Minchen Li
Most Recent Affiliation(s):
- University of Pennsylvania, Adobe Research
Other Affiliation(s):
- The University of British Columbia
Award(s):
Experience(s):
Learning Presentation(s):
![A Contact Proxy Splitting Method for Lagrangian Solid-fluid Coupling](https://history.siggraph.org/wp-content/uploads/2024/02/2023-Tech-Papers-Xie_A-Contact-Proxy-Splitting-Method-for-Lagrangian-Solid-Fluid-Coupling-150x150.jpg)
Type: [Technical Papers]
A Contact Proxy Splitting Method for Lagrangian Solid-fluid Coupling Presenter(s): [Xie] [Li] [Yang] [Jiang]
[SIGGRAPH 2023]
![A Sparse Distributed Gigascale Resolution Material Point Method](https://history.siggraph.org/wp-content/uploads/2024/02/2023_Technical-Paper_Qiu_A-Sparse-Distributed-Gigascale-Resolution-Material-Point-Method-150x150.jpg)
Type: [Technical Papers]
A Sparse Distributed Gigascale Resolution Material Point Method Presenter(s): [Qiu] [Reeve] [Li] [Yang] [Slattery] [Jiang]
[SIGGRAPH 2023]
![Multi-layer Thick Shells](https://history.siggraph.org/wp-content/uploads/2024/02/2023-Tech-Papers-Chen_Spectrally-Coupled-Multi-Layer-Thick-Shells-150x150.jpg)
Type: [Technical Papers]
Multi-layer Thick Shells Presenter(s): [Chen] [Xie] [Yuksel] [Kaufman] [Yang] [Jiang] [Li]
[SIGGRAPH 2023]
![Second-order Stencil Descent for Interior-point Hyperelasticity](https://history.siggraph.org/wp-content/uploads/2024/02/2023-Tech-Papers-Lan_Second-order-Stencil-Descent-for-Interior-point-Hyperelasticity-150x150.jpg)
Type: [Technical Papers]
Second-order Stencil Descent for Interior-point Hyperelasticity Presenter(s): [Lan] [Li] [Jiang] [Wang] [Yang]
[SIGGRAPH 2023]
![A unified newton barrier method for multibody dynamics](https://history.siggraph.org/wp-content/uploads/2023/06/2022-Technical-Papers-Chen_-A-Unified-Newton-Barrier-Method-for-Multibody-Dynamics-150x150.jpg)
Type: [Technical Papers]
A unified newton barrier method for multibody dynamics Presenter(s): [Chen] [Li] [Lan] [Su] [Yang] [Jiang]
[SIGGRAPH 2022]
![Affine body dynamics: fast, stable and intersection-free simulation of stiff materials](https://history.siggraph.org/wp-content/uploads/2023/06/2022-Technical-Papers-Lan_-Affine-Body-Dynamics-Fast-Stable-and-Intersection-free-Simulation-of-Stiff-Materials-150x150.jpg)
Type: [Technical Papers]
Affine body dynamics: fast, stable and intersection-free simulation of stiff materials Presenter(s): [Lan] [Kaufman] [Li] [Jiang] [Yang]
[SIGGRAPH 2022]
![Energetically consistent inelasticity for optimization time integration](https://history.siggraph.org/wp-content/uploads/2023/06/2022-Technical-Papers-Li_-Energetically-Consistent-Inelasticity-for-Optimization-Time-Integration-150x150.jpg)
Type: [Technical Papers]
Energetically consistent inelasticity for optimization time integration Presenter(s): [Li] [Li] [Jiang]
[SIGGRAPH 2022]
![Penetration-free projective dynamics on the GPU](https://history.siggraph.org/wp-content/uploads/2023/06/2022-Technical-Papers-Lan_-Penetration-free-Projective-Dynamics-on-the-GPU-150x150.jpg)
Type: [Technical Papers]
Penetration-free projective dynamics on the GPU Presenter(s): [Lan] [Ma] [Yang] [Zheng] [Li] [Jiang]
[SIGGRAPH 2022]
![The power particle-in-cell method](https://history.siggraph.org/wp-content/uploads/2023/10/2022-Technical-Paper-Qu_The-Power-Particle-in-Cell-Method-150x150.jpg)
Type: [Technical Papers]
The power particle-in-cell method Presenter(s): [Qu] [Li] [Goes] [Jiang]
[SIGGRAPH 2022]
![Codimensional incremental potential contact](https://history.siggraph.org/wp-content/uploads/2023/06/2021-Technical-Papers-Li_Codimensional-Incremental-Potential-Contact-150x150.jpg)
Type: [Technical Papers]
Codimensional incremental potential contact Presenter(s): [Li] [Kaufman] [Jiang]
[SIGGRAPH 2021]
![Guaranteed globally injective 3D deformation processing](https://history.siggraph.org/wp-content/uploads/2023/06/2021-Technical-Papers-Fang_Guaranteed-Globally-Injective-3D-Deformation-Processing-150x150.jpg)
Type: [Technical Papers]
Guaranteed globally injective 3D deformation processing Presenter(s): [Fang] [Li] [Jiang] [Kaufman]
[SIGGRAPH 2021]
![Intersection-free rigid body dynamics](https://history.siggraph.org/wp-content/uploads/2023/06/2021-Technical-Papers-Ferguson_Intersection-free-Rigid-Body-Dynamics-150x150.jpg)
