Cong Wang
ABSTRACT
Rendering photorealistic and dynamically moving human heads is crucial for ensuring a pleasant and immersive experience in AR/VR and video conferencing applications. However, existing methods often struggle to model challenging facial regions (e.g., mouth interior, eyes, and beard), resulting in unrealistic and blurry results. In this paper, we propose Neural Point-based Volumetric Avatar (NPVA), a method that adopts the neural point representation as well as the neural volume rendering process and discards the predefined connectivity and hard correspondence imposed by mesh-based approaches. Specifically, the neural points are strategically constrained around the surface of the target expression via a high-resolution UV displacement map, achieving increased modeling capacity and more accurate control. We introduce three technical innovations to improve the rendering and training efficiency: a patch-wise depth-guided (shading point) sampling strategy, a lightweight radiance decoding process, and a Grid-Error-Patch (GEP) ray sampling strategy during training. By design, our NPVA is better equipped to handle topologically changing regions and thin structures while also ensuring accurate expression control when animating avatars. Experiments conducted on three subjects from the Multiface dataset demonstrate the effectiveness of our designs, outperforming previous state-of-the-art methods, especially in handling challenging facial regions.
- Kara-Ali Aliev, Artem Sevastopolsky, Maria Kolos, Dmitry Ulyanov, and Victor S. Lempitsky. 2020. Neural Point-Based Graphics. In Computer Vision - ECCV 2020 - 16th European Conference, Glasgow, UK, August 23-28, 2020, Proceedings, Part XXII(Lecture Notes in Computer Science, Vol. 12367), Andrea Vedaldi, Horst Bischof, Thomas Brox, and Jan-Michael Frahm (Eds.). Springer, UK, 696–712. https://doi.org/10.1007/978-3-030-58542-6_42Google Scholar
Digital Library
- Ziqian Bai, Feitong Tan, Zeng Huang, Kripasindhu Sarkar, Danhang Tang, Di Qiu, Abhimitra Meka, Ruofei Du, Mingsong Dou, Sergio Orts-Escolano, Rohit Pandey, Ping Tan, Thabo Beeler, Sean Fanello, and Yinda Zhang. 2023. Learning Personalized High Quality Volumetric Head Avatars from Monocular RGB Videos. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2023, Vancouver, BC, Canada, June 17-24, 2023. IEEE, Canada, 16890–16900. https://doi.org/10.1109/CVPR52729.2023.01620Google ScholarCross Ref
- Chen Cao, Tomas Simon, Jin Kyu Kim, Gabe Schwartz, Michael Zollhöfer, Shunsuke Saito, Stephen Lombardi, Shih-En Wei, Danielle Belko, Shoou-I Yu, Yaser Sheikh, and Jason M. Saragih. 2022. Authentic volumetric avatars from a phone scan. ACM Trans. Graph. 41, 4 (2022), 163:1–163:19.Google ScholarDigital Library
- Zhiqin Chen and Hao Zhang. 2019. Learning Implicit Fields for Generative Shape Modeling. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2019, Long Beach, CA, USA, June 16-20, 2019. Computer Vision Foundation / IEEE, USA, 5939–5948.Google Scholar
- Bernhard Egger, William A. P. Smith, Ayush Tewari, Stefanie Wuhrer, Michael Zollhöfer, Thabo Beeler, Florian Bernard, Timo Bolkart, Adam Kortylewski, Sami Romdhani, Christian Theobalt, Volker Blanz, and Thomas Vetter. 2020. 3D Morphable Face Models - Past, Present, and Future. ACM Trans. Graph. 39, 5 (2020), 157:1–157:38.Google ScholarDigital Library
- P. Ekman. 1980. The Face of Man: Expressions of Universal Emotions in a New Guinea Village. Garland STPM Press, virtual. https://books.google.com.hk/books?id=cMO0AAAAIAAJGoogle Scholar
