Xiaohan Shi scite author profile

In this paper, we introduce a novel approach to mesh editing with the Poisson equation as the theoretical foundation. The most distinctive feature of this approach is that it modifies the original mesh geometry implicitly through gradient field manipulation. Our approach can produce desirable and pleasing results for both global and local editing operations, such as deformation, object merging, and smoothing. With the help from a few novel interactive tools, these operations can be performed conveniently with a small amount of user interaction. Our technique has three key components, a basic mesh solver based on the Poisson equation, a gradient field manipulation scheme using local transforms, and a generalized boundary condition representation based on local frames. Experimental results indicate that our framework can outperform previous related mesh editing techniques.

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Mesh editing with poisson-based gradient field manipulation

Zhou

Dong

et al. 2004

206

267

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Subspace gradient domain mesh deformation

Huang¹,

Shi²,

Liu³

et al. 2006

132

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In this paper we present a general framework for performing constrained mesh deformation tasks with gradient domain techniques. We present a gradient domain technique that works well with a wide variety of linear and nonlinear constraints. The constraints we introduce include the nonlinear volume constraint for volume preservation, the nonlinear skeleton constraint for maintaining the rigidity of limb segments of articulated figures, and the projection constraint for easy manipulation of the mesh without having to frequently switch between multiple viewpoints. To handle nonlinear constraints, we cast mesh deformation as a nonlinear energy minimization problem and solve the problem using an iterative algorithm. The main challenges in solving this nonlinear problem are the slow convergence and numerical instability of the iterative solver. To address these issues, we develop a subspace technique that builds a coarse control mesh around the original mesh and projects the deformation energy and constraints onto the control mesh vertices using the mean value interpolation. The energy minimization is then carried out in the subspace formed by the control mesh vertices. Running in this subspace, our energy minimization solver is both fast and stable and it provides interactive responses. We demonstrate our deformation constraints and subspace deformation technique with a variety of constrained deformation examples.

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Subspace gradient domain mesh deformation

et al. 2006

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CFD analysis of liquid phase flow in a rotating packed bed reactor

Shi

Xiang

Wen

et al. 2013

Chemical Engineering Journal

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Xiaohan Shi

Mesh editing with poisson-based gradient field manipulation

Mesh editing with poisson-based gradient field manipulation

Subspace gradient domain mesh deformation

Subspace gradient domain mesh deformation

CFD analysis of liquid phase flow in a rotating packed bed reactor

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