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Ronald Fedkiw
Ron Fedkiw
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- affiliation: Stanford University, USA
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2020 – today
- 2024
- [j65]Yizhou Chen
, Yushan Han, Jingyu Chen, Shiqian Ma, Ronald Fedkiw, Joseph Teran:
Primal residual reduction with extended position based dynamics and hyperelasticity. Comput. Graph. 119: 103902 (2024) - [j64]Steven Gagniere, Yushan Han, Yizhou Chen, David Hyde, Alan Marquez-Razon
A Robust Grid-Based Meshing Algorithm for Embedding Self-Intersecting Surfaces. Comput. Graph. Forum 43(1) (2024) - [j63]Daniel Johnson, Ronald Fedkiw:
Addressing discontinuous root-finding for subsequent differentiability in machine learning, inverse problems, and control. J. Comput. Phys. 497: 112624 (2024) - [j62]Matthew Cong
Local Geometric Indexing of High Resolution Data for Facial Reconstruction From Sparse Markers. IEEE Trans. Vis. Comput. Graph. 30(8): 5289-5298 (2024) - [i18]Yilin Zhu, Dalton Omens, Haodi He, Ron Fedkiw:
Democratizing the Creation of Animatable Facial Avatars. CoRR abs/2401.16534 (2024) - [i17]Yongxu Jin, Dalton Omens, Zhenglin Geng, Joseph Teran, Abishek Kumar, Kenji Tashiro, Ronald Fedkiw:
A Neural-Network-Based Approach for Loose-Fitting Clothing. CoRR abs/2404.16896 (2024) - 2023
- [c47]Yizhou Chen
Primal Extended Position Based Dynamics for Hyperelasticity. MIG 2023: 21:1-21:10 - [i16]Daniel Johnson, Trevor Maxfield, Yongxu Jin, Ronald Fedkiw:
Software-based Automatic Differentiation is Flawed. CoRR abs/2305.03863 (2023) - [i15]Daniel Johnson, Ronald Fedkiw:
Addressing Discontinuous Root-Finding for Subsequent Differentiability in Machine Learning, Inverse Problems, and Control. CoRR abs/2306.12413 (2023) - [i14]Jane Wu, Diego Thomas, Ronald Fedkiw:
Weakly-Supervised 3D Reconstruction of Clothed Humans via Normal Maps. CoRR abs/2311.16042 (2023) - 2022
- [c46]Yongxu Jin
Analytically Integratable Zero-restlength Springs for Capturing Dynamic Modes unrepresented by Quasistatic Neural Networks. SIGGRAPH (Conference Paper Track) 2022: 37:1-37:9 - [i13]Steven W. Gagniere, Yushan Han, Yizhou Chen, David A. B. Hyde, Alan Marquez-Razon, Joseph Teran, Ronald Fedkiw:
A Robust Grid-Based Meshing Algorithm for Embedding Self-Intersecting Surfaces. CoRR abs/2201.06256 (2022) - [i12]Yongxu Jin, Yushan Han, Zhenglin Geng, Joseph Teran, Ronald Fedkiw:
Analytically Integratable Zero-restlength Springs for Capturing Dynamic Modes unrepresented by Quasistatic Neural Networks. CoRR abs/2201.10122 (2022) - [i11]Winnie Lin, Yilin Zhu, Demi Guo, Ron Fedkiw:
Leveraging Deepfakes to Close the Domain Gap between Real and Synthetic Images in Facial Capture Pipelines. CoRR abs/2204.10746 (2022) - 2021
- [j61]David A. B. Hyde
On obtaining sparse semantic solutions for inverse problems, control, and neural network training. J. Comput. Phys. 443: 110498 (2021) - [j60]Ed Quigley, Winnie Lin, Yilin Zhu, Ronald Fedkiw:
Three Dimensional Reconstruction of Botanical Trees with Simulatable Geometry. Proc. ACM Comput. Graph. Interact. Tech. 4(3): 37:1-37:16 (2021) - [j59]Jane Wu, Yongxu Jin
