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ORCIDJan Novák
This is just a disambiguation page, and is not intended to be the bibliography of an actual person. Any publication listed on this page has not been assigned to an actual author yet. If you know the true author of one of the publications listed below, you are welcome to contact us.
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2020 – today
- 2024
[j38]Tizian Zeltner
, Fabrice Rousselle, Andrea Weidlich, Petrik Clarberg, Jan Novák, Benedikt Bitterli, Alex Evans, Tomás Davidovic, Simon Kallweit, Aaron E. Lefohn:
Real-time Neural Appearance Models. ACM Trans. Graph. 43(3): 33:1-33:17 (2024)- [c18]Kamil Dedecius, Jan Novák, Petr Jechumtál:
JIPDA Filtering with Information Diffusion. EUSIPCO 2024: 2477-2481 - 2023
- [j37]Stavros Diolatzis, Jan Novák, Fabrice Rousselle, Jonathan Granskog, Miika Aittala, Ravi Ramamoorthi, George Drettakis:
MesoGAN: Generative Neural Reflectance Shells. Comput. Graph. Forum 42(6) (2023) - [j36]Baptiste Nicolet, Fabrice Rousselle, Jan Novák, Alexander Keller, Wenzel Jakob, Thomas Müller:
Recursive Control Variates for Inverse Rendering. ACM Trans. Graph. 42(4): 62:1-62:13 (2023) - [c17]Saeed Hadadan, Geng Lin, Jan Novák, Fabrice Rousselle, Matthias Zwicker:
Inverse Global Illumination using a Neural Radiometric Prior. SIGGRAPH (Conference Paper Track) 2023: 17:1-17:11 - [i12]Saeed Hadadan, Geng Lin, Jan Novák, Fabrice Rousselle, Matthias Zwicker:
Inverse Global Illumination using a Neural Radiometric Prior. CoRR abs/2305.02192 (2023) - [i11]Tizian Zeltner, Fabrice Rousselle, Andrea Weidlich, Petrik Clarberg, Jan Novák, Benedikt Bitterli, Alex Evans, Tomás Davidovic, Simon Kallweit, Aaron E. Lefohn:
Real-Time Neural Appearance Models. CoRR abs/2305.02678 (2023) - 2022
- [j35]Hendrik Baatz, Jonathan Granskog, Marios Papas, Fabrice Rousselle, Jan Novák:
NeRF-Tex: Neural Reflectance Field Textures. Comput. Graph. Forum 41(6): 287-301 (2022) - 2021
- [j34]Thomas Müller, Fabrice Rousselle, Jan Novák, Alexander Keller:
Real-time neural radiance caching for path tracing. ACM Trans. Graph. 40(4): 36:1-36:16 (2021) - [j33]Markus Kettunen, Eugene d'Eon, Jacopo Pantaleoni, Jan Novák:
An unbiased ray-marching transmittance estimator. ACM Trans. Graph. 40(4): 137:1-137:20 (2021) - [j32]Jonathan Granskog, Till N. Schnabel, Fabrice Rousselle, Jan Novák:
Neural scene graph rendering. ACM Trans. Graph. 40(4): 164:1-164:11 (2021) - [c16]Hendrik Baatz, Jonathan Granskog, Marios Papas, Fabrice Rousselle, Jan Novák:
NeRF-Tex: Neural Reflectance Field Textures. EGSR (DL) 2021: 1-13 - [c15]Eugene d'Eon, Jan Novák:
Zero-variance Transmittance Estimation. EGSR (DL) 2021: 15-20 - [i10]Markus Kettunen, Eugene d'Eon, Jacopo Pantaleoni, Jan Novák:
An unbiased ray-marching transmittance estimator. CoRR abs/2102.10294 (2021) - [i9]Thomas Müller, Fabrice Rousselle, Jan Novák, Alexander Keller:
Real-time Neural Radiance Caching for Path Tracing. CoRR abs/2106.12372 (2021) - 2020
- [j31]Martin Doskár, Jan Zeman, Daniel Rypl, Jan Novák:
Level-set Based Design of Wang Tiles for Modelling Complex Microstructures. Comput. Aided Des. 123: 102827 (2020) - [j30]Jonathan Granskog, Fabrice Rousselle, Marios Papas, Jan Novák:
