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Geometric Motion Planning for High-Dimensional Systems: Gait-Based Optimization and Local Metrics


核心概念
The author proposes a gait-based coordinate optimization method to overcome the curse of dimensionality in geometric motion planning for high-dimensional systems.
摘要

Geometric motion planning offers effective tools for locomotion analysis. The proposed method optimizes gaits in high-dimensional systems, showing better efficiency compared to reduced-order models. By combining coordinate optimization and local metrics, the approach takes a step towards geometric motion planning for complex systems.

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統計資料
"We test our method in two classes of high-dimensional systems - low Reynolds number swimmers and free-falling Cassie - with up to 11-dimensional shape variables." "The resulting optimal gait in the high-dimensional system shows better efficiency compared to that of the reduced-order model." "For this reason, applying geometric motion planning to high-dimensional systems becomes nearly impractical." "Although attempts have been made to address this issue via random sampling of the configuration space in a mesh-free manner, the number of samples required still increases exponentially with the dimensionality." "In this paper, we take a step towards geometric motion planning for high-dimensional systems by proposing a new method for coordinate optimization and a unified modeling framework."
引述
"The resulting optimal gait in the high-dimensional system shows better efficiency compared to that of the reduced-order model." "By combining these two approaches, we take a step towards geometric motion planning for high-dimensional systems." "Our proposed local metric representation approach will yield the same feasible projections of local connections as alternative modeling methods." "The subspace formed by the gait captures a large portion of the maximum attainable CCF flux." "The optimal gait covers a CCF-rich region in the subspace."

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by Yanhao Yang,... arxiv.org 03-08-2024

https://arxiv.org/pdf/2309.08871.pdf
Towards Geometric Motion Planning for High-Dimensional Systems

深入探究

How can higher-order terms be incorporated into gait analysis?

Incorporating higher-order terms into gait analysis involves considering additional terms beyond the traditional first two terms captured by the corrected body velocity integral (cBVI). These higher-order terms, which are typically neglected in cBVI-based approximations, play a crucial role in accurately predicting the displacement of non-infinitesimal gaits and reducing phase dependencies. One approach to include these higher-order terms is to extend the truncated Baker-Campbell-Hausdorff (BCH) series used in cBVI calculations. By accounting for these additional terms, gait analysis can provide more precise predictions of system motion and optimize gaits with greater accuracy.

What are potential applications beyond robotics for this geometric motion planning approach?

The geometric motion planning approach proposed in the context has broader applications beyond robotics. Some potential areas where this methodology could be applied include: Biomechanics: Understanding human or animal locomotion patterns and optimizing movements for rehabilitation or sports performance. Aerospace: Designing optimal trajectories for spacecraft or drones based on efficient movement principles. Material Science: Analyzing molecular dynamics and optimizing material structures based on geometric constraints. Medical Imaging: Developing algorithms to analyze anatomical movements from medical imaging data for diagnostic purposes. By applying geometric motion planning principles outside of robotics, researchers can enhance various fields that involve complex systems' dynamic behaviors.

How does non-commutativity impact coordinate optimization in complex systems?

Non-commutativity plays a significant role in coordinate optimization within complex systems by influencing how effectively coordinates capture system dynamics and interactions between components. In geometric motion planning, non-commutative elements introduce challenges during coordinate optimization due to their effects on approximation errors and solution accuracy. When dealing with high-dimensional systems, such as those with multiple degrees of freedom or intricate kinematic structures like articulated robots or biological organisms, non-commutativity complicates the process of finding optimal coordinates that minimize error while representing system behavior faithfully. The presence of non-commutative elements leads to increased complexity in solving partial differential equations across all degrees of freedom, making it challenging to achieve accurate results without careful consideration of these factors during coordinate optimization. Addressing non-commutativity becomes crucial when developing effective strategies for coordinating optimization tasks within complex systems, ensuring that solutions account for all relevant constraints and interactions present within the system's dynamics.
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