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Bounding Stochastic Safety: Leveraging Freedman’s Inequality with Discrete-Time Control Barrier Functions


Kernekoncepter
This paper leverages Freedman's inequality to provide less conservative safety guarantees for stochastic systems using discrete-time control barrier functions.
Resumé

The paper introduces a novel approach to enhancing safety guarantees for stochastic systems by utilizing Freedman's inequality with discrete-time control barrier functions. By considering the entire distribution of possible disturbances, the method provides stronger safety guarantees compared to traditional worst-case bounding methods. The study focuses on extending martingale-based techniques and demonstrates the effectiveness through simulation examples, such as bipedal obstacle avoidance scenarios.

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Statistik
Safety results for a bipedal robot navigating around an obstacle using our method are shown in Fig. 1. The theoretical bound on safety failure from Thm. 3 is presented as a dotted line in Fig. 1. Approximated probabilities from 5000 trials are shown as solid colored lines in Fig. 1. The probability that the system is unsafe is compared between different bounds in Fig. 2. Simulation results for various level sets and distributions over time are shown in Fig. 3.
Citater
"Safe control methods must be robust to unstructured uncertainties." - Ryan K. Cosner, et al. "Our approach accounts for the underlying disturbance distribution instead of relying exclusively on its worst-case bound." - Ryan K. Cosner, et al. "We show that our theory provides sharp safety probability bounds, enabling non-conservative, stochastic collision avoidance." - Ryan K. Cosner, et al.

Vigtigste indsigter udtrukket fra

by Ryan K. Cosn... kl. arxiv.org 03-12-2024

https://arxiv.org/pdf/2403.05745.pdf
Bounding Stochastic Safety

Dybere Forespørgsler

How can the proposed method be extended to more complex robotic systems beyond bipedal locomotion

The proposed method can be extended to more complex robotic systems beyond bipedal locomotion by adapting the control barrier functions and martingale-based techniques to suit the dynamics and constraints of the specific system. For example, in multi-legged robots or aerial vehicles, the safety guarantees can be enhanced by incorporating additional state variables, constraints, and disturbance models into the analysis. The discrete-time control barrier functions (DTCBFs) can be tailored to account for different types of disturbances and uncertainties that are prevalent in these systems. Additionally, the use of Freedman's inequality can provide tighter bounds on safety probabilities for more intricate robotic platforms.

What are potential limitations or drawbacks of relying on martingale-based techniques for safety guarantees

One potential limitation of relying on martingale-based techniques for safety guarantees is their computational complexity and sensitivity to model inaccuracies. Martingales require assumptions about predictable variations in stochastic processes which may not always hold true in real-world scenarios. Moreover, ensuring bounded differences or predictable quadratic variations might impose restrictions on the type of systems that can be analyzed using these methods. Additionally, interpreting and implementing martingale results effectively requires a deep understanding of probability theory and stochastic processes, which could pose challenges for practitioners without specialized knowledge.

How might advancements in probabilistic safety analysis impact other fields outside of robotics

Advancements in probabilistic safety analysis have far-reaching implications beyond robotics. In fields such as autonomous vehicles, medical devices, aerospace engineering, finance, and cybersecurity - where uncertainty plays a significant role - probabilistic safety analysis techniques offer a way to quantify risks accurately while considering various sources of uncertainty. By leveraging probabilistic methods like martingales or Freedman's inequality across industries prone to unpredictable events or disturbances, decision-makers can make informed choices based on rigorous risk assessments rather than deterministic worst-case scenarios alone. This shift towards probabilistic approaches enhances overall system reliability and robustness against unforeseen circumstances.
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