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arxiv: 2403.11237 · v2 · pith:SX6D2T24 · submitted 2024-03-17 · cs.CV · cs.RO

FORCE: Physics-aware Human-object Interaction

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classification cs.CV cs.RO
keywords humanforcemotioninteractionsmodelphysicalattributeshuman-object
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Interactions between human and objects are influenced not only by the object's pose and shape, but also by physical attributes such as object mass and surface friction. They introduce important motion nuances that are essential for diversity and realism. Despite advancements in recent human-object interaction methods, this aspect has been overlooked. Generating nuanced human motion presents two challenges. First, it is non-trivial to learn from multi-modal human and object information derived from both the physical and non-physical attributes. Second, there exists no dataset capturing nuanced human interactions with objects of varying physical properties, hampering model development. This work addresses the gap by introducing the FORCE model, an approach for synthesizing diverse, nuanced human-object interactions by modeling physical attributes. Our key insight is that human motion is dictated by the interrelation between the force exerted by the human and the perceived resistance. Guided by a novel intuitive physics encoding, the model captures the interplay between human force and resistance. Experiments also demonstrate incorporating human force facilitates learning multi-class motion. Accompanying our model, we contribute a dataset, which features diverse, different-styled motion through interactions with varying resistances.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. MOCHI: Motion Enhancement of Collaborative Human-object Interactions

    cs.CV 2026-06 unverdicted novelty 6.0

    MOCHI enhances noisy collaborative human-object interaction captures via grasp optimization followed by diffusion-based full-body refinement that incorporates interaction information into single-person motion priors.

  2. Fatigue-PINN: Physics-Informed Fatigue-Driven Motion Modulation and Synthesis

    cs.GR 2025-02 unverdicted novelty 6.0

    Fatigue-PINN applies physics-informed neural networks to simulate fatigue effects on human motion using a three-compartment muscle model for joint torque modulation in motion synthesis.