Compositional neural scene representations for shading inference. ACM Trans. Graph. 39(4): 135 (2020) - [j29]Thomas Müller, Fabrice Rousselle, Alexander Keller, Jan Novák:
Neural control variates. ACM Trans. Graph. 39(6): 243:1-243:19 (2020) - [i8]Thomas Müller, Fabrice Rousselle, Jan Novák, Alexander Keller:
Neural Control Variates. CoRR abs/2006.01524 (2020) - [i7]Martin Doskár, Jan Zeman, Petr Krysl, Jan Novák:
Microstructure-informed reduced modes synthesized with Wang tiles and the Generalized Finite Element Method. CoRR abs/2010.02690 (2020)
2010 – 2019
- 2019
- [j28]Delio Vicini, David Adler, Jan Novák, Fabrice Rousselle, Brent Burley:
Denoising Deep Monte Carlo Renderings. Comput. Graph. Forum 38(1): 316-327 (2019) - [j27]Emma Metcalfe-Smith, Emma M. Meeus, Jan Novák, Hamid Dehghani, Andrew C. Peet, Niloufar Zarinabad Nooralipour:
Auto-Regressive Discrete Acquisition Points Transformation for Diffusion Weighted MRI Data. IEEE Trans. Biomed. Eng. 66(9): 2617-2628 (2019) - [j26]Thomas Müller, Brian McWilliams, Fabrice Rousselle, Markus Gross, Jan Novák:
Neural Importance Sampling. ACM Trans. Graph. 38(5): 145:1-145:19 (2019) - [c14]Jakub Spanhel, Roman Juránek, Adam Herout, Jan Novák, Pavel Havránek:
Analysis of Vehicle Trajectories for Determining Cross-Sectional Load Density Based on Computer Vision. ITSC 2019: 1001-1006 - [i6]Martin Doskár, Jan Zeman, Daniel Rypl, Jan Novák:
Level-set based design of Wang tiles for modelling complex microstructures. CoRR abs/1904.07657 (2019) - 2018
- [j25]Jan Novák, Iliyan Georgiev, Johannes Hanika, Wojciech Jarosz:
Monte Carlo Methods for Volumetric Light Transport Simulation. Comput. Graph. Forum 37(2): 551-576 (2018) - [j24]Benedikt Bitterli, Wenzel Jakob, Jan Novák, Wojciech Jarosz:
Reversible Jump Metropolis Light Transport Using Inverse Mappings. ACM Trans. Graph. 37(1): 1 (2018) - [j23]Thijs Vogels, Fabrice Rousselle, Brian McWilliams, Gerhard Röthlin, Alex Harvill, David Adler, Mark Meyer, Jan Novák:
Denoising with kernel prediction and asymmetric loss functions. ACM Trans. Graph. 37(4): 124 (2018) - [j22]Zdravko Velinov, Marios Papas, Derek Bradley, Paulo F. U. Gotardo, Parsa Mirdehghan, Steve Marschner, Jan Novák, Thabo Beeler:
Appearance capture and modeling of human teeth. ACM Trans. Graph. 37(6): 207 (2018) - [j21]Benedikt Bitterli, Srinath Ravichandran, Thomas Müller, Magnus Wrenninge, Jan Novák, Steve Marschner, Wojciech Jarosz:
A radiative transfer framework for non-exponential media. ACM Trans. Graph. 37(6): 225 (2018) - [c13]Jan Novák, Iliyan Georgiev, Johannes Hanika, Jaroslav Krivánek, Wojciech Jarosz:
Monte Carlo methods for physically based volume rendering. SIGGRAPH Courses 2018: 14:1 - [c12]Alexander Keller, Jaroslav Krivánek, Jan Novák, Anton Kaplanyan, Marco Salvi:
Machine learning and rendering. SIGGRAPH Courses 2018: 19:1-19:2 - [i5]Thomas Müller, Brian McWilliams, Fabrice Rousselle, Markus Gross, Jan Novák:
Neural Importance Sampling. CoRR abs/1808.03856 (2018) - 2017
- [j20]Alessia Marra, Maurizio Nitti, Marios Papas, Thomas Müller, Markus H. Gross, Wojciech Jarosz, Jan Novák:
2017 Cover Image: Mixing Bowl. Comput. Graph. Forum 36(1): 345-346 (2017) - [j19]Thomas Müller, Markus H. Gross, Jan Novák:
