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içgörü - Robotics Control - # Adaptive safe trajectory planning and tracking

Parameterized Fast and Safe Tracking (PFaSTrack) for Efficient and Guaranteed Navigation in Unknown Environments


Temel Kavramlar
Parametric FaSTrack (PF) is a framework that combines the safety guarantees of Fast and Safe Tracking (FaSTrack) with the scalability and online adaptability of DeepReach to enable efficient and guaranteed navigation in unknown environments. PF parameterizes the tracking error bound and controller by the planner's control authority, allowing it to automatically trade off between safety and navigation speed.
Özet

The paper proposes Parametric FaSTrack (PF), a framework that combines the safety guarantees of Fast and Safe Tracking (FaSTrack) with the scalability and online adaptability of DeepReach. The key contributions are:

  1. Using DeepReach to approximate the Hamilton-Jacobi (HJ) value function, which improves the scalability of FaSTrack to high-dimensional systems.
  2. Parameterizing the tracking error bound (TEB) and controller by the planner's control authority, allowing PF to automatically trade off between safety and navigation speed.
    • In open environments, PF can use a larger TEB associated with faster planning for efficiency.
    • In cluttered environments, PF uses a tighter TEB and slower planning for safety.
  3. Providing algorithms to smoothly switch between different TEBs based on the distance to obstacles, increasing the overall navigation speed by up to 40% compared to state-of-the-art online planning methods.

The offline computation in PF involves training a parameterized value function using DeepReach, which outputs the static TEB (sTEB), dynamic TEB (dTEB), and the tracking controller. The online execution adapts the planner's control bound based on the distance to obstacles, using the sTEB and dTEB to guarantee safety while maximizing efficiency.

The paper demonstrates the effectiveness of PF through simulations of a 6D Dubin's car system and a 13D quadcopter system, showing significant improvements in navigation speed while preserving safety compared to existing methods.

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İstatistikler
The system dynamics for the 6D Dubin's car example are: ˙r1 = r4 sin(r3) - upx ˙r2 = r4 cos(r3) - upy ˙r3 = ω ˙r4 = α ˙β1 = 0 ˙β2 = 0 The system dynamics for the 13D quadcopter example are: ˙r1 = r2 - upx ˙r2 = g tan(r3) ˙r3 = -d1r3 + r4 ˙r4 = -d0r3 + n0ux ˙r5 = r6 - upy ˙r6 = g tan(r7) ˙r7 = -d1r7 + r8 ˙r8 = -d0r7 + n0uy ˙r9 = s10 - upz ˙r10 = kT uz - g ˙β1 = 0 ˙β2 = 0 ˙β3 = 0
Alıntılar
"Parametric FaSTrack (PF) is a framework that combines the safety guarantees of Fast and Safe Tracking (FaSTrack) with the scalability and online adaptability of DeepReach to enable efficient and guaranteed navigation in unknown environments." "PF parameterizes the tracking error bound (TEB) and controller by the planner's control authority, allowing it to automatically trade off between safety and navigation speed." "The paper demonstrates the effectiveness of PF through simulations of a 6D Dubin's car system and a 13D quadcopter system, showing significant improvements in navigation speed while preserving safety compared to existing methods."

Önemli Bilgiler Şuradan Elde Edildi

by Hyun Joe Jeo... : arxiv.org 04-12-2024

https://arxiv.org/pdf/2404.07431.pdf
Parameterized Fast and Safe Tracking (FaSTrack) using Deepreach

Daha Derin Sorular

How can the PF framework be extended to handle dynamic obstacles or uncertain environments beyond the parameterized planner control bounds

To extend the PF framework to handle dynamic obstacles or uncertain environments beyond the parameterized planner control bounds, we can incorporate adaptive strategies that dynamically adjust the planner control bounds based on real-time sensor feedback. This adaptation can be achieved by integrating sensor data into the decision-making process to update the planner control bounds in response to changing environmental conditions. By continuously monitoring the surroundings and detecting dynamic obstacles or uncertainties, the system can adjust the planner control bounds to ensure safe and efficient navigation. Additionally, incorporating probabilistic models or predictive algorithms can help anticipate potential obstacles or uncertainties, allowing the system to proactively adjust the planner control bounds before encountering them.

What are the theoretical guarantees on the conservativeness of the error bounds computed by DeepReach compared to traditional HJ reachability analysis

Theoretical guarantees on the conservativeness of the error bounds computed by DeepReach compared to traditional HJ reachability analysis stem from the training process and architecture of the deep neural network (DNN). DeepReach approximates the value function using a DNN that learns a parameterized estimation of the value function, allowing for efficient and scalable reachability analysis in high-dimensional spaces. The conservativeness of the error bounds is ensured through the training process, where the DNN is trained to approximate the value function while satisfying the constraints of the Hamilton-Jacobi reachability analysis. By optimizing the loss function that balances the ground truth value function and the HJI-VI constraints, DeepReach produces error bounds that are empirically shown to be conservative, providing safety assurances for the system.

Can the PF framework be applied to other robotic systems beyond the car and quadcopter examples, such as legged robots or manipulators, and how would the parameterization and online adaptation need to be modified

The PF framework can be applied to other robotic systems beyond cars and quadcopters, such as legged robots or manipulators, by adapting the parameterization and online adaptation strategies to suit the dynamics and constraints of these systems. For legged robots, the parameterization can include variables related to leg configurations, joint angles, and terrain characteristics, allowing for adaptive control strategies based on the robot's locomotion capabilities. Online adaptation for legged robots may involve adjusting the gait patterns, step lengths, or foothold positions in response to terrain variations or obstacles. Similarly, for manipulators, the parameterization can involve the configuration space of the robot arm, joint velocities, and end-effector positions, enabling real-time adjustments to the manipulation tasks based on environmental constraints. The online adaptation for manipulators may focus on optimizing trajectories, avoiding collisions, and ensuring task completion under uncertainties. By customizing the parameterization and adaptation mechanisms to the specific requirements of legged robots or manipulators, the PF framework can be effectively applied to a diverse range of robotic systems.
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