- Guy Gafni, Justus Thies, Michael Zollhöfer, and Matthias Nießner. 2021. Dynamic Neural Radiance Fields for Monocular 4D Facial Avatar Reconstruction. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2021, virtual, June 19-25, 2021. Computer Vision Foundation / IEEE, virtual, 8649–8658.Google ScholarCross Ref
- Philip-William Grassal, Malte Prinzler, Titus Leistner, Carsten Rother, Matthias Nießner, and Justus Thies. 2022. Neural Head Avatars from Monocular RGB Videos. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2022, New Orleans, LA, USA, June 18-24, 2022. IEEE, USA, 18632–18643.Google ScholarCross Ref
- Zhenyi He, Ruofei Du, and Ken Perlin. 2020. CollaboVR: A Reconfigurable Framework for Creative Collaboration in Virtual Reality. In 2020 IEEE International Symposium on Mixed and Augmented Reality, ISMAR 2020, Recife/Porto de Galinhas, Brazil, November 9-13, 2020. IEEE, Brazil, 542–554. https://doi.org/10.1109/ISMAR50242.2020.00082Google ScholarCross Ref
- Yue Jiang, Dantong Ji, Zhizhong Han, and Matthias Zwicker. 2020. SDFDiff: Differentiable Rendering of Signed Distance Fields for 3D Shape Optimization. In 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2020, Seattle, WA, USA, June 13-19, 2020. Computer Vision Foundation / IEEE, USA, 1248–1258.Google ScholarCross Ref
- Petr Kellnhofer, Lars Jebe, Andrew Jones, Ryan Spicer, Kari Pulli, and Gordon Wetzstein. 2021. Neural Lumigraph Rendering. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2021, virtual, June 19-25, 2021. Computer Vision Foundation / IEEE, virtual, 4287–4297.Google Scholar
- Taras Khakhulin, Vanessa Sklyarova, Victor Lempitsky, and Egor Zakharov. 2022. Realistic One-Shot Mesh-Based Head Avatars. In Computer Vision - ECCV 2022 - 17th European Conference, Tel Aviv, Israel, October 23-27, 2022, Proceedings, Part II(Lecture Notes in Computer Science, Vol. 13662), Shai Avidan, Gabriel J. Brostow, Moustapha Cissé, Giovanni Maria Farinella, and Tal Hassner (Eds.). Springer, Israel, 345–362.Google ScholarDigital Library
- Diederik P. Kingma and Jimmy Ba. 2015. Adam: A Method for Stochastic Optimization. In 3rd International Conference on Learning Representations, ICLR 2015, May 7-9, 2015, Conference Track Proceedings, Yoshua Bengio and Yann LeCun (Eds.). Computer Vision Foundation / IEEE Computer Society, San Diego, CA, USA, .Google Scholar
- Samuli Laine, Janne Hellsten, Tero Karras, Yeongho Seol, Jaakko Lehtinen, and Timo Aila. 2020. Modular primitives for high-performance differentiable rendering. ACM Trans. Graph. 39, 6 (2020), 194:1–194:14.Google ScholarDigital Library
- Christoph Lassner and Michael Zollhöfer. 2021. Pulsar: Efficient Sphere-Based Neural Rendering. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2021, virtual, June 19-25, 2021. Computer Vision Foundation / IEEE, ., 1440–1449.Google Scholar
- Tianye Li, Timo Bolkart, Michael J. Black, Hao Li, and Javier Romero. 2017. Learning a model of facial shape and expression from 4D scans. ACM Trans. Graph. 36, 6 (2017), 194:1–194:17.Google ScholarDigital Library
- Haotong Lin, Sida Peng, Zhen Xu, Yunzhi Yan, Qing Shuai, Hujun Bao, and Xiaowei Zhou. 2022. Efficient Neural Radiance Fields for Interactive Free-viewpoint Video. In SIGGRAPH Asia 2022 Conference Papers, SA 2022, December 6-9, 2022, Soon Ki Jung, Jehee Lee, and Adam W. Bargteil (Eds.). ACM, Daegu, Republic of Korea, 39:1–39:9.Google Scholar
