Exploiting physical dynamics for concurrent control of a mobile robot

Conventionally, mobile robots are controlled through an action selection mechanism (ASM) that chooses among multiple proposed actions. This choice can be made in a variety of ways, and ASMs have been developed that demonstrate many of them, from strict priority schemes to voting systems. We take a different approach, which we call concurrent control. Abandoning explicit action selection, we rely instead on the physical dynamics of the robot´s actuators to achieve robust control. We claim that with many noisy controllers and no arbitration among commands we can elicit stable predictable behavior from a mobile robot. Specifically, we concern ourselves with the problem of driving a single planar mobile robot with multiple controlling agents that are concurrently sending commands directly to the robot´s wheel motors. We state analytically conditions necessary for our concurrent control approach to be viable, and verify empirically its general effectiveness and robustness to error through experiments with a physical robot.