Conceitos essenciais
This paper introduces a novel method using Differentiable Motion Manifold Primitives (DMMP) to achieve fast and adaptive kinodynamic motion planning for robots, enabling them to efficiently plan complex motions while adhering to dynamic constraints.
Resumo
Bibliographic Information
Lee, Y. (2024). Trajectory Manifold Optimization for Fast and Adaptive Kinodynamic Motion Planning [Preprint]. arXiv. https://arxiv.org/abs/2410.12193v1
Research Objective
This paper addresses the challenge of fast kinodynamic motion planning in robotics, aiming to develop a method that enables robots to quickly generate feasible trajectories for complex tasks while satisfying dynamic constraints.
Methodology
The authors propose a novel method called Differentiable Motion Manifold Primitives (DMMP) for fast and adaptive kinodynamic motion planning.
- The method first collects a diverse set of feasible trajectories for a given task using traditional trajectory optimization methods.
- These trajectories are then used to train a differentiable motion manifold, which encodes the task-relevant motions in a lower-dimensional latent space.
- A flow-based model is trained in the latent space to capture the task-conditioned distribution of trajectories.
- Finally, the motion manifold is fine-tuned to ensure that generated trajectories satisfy both task objectives and kinodynamic constraints.
Key Findings
- The proposed DMMP method significantly outperforms traditional trajectory optimization methods in terms of planning speed, achieving comparable success rates and constraint satisfaction.
- DMMP also demonstrates superior performance compared to existing motion manifold primitives, particularly in terms of constraint satisfaction and generalization to unseen task parameters.
- The effectiveness of DMMP is demonstrated through a case study on a dynamic throwing task using a 7-DoF robot arm, showcasing its ability to handle complex kinodynamic constraints and achieve fast replanning.
Main Conclusions
The authors conclude that DMMP provides a practical and efficient solution for fast and adaptive kinodynamic motion planning in robotics. By leveraging the learned motion manifold and flow-based model, DMMP enables robots to quickly generate feasible and optimized trajectories for complex tasks while adhering to dynamic constraints.
Significance
This research contributes to the field of robotics by introducing a novel and efficient method for kinodynamic motion planning. The proposed DMMP approach has the potential to enhance the adaptability and responsiveness of robots in dynamic environments, enabling them to perform complex tasks with greater speed and accuracy.
Limitations and Future Research
- The current DMMP method assumes a fixed terminal time for all trajectories, which may limit its applicability to tasks with varying durations.
- Future research could explore extending DMMP to handle trajectories with different terminal times.
- Additionally, investigating the use of more sophisticated flow-based models or incorporating reinforcement learning techniques could further improve the performance and generalization capabilities of DMMP.
Estatísticas
The task parameter space for the throwing task is defined as T := {(r, 0, h) | r ∈[1.1, 2.0], h ∈[0.0, 0.3]}.
The total time for the throwing task is T = 5 seconds.
The optimization process for trajectory collection involved 300 trajectories for each task parameter, resulting in a total of 12,000 trajectories across 40 candidate task parameters.
The data collection process resulted in 3,523 usable trajectories after filtering and adjustments.
The latent space for the motion manifold primitives was set to 32 dimensions.
When using the Adam optimizer for trajectory optimization, the time limit for successful convergence was set to 10,000 iterations.
Citações
"In such dynamically changing environments, fast kinodynamic motion planning is crucial for adaptation, which we aim to address in this paper."
"Building on this concept, we propose identifying a trajectory manifold – a lower-dimensional subspace consisting of task-relevant motions – offline, and then quickly searching for solutions online within this manifold."
"Our findings demonstrate that our method generates trajectories much more quickly than traditional trajectory optimization, with significantly higher success and constraint satisfaction rates compared to existing MMPs."