Your search keyword '"Tae Yong Kim"' showing total 8 results

1. Air meshes for robust collision handling

Author

Nuttapong Chentanez, Miles Macklin, Tae-Yong Kim, and Matthias Müller

Subjects

Mathematical optimization, Computer science, Simple (abstract algebra), Collision response, Constraint (computer-aided design), Collision detection, Polygon mesh, Element (category theory), Collision, Computer Graphics and Computer-Aided Design, Algorithm, Inversion (discrete mathematics), ComputingMethodologies_COMPUTERGRAPHICS

Abstract

We propose a new method for both collision detection and collision response geared towards handling complex deformable objects in close contact. Our method does not miss collision events between time steps and solves the challenging problem of untangling automatically and robustly. It is conceptually simple and straight forward to parallelize due to the regularity of the algorithm. The main idea is to tessellate the air between objects once before the simulation and by considering one unilateral constraint per element that prevents its inversion during the simulation. If large relative rotations and translations are present in the simulation, an additional dynamic mesh optimization step is needed to prevent mesh locking. This step is fast in 2D and allows the simulation of arbitrary scenes. Because mesh optimization is expensive in 3D, however, the method is best suited for the subclass of 3D scenarios in which relative motions are limited. This subclass contains two important problems, namely the simulation of multi-layered clothing and tissue on animated characters.

Published

2015

2. Fast grid-free surface tracking

Author

Tae-Yong Kim, Matthias Müller, Nuttapong Chentanez, and Miles Macklin

Subjects

Flexibility (engineering), Mathematical optimization, Boundary (topology), Eulerian path, Grid, Tracking (particle physics), Computer Graphics and Computer-Aided Design, Manifold, symbols.namesake, Free surface, symbols, Point (geometry), Algorithm, ComputingMethodologies_COMPUTERGRAPHICS, Mathematics

Abstract

We present a novel explicit surface tracking method. Its main advantage over existing approaches is the fact that it is both completely grid-free and fast which makes it ideal for the use in large unbounded domains. A further advantage is that its running time is less sensitive to temporal variations of the input mesh than existing approaches. In terms of performance, the method provides a good trade-off point between speed and quality. The main idea behind our approach to handle topological changes is to delete all overlapping triangles and to fill or join the resulting holes in a robust and efficient way while guaranteeing that the output mesh is both manifold and without boundary. We demonstrate the flexibility, speed and quality of our method in various applications such as Eulerian and Lagrangian liquid simulations and the simulation of solids under large plastic deformations.

Published

2015

3. Unified particle physics for real-time applications

Author

Miles Macklin, Nuttapong Chentanez, Matthias Müller, and Tae-Yong Kim

Subjects

Fluid simulation, CUDA, Position (vector), Computer science, Particle, Representation (mathematics), Computer Graphics and Computer-Aided Design, Constraint satisfaction problem, ComputingMethodologies_COMPUTERGRAPHICS, Block (data storage), Computational science

Abstract

We present a unified dynamics framework for real-time visual effects. Using particles connected by constraints as our fundamental building block allows us to treat contact and collisions in a unified manner, and we show how this representation is flexible enough to model gases, liquids, deformable solids, rigid bodies and cloth with two-way interactions. We address some common problems with traditional particle-based methods and describe a parallel constraint solver based on position-based dynamics that is efficient enough for real-time applications.

Published

2014

4. Real time dynamic fracture with volumetric approximate convex decompositions

Author

Matthias Müller, Tae-Yong Kim, and Nuttapong Chentanez

Subjects

Convex hull, Mathematical optimization, Convex decomposition, Regular polygon, Common method, Object (computer science), Computer Graphics and Computer-Aided Design, GeneralLiterature_MISCELLANEOUS, Physics::Geophysics, Fracture (geology), Polygon mesh, Voronoi diagram, Algorithm, ComputingMethodologies_COMPUTERGRAPHICS, Mathematics

Abstract

We propose a new fast, robust and controllable method to simulate the dynamic destruction of large and complex objects in real time. The common method for fracture simulation in computer games is to pre-fracture models and replace objects by their pre-computed parts at run-time. This popular method is computationally cheap but has the disadvantages that the fracture pattern does not align with the impact location and that the number of hierarchical fracture levels is fixed. Our method allows dynamic fracturing of large objects into an unlimited number of pieces fast enough to be used in computer games. We represent visual meshes by volumetric approximate convex decompositions (VACD) and apply user-defined fracture patterns dependent on the impact location. The method supports partial fracturing meaning that fracture patterns can be applied locally at multiple locations of an object. We propose new methods for computing a VACD, for approximate convex hull construction and for detecting islands in the convex decomposition after partial destruction in order to determine support structures.

