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Idée - Robotics - # Motion Planning Algorithms

PINSAT: Parallelized Interleaving of Graph Search and Trajectory Optimization for Kinodynamic Motion Planning


Concepts de base
PINSAT introduces systematic parallelization in INSAT to reduce planning times while maintaining lower costs.
Résumé

PINSAT is an algorithm that combines graph search and trajectory optimization for kinodynamic motion planning. It addresses challenges in long-horizon planning around obstacles by parallelizing the expensive calls to the optimizer. By leveraging edge-based parallel search techniques, PINSAT achieves close to real-time performance with higher success rates compared to INSAT. The algorithm guarantees completeness and aims to explore independence checks for optimality in the future.

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Stats
Threads: 5, 10, 50, 120 Success rate (%): 58, 72, 81, 90 (for different thread budgets) Time (s): Mean planning time ranges from 0.02s to 0.99s for various thread budgets. Cost: Mean cost ranges from 4.25 to 9.19 for different thread budgets.
Citations
"We demonstrate PINSAT by evaluating it on 6 DoF kinodynamic manipulation planning with obstacles." "PINSAT achieves significantly higher success rates than INSAT for all thread budgets greater than 1." "PINSAT guarantees only completeness at present, but in the future, we aim to explore how to establish independence checks."

Idées clés tirées de

by Ramkumar Nat... à arxiv.org 03-19-2024

https://arxiv.org/pdf/2401.08948.pdf
PINSAT

Questions plus approfondies

How can PINSAT's approach be applied to other complex dynamical systems beyond robotics

PINSAT's approach can be applied to various complex dynamical systems beyond robotics by adapting the concept of interleaving graph search and trajectory optimization. For instance, in autonomous vehicles' path planning, PINSAT could optimize long dynamically feasible maneuvers or persistent multi-UAV coverage with global deconfliction. By leveraging the parallelization techniques used in PINSAT, such systems can efficiently navigate challenging environments while considering dynamic constraints and optimizing trajectories over long horizons.

What potential drawbacks or limitations might arise from relying heavily on parallelization in motion planning algorithms

Relying heavily on parallelization in motion planning algorithms may introduce certain drawbacks or limitations. One potential limitation is the increased complexity of managing multiple threads simultaneously, which could lead to synchronization issues or inefficiencies if not implemented correctly. Additionally, parallelization might require significant computational resources, making it less practical for resource-constrained systems or real-time applications where speed is crucial. Moreover, excessive parallelization without proper load balancing could result in uneven distribution of tasks among threads, leading to suboptimal performance.

How can the concepts of edge expansion and asynchronous evaluation used in PINSAT be adapted for different optimization problems

The concepts of edge expansion and asynchronous evaluation used in PINSAT can be adapted for different optimization problems by customizing them based on the specific problem requirements. For instance: Edge Expansion: In a supply chain optimization scenario, edges representing different transportation routes between locations can be expanded asynchronously to evaluate cost-effective delivery options. Asynchronous Evaluation: In financial portfolio optimization, assets' performance metrics can be evaluated asynchronously based on market data updates to make real-time investment decisions. By tailoring these concepts to suit diverse optimization problems across various domains like logistics, finance, healthcare, etc., similar benefits of improved efficiency and scalability seen in PINSAT can be achieved.
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