Recovering Geometric Information with Learned Texture Perturbations. Proc. ACM Comput. Graph. Interact. Tech. 4(3): 38:1-38:18 (2021) - 2020
- [j58]Ning Jin
A Pixel-Based Framework for Data-Driven Clothing. Comput. Graph. Forum 39(8): 135-144 (2020) - [j57]Zhenglin Geng, Daniel Johnson, Ronald Fedkiw:
Coercing machine learning to output physically accurate results. J. Comput. Phys. 406: 109099 (2020) - [i10]Jane Wu, Yongxu Jin, Zhenglin Geng, Hui Zhou, Ronald Fedkiw:
Recovering Geometric Information with Learned Texture Perturbations. CoRR abs/2001.07253 (2020) - [i9]Jane Wu, Zhenglin Geng, Hui Zhou, Ronald Fedkiw:
Skinning a Parameterization of Three-Dimensional Space for Neural Network Cloth. CoRR abs/2006.04874 (2020)
2010 – 2019
- 2019
- [j56]Frédéric Gibou, David Hyde
Sharp interface approaches and deep learning techniques for multiphase flows. J. Comput. Phys. 380: 442-463 (2019) - [j55]David A. B. Hyde
A unified approach to monolithic solid-fluid coupling of sub-grid and more resolved solids. J. Comput. Phys. 390: 490-526 (2019) - [j54]Minjae Lee
A Skinned Tetrahedral Mesh for Hair Animation and Hair-Water Interaction. IEEE Trans. Vis. Comput. Graph. 25(3): 1449-1459 (2019) - [c45]Michael Bao, Matthew Cong, Stéphane Grabli, Ronald Fedkiw:
High-Quality Face Capture Using Anatomical Muscles. CVPR 2019: 10802-10811 - [c44]Minjae Lee, David Hyde
A robust volume conserving method for character-water interaction. Symposium on Computer Animation 2019: 3:1-3:12 - [c43]Matthew Cong, Ronald Fedkiw:
Muscle-based facial retargeting with anatomical constraints. SIGGRAPH Talks 2019: 5:1-5:2 - [i8]Minjae Lee, David Hyde, Kevin Li, Ronald Fedkiw:
A Robust Volume Conserving Method for Character-Water Interaction. CoRR abs/1902.00801 (2019) - [i7]Matthew Cong, Lana Lan, Ronald Fedkiw:
Local Geometric Indexing of High Resolution Data for Facial Reconstruction from Sparse Markers. CoRR abs/1903.00119 (2019) - [i6]Zhenglin Geng, Dan Johnson
Coercing Machine Learning to Output Physically Accurate Results. CoRR abs/1910.09671 (2019) - 2018
- [j53]Frédéric Gibou, Ronald Fedkiw, Stanley J. Osher:
A review of level-set methods and some recent applications. J. Comput. Phys. 353: 82-109 (2018) - [j52]Ed Quigley
Real-Time Interactive Tree Animation. IEEE Trans. Vis. Comput. Graph. 24(5): 1717-1727 (2018) - [i5]Ning Jin, Yilin Zhu, Zhenglin Geng, Ronald Fedkiw:
A Pixel-Based Framework for Data-Driven Clothing. CoRR abs/1812.01677 (2018) - [i4]Michael Bao, Matthew Cong, Stéphane Grabli, Ronald Fedkiw:
High-Quality Face Capture Using Anatomical Muscles. CoRR abs/1812.02836 (2018) - [i3]Michael Bao, Xinru Hua, Ronald Fedkiw:
Improved Search Strategies for Determining Facial Expression. CoRR abs/1812.02897 (2018) - [i2]Michael Bao, Jane Wu, Xinwei Yao, Ronald Fedkiw:
Deep Energies for Estimating Three-Dimensional Facial Pose and Expression. CoRR abs/1812.02899 (2018) - [i1]Ed Quigley, Winnie Lin, Yilin Zhu, Ronald Fedkiw:
Three Dimensional Reconstruction of Botanical Trees with Simulatable Geometry. CoRR abs/1812.08849 (2018) - 2017