Published

2013

5. Fast grid-free surface tracking.

Author

Chentanez, Nuttapong, Müller, Matthias, Macklin, Miles, and Tae-Yong Kim

Subjects

GEOMETRIC surfaces, MESH networks, DEFORMATIONS (Mechanics), SIMULATION methods & models, MANIFOLDS (Mathematics)

Abstract

We present a novel explicit surface tracking method. Its main advantage over existing approaches is the fact that it is both completely grid- free and fast which makes it ideal for the use in large unbounded domains. A further advantage is that its running time is less sensitive to temporal variations of the input mesh than existing approaches. In terms of performance, the method provides a good trade-off point between speed and quality. The main idea behind our approach to handle topological changes is to delete all overlapping triangles and to fill or join the resulting holes in a robust and efficient way while guaranteeing that the output mesh is both manifold and without boundary. We demonstrate the flexibility, speed and quality of our method in various applications such as Eulerian and Lagrangian liquid simulations and the simulation of solids under large plastic deformations. [ABSTRACT FROM AUTHOR]

Published

2015

6. Air meshes for robust collision handling.

Author

Müller, Matthias, Chentanez, Nuttapong, Tae-Yong Kim, and Macklin, Miles

Subjects

MECHANICAL deformation measurement, ALGORITHM research, MATHEMATICAL optimization, ANIMATED films, SIMULATION methods & models

Abstract

We propose a new method for both collision detection and collision response geared towards handling complex deformable objects in close contact. Our method does not miss collision events between time steps and solves the challenging problem of untangling automatically and robustly. It is conceptually simple and straight forward to parallelize due to the regularity of the algorithm. The main idea is to tessellate the air between objects once before the simulation and by considering one unilateral constraint per element that prevents its inversion during the simulation. If large relative rotations and translations are present in the simulation, an additional dynamic mesh optimization step is needed to prevent mesh locking. This step is fast in 2D and allows the simulation of arbitrary scenes. Because mesh optimization is expensive in 3D, however, the method is best suited for the subclass of 3D scenarios in which relative motions are limited. This subclass contains two important problems, namely the simulation of multi-layered clothing and tissue on animated characters. [ABSTRACT FROM AUTHOR]

Published

2015

7. Unified particle physics for real-time applications.

Author

Macklin, Miles, Müller, Matthias, Chentanez, Nuttapong, and Tae-Yong Kim

Subjects

DYNAMICS, REAL-time computing, PARTICLES, NANOPARTICLES, PARTICLE size distribution

Abstract

We present a unified dynamics framework for real-time visual effects. Using particles connected by constraints as our fundamental building block allows us to treat contact and collisions in a unified manner, and we show how this representation is flexible enough to model gases, liquids, deformable solids, rigid bodies and cloth with two-way interactions. We address some common problems with traditional particle-based methods and describe a parallel constraint solver based on position-based dynamics that is efficient enough for real-time applications. [ABSTRACT FROM AUTHOR]

Published

2014

8. Real Time Dynamic Fracture with Volumetric Approximate Convex Decompositions.

Author

Müller, Matthias, Chentanez, Nuttapong, and Tae-Yong Kim

Subjects

ROBUST control, ELECTRONIC games, VIDEO game development, CONVEX domains

Abstract

We propose a new fast, robust and controllable method to simulate the dynamic destruction of large and complex objects in real time. The common method for fracture simulation in computer games is to pre-fracture models and replace objects by their pre-computed parts at run-time. This popular method is computationally cheap but has the disadvantages that the fracture pattern does not align with the impact location and that the number of hierarchical fracture levels is fixed. Our method allows dynamic fracturing of large objects into an unlimited number of pieces fast enough to be used in computer games. We represent visual meshes by volumetric approximate convex decompositions (VACD) and apply user-defined fracture patterns dependent on the impact location. The method supports partial fracturing meaning that fracture patterns can be applied locally at multiple locations of an object. We propose new methods for computing a VACD, for approximate convex hull construction and for detecting islands in the convex decomposition after partial destruction in order to determine support structures. [ABSTRACT FROM AUTHOR]

Published

2013