important for accurate rendering of hair. However, a volume of hair is a difficult scene to simulate because scattering from an individual fiber is very structured and forward directed, and because the ...

Comments

Information & Contributors

Information

Published In

cover image ACM Transactions on Graphics

ACM Transactions on Graphics Volume 37, Issue 6

December 2018

1401 pages

ISSN:0730-0301

EISSN:1557-7368

DOI:10.1145/3272127

Editor:
Takeo Igarashi
The University of Tokyo, Japan

Issue’s Table of Contents

Copyright © 2018 ACM.

Permission to make digital or hard copies of all or part 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 components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 04 December 2018

Published in TOG Volume 37, Issue 6

Permissions

Request permissions for this article.

Request Permissions

Check for updates

Author Tags

Qualifiers

Research-article

Funding Sources

National Research Foundation of Korea
Cross-Ministry Giga KOREA Project
Samsung Electronics
ICT R&D program of MSIT/IITP of Korea
Defense Advanced Research Projects Agency
European Research Council
Spanish Ministerio de Economia y Competitividad
KOCCA in MCST of Korea

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

58
Total Citations
View Citations
1,288
Total Downloads

Downloads (Last 12 months)280
Downloads (Last 6 weeks)31

Reflects downloads up to 08 Feb 2025

Other Metrics

View Author Metrics

Citations

Cited By

Yi SHong SQin YWang HLiu N(2025)Virtual Machine Placement in Edge Computing Based on Multi-Objective Reinforcement LearningElectronics10.3390/electronics1403063314:3(633)Online publication date: 6-Feb-2025
https://doi.org/10.3390/electronics14030633
Kang KGu TKwon T(2025)Learning Climbing Controllers for Physics‐Based CharactersComputer Graphics Forum10.1111/cgf.15284Online publication date: 30-Jan-2025
https://doi.org/10.1111/cgf.15284
Tamisier ERibardière MMeneveaux DHorna SPoulin P(2025)Visibility Evaluation in Microfacet TheoryIEEE Transactions on Visualization and Computer Graphics10.1109/TVCG.2024.336365931:2(1422-1434)Online publication date: 1-Feb-2025
https://dl.acm.org/doi/10.1109/TVCG.2024.3363659
Peng SLadenheim KShrestha SFermüller C(2024)Generation of Novel Fall Animation with Configurable AttributesProceedings of the 9th International Conference on Movement and Computing10.1145/3658852.3659087(1-6)Online publication date: 30-May-2024
https://dl.acm.org/doi/10.1145/3658852.3659087
Starke SStarke PHe NKomura TYe Y(2024)Categorical Codebook Matching for Embodied Character ControllersACM Transactions on Graphics10.1145/365820943:4(1-14)Online publication date: 19-Jul-2024
https://dl.acm.org/doi/10.1145/3658209
Zhang ZLiu RHanocka RAberman K(2024)TEDi: Temporally-Entangled Diffusion for Long-Term Motion SynthesisACM SIGGRAPH 2024 Conference Papers10.1145/3641519.3657515(1-11)Online publication date: 13-Jul-2024
https://dl.acm.org/doi/10.1145/3641519.3657515
Yang SZhu QZhuge JQiu QLi CYan YXu HYan LJin X(2024)Mob-FGSR: Frame Generation and Super Resolution for Mobile Real-Time RenderingACM SIGGRAPH 2024 Conference Papers10.1145/3641519.3657424(1-11)Online publication date: 13-Jul-2024
https://dl.acm.org/doi/10.1145/3641519.3657424
Lee JHong SCho C(2024)Reinforcement-learning agents for architects' trade-offs in designing children's play environment: A qualitative comparative analysisDesign Studies10.1016/j.destud.2024.10124891-92(101248)Online publication date: Mar-2024
https://doi.org/10.1016/j.destud.2024.101248
Jensen AChatagnon TKhoshsiyar NReda DVan De Panne MPontonnier CPettré J(2023)Physical Simulation of Balance Recovery after a PushProceedings of the 16th ACM SIGGRAPH Conference on Motion, Interaction and Games10.1145/3623264.3624448(1-11)Online publication date: 15-Nov-2023
https://dl.acm.org/doi/10.1145/3623264.3624448
Lucas SRibardiere MPacanowski RBarla P(2023)A Micrograin BSDF Model for the Rendering of Porous LayersSIGGRAPH Asia 2023 Conference Papers10.1145/3610548.3618241(1-10)Online publication date: 10-Dec-2023
https://dl.acm.org/doi/10.1145/3610548.3618241
Show More Cited By

View Options

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Article

Figures

Tables

Media

View Issue’s Table of Contents