- [c42]Lana Lan, Matthew Cong, Ronald Fedkiw:
Lessons from the evolution of an anatomical facial muscle model. DigiPro 2017: 11:1-11:3 - [c41]Ning Jin, Wenlong Lu, Zhenglin Geng, Ronald Fedkiw:
Inequality cloth. Symposium on Computer Animation 2017: 16:1-16:10 - [c40]Matthew Cong, Lana Lan, Ronald Fedkiw:
Muscle simulation for facial animation in Kong: Skull Island. SIGGRAPH Talks 2017: 21:1-21:2 - 2016
- [j51]Linhai Qiu
An adaptive discretization of compressible flow using a multitude of moving Cartesian grids. J. Comput. Phys. 305: 75-110 (2016) - [j50]Saket Patkar, Mridul Aanjaneya, Wenlong Lu, Michael Lentine, Ronald Fedkiw:
Towards positivity preservation for monolithic two-way solid-fluid coupling. J. Comput. Phys. 312: 82-114 (2016) - [c39]Wenlong Lu, Ning Jin, Ronald Fedkiw:
Two-way coupling of fluids to reduced deformable bodies. Symposium on Computer Animation 2016: 67-76 - [c38]Matthew Cong, Kiran S. Bhat, Ronald Fedkiw:
Art-directed muscle simulation for high-end facial animation. Symposium on Computer Animation 2016: 119-127 - [c37]Stefan Feess, Kathrin Kurfiss, Ronald Fedkiw, Dominik L. Michels:
Accurate simulation of wound healing and skin deformation. Symposium on Computer Animation 2016: 129-137 - 2015
- [j49]Zheng Wen, Bo Zhu, ByungMoon Kim, Ronald Fedkiw:
A new incompressibility discretization for a hybrid particle MAC grid representation with surface tension. J. Comput. Phys. 280: 96-142 (2015) - [j48]Linhai Qiu
On thin gaps between rigid bodies two-way coupled to incompressible flow. J. Comput. Phys. 292: 1-29 (2015) - [j47]Bo Zhu, Minjae Lee, Ed Quigley, Ronald Fedkiw:
Codimensional non-Newtonian fluids. ACM Trans. Graph. 34(4): 115:1-115:9 (2015) - [c36]Saket Patkar, Ning Jin, Ronald Fedkiw:
A new sharp-crease bending element for folding and wrinkling surfaces and volumes. Symposium on Computer Animation 2015: 7-15 - [c35]Rahul Sheth, Wenlong Lu, Yue Yu, Ronald Fedkiw:
Fully momentum-conserving reduced deformable bodies with collision, contact, articulation, and skinning. Symposium on Computer Animation 2015: 45-54 - [c34]Matthew Cong, Michael Bao, Jane L. E
Fully automatic generation of anatomical face simulation models. Symposium on Computer Animation 2015: 175-183 - 2014
- [j46]Bo Zhu, Ed Quigley, Matthew Cong, Justin Solomon, Ronald Fedkiw:
Codimensional surface tension flow on simplicial complexes. ACM Trans. Graph. 33(4): 111:1-111:11 (2014) - [c33]Saket Patkar, Mridul Aanjaneya, Aric Bartle, Minjae Lee, Ronald Fedkiw:
Efficient Denting and Bending of Rigid Bodies. Symposium on Computer Animation 2014: 87-96 - 2013
- [j45]Jón Tómas Grétarsson, Ron Fedkiw:
Fully conservative leak-proof treatment of thin solid structures immersed in compressible fluids. J. Comput. Phys. 245: 160-204 (2013) - [j44]Mridul Aanjaneya, Saket Patkar, Ronald Fedkiw:
A monolithic mass tracking formulation for bubbles in incompressible flow. J. Comput. Phys. 247: 17-61 (2013) - [j43]R. Elliot English, Linhai Qiu, Yue Yu, Ronald Fedkiw:
