Safe Feedback Motion Planning in Unknown Environments: An Instantaneous Local Control Barrier Function Approach

Cong Li, Zengjie Zhang, Nesrin Ahmed, Qingchen Liu, Fangzhou Liu, Martin Buss

Research output: Contribution to journalArticlepeer-review

Abstract

Mobile robots are desired with resilience to safely interact with prior-unknown environments and finally accomplish given tasks. This paper utilizes instantaneous local sensory data to stimulate the safe feedback motion planning (SFMP) strategy with adaptability to diverse prior-unknown environments without building a global map. This is achieved by the numerical optimization with the constraints, referred to as instantaneous local control barrier functions (IL-CBFs) and goal-driven control Lyapunov functions (GD-CLFs), learned from perceptional signals. In particular, the IL-CBFs reflecting potential collisions and GD-CLFs encoding incrementally discovered subgoals are first online learned from local perceptual data. Then, the learned IL-CBFs are united with GD-CLFs in the context of quadratic programming (QP) to generate the safe feedback motion planning strategy. Rather importantly, an optimization over the admissible control space of IL-CBFs is conducted to enhance the solution feasibility of QP. The SFMP strategy is developed with theoretically guaranteed collision avoidance and convergence to destinations. Numerical simulations are conducted to reveal the effectiveness of the proposed SFMP strategy that drives mobile robots to safely reach the destination incrementally in diverse prior-unknown environments.

Original languageEnglish
Article number40
JournalJournal of Intelligent and Robotic Systems: Theory and Applications
Volume109
Issue number2
DOIs
StatePublished - Oct 2023

Keywords

  • Collision avoidance
  • Goal-driven control lyapunov function
  • Instantaneous local control barrier function
  • Safe feedback motion planning

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