Real-Time Model Checking for Closed-Loop Robot Reactive Planning
Abstract
Reactive obstacle avoidance methods often cause agents to become trapped in local minima, because they can often only reason one step ahead (i.e., the next action based on the current state).
In this paper, we use model checking to achieve reactive multi-step planning and obstacle avoidance on an autonomous robot.
Our small, purpose-built model checking algorithm generates plans in situ (within the robot's code) based on ``core'' knowledge and attention as found in biological agents.
This is achieved in real-time using no pre-computed data on a low-powered device.
Our approach is based on chaining temporary control systems that are spawned to counteract disturbances in the local environment which disrupt an autonomous agent from its preferred action (or resting state).
We mitigate state-space explosion by relying on temporary snapshots of the immediate environment, restricting the number of states.
Multi-step planning using counter-examples generated by depth-first search and a negated LTL path property is applied to scenarios involving a cul-de-sac and a free-standing obstacle.
Empirical results and informal proofs of two fundamental properties demonstrate the effectiveness of our approach for the creation of efficient multi-step plans for local obstacle avoidance.
We significantly improve performance compared to a purely reactive agent that can only plan one step ahead.
Our approach is an instructional case study for the development of safe and reliable navigation in the context of autonomous vehicles.
We believe it also has general application in navigation for mission-critical mobile robots.
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