An adaptive discretization of incompressible flow using a multitude of moving Cartesian grids. J. Comput. Phys. 254: 107-154 (2013) - [j42]Frédéric Gibou, Chohong Min, Ronald Fedkiw:
High Resolution Sharp Computational Methods for Elliptic and Parabolic Problems in Complex Geometries. J. Sci. Comput. 54(2-3): 369-413 (2013) - [j41]Bo Zhu, Wenlong Lu, Matthew Cong, ByungMoon Kim, Ronald Fedkiw:
A new grid structure for domain extension. ACM Trans. Graph. 32(4): 63:1-63:12 (2013) - [j40]Jonathan Su, Rahul Sheth, Ronald Fedkiw:
Energy Conservation for the Simulation of Deformable Bodies. IEEE Trans. Vis. Comput. Graph. 19(2): 189-200 (2013) - [j39]R. Elliot English, Michael Lentine, Ron Fedkiw:
Interpenetration Free Simulation of Thin Shell Rigid Bodies. IEEE Trans. Vis. Comput. Graph. 19(6): 991-1004 (2013) - [c32]R. Elliot English, Linhai Qiu, Yue Yu, Ronald Fedkiw:
Chimera grids for water simulation. Symposium on Computer Animation 2013: 85-94 - [c31]Saket Patkar, Mridul Aanjaneya, Dmitriy Karpman, Ronald Fedkiw:
A hybrid Lagrangian-Eulerian formulation for bubble generation and dynamics. Symposium on Computer Animation 2013: 105-114 - 2012
- [j38]Craig A. Schroeder
Semi-implicit surface tension formulation with a Lagrangian surface mesh on an Eulerian simulation grid. J. Comput. Phys. 231(4): 2092-2115 (2012) - [c30]Michael Lentine, Matthew Cong, Saket Patkar, Ronald Fedkiw:
Simulating Free Surface Flow with Very Large Time Steps. Symposium on Computer Animation 2012: 107-116 - 2011
- [j37]Craig A. Schroeder, Nipun Kwatra, Zheng Wen, Ronald Fedkiw:
Asynchronous Evolution for Fully-Implicit and Semi-Implicit Time Integration. Comput. Graph. Forum 30(7): 1983-1992 (2011) - [j36]Avi Robinson-Mosher, Craig A. Schroeder
A symmetric positive definite formulation for monolithic fluid structure interaction. J. Comput. Phys. 230(4): 1547-1566 (2011) - [j35]Michael Lentine, Jón Tómas Grétarsson, Ronald Fedkiw:
An unconditionally stable fully conservative semi-Lagrangian method. J. Comput. Phys. 230(8): 2857-2879 (2011) - [j34]Jón Tómas Grétarsson, Nipun Kwatra, Ronald Fedkiw:
Numerically stable fluid-structure interactions between compressible flow and solid structures. J. Comput. Phys. 230(8): 3062-3084 (2011) - [j33]Michael Lentine, Jon Gretarsson, Craig A. Schroeder, Avi Robinson-Mosher, Ronald Fedkiw:
Creature Control in a Fluid Environment. IEEE Trans. Vis. Comput. Graph. 17(5): 682-693 (2011) - [c29]Michael Lentine, Mridul Aanjaneya, Ronald Fedkiw:
Mass and Momentum Conservation for Fluid Simulation. Symposium on Computer Animation 2011: 91-100 - [c28]Pradeep Dubey, Pat Hanrahan, Ronald Fedkiw, Michael Lentine, Craig A. Schroeder:
PhysBAM: physically based simulation. SIGGRAPH Courses 2011: 10:1-10:22 - 2010
- [j32]Michael Lentine, Zheng Wen, Ronald Fedkiw:
A novel algorithm for incompressible flow using only a coarse grid projection. ACM Trans. Graph. 29(4): 114:1-114:9 (2010) - [c27]Nipun Kwatra, Jon Gretarsson, Ronald Fedkiw:
Practical Animation of Compressible Flow for ShockWaves and Related Phenomena. Symposium on Computer Animation 2010: 207-215
2000 – 2009
- 2009
- [j31]Nipun Kwatra, Jonathan Su, Jón Tómas Grétarsson, Ronald Fedkiw:
