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Wenzel Jakob
Person information
- affiliation: École Polytechnique Fédérale de Lausanne (EPFL), Switzerland
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Books and Theses
- 2013
- [b1]Wenzel Jakob:
Light Transport on Path-Space Manifolds. Cornell University, USA, 2013
Journal Articles
- 2024
- [j46]Ekrem Fatih Yilmazer, Delio Vicini, Wenzel Jakob:
Solving Inverse PDE Problems using Grid-Free Monte Carlo Estimators. ACM Trans. Graph. 43(6): 175:1-175:18 (2024) - [j45]Baptiste Nicolet, Felix Wechsler, Jorge Madrid-Wolff, Christophe Moser, Wenzel Jakob:
Inverse Rendering for Tomographic Volumetric Additive Manufacturing. ACM Trans. Graph. 43(6): 228:1-228:17 (2024) - 2023
- [j44]Baptiste Nicolet
, Fabrice Rousselle
Recursive Control Variates for Inverse Rendering. ACM Trans. Graph. 42(4): 62:1-62:13 (2023) - [j43]Ziyi Zhang
Projective Sampling for Differentiable Rendering of Geometry. ACM Trans. Graph. 42(6): 212:1-212:14 (2023) - 2022
- [j42]Merlin Nimier-David
Unbiased inverse volume rendering with differential trackers. ACM Trans. Graph. 41(4): 44:1-44:20 (2022) - [j41]Wenzel Jakob, Sébastien Speierer, Nicolas Roussel, Delio Vicini:
DR.JIT: a just-in-time compiler for differentiable rendering. ACM Trans. Graph. 41(4): 124:1-124:19 (2022) - [j40]Delio Vicini, Sébastien Speierer, Wenzel Jakob:
Differentiable signed distance function rendering. ACM Trans. Graph. 41(4): 125:1-125:18 (2022) - 2021
- [j39]Tizian Zeltner
Monte Carlo estimators for differential light transport. ACM Trans. Graph. 40(4): 78:1-78:16 (2021) - [j38]Delio Vicini
Path replay backpropagation: differentiating light paths using constant memory and linear time. ACM Trans. Graph. 40(4): 108:1-108:14 (2021) - [j37]Delio Vicini
A non-exponential transmittance model for volumetric scene representations. ACM Trans. Graph. 40(4): 136:1-136:16 (2021) - [j36]Baptiste Nicolet, Alec Jacobson, Wenzel Jakob:
Large steps in inverse rendering of geometry. ACM Trans. Graph. 40(6): 248:1-248:13 (2021) - 2020
- [j35]Gilles Rainer, Abhijeet Ghosh, Wenzel Jakob, Tim Weyrich
Unified Neural Encoding of BTFs. Comput. Graph. Forum 39(2): 167-178 (2020) - [j34]Stavros Diolatzis, Adrien Gruson, Wenzel Jakob, Derek Nowrouzezahrai, George Drettakis:
Practical Product Path Guiding Using Linearly Transformed Cosines. Comput. Graph. Forum 39(4): 23-33 (2020) - [j33]Seung-Hwan Baek
Image-based acquisition and modeling of polarimetric reflectance. ACM Trans. Graph. 39(4): 139 (2020) - [j32]Merlin Nimier-David, Sébastien Speierer, Benoît Ruiz, Wenzel Jakob:
Radiative backpropagation: an adjoint method for lightning-fast differentiable rendering. ACM Trans. Graph. 39(4): 146 (2020) - [j31]Tizian Zeltner
Specular manifold sampling for rendering high-frequency caustics and glints. ACM Trans. Graph. 39(4): 149 (2020) - [j30]Guillaume Loubet, Tizian Zeltner
Slope-space integrals for specular next event estimation. ACM Trans. Graph. 39(6): 239:1-239:13 (2020) - [j29]Ibón Guillén
A general framework for pearlescent materials. ACM Trans. Graph. 39(6): 253:1-253:15 (2020) - 2019
- [j28]Wenzel Jakob, Johannes Hanika:
A Low-Dimensional Function Space for Efficient Spectral Upsampling. Comput. Graph. Forum 38(2): 147-155 (2019) - [j27]Gilles Rainer, Wenzel Jakob, Abhijeet Ghosh, Tim Weyrich
Neural BTF Compression and Interpolation. Comput. Graph. Forum 38(2): 235-244 (2019) - [j26]Alisa Jung, Alexander Wilkie
Wide Gamut Spectral Upsampling with Fluorescence. Comput. Graph. Forum 38(4): 87-96 (2019) - [j25]A. Celarek, Wenzel Jakob, Manuel Wimmer, Jaakko Lehtinen:
Quantifying the Error of Light Transport Algorithms. Comput. Graph. Forum 38(4): 111-121 (2019) - [j24]Delio Vicini