- Shichen Liu, Weikai Chen, Tianye Li, and Hao Li. 2019. Soft Rasterizer: A Differentiable Renderer for Image-Based 3D Reasoning. In 2019 IEEE/CVF International Conference on Computer Vision, ICCV 2019, October 27 - November 2, 2019. IEEE, Seoul, Korea (South), 7707–7716.Google ScholarCross Ref
- Shaohui Liu, Yinda Zhang, Songyou Peng, Boxin Shi, Marc Pollefeys, and Zhaopeng Cui. 2020. DIST: Rendering Deep Implicit Signed Distance Function With Differentiable Sphere Tracing. In 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2020, June 13-19, 2020. Computer Vision Foundation / IEEE, Seattle, WA, USA, 2016–2025.Google Scholar
- Stephen Lombardi, Jason M. Saragih, Tomas Simon, and Yaser Sheikh. 2018. Deep appearance models for face rendering. ACM Trans. Graph. 37, 4 (2018), 68.Google ScholarDigital Library
- Stephen Lombardi, Tomas Simon, Jason M. Saragih, Gabriel Schwartz, Andreas M. Lehrmann, and Yaser Sheikh. 2019. Neural volumes: learning dynamic renderable volumes from images. ACM Trans. Graph. 38, 4 (2019), 65:1–65:14.Google ScholarDigital Library
- Stephen Lombardi, Tomas Simon, Gabriel Schwartz, Michael Zollhöfer, Yaser Sheikh, and Jason M. Saragih. 2021. Mixture of volumetric primitives for efficient neural rendering. ACM Trans. Graph. 40, 4 (2021), 59:1–59:13.Google ScholarDigital Library
- Huiwen Luo, Koki Nagano, Han-Wei Kung, Qingguo Xu, Zejian Wang, Lingyu Wei, Liwen Hu, and Hao Li. 2021. Normalized Avatar Synthesis Using StyleGAN and Perceptual Refinement. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2021, virtual, June 19-25, 2021. Computer Vision Foundation / IEEE, ., 11662–11672.Google Scholar
- Shugao Ma, Tomas Simon, Jason M. Saragih, Dawei Wang, Yuecheng Li, Fernando De la Torre, and Yaser Sheikh. 2021. Pixel Codec Avatars. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2021, virtual, June 19-25, 2021. Computer Vision Foundation / IEEE, ., 64–73.Google Scholar
- Zhiyuan Ma, Xiangyu Zhu, Guojun Qi, Zhen Lei, and Lei Zhang. 2023. OTAvatar: One-Shot Talking Face Avatar with Controllable Tri-Plane Rendering. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2023, Vancouver, BC, Canada, June 17-24, 2023. IEEE, ., 16901–16910.Google Scholar
- Julien N. P. Martel, David B. Lindell, Connor Z. Lin, Eric R. Chan, Marco Monteiro, and Gordon Wetzstein. 2021. Acorn: adaptive coordinate networks for neural scene representation. ACM Trans. Graph. 40, 4 (2021), 58:1–58:13.Google ScholarDigital Library
- Sachit Menon, Alexandru Damian, Shijia Hu, Nikhil Ravi, and Cynthia Rudin. 2020. PULSE: Self-Supervised Photo Upsampling via Latent Space Exploration of Generative Models. In 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2020, Seattle, WA, USA, June 13-19, 2020. Computer Vision Foundation / IEEE, ., 2434–2442.Google ScholarCross Ref
- Lars M. Mescheder, Michael Oechsle, Michael Niemeyer, Sebastian Nowozin, and Andreas Geiger. 2019. Occupancy Networks: Learning 3D Reconstruction in Function Space. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2019, Long Beach, CA, USA, June 16-20, 2019. Computer Vision Foundation / IEEE, ., 4460–4470.Google ScholarCross Ref
- Marko Mihajlovic, Aayush Bansal, Michael Zollhöfer, Siyu Tang, and Shunsuke Saito. 2022. KeypointNeRF: Generalizing Image-Based Volumetric Avatars Using Relative Spatial Encoding of Keypoints. In Computer Vision - ECCV 2022 - 17th European Conference, Tel Aviv, Israel, October 23-27, 2022, Proceedings, Part XV(Lecture Notes in Computer Science, Vol. 13675), Shai Avidan, Gabriel J. Brostow, Moustapha Cissé, Giovanni Maria Farinella, and Tal Hassner (Eds.). Springer,., 179–197.Google ScholarDigital Library