A method for avoiding the acoustic time step restriction in compressible flow. J. Comput. Phys. 228(11): 4146-4161 (2009) - [j30]Andrew Selle, Jonathan Su, Geoffrey Irving, Ronald Fedkiw:
Robust High-Resolution Cloth Using Parallelism, History-Based Collisions, and Accurate Friction. IEEE Trans. Vis. Comput. Graph. 15(2): 339-350 (2009) - [c26]Jonathan Su, Craig A. Schroeder, Ronald Fedkiw:
Energy stability and fracture for frame rate rigid body simulations. Symposium on Computer Animation 2009: 155-164 - [c25]Avi Robinson-Mosher, R. Elliot English, Ronald Fedkiw:
Accurate tangential velocities for solid fluid coupling. Symposium on Computer Animation 2009: 227-236 - 2008
- [j29]Andrew Selle, Ronald Fedkiw, ByungMoon Kim, Yingjie Liu, Jarek Rossignac:
An Unconditionally Stable MacCormack Method. J. Sci. Comput. 35(2-3): 350-371 (2008) - [j28]Avi Robinson-Mosher, Tamar Shinar
Two-way coupling of fluids to rigid and deformable solids and shells. ACM Trans. Graph. 27(3): 46 (2008) - [j27]Andrew Selle, Michael Lentine, Ronald Fedkiw:
A mass spring model for hair simulation. ACM Trans. Graph. 27(3): 64 (2008) - [j26]Rachel Weinstein, Eran Guendelman, Ronald Fedkiw:
Impulse-Based Control of Joints and Muscles. IEEE Trans. Vis. Comput. Graph. 14(1): 37-46 (2008) - [j25]Frank Losasso, Jerry O. Talton, Nipun Kwatra, Ronald Fedkiw:
Two-Way Coupled SPH and Particle Level Set Fluid Simulation. IEEE Trans. Vis. Comput. Graph. 14(4): 797-804 (2008) - [c24]Tamar Shinar, Craig A. Schroeder
Two-way Coupling of Rigid and Deformable Bodies. Symposium on Computer Animation 2008: 95-103 - 2007
- [j24]Jeong-Mo Hong, Tamar Shinar
On Boundary Condition Capturing for Multiphase Interfaces. J. Sci. Comput. 31(1-2): 99-125 (2007) - [j23]Ron Fedkiw:
The immersed interface method. Numerical solutions of PDEs involving interfaces and irregular domains. Math. Comput. 76(259): 1691 (2007) - [j22]Geoffrey Irving, Craig A. Schroeder, Ronald Fedkiw:
Volume conserving finite element simulations of deformable models. ACM Trans. Graph. 26(3): 13 (2007) - [j21]Jeong-Mo Hong, Tamar Shinar
Wrinkled flames and cellular patterns. ACM Trans. Graph. 26(3): 47 (2007) - [j20]Zhaosheng Bao, Jeong-Mo Hong, Joseph Teran, Ronald Fedkiw:
Fracturing Rigid Materials. IEEE Trans. Vis. Comput. Graph. 13(2): 370-378 (2007) - [c23]Eftychios Sifakis, Kevin G. Der, Ronald Fedkiw:
Arbitrary cutting of deformable tetrahedralized objects. Symposium on Computer Animation 2007: 73-80 - [c22]Eftychios Sifakis, Tamar Shinar, Geoffrey Irving, Ronald Fedkiw:
Hybrid simulation of deformable solids. Symposium on Computer Animation 2007: 81-90 - 2006
- [j19]Geoffrey Irving, Joseph Teran, Ronald Fedkiw:
Tetrahedral and hexahedral invertible finite elements. Graph. Model. 68(2): 66-89 (2006) - [j18]Geoffrey Irving, Eran Guendelman, Frank Losasso, Ronald Fedkiw:
Efficient simulation of large bodies of water by coupling two and three dimensional techniques. ACM Trans. Graph. 25(3): 805-811 (2006) - [j17]Frank Losasso, Tamar Shinar
