Two-way coupling of fluids to rigid and deformable solids and shells

Robinson-Mosher, Avi; Shinar, Tamar; Gretarsson, Jon; Su, Jonathan; Fedkiw, Ronald

doi:10.1145/1360612.1360645

Cited by 120 publications

(66 citation statements)

References 28 publications

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“…Robinson-Mosher et al [11] studied the cloth-fluid interface through two-way interaction conserving momentum and constraining the surface boundary. This work focuses on the surface interaction of cloth and fluid.…”

Section: Fluid Based Simulationmentioning

confidence: 99%

Physical simulation of wet clothing for virtual humans

2012

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We present a technique that simulates wet garments for virtual humans with realistic folds and wrinkles. Our approach combines three new models to allow realistic simulation of wet garments: (1) a simplified saturation model that modifies the masses, (2) a nonlinear friction model derived from previously reported, real-world measurements, and (3) a wrinkle model based on imperfection sensitivity theory. In contrast to previous approaches to wet cloth, the proposed models are supported by the experimental results reported in the textile literature with parameters varying over the course of the simulation. As a result, the wet garment motions simulated by our method are comparable to that of real wet garments. Our approach recognizes the special, practical importance of contact models with human skin and provides a specific skin-cloth friction solution. We evaluate our approach by draping a rotating sphere and simulating a typical garment on a virtual human in the rain. Both of these examples are typical scenarios within computer graphics research.

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Section: Fluid Based Simulationmentioning

confidence: 99%

Physical simulation of wet clothing for virtual humans

2012

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“…Hong and Kim [11] considered surface tension between multi-phase fluids using the ghost fluid method (GFM) to deal with discontinuities at the fluid surface. Robinson-Mosher et al introduced interactions between rigid bodies and a fluid [23]. Hong and Kim [10] and Shin and Kim [24] controlled the shape of a fluid using a gradient-based non-linear method, and Shi and Yu [27] introduced a target-driven method to force fluids to follow a rapidly deforming target shape.…”

Section: Related Workmentioning

confidence: 99%

Controlling shapes of air bubbles in a multi-phase fluid simulation

et al. 2012

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Controlling shapes is a challenging problem in a multi-phase fluid simulation. Bubble particles enable the details of air bubbles to be represented within a simulation based on an Euler grid. We control the target shapes of bubbles by the gradient vectors of the signed distance field and attraction forces associated with control particles. Our hybrid approach enables to simulate physically plausible movements of bubbles while preserving the details of a target shape. Furthermore, we control the paths of moving bubbles using user-defined curves and the shape of an air bubbles by drag force. An accurate model of the drag force near the fluid surface means that bubbles have realistic ellipsoidal shapes.

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“…Full simultaneous coupling between fluid and solid was achieved by Klingner et al [21] and Chentanez et al [26]. Later on, Batty et al [27] introduced the fast and robust variational framework and Robinson-Mosher et al [28] used the "back-of-the-envelope" method to achieve higher accuracy and better performance. By the way, the Lattice Boltzmann method (LBM) in computer graphics is becoming popular as it can naturally handle some problem difficult for the classical Euler and Lagrangian methods.…”

Section: Handling Irregular and Dynamic Solid Boundariesmentioning

confidence: 99%

Fluid simulation with adaptively sharpening and embedded boundary conditions

Yang

Chen

2011

Vis Comput

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In this paper, we present a physically based technique for simulating inviscid fluids. Our contribution is concerned with two issues. First, for solving the advection equation, we introduce a hybrid scheme that couples the FLIP scheme with the semi-Lagrangian scheme by adaptively distributing implicit particles and using a transition layer to propagate information. Secondly, for solving pressure, we develop a flux based scheme that can embed arbitrary solid boundaries into a Poisson equation. And based on this scheme we make further improvement to achieve two-way fluid/solid coupling on an octree structure with second-order accuracy. Finally, the experimental results demonstrate that our hybrid scheme for advection can preserve relatively fine surface details with less computation expenditure; and simultaneously our robust pressure solver can handle both stationary and moving obstacles more efficiently compared with unstructured meshes.

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Two-way coupling of fluids to rigid and deformable solids and shells

Cited by 120 publications

References 28 publications

Physical simulation of wet clothing for virtual humans

Physical simulation of wet clothing for virtual humans

Controlling shapes of air bubbles in a multi-phase fluid simulation

Fluid simulation with adaptively sharpening and embedded boundary conditions

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