- Ben Mildenhall, Pratul P. Srinivasan, Matthew Tancik, Jonathan T. Barron, Ravi Ramamoorthi, and Ren Ng. 2020. NeRF: Representing Scenes as Neural Radiance Fields for View Synthesis. In Computer Vision - ECCV 2020 - 16th European Conference, Glasgow, UK, August 23-28, 2020, Proceedings, Part I(Lecture Notes in Computer Science, Vol. 12346), Andrea Vedaldi, Horst Bischof, Thomas Brox, and Jan-Michael Frahm (Eds.). Springer,., 405–421.Google ScholarDigital Library
- Thomas Müller, Alex Evans, Christoph Schied, and Alexander Keller. 2022. Instant neural graphics primitives with a multiresolution hash encoding. ACM Trans. Graph. 41, 4 (2022), 102:1–102:15.Google ScholarDigital Library
- Sergio Orts-Escolano, Christoph Rhemann, Sean Ryan Fanello, Wayne Chang, Adarsh Kowdle, Yury Degtyarev, David Kim, Philip L. Davidson, Sameh Khamis, Mingsong Dou, Vladimir Tankovich, Charles T. Loop, Qin Cai, Philip A. Chou, Sarah Mennicken, Julien P. C. Valentin, Vivek Pradeep, Shenlong Wang, Sing Bing Kang, Pushmeet Kohli, Yuliya Lutchyn, Cem Keskin, and Shahram Izadi. 2016. Holoportation: Virtual 3D Teleportation in Real-time. In Proceedings of the 29th Annual Symposium on User Interface Software and Technology, UIST 2016, Tokyo, Japan, October 16-19, 2016, Jun Rekimoto, Takeo Igarashi, Jacob O. Wobbrock, and Daniel Avrahami (Eds.). ACM, ., 741–754.Google ScholarDigital Library
- Jin-Si R Over, Andrew C Ritchie, Christine J Kranenburg, Jenna A Brown, Daniel D Buscombe, Tom Noble, Christopher R Sherwood, Jonathan A Warrick, and Phillipe A Wernette. 2021. Processing coastal imagery with Agisoft Metashape Professional Edition, version 1.6—Structure from motion workflow documentation. Technical Report. US Geological Survey.Google Scholar
- Jeong Joon Park, Peter R. Florence, Julian Straub, Richard A. Newcombe, and Steven Lovegrove. 2019. DeepSDF: Learning Continuous Signed Distance Functions for Shape Representation. In IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2019, Long Beach, CA, USA, June 16-20, 2019. Computer Vision Foundation / IEEE, ., 165–174.Google Scholar
- Amit Raj, Michael Zollhöfer, Tomas Simon, Jason M. Saragih, Shunsuke Saito, James Hays, and Stephen Lombardi. 2021. PVA: Pixel-aligned Volumetric Avatars. CoRR abs/2101.02697 (2021), .Google Scholar
- Ruslan Rakhimov, Andrei-Timotei Ardelean, Victor Lempitsky, and Evgeny Burnaev. 2022. NPBG++: Accelerating Neural Point-Based Graphics. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2022, New Orleans, LA, USA, June 18-24, 2022. IEEE, ., 15948–15958.Google ScholarCross Ref
- Darius Rückert, Linus Franke, and Marc Stamminger. 2022. ADOP: approximate differentiable one-pixel point rendering. ACM Trans. Graph. 41, 4 (2022), 99:1–99:14.Google ScholarDigital Library
- Katja Schwarz, Yiyi Liao, Michael Niemeyer, and Andreas Geiger. 2020. GRAF: Generative Radiance Fields for 3D-Aware Image Synthesis. In Advances in Neural Information Processing Systems 33: Annual Conference on Neural Information Processing Systems 2020, NeurIPS 2020, December 6-12, 2020, virtual, Hugo Larochelle, Marc’Aurelio Ranzato, Raia Hadsell, Maria-Florina Balcan, and Hsuan-Tien Lin (Eds.). ., ., .Google Scholar
- Vincent Sitzmann, Michael Zollhöfer, and Gordon Wetzstein. 2019. Scene Representation Networks: Continuous 3D-Structure-Aware Neural Scene Representations. In Advances in Neural Information Processing Systems 32: Annual Conference on Neural Information Processing Systems 2019, NeurIPS 2019, December 8-14, 2019, Vancouver, BC, Canada, Hanna M. Wallach, Hugo Larochelle, Alina Beygelzimer, Florence d’Alché-Buc, Emily B. Fox, and Roman Garnett (Eds.). ., ., 1119–1130.Google Scholar