Multiple interacting liquids. ACM Trans. Graph. 25(3): 812-819 (2006) - [j16]Frank Losasso, Geoffrey Irving, Eran Guendelman, Ronald Fedkiw:
Melting and Burning Solids into Liquids and Gases. IEEE Trans. Vis. Comput. Graph. 12(3): 343-352 (2006) - [j15]Rachel Weinstein, Joseph Teran, Ronald Fedkiw:
Dynamic Simulation of Articulated Rigid Bodies with Contact and Collision. IEEE Trans. Vis. Comput. Graph. 12(3): 365-374 (2006) - [c21]Matthias Teschner, Marie-Paule Cani, Ron Fedkiw, Robert Bridson, Stéphane Redon, Pascal Volino, Gabriel Zachmann:
Collision Handling and its Applications. Eurographics (Tutorials) 2006: 1279-1339 - [c20]Eftychios Sifakis, Andrew Selle, Avram Lev Robinson-Mosher, Ronald Fedkiw:
Simulating speech with a physics-based facial muscle model. Symposium on Computer Animation 2006: 261-270 - [c19]Robert Bridson, Ronald Fedkiw, Matthias Müller-Fischer:
Fluid simulation: SIGGRAPH 2006 course notes Fedkiw and Muller-Fischer presenation videos are available from the citation page. SIGGRAPH Courses 2006: 1-87 - [c18]Willi Geiger, Mohen Leo, Nick Rasmussen, Frank Losasso, Ron Fedkiw:
So real it'll make you wet. SIGGRAPH Sketches 2006: 20 - [c17]Rachel Weinstein, Eran Guendelman, Ron Fedkiw:
Impulse-based PD control for joints and muscles. SIGGRAPH Sketches 2006: 120 - 2005
- [j14]Joseph Teran, Neil Molino, Ronald Fedkiw, Robert Bridson:
Adaptive physics based tetrahedral mesh generation using level sets. Eng. Comput. 21(1): 2-18 (2005) - [j13]Eftychios Sifakis, Igor Neverov, Ronald Fedkiw:
Automatic determination of facial muscle activations from sparse motion capture marker data. ACM Trans. Graph. 24(3): 417-425 (2005) - [j12]Andrew Selle, Nick Rasmussen, Ronald Fedkiw:
A vortex particle method for smoke, water and explosions. ACM Trans. Graph. 24(3): 910-914 (2005) - [j11]Eran Guendelman, Andrew Selle, Frank Losasso, Ronald Fedkiw:
Coupling water and smoke to thin deformable and rigid shells. ACM Trans. Graph. 24(3): 973-981 (2005) - [j10]Joseph Teran, Eftychios Sifakis, Silvia S. Blemker, Victor Ng-Thow-Hing, Cynthia Lau, Ronald Fedkiw:
Creating and Simulating Skeletal Muscle from the Visible Human Data Set. IEEE Trans. Vis. Comput. Graph. 11(3): 317-328 (2005) - [c16]Eftychios Sifakis, Ronald Fedkiw:
Facial Muscle Activations from Motion Capture. CVPR (2) 2005: 1195 - [c15]Joseph Teran, Eftychios Sifakis, Geoffrey Irving, Ronald Fedkiw:
Robust quasistatic finite elements and flesh simulation. Symposium on Computer Animation 2005: 181-190 - [c14]Robert Bridson, Ronald Fedkiw, John Anderson:
Robust treatment of collisions, contact and friction for cloth animation. SIGGRAPH Courses 2005: 2 - [c13]Robert Bridson, Sebastian Marino, Ron Fedkiw:
Simulation of clothing with folds and wrinkles. SIGGRAPH Courses 2005: 3 - [c12]Neil Molino, Zhaosheng Bao, Ron Fedkiw:
A virtual node algorithm for changing mesh topology during simulation. SIGGRAPH Courses 2005: 4 - [c11]Rachel Weinstein, Joseph Teran, Ron Fedkiw:
Pre-stabilization for rigid body articulation with contact and collision. SIGGRAPH Sketches 2005: 79 - [c10]Willi Geiger, Nick Rasmussen, Samir Hoon, Ron Fedkiw:
