Rudolf Reiter, Armin Nurkanovic, Daniele Bernadini, Moritz Diehl, Alberto Bemporad
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A Long-Short-Term Mixed-Integer Formulation for Highway Lane Change Planning
This work considers the problem of optimal lane changing in a structured
multi-agent road environment. A novel motion planning algorithm that can
capture long-horizon dependencies as well as short-horizon dynamics is
presented. Pivotal to our approach is a geometric approximation of the
long-horizon combinatorial transition problem which we formulate in the
continuous time-space domain. Moreover, a discrete-time formulation of a
short-horizon optimal motion planning problem is formulated and combined with
the long-horizon planner. Both individual problems, as well as their
combination, are formulated as MIQP and solved in real-time by using
state-of-the-art solvers. We show how the presented algorithm outperforms two
other state-of-the-art motion planning algorithms in closed-loop performance
and computation time in lane changing problems. Evaluations are performed using
the traffic simulator SUMO, a custom low-level tracking model predictive
controller, and high-fidelity vehicle models and scenarios, provided by the
CommonRoad environment.
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