“A Free-space Diffraction BSDF”
Conference:
Type(s):
Title:
- A Free-space Diffraction BSDF
Presenter(s)/Author(s):
Abstract:
Free-space diffractions are an optical phenomenon where light diffracts (?bends?) around the geometric edges and corners of scene objects. In this paper, we present an efficient method to simulate such effects and show that we can run wave simulations on scenes orders-of-magnitude more complex than what’s possible with the state of the art.
References:
[1]
Birk Andreas, Giovanni Mana, and Carlo Palmisano. 2015. Vectorial ray-based diffraction integral. Journal of the Optical Society of America A 32, 8 (July 2015), 1403.
[2]
Laurent Belcour and Pascal Barla. 2017. A Practical Extension to Microfacet Theory for the Modeling of Varying Iridescence. ACM Trans. Graph. 36, 4, Article 65 (July 2017), 14 pages.
[3]
D Bilibashi, EM Vitucci, and V Degli-Esposti. 2020. Dynamic ray tracing: Introduction and concept. In 2020 14th European Conference on Antennas and Propagation (EuCAP). IEEE, 1–5.
[4]
Mate Boban, Joao Barros, and Ozan K Tonguz. 2014. Geometry-based vehicle-to-vehicle channel modeling for large-scale simulation. IEEE Transactions on Vehicular Technology 63, 9 (2014), 4146–4164.
[5]
Max Born and Emil Wolf. 1999. Principles of optics : electromagnetic theory of propagation, interference and diffraction of light. Cambridge University Press, Cambridge New York.
[6]
Mikel Celaya-Echarri, Leyre Azpilicueta, Peio Lopez-Iturri, Francisco Falcone, Manuel Garcia Sanchez, and Ana Vazquez Alejos. 2020. Validation of 3D simulation tool for radio channel modeling at 60 GHz: A meeting point for empirical and simulation-based models. Measurement (Lond.) 163, 108038 (Oct. 2020), 108038.
[7]
Hyuckjin Choi, Jaeky Oh, Jaehoon Chung, George C Alexandropoulos, and Junil Choi. 2023. WiThRay: A Versatile Ray-Tracing Simulator for Smart Wireless Environments. IEEE Access (2023).
[8]
FS de Adana, O Gutierrez, I Gonzalez, and MF Catedra. 2005. FASPRO: Fast computer tool for the analysis of propagation in mobile communications. In INDIN’05. 2005 3rd IEEE International Conference on Industrial Informatics, 2005. IEEE, 257–261.
[9]
Pengcheng Gao, Xiaobing Wang, Zichang Liang, and Wei Gao. 2015. Efficient GPU implementation of SBR for fast computation of composite scattering from electrically large target over a randomly rough surface. In 2015 IEEE International Symposium on Antennas and Propagation ; USNC/URSI National Radio Science Meeting. IEEE.
[10]
Junfeng Guan, Sohrab Madani, Suraj Jog, Saurabh Gupta, and Haitham Hassanieh. 2020. Through fog high-resolution imaging using millimeter wave radar. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition. 11464–11473.
[11]
J G Huang, J M Christian, and G S McDonald. 2006. Fresnel diffraction and fractal patterns from polygonal apertures. J. Opt. Soc. Am. A Opt. Image Sci. Vis. 23, 11 (Nov. 2006), 2768–2774.
[12]
Weizhen Huang, Julian Iseringhausen, Tom Kneiphof, Ziyin Qu, Chenfanfu Jiang, and Matthias B. Hullin. 2020. Chemomechanical simulation of soap film flow on spherical bubbles. ACM Transactions on Graphics 39, 4 (Aug. 2020).
[13]
Wenzel Jakob. 2010. Mitsuba renderer. http://www.mitsuba-renderer.org.
[14]
K.-S. Jin, T.-I. Suh, S.-H. Suk, B.-C. Kim, and H.-T. Kim. 2006. Fast Ray Tracing Using A Space-Division Algorithm for RCS Prediction. Journal of Electromagnetic Waves and Applications 20, 1 (Jan. 2006), 119–126.
[15]
Ji?? Komrska. 1982. Simple derivation of formulas for Fraunhofer diffraction at polygonal apertures. J. Opt. Soc. Am. 72, 10 (Oct. 1982), 1382.
[16]
Samir Mezouari and Andy Robert Harvey. 2003. Validity of Fresnel and Fraunhofer approximations in scalar diffraction. J. Opt. Pure Appl. Opt. 5, 4 (July 2003), S86–S91.