Space battle pyromania. SIGGRAPH Sketches 2005: 88 - 2004
- [j9]Neil Molino, Zhaosheng Bao, Ronald Fedkiw:
A virtual node algorithm for changing mesh topology during simulation. ACM Trans. Graph. 23(3): 385-392 (2004) - [j8]Frank Losasso, Frédéric Gibou, Ronald Fedkiw:
Simulating water and smoke with an octree data structure. ACM Trans. Graph. 23(3): 457-462 (2004) - [c9]Geoffrey Irving, Joseph Teran, Ronald Fedkiw:
Invertible finite elements for robust simulation of large deformation. Symposium on Computer Animation 2004: 131-140 - [c8]Nick Rasmussen, Douglas Enright, Duc Quang Nguyen, Sebastian Marino, Nigel Sumner, Willi Geiger, Samir Hoon, Ronald Fedkiw:
Directable photorealistic liquids. Symposium on Computer Animation 2004: 193-202 - [c7]David E. Breen, Ron Fedkiw, Ken Museth, Stanley J. Osher, Guillermo Sapiro, Ross T. Whitaker:
Level set and PDE methods for computer graphics. SIGGRAPH Course Notes 2004: 28 - [c6]Oliver Deussen, David S. Ebert
The elements of nature: interactive and realistic techniques. SIGGRAPH Course Notes 2004: 32 - 2003
- [b1]Stanley J. Osher, Ronald Fedkiw:
Level set methods and dynamic implicit surfaces. Applied mathematical sciences 153, Springer 2003, ISBN 0387954821, pp. I-XIII, 1-273 - [j7]Frédéric Gibou, Ronald Fedkiw, Russel E. Caflisch, Stanley J. Osher:
A Level Set Approach for the Numerical Simulation of Dendritic Growth. J. Sci. Comput. 19(1-3): 183-199 (2003) - [j6]Nick Rasmussen, Duc Quang Nguyen, Willi Geiger, Ronald Fedkiw:
Smoke simulation for large scale phenomena. ACM Trans. Graph. 22(3): 703-707 (2003) - [j5]Eran Guendelman, Robert Bridson, Ronald Fedkiw:
Nonconvex rigid bodies with stacking. ACM Trans. Graph. 22(3): 871-878 (2003) - [c5]Neil Molino, Robert Bridson, Joseph Teran, Ronald Fedkiw:
A Crystalline, Red Green Strategy for Meshing Highly Deformable Objects with Tetrahedra. IMR 2003: 103-114 - [c4]Robert Bridson, Sebastian Marino, Ronald Fedkiw:
Simulation of clothing with folds and wrinkles. Symposium on Computer Animation 2003: 28-36 - [c3]Joseph Teran, Silvia S. Blemker, Victor Ng-Thow-Hing, Ronald Fedkiw:
Finite volume methods for the simulation of skeletal muscle. Symposium on Computer Animation 2003: 68-74 - 2002
- [j4]Robert Bridson, Ronald Fedkiw, John Anderson:
Robust treatment of collisions, contact and friction for cloth animation. ACM Trans. Graph. 21(3): 594-603 (2002) - [j3]Duc Quang Nguyen, Ronald Fedkiw, Henrik Wann Jensen:
Physically based modeling and animation of fire. ACM Trans. Graph. 21(3): 721-728 (2002) - [j2]Douglas Enright, Stephen R. Marschner, Ronald Fedkiw:
Animation and rendering of complex water surfaces. ACM Trans. Graph. 21(3): 736-744 (2002) - 2001
- [c2]Ronald Fedkiw, Jos Stam, Henrik Wann Jensen:
Visual simulation of smoke. SIGGRAPH 2001: 15-22 - [c1]Nick Foster, Ronald Fedkiw:
Practical animation of liquids. SIGGRAPH 2001: 23-30 - 2000
- [j1]Myungjoo Kang, Ronald Fedkiw, Xu-Dong Liu:
A Boundary Condition Capturing Method for Multiphase Incompressible Flow. J. Sci. Comput. 15(3): 323-360 (2000)
Coauthor Index
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