Maximizing Road Capacity Using Cars that Influence People
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The emerging technology enabling autonomy in vehicles has led to a variety of new problems in transportation networks. In particular, challenges exist in guaranteeing safety and optimizing traffic flow when the transportation network is under heterogeneous use: when cars of differing levels of autonomy co-exist on the same roads. Problems involving heterogeneous use of transportation networks have diverged into two major techniques: one leveraging only local interactions between cars benefiting the vehicles locally, and the other leveraging only global control techniques benefiting the traffic network. In this paper, we attempt to bridge the gap between these two paradigms. Our key insight is that the micro level interactions between the vehicles can in fact inform and affect the global behavior of the network, and vice versa. To this end, we utilize features of high levels of autonomy such as platooning to inform low-level controllers that incorporate the interaction between the vehicles. We will examine a high-level queuing framework to study the capacity of a transportation network, and then outline a lower-level control framework that leverages local interactions between cars to achieve a more efficient traffic flow via intelligent reordering of the cars. Such reorderings can be enforced by leveraging the interaction between autonomous and human-driven cars. We present a novel algorithm to show that the local actions of the autonomous cars on the road can initiate optimal orderings for the global properties in spite of randomly allocated initial ordering of the vehicles. We showcase our algorithm using a simulated mixed-autonomy traffic network, where we illustrate the re-ordering in action.
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