Practical Path Guiding for Efficient Light-Transport Simulation. Comput. Graph. Forum 36(4): 91-100 (2017) - [j18]Steve Bako, Thijs Vogels, Brian McWilliams, Mark Meyer, Jan Novák, Alex Harvill, Pradeep Sen, Tony DeRose, Fabrice Rousselle:
Kernel-predicting convolutional networks for denoising Monte Carlo renderings. ACM Trans. Graph. 36(4): 97:1-97:14 (2017) - [j17]Peter Kutz, Ralf Habel, Yining Karl Li, Jan Novák:
Spectral and decomposition tracking for rendering heterogeneous volumes. ACM Trans. Graph. 36(4): 111:1-111:16 (2017) - [j16]Simon Kallweit, Thomas Müller, Brian McWilliams, Markus H. Gross, Jan Novák:
Deep scattering: rendering atmospheric clouds with radiance-predicting neural networks. ACM Trans. Graph. 36(6): 231:1-231:11 (2017) - [i4]Benedikt Bitterli, Wenzel Jakob, Jan Novák, Wojciech Jarosz:
Reversible Jump Metropolis Light Transport using Inverse Mappings. CoRR abs/1704.06835 (2017) - [i3]Simon Kallweit, Thomas Müller, Brian McWilliams, Markus H. Gross, Jan Novák:
Deep Scattering: Rendering Atmospheric Clouds with Radiance-Predicting Neural Networks. CoRR abs/1709.05418 (2017) - 2016
- [j15]Ladislav Svoboda, Stanislav Sulc, Tomás Janda, Jan Vorel, Jan Novák:
μMech micromechanics library. Adv. Eng. Softw. 100: 148-160 (2016) - [j14]Benedikt Bitterli, Fabrice Rousselle, Bochang Moon, José Antonio Iglesias Guitián, David Adler, Kenny Mitchell, Wojciech Jarosz, Jan Novák:
Nonlinearly Weighted First-order Regression for Denoising Monte Carlo Renderings. Comput. Graph. Forum 35(4): 107-117 (2016) - [j13]Adrian Blumer, Jan Novák, Ralf Habel, Derek Nowrouzezahrai, Wojciech Jarosz:
Reduced Aggregate Scattering Operators for Path Tracing. Comput. Graph. Forum 35(7): 461-473 (2016) - [j12]Thomas Müller, Marios Papas, Markus H. Gross, Wojciech Jarosz, Jan Novák:
Efficient rendering of heterogeneous polydisperse granular media. ACM Trans. Graph. 35(6): 168:1-168:14 (2016) - [j11]Fabrice Rousselle, Wojciech Jarosz, Jan Novák:
Image-space control variates for rendering. ACM Trans. Graph. 35(6): 169:1-169:12 (2016) - [c11]David Koerner, Jan Novák, Peter Kutz, Ralf Habel, Wojciech Jarosz:
Subdivision Next-Event Estimation for Path-Traced Subsurface Scattering. EGSR (EI&I) 2016: 91-96 - 2015
- [j10]Benedikt Bitterli, Jan Novák, Wojciech Jarosz:
Portal-Masked Environment Map Sampling. Comput. Graph. Forum 34(4): 13-19 (2015) - [c10]Ahmed E. Fetit, Jan Novák, Daniel Rodríguez, Dorothee P. Auer, Chris A. Clark, Richard G. Grundy, Tim Jaspan, Andrew C. Peet, Theodoros N. Arvanitis:
3D Texture Analysis of Heterogeneous MRI Data for Diagnostic Classification of Childhood Brain Tumours. ICIMTH 2015: 19-22 - [c9]Ahmed E. Fetit, Omar Khan, Soroosh Afyouni, Niloufar Zarinabad Nooralipour, Jan Novák, Andrew C. Peet, Theodoros N. Arvanitis:
An Extensible Neuroimaging e-Repository for Clinical Trials of Paediatric Brain Tumours. ICIMTH 2015: 49-52 - 2014
- [b1]Jan Novák:
Efficient Many-Light Rendering of Scenes with Participating Media. Karlsruhe Institute of Technology, 2014 - [j9]Ladislav Svoboda, Jan Novák, Lukás Kurilla, Jan Zeman:
A framework for integrated design of algorithmic architectural forms. Adv. Eng. Softw. 72: 109-118 (2014) - [j8]Carsten Dachsbacher, Jaroslav Krivánek, Milos Hasan, Adam Arbree, Bruce Walter, Jan Novák:
Scalable Realistic Rendering with Many-Light Methods. Comput. Graph. Forum 33(1): 88-104 (2014) - [j7]Jan Novák, Andrew Selle, Wojciech Jarosz:
