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    Area of Science:

    • Computer Graphics
    • Computational Physics
    • Geometric Modeling

    Background:

    • Elastic shape morphing often struggles with complex topological changes.
    • Existing methods may lack physical realism or temporal coherence.
    • The material point method (MPM) offers a robust framework for simulating deformable objects with changing topology.

    Purpose of the Study:

    • To develop a novel, physically-based morphing technique for elastic shapes.
    • To enable complex topological transitions within a unified simulation framework.
    • To generate temporally coherent and detailed morphing sequences.

    Main Methods:

    • Leveraging the differentiable material point method (MPM).
    • Implementing space-time control via per-particle deformation gradients.
    • Employing a chained iterative optimization technique for sequence generation.

    Main Results:

    • Successfully demonstrated physically-based morphing for elastic shapes.
    • Accommodated complex topology changes, including object fusion and fission.
    • Produced detailed elastic deformations and coherent morphing sequences across challenging scenarios.

    Conclusions:

    • The proposed differentiable MPM approach provides a robust solution for physics-based elastic shape morphing.
    • The method effectively handles dynamic topology changes with high fidelity.
    • This technique advances the state-of-the-art in realistic shape transformation and animation.