Avoiding Deadlocks Is Not Enough: Analysis and Resolution of Blocked Airplanes

The foreseen increased usage of unmanned airplanes has been shown to lead to the emergence of pathological phenomena referred to as blocking in which airplanes stick together and fly in parallel for a long time. Although deadlock, a well-known pathological phenomenon in multi-agent systems, has been widely studied, it does not cover this temporal blocking phenomenon. As airspace becomes not only more autonomous but also increasingly crowded, and accommodates various types of aircraft, the blocking phenomenon is likely to occur even more frequently and negatively impact airplane systems. Therefore, it is crucial to understand and address the blocking phenomenon carefully in control design. To analyze blocking, we model airplane avoidance controllers using safety filters and examine the underlying causes in a two-airplane encounter situation. Furthermore, we propose an intention-aware strategy that efficiently resolves this pathological behavior while incidentally addressing deadlocks. Notably, the developed strategy does not rely on central coordination and communications which become unreliable in harsh situations. The analytical results are based on a simple dynamic model for airplanes, while the proposed resolution strategy is verified in both this simple model and a more realistic one.