Residual ratio tracking for estimating attenuation in participating media. ACM Trans. Graph. 33(6): 179:1-179:11 (2014) - [c8]Ahmed E. Fetit, Jan Novák, Andrew C. Peet, Theodoros N. Arvanitis:
3D texture analysis of MR images to improve classification of paediatric brain tumours: a preliminary study. ICIMTH 2014: 213-216 - 2013
- [j6]Thorsten-Walther Schmidt, Jan Novák, Johannes Meng, Anton Kaplanyan, Tim Reiner, Derek Nowrouzezahrai, Carsten Dachsbacher:
Path-space manipulation of physically-based light transport. ACM Trans. Graph. 32(4): 129:1-129:11 (2013) - [c7]Carsten Dachsbacher, Jaroslav Krivánek, Milos Hasan, Adam Arbree, Bruce Walter, Jan Novák:
Scalable Realistic Rendering with Many-Light Methods. Eurographics (State of the Art Reports) 2013: 23-38 - [c6]Ahmed E. Fetit, Jan Novák, Daniel Rodríguez, Dorothee P. Auer, Chris A. Clark, Richard G. Grundy, Tim Jaspan, Andrew Peet, Theodoros N. Arvanitis:
MRI Texture Analysis in Paediatric Oncology: A Preliminary Study. ICIMTH 2013: 169-171 - [c5]Justus Ulbrich, Jan Novák, Hauke Rehfeld, Carsten Dachsbacher:
Progressive Visibility Caching for Fast Indirect Illumination. VMV 2013: 203-210 - 2012
- [j5]Jan Novák, Carsten Dachsbacher:
Rasterized Bounding Volume Hierarchies. Comput. Graph. Forum 31(2pt2): 403-412 (2012) - [j4]Jan Novák, Derek Nowrouzezahrai, Carsten Dachsbacher, Wojciech Jarosz:
Progressive Virtual Beam Lights. Comput. Graph. Forum 31(4): 1407-1413 (2012) - [j3]Thomas Engelhardt, Jan Novák, Thorsten-Walther Schmidt, Carsten Dachsbacher:
Approximate Bias Compensation for Rendering Scenes with Heterogeneous Participating Media. Comput. Graph. Forum 31(7): 2145-2154 (2012) - [j2]Jan Novák, Derek Nowrouzezahrai, Carsten Dachsbacher, Wojciech Jarosz:
Virtual ray lights for rendering scenes with participating media. ACM Trans. Graph. 31(4): 60:1-60:11 (2012) - [c4]Jirí Horák, Jan Ruzicka, Jan Novák, Jirí Ardielli, Daniela Szturcová:
Influence of the Number and Pattern of Geometrical Entities in the Image upon PNG Format Image Size. ACIIDS (2) 2012: 448-457 - [i2]Ladislav Svoboda, Jan Novák, Jan Zeman, Lukás Kurilla:
A simple framework for integrated design of complex architectural forms. CoRR abs/1203.2499 (2012) - 2011
- [c3]Jan Novák, Thomas Engelhardt, Carsten Dachsbacher:
Screen-space bias compensation for interactive high-quality global illumination with virtual point lights. SI3D 2011: 119-124 - [i1]Jan Novák, Lukasz Kaczmarczyk, P. Grassl, Jan Zeman, Chris J. Pearce:
A micromechanics-enhanced finite element formulation for modelling heterogeneous materials. CoRR abs/1103.5633 (2011) - 2010
- [j1]Jan Zeman, Jaroslav Vondrejc, Jan Novák, Ivo Marek:
Accelerating a FFT-based solver for numerical homogenization of periodic media by conjugate gradients. J. Comput. Phys. 229(21): 8065-8071 (2010) - [c2]Jan Novák, Vlastimil Havran, Carsten Dachsbacher:
Path Regeneration for Interactive Path Tracing. Eurographics (Short Papers) 2010: 61-64
2000 – 2009
- 2002
- [c1]Milos Zelezný, Petr Císar, Zdenek Krnoul, Jan Novák:
Design of an audio-visual speech corpus for the czech audio-visual speech synthesis. INTERSPEECH 2002: 1941-1944
Coauthor Index
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