Farhan Rasheed, Abrar Naseer, Emma Nilsson, Talha Bin Masood, Ingrid Hotz
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引用次数: 0
Abstract
This paper presents a nested tracking framework for analyzing cycles in 2D
force networks within granular materials. These materials are composed of
interacting particles, whose interactions are described by a force network.
Understanding the cycles within these networks at various scales and their
evolution under external loads is crucial, as they significantly contribute to
the mechanical and kinematic properties of the system. Our approach involves
computing a cycle hierarchy by partitioning the 2D domain into segments bounded
by cycles in the force network. We can adapt concepts from nested tracking
graphs originally developed for merge trees by leveraging the duality between
this partitioning and the cycles. We demonstrate the effectiveness of our
method on two force networks derived from experiments with photoelastic disks.
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