Type: [Technical Papers]
Intersection-free rigid body dynamics Presenter(s): [Ferguson] [Li] [Schneider] [Ureta] [Langlois] [Jiang] [Zorin] [Kaufman] [Panozzo]
[SIGGRAPH 2021]
![Medial IPC: accelerated incremental potential contact with medial elastics](https://history.siggraph.org/wp-content/uploads/2023/06/2021-Technical-Papers-Lan_Medial-IPC-Accelerated-Incremental-Potential-Contact-with-Medial-Elastics-150x150.jpg)
Type: [Technical Papers]
Medial IPC: accelerated incremental potential contact with medial elastics Presenter(s): [Lan] [Yang] [Kaufman] [Yao] [Li] [Jiang]
[SIGGRAPH 2021]
![A Massively Parallel and Scalable Multi-GPU Material Point Method](https://history.siggraph.org/wp-content/uploads/2023/01/2020-Technical-Papers-Wang_A-Massively-Parallel-and-Scalable-Multi-GPU-Material-Point-Method-150x150.jpg)
Type: [Technical Papers]
A Massively Parallel and Scalable Multi-GPU Material Point Method Presenter(s): [Wang] [Qiu] [Slattery] [Fang] [Li] [Zhu] [Zhu] [Tang] [Manocha] [Jiang]
[SIGGRAPH 2020]
![AnisoMPM: Animating Anisotropic Damage Mechanics](https://history.siggraph.org/wp-content/uploads/2023/01/2020-Technical-Papers-Wolper_AnisoMPM-Animating-Anisotropic-Damage-Mechanics-150x150.jpg)
Type: [Technical Papers]
AnisoMPM: Animating Anisotropic Damage Mechanics Presenter(s): [Wolper] [Chen] [Li] [Fang] [Qu] [Lu] [Cheng] [Jiang]
[SIGGRAPH 2020]
![Hierarchical Optimization Time Integration for CFL-rate MPM Stepping](https://history.siggraph.org/wp-content/uploads/2023/02/2020-Technical-Papers-Wang_Hierarchical-Optimization-Time-Integration-for-CFL-rate-MPM-Stepping-150x150.jpg)
Type: [Technical Papers]
Hierarchical Optimization Time Integration for CFL-rate MPM Stepping Presenter(s): [Wang] [Li] [Fang] [Zhang] [Gao] [Tang] [Kaufman] [Jiang]
[SIGGRAPH 2020]
![Incremental Potential Contact: Intersection- and Inversion-free,Large-Deformation Dynamics](https://history.siggraph.org/wp-content/uploads/2022/09/2020-Technical-Papers-Li_Incremental-Potential-Contact_-Intersection-and-Inversion-free-Large-Deformation-Dynamics-150x150.jpg)
Type: [Technical Papers]
Incremental Potential Contact: Intersection- and Inversion-free,Large-Deformation Dynamics Presenter(s): [Li] [Ferguson] [Schneider] [Langlois] [Zorin] [Panozzo] [Jiang] [Kaufman]
[SIGGRAPH 2020]
![IQ-MPM: An Interface Quadrature Material Point Method forNon-sticky Strongly Two-Way Coupled Nonlinear Solids and Fluids](https://history.siggraph.org/wp-content/uploads/2022/09/2020-Technical-Papers-Fang_IQ-MPM_-An-Interface-Quadrature-Material-Point-Method-for-Non-sticky-Strongly-Two-Way-Coupled-Nonlinear-Solids-and-Fluids-150x150.jpg)
Type: [Technical Papers]
IQ-MPM: An Interface Quadrature Material Point Method forNon-sticky Strongly Two-Way Coupled Nonlinear Solids and Fluids Presenter(s): [Fang] [Qu] [Li] [Zhang] [Zhu] [Aanjaneya] [Jiang]
[SIGGRAPH 2020]
![CD-MPM: continuum damage material point methods for dynamic fracture animation](https://history.siggraph.org/wp-content/uploads/2023/01/2019-Technical-Papers-Wolper_CD-MPM_-Continuum-Damage-Material-Point-Methods-for-Dynamic-Fracture-Animation-150x150.jpg)
Type: [Technical Papers]
CD-MPM: continuum damage material point methods for dynamic fracture animation Presenter(s): [Wolper] [Fang] [Li] [Lu] [Gao] [Jiang]
[SIGGRAPH 2019]
![Decomposed optimization time integrator for large-step elastodynamics](https://history.siggraph.org/wp-content/uploads/2023/01/2019-Technical-Papers-Li_Decomposed-Optimization-Time-Integrator-for-Large-Step-Elastodynamics-150x150.jpg)
Type: [Technical Papers]
Decomposed optimization time integrator for large-step elastodynamics Presenter(s): [Li] [Gao] [Langlois] [Jiang] [Kaufman]
[SIGGRAPH 2019]
![Silly rubber: an implicit material point method for simulating non-equilibrated viscoelastic and elastoplastic solids](https://history.siggraph.org/wp-content/uploads/2023/01/2019-Technical-Papers-Fang_Silly-Rubber_-An-Implicit-Material-Point-Method-for-Simulating-Non-equilibrated-Viscoelastic-and-Elastoplastic-Solids-150x150.jpg)
Type: [Technical Papers]
Silly rubber: an implicit material point method for simulating non-equilibrated viscoelastic and elastoplastic solids Presenter(s): [Fang] [Li] [Gao] [Jiang]
[SIGGRAPH 2019]
Role(s):
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