- Edgar Sucar, Shikun Liu, Joseph Ortiz, and Andrew J. Davison. 2021. iMAP: Implicit Mapping and Positioning in Real-Time. In 2021 IEEE/CVF International Conference on Computer Vision, ICCV 2021, Montreal, QC, Canada, October 10-17, 2021. IEEE, ., 6209–6218.Google ScholarCross Ref
- Junshu Tang, Bo Zhang, Binxin Yang, Ting Zhang, Dong Chen, Lizhuang Ma, and Fang Wen. 2022. Explicitly controllable 3d-aware portrait generation. arXiv preprint arXiv:2209.05434 ., . (2022), .Google Scholar
- Justus Thies, Michael Zollhöfer, and Matthias Nießner. 2019. Deferred neural rendering: image synthesis using neural textures. ACM Trans. Graph. 38, 4 (2019), 66:1–66:12.Google ScholarDigital Library
- Edgar Tretschk, Ayush Tewari, Vladislav Golyanik, Michael Zollhöfer, Carsten Stoll, and Christian Theobalt. 2020. PatchNets: Patch-Based Generalizable Deep Implicit 3D Shape Representations. In Computer Vision - ECCV 2020 - 16th European Conference, Glasgow, UK, August 23-28, 2020, Proceedings, Part XVI(Lecture Notes in Computer Science, Vol. 12361), Andrea Vedaldi, Horst Bischof, Thomas Brox, and Jan-Michael Frahm (Eds.). Springer,., 293–309.Google ScholarDigital Library
- Zach Waggoner. 2009. My avatar, my self: Identity in video role-playing games. McFarland, .Google Scholar
- Peng Wang, Xiaoliang Bai, Mark Billinghurst, Shusheng Zhang, Xiangyu Zhang, Shuxia Wang, Weiping He, Yuxiang Yan, and Hongyu Ji. 2021a. AR/MR Remote Collaboration on Physical Tasks: A Review. Robotics Comput. Integr. Manuf. 72 (2021), 102071.Google ScholarDigital Library
- Peng Wang, Lingjie Liu, Yuan Liu, Christian Theobalt, Taku Komura, and Wenping Wang. 2021b. NeuS: Learning Neural Implicit Surfaces by Volume Rendering for Multi-view Reconstruction. In Advances in Neural Information Processing Systems 34: Annual Conference on Neural Information Processing Systems 2021, NeurIPS 2021, December 6-14, 2021, virtual, Marc’Aurelio Ranzato, Alina Beygelzimer, Yann N. Dauphin, Percy Liang, and Jennifer Wortman Vaughan (Eds.). ., ., 27171–27183.Google Scholar
- Sijing Wu, Yichao Yan, Yunhao Li, Yuhao Cheng, Wenhan Zhu, Ke Gao, Xiaobo Li, and Guangtao Zhai. 2023b. GANHead: Towards Generative Animatable Neural Head Avatars. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2023, Vancouver, BC, Canada, June 17-24, 2023. IEEE, ., 437–447.Google Scholar
- Xiuzhe Wu, Pengfei Hu, Yang Wu, Xiaoyang Lyu, Yan-Pei Cao, Ying Shan, Wenming Yang, Zhongqian Sun, and Xiaojuan Qi. 2023a. Speech2Lip: High-fidelity Speech to Lip Generation by Learning from a Short Video. arXiv preprint arXiv:2309.04814 ., . (2023), .Google Scholar
- Cheng-hsin Wuu, Ningyuan Zheng, Scott Ardisson, Rohan Bali, Danielle Belko, Eric Brockmeyer, Lucas Evans, Timothy Godisart, Hyowon Ha, Alexander Hypes, Taylor Koska, Steven Krenn, Stephen Lombardi, Xiaomin Luo, Kevyn McPhail, Laura Millerschoen, Michal Perdoch, Mark Pitts, Alexander Richard, Jason M. Saragih, Junko Saragih, Takaaki Shiratori, Tomas Simon, Matt Stewart, Autumn Trimble, Xinshuo Weng, David Whitewolf, Chenglei Wu, Shoou-I Yu, and Yaser Sheikh. 2022. Multiface: A Dataset for Neural Face Rendering. CoRR abs/2207.11243 (2022), .Google Scholar
- Qiangeng Xu, Zexiang Xu, Julien Philip, Sai Bi, Zhixin Shu, Kalyan Sunkavalli, and Ulrich Neumann. 2022. Point-NeRF: Point-based Neural Radiance Fields. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2022, New Orleans, LA, USA, June 18-24, 2022. IEEE, ., 5428–5438.Google Scholar