A learned shape-adaptive subsurface scattering model. ACM Trans. Graph. 38(4): 127:1-127:15 (2019) - [j23]Merlin Nimier-David, Delio Vicini
Mitsuba 2: a retargetable forward and inverse renderer. ACM Trans. Graph. 38(6): 203:1-203:17 (2019) - [j22]Guillaume Loubet, Nicolas Holzschuch, Wenzel Jakob:
Reparameterizing discontinuous integrands for differentiable rendering. ACM Trans. Graph. 38(6): 228:1-228:14 (2019) - 2018
- [j21]Benedikt Bitterli, Wenzel Jakob, Jan Novák, Wojciech Jarosz
Reversible Jump Metropolis Light Transport Using Inverse Mappings. ACM Trans. Graph. 37(1): 1 (2018) - [j20]Tizian Zeltner
The layer laboratory: a calculus for additive and subtractive composition of anisotropic surface reflectance. ACM Trans. Graph. 37(4): 74 (2018) - [j19]Jonathan Dupuy, Wenzel Jakob:
An adaptive parameterization for efficient material acquisition and rendering. ACM Trans. Graph. 37(6): 274 (2018) - 2017
- [j18]Nico Schertler, Marco Tarini, Wenzel Jakob, Misha Kazhdan, Stefan Gumhold, Daniele Panozzo:
Field-aligned online surface reconstruction. ACM Trans. Graph. 36(4): 77:1-77:13 (2017) - [j17]Xifeng Gao, Wenzel Jakob, Marco Tarini, Daniele Panozzo:
Robust hex-dominant mesh generation using field-guided polyhedral agglomeration. ACM Trans. Graph. 36(4): 114:1-114:13 (2017) - [j16]Sebastian Werner
Scratch iridescence: wave-optical rendering of diffractive surface structure. ACM Trans. Graph. 36(6): 207:1-207:14 (2017) - 2015
- [j15]Wenzel Jakob, Steve Marschner:
Geometric tools for exploring manifolds of light transport paths. Commun. ACM 58(11): 103-111 (2015) - [j14]Henning Zimmer, Fabrice Rousselle
Path-space Motion Estimation and Decomposition for Robust Animation Filtering. Comput. Graph. Forum 34(4): 131-142 (2015) - [j13]Wenzel Jakob, Marco Tarini, Daniele Panozzo, Olga Sorkine-Hornung:
Instant field-aligned meshes. ACM Trans. Graph. 34(6): 189:1-189:15 (2015) - [j12]Tzu-Mao Li, Jaakko Lehtinen, Ravi Ramamoorthi, Wenzel Jakob, Frédo Durand:
Anisotropic Gaussian mutations for metropolis light transport through Hessian-Hamiltonian dynamics. ACM Trans. Graph. 34(6): 209:1-209:13 (2015) - 2014
- [j11]Shuang Zhao, Wenzel Jakob, Steve Marschner, Kavita Bala
Building volumetric appearance models of fabric using micro CT imaging. Commun. ACM 57(11): 98-105 (2014) - [j10]Wenzel Jakob, Milos Hasan, Ling-Qi Yan, Jason Lawrence, Ravi Ramamoorthi, Steve Marschner:
Discrete stochastic microfacet models. ACM Trans. Graph. 33(4): 115:1-115:10 (2014) - [j9]Ling-Qi Yan, Milos Hasan, Wenzel Jakob, Jason Lawrence, Steve Marschner, Ravi Ramamoorthi:
Rendering glints on high-resolution normal-mapped specular surfaces. ACM Trans. Graph. 33(4): 116:1-116:9 (2014) - [j8]Wenzel Jakob, Eugene d'Eon
A comprehensive framework for rendering layered materials. ACM Trans. Graph. 33(4): 118:1-118:14 (2014) - 2012
- [j7]Wenzel Jakob, Steve Marschner:
Manifold exploration: a Markov Chain Monte Carlo technique for rendering scenes with difficult specular transport. ACM Trans. Graph. 31(4): 58:1-58:13 (2012) - [j6]Shuang Zhao
Structure-aware synthesis for predictive woven fabric appearance. ACM Trans. Graph. 31(4): 75:1-75:10 (2012) - 2011
- [j5]Marios Papas, Wojciech Jarosz
Goal-based Caustics. Comput. Graph. Forum 30(2): 503-511 (2011) - [j4]Wenzel Jakob, Christian Regg, Wojciech Jarosz
Progressive Expectation-Maximization for Hierarchical Volumetric Photon Mapping. Comput. Graph. Forum 30(4): 1287-1297 (2011) - [j3]Shuang Zhao
Building volumetric appearance models of fabric using micro CT imaging. ACM Trans. Graph. 30(4): 44 (2011) - 2010
- [j2]Wenzel Jakob, Adam Arbree, Jonathan T. Moon, Kavita Bala
A radiative transfer framework for rendering materials with anisotropic structure. ACM Trans. Graph. 29(4): 53:1-53:13 (2010) - 2009