[17]
Marco Mout, Andreas Flesch, Michael Wick, Florian Bociort, Joerg Petschulat, and Paul Urbach. 2018. Ray-based method for simulating cascaded diffraction in high-numerical-aperture systems. J. Opt. Soc. Am. A Opt. Image Sci. Vis. 35, 8 (Aug. 2018), 1356.
[18]
Robert Paknys. 2016. Uniform theory of diffraction. In Applied Frequency-Domain Electromagnetics. John Wiley & Sons, Ltd, Chichester, UK, Chapter 8, 268–316.
[19]
Louis Pisha, Siddharth Atre, John Burnett, and Shahrokh Yadegari. 2020. Approximate diffraction modeling for real-time sound propagation simulation. J. Acoust. Soc. Am. 148, 4 (Oct. 2020), 1922.
[20]
Iman Sadeghi, Adolfo Munoz, Philip Laven, Wojciech Jarosz, Francisco Seron, Diego Gutierrez, and Henrik Wann Jensen. 2012. Physically-based Simulation of Rainbows. ACM Transactions on Graphics (Presented at SIGGRAPH) 31, 1 (Feb. 2012), 3:1–3:12.
[21]
Carl Schissler, Gregor M?ckl, and Paul Calamia. 2021. Fast diffraction pathfinding for dynamic sound propagation. ACM Trans. Graph. 40, 4 (Aug. 2021), 1–13.
[22]
Hae-Won Son and Noh-Hoon Myung. 1999. A deterministic ray tube method for microcellular wave propagation prediction model. IEEE Transactions on Antennas and Propagation 47, 8 (1999), 1344–1350.
[23]
Shlomi Steinberg. 2019. Analytic Spectral Integration of Birefringence-Induced Iridescence. Computer Graphics Forum 38, 4 (Jul 2019), 97–110.
[24]
Shlomi Steinberg, Ravi Ramamoorthi, Benedikt Bitterli, Eugene d’Eon, Ling-Qi Yan, and Matt Pharr. 2023. A generalized ray formulation for wave-optics rendering. (2023).
[25]
Shlomi Steinberg, Pradeep Sen, and Ling-Qi Yan. 2022. Towards Practical Physical-Optics Rendering. ACM Transactions on Graphics 41, 4 (Jul 2022), 1–13.
[26]
Shlomi Steinberg and Ling-Qi Yan. 2021. A generic framework for physical light transport. ACM Transactions on Graphics 40, 4 (Aug 2021), 1–20.
[27]
Sungha Suk, Tae-Il Seo, Hae-Sung Park, and Hyo-Tae Kim. 2001. Multiresolution grid algorithm in the SBR and its application to the RCS calculation. Microwave and Optical Technology Letters 29, 6 (2001), 394–397.
[28]
Yubo Tao, Hai Lin, and Hujun Bao. 2010. GPU-Based Shooting and Bouncing Ray Method for Fast RCS Prediction. IEEE Transactions on Antennas and Propagation 58, 2 (Feb. 2010), 494–502.
[29]
Yu-Bo Tao, Hai Lin, and Hu Jun Bao. 2008. Kd-tree based fast ray tracing for rcs prediction. Electromagn. Waves (Camb.) 81 (2008), 329–341.
[30]
Nicolas Tsingos, Thomas Funkhouser, Addy Ngan, and Ingrid Carlbom. 2001. Modeling acoustics in virtual environments using the uniform theory of diffraction. In Proceedings of the 28th annual conference on Computer graphics and interactive techniques (SIGGRAPH01). ACM.
[31]
Fukun Wu and Changwen Zheng. 2016. Interference Shader for Multilayer Films. Springer International Publishing, 62–74.
[32]
Mengqi (Mandy) Xia, Bruce Walter, Eric Michielssen, David Bindel, and Steve Marschner. 2020. A wave optics based fiber scattering model. ACM Transactions on Graphics 39, 6 (Nov. 2020), 1–16.
[33]
Haofan Yi, Danping He, P Takis Mathiopoulos, Bo Ai, Juan Moreno Garcia-Loygorri, Jianwu Dou, and Zhangdui Zhong. 2022. Ray tracing meets terahertz: Challenges and opportunities. IEEE Communications Magazine (2022).
[34]
Andrew Zangwill. 2013. Modern electrodynamics. Cambridge University Press, Cambridge.