- Shunyu Yao, Ruizhe Zhong, Yichao Yan, Guangtao Zhai, and Xiaokang Yang. 2022. DFA-NeRF: Personalized Talking Head Generation via Disentangled Face Attributes Neural Rendering. CoRR abs/2201.00791 (2022), .Google Scholar
- Wangbo Yu, Yanbo Fan, Yong Zhang, Xuan Wang, Fei Yin, Yunpeng Bai, Yan-Pei Cao, Ying Shan, Yang Wu, Zhongqian Sun, 2023. NOFA: NeRF-based One-shot Facial Avatar Reconstruction. In ACM SIGGRAPH 2023 Conference Proceedings. ., ., 1–12.Google Scholar
- Richard Zhang, Phillip Isola, Alexei A. Efros, Eli Shechtman, and Oliver Wang. 2018. The Unreasonable Effectiveness of Deep Features as a Perceptual Metric. In 2018 IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2018, Salt Lake City, UT, USA, June 18-22, 2018. Computer Vision Foundation / IEEE Computer Society, ., 586–595.Google ScholarCross Ref
- Mingwu Zheng, Haiyu Zhang, Hongyu Yang, and Di Huang. 2023b. NeuFace: Realistic 3D Neural Face Rendering from Multi-View Images. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2023, Vancouver, BC, Canada, June 17-24, 2023. IEEE, ., 16868–16877.Google ScholarCross Ref
- Yufeng Zheng, Wang Yifan, Gordon Wetzstein, Michael J. Black, and Otmar Hilliges. 2023a. PointAvatar: Deformable Point-Based Head Avatars from Videos. In IEEE/CVF Conference on Computer Vision and Pattern Recognition, CVPR 2023, Vancouver, BC, Canada, June 17-24, 2023. IEEE, ., 21057–21067.Google ScholarCross Ref
- Runsong Zhu, Di Kang, Ka-Hei Hui, Yue Qian, Xuefei Zhe, Zhen Dong, Linchao Bao, and Chi-Wing Fu. 2022. Semi-signed neural fitting for surface reconstruction from unoriented point clouds. arXiv preprint arXiv:2206.06715 . (2022), .Google Scholar
- D. Zimny, Tomasz Trzcinski, and Przemyslaw Spurek. 2022. Points2NeRF: Generating Neural Radiance Fields from 3D point cloud. CoRR abs/2206.01290 (2022), .Google Scholar
- Michael Zollhöfer, Justus Thies, Pablo Garrido, Derek Bradley, Thabo Beeler, Patrick Pérez, Marc Stamminger, Matthias Nießner, and Christian Theobalt. 2018. State of the Art on Monocular 3D Face Reconstruction, Tracking, and Applications. Comput. Graph. Forum 37, 2 (2018), 523–550.Google ScholarCross Ref
Index Terms
- Neural Point-based Volumetric Avatar: Surface-guided Neural Points for Efficient and Photorealistic Volumetric Head Avatar
Recommendations
Volumetric shadows using splatting
VIS '02: Proceedings of the conference on Visualization '02This paper describes an efficient algorithm to model the light attenuation due to a participating media with low albedo. The light attenuation is modeled using splatting volume renderer for both the viewer and the light source. During the rendering, a ...
A Hardware Acceleration Method for Volumetric Ray Tracing
VIS '95: Proceedings of the 6th conference on Visualization '95In this paper we present an acceleration method for volumetric ray tracing which utilizes standard graphics hardware without compromising image accuracy. The graphics hardware is employed to identify those segments of each ray that could possibly ...
Hardware-accelerated parallel non-photorealistic volume rendering
NPAR '02: Proceedings of the 2nd international symposium on Non-photorealistic animation and renderingNon-photorealistic rendering can be used to illustrate subtle spatial relationships that might not be visible with more realistic rendering techniques. We present a parallel hardware-accelerated rendering technique, making extensive use of multi-...
Comments