Simulating deformable models with anisotropic materials

This research work is on dynamics simulation of deformable objects. We focus on the simulation of anisotropic materials, which is less exploited in existing research. To do this, it is essential to improve the physical realism of simulation, since many real-world objects have complex mechanical rath...

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Main Author: Cai, Jianping
Other Authors: Lin Feng
Format: Theses and Dissertations
Language:English
Published: 2016
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Online Access:https://hdl.handle.net/10356/68800
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-688002023-03-04T00:51:41Z Simulating deformable models with anisotropic materials Cai, Jianping Lin Feng Seah Hock Soon School of Computer Science and Engineering DRNTU::Engineering::Computer science and engineering This research work is on dynamics simulation of deformable objects. We focus on the simulation of anisotropic materials, which is less exploited in existing research. To do this, it is essential to improve the physical realism of simulation, since many real-world objects have complex mechanical rather than isotropic properties. Both physically-based and geometrically-based approaches are studied, and contributions are made in modeling and control of anisotropic dynamics deformations. First, we studied transversely isotropic materials for the simulation of deformable objects with fibrous structures. In existing work, direction-dependent behaviors of transversely isotropic materials can only be achieved with an additional energy function which incorporates the material preferred direction. Such an additional energy term increases the computational complexity. We propose a fiber-field incorporated corotational finite element model (CLFEM) that works directly with a constitutive model of transversely isotropic material. A smooth fiber-field is used to establish the local frames for each element. The orientation information of each element is incorporated into the CLFEM model by adding local transformations onto each element of the stiffness matrix. With pre-computation, it adds no additional computational cost on the existing model during dynamics simulation. We further introduce deformation simulation for orthotropic materials. Technical innovations are made in several aspects: An orthotropic deformation controlling frame-field is conceptualized and a frame construction tool is developed for users to define the desired material properties. A quaternion Laplacian smoothing algorithm is designed for propagating the user-defined sparsely distributed frames into the entire object. The orthotropic frame-field is coupled with the CLFEM model to complete an orthotropic deformable model. Finally, we present an integrated real-time system for animation of skeletal characters with anisotropic tissues. Existing geometrically-based skinning techniques suffer from obvious volume distortion artifact, and they cannot produce secondary dynamic motions, such as jiggling effects. Physically-based skinning with FEM models has high computational cost that restricts its practical applications. To solve these problems, we developed a novel strain-based PBD framework for skeletal animation. It bridges the gap between geometric models and physically-based models, and achieves both efficient and physically-plausible performance. Natural secondary motion of soft tissues is produced. Anisotropic deformations are made possible with separately defined stretch and shear properties of the material, using the user-designed frame-field. Owing to the efficiency and stability of our proposed layered constraint solving scheme, we can achieve real-time performance, and the system is robust with large deformations and degenerate cases. Limitations of our system and directions of future work, such as self-collision constraint and two-way coupling of rigid and soft bodies for locomotion control, are also discussed. DOCTOR OF PHILOSOPHY (SCE) 2016-06-01T06:24:02Z 2016-06-01T06:24:02Z 2016 Thesis Cai, J. (2016). Simulating deformable models with anisotropic materials. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/68800 10.32657/10356/68800 en 159 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Computer science and engineering
spellingShingle DRNTU::Engineering::Computer science and engineering
Cai, Jianping
Simulating deformable models with anisotropic materials
description This research work is on dynamics simulation of deformable objects. We focus on the simulation of anisotropic materials, which is less exploited in existing research. To do this, it is essential to improve the physical realism of simulation, since many real-world objects have complex mechanical rather than isotropic properties. Both physically-based and geometrically-based approaches are studied, and contributions are made in modeling and control of anisotropic dynamics deformations. First, we studied transversely isotropic materials for the simulation of deformable objects with fibrous structures. In existing work, direction-dependent behaviors of transversely isotropic materials can only be achieved with an additional energy function which incorporates the material preferred direction. Such an additional energy term increases the computational complexity. We propose a fiber-field incorporated corotational finite element model (CLFEM) that works directly with a constitutive model of transversely isotropic material. A smooth fiber-field is used to establish the local frames for each element. The orientation information of each element is incorporated into the CLFEM model by adding local transformations onto each element of the stiffness matrix. With pre-computation, it adds no additional computational cost on the existing model during dynamics simulation. We further introduce deformation simulation for orthotropic materials. Technical innovations are made in several aspects: An orthotropic deformation controlling frame-field is conceptualized and a frame construction tool is developed for users to define the desired material properties. A quaternion Laplacian smoothing algorithm is designed for propagating the user-defined sparsely distributed frames into the entire object. The orthotropic frame-field is coupled with the CLFEM model to complete an orthotropic deformable model. Finally, we present an integrated real-time system for animation of skeletal characters with anisotropic tissues. Existing geometrically-based skinning techniques suffer from obvious volume distortion artifact, and they cannot produce secondary dynamic motions, such as jiggling effects. Physically-based skinning with FEM models has high computational cost that restricts its practical applications. To solve these problems, we developed a novel strain-based PBD framework for skeletal animation. It bridges the gap between geometric models and physically-based models, and achieves both efficient and physically-plausible performance. Natural secondary motion of soft tissues is produced. Anisotropic deformations are made possible with separately defined stretch and shear properties of the material, using the user-designed frame-field. Owing to the efficiency and stability of our proposed layered constraint solving scheme, we can achieve real-time performance, and the system is robust with large deformations and degenerate cases. Limitations of our system and directions of future work, such as self-collision constraint and two-way coupling of rigid and soft bodies for locomotion control, are also discussed.
author2 Lin Feng
author_facet Lin Feng
Cai, Jianping
format Theses and Dissertations
author Cai, Jianping
author_sort Cai, Jianping
title Simulating deformable models with anisotropic materials
title_short Simulating deformable models with anisotropic materials
title_full Simulating deformable models with anisotropic materials
title_fullStr Simulating deformable models with anisotropic materials
title_full_unstemmed Simulating deformable models with anisotropic materials
title_sort simulating deformable models with anisotropic materials
publishDate 2016
url https://hdl.handle.net/10356/68800
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