- [j1]Wenzel Jakob, Jonathan T. Moon, Steve Marschner:
Capturing hair assemblies fiber by fiber. ACM Trans. Graph. 28(5): 164 (2009)
Conference and Workshop Papers
- 2024
- [c10]Zichen Wang, Xi Deng, Ziyi Zhang, Wenzel Jakob, Steve Marschner:
A Simple Approach to Differentiable Rendering of SDFs. SIGGRAPH Asia 2024: 119:1-119:11 - 2021
- [c9]Yinlin Hu, Sébastien Speierer, Wenzel Jakob, Pascal Fua, Mathieu Salzmann:
Wide-Depth-Range 6D Object Pose Estimation in Space. CVPR 2021: 15870-15879 - [c8]Merlin Nimier-David, Zhao Dong, Wenzel Jakob, Anton Kaplanyan:
Material and Lighting Reconstruction for Complex Indoor Scenes with Texture-space Differentiable Rendering. EGSR (DL) 2021: 73-84 - 2020
- [c7]Shuang Zhao, Wenzel Jakob, Tzu-Mao Li:
Physics-based differentiable rendering: from theory to implementation. SIGGRAPH Courses 2020: 14:1-14:30 - 2019
- [c6]Wenzel Jakob, Andrea Weidlich, Andrew Beddini, Rob Pieké, Hanzhi Tang, Luca Fascione, Johannes Hanika:
Path tracing in production: part 2: making movies. SIGGRAPH Courses 2019: 20:1-20:41 - 2018
- [c5]David Koerner, Jamie Portsmouth, Wenzel Jakob:
PN-Method for Multiple Scattering in Participating Media. EGSR (EI&I) 2018: 33-40 - 2015
- [c4]Stephen Hill, Stephen McAuley, Brent Burley, Danny Chan, Luca Fascione, Michal Iwanicki, Naty Hoffman, Wenzel Jakob, David Neubelt, Angelo Pesce, Matt Pettineo:
Physically based shading in theory and practice. SIGGRAPH Courses 2015: 22:1-22:8 - 2014
- [c3]Wenzel Jakob:
Linear Transport Theory and Applications to Rendering. Material Appearance Modeling 2014: 19-20 - [c2]Wenzel Jakob:
Path Space Markov Chain Monte Carlo Methods in Computer Graphics. MCQMC 2014: 107-141 - 2012
- [c1]Toshiya Hachisuka, Wojciech Jarosz, Guillaume Bouchard, Per H. Christensen, Jeppe Revall Frisvad
State of the art in photon density estimation. SIGGRAPH Courses 2012: 6:1-6:469
Editorship
- 2019
- [e2]Wenzel Jakob, Enrico Puppo:
40th Annual Conference of the European Association for Computer Graphics, Eurographics 2019 - Tutorials, Genoa, Italy, May 6-10, 2019. Eurographics Association 2019 [contents] - 2018
- [e1]Wenzel Jakob, Toshiya Hachisuka:
29th Eurographics Symposium on Rendering, Experimental Ideas & Implementations, EGSR 2018, EI&I Track, Karlsruhe, Germany, 1-4 July 2018. Eurographics Association 2018, ISBN 978-3-03868-068-0 [contents]
Informal and Other Publications
- 2024
- [i8]Zichen Wang, Xi Deng, Ziyi Zhang, Wenzel Jakob, Steve Marschner:
A Simple Approach to Differentiable Rendering of SDFs. CoRR abs/2405.08733 (2024) - [i7]Ziyi Zhang, Nicolas Roussel, Wenzel Jakob:
Many-Worlds Inverse Rendering. CoRR abs/2408.16005 (2024) - 2022
- [i6]Wenzel Jakob, Sébastien Speierer, Nicolas Roussel, Delio Vicini:
Dr.Jit: A Just-In-Time Compiler for Differentiable Rendering. CoRR abs/2202.01284 (2022) - [i5]Ekrem Fatih Yilmazer, Delio Vicini, Wenzel Jakob:
Solving Inverse PDE Problems using Grid-Free Monte Carlo Estimators. CoRR abs/2208.02114 (2022) - 2021
- [i4]Yinlin Hu, Sébastien Speierer, Wenzel Jakob, Pascal Fua, Mathieu Salzmann:
Wide-Depth-Range 6D Object Pose Estimation in Space. CoRR abs/2104.00337 (2021) - 2018
- [i3]David Koerner, Jamie Portsmouth, Wenzel Jakob:
PN-Method for Multiple Scattering in Participating Media. CoRR abs/1807.00410 (2018) - 2017
- [i2]Benedikt Bitterli, Wenzel Jakob, Jan Novák, Wojciech Jarosz:
Reversible Jump Metropolis Light Transport using Inverse Mappings. CoRR abs/1704.06835 (2017) - [i1]Sebastian Werner, Zdravko Velinov, Wenzel Jakob, Matthias B. Hullin:
Scratch iridescence: Wave-optical rendering of diffractive surface structure. CoRR abs/1705.06086 (2017)
Coauthor Index
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