Sebastian Schmitt, "Quantum multi-objective optimization ", QC Workshop 2024: GI Quantum Computing Workshop 2024, 2024.

Solving combinatorial optimization problems using variational quantum algorithms to be executed on near-term quantum devices has gained a lot of attraction in recent years. Currently, most works have focused on single-objective problems. In contrast, many real-world problems need to consider multiple conflicting objectives simultaneously, which is not well studied using variation quantum algorithms. In multi-objective optimization, one seeks the optimal trade-offs among conflicting objectives - the well-known Pareto set/front. We present a variational quantum multiple-objective optimization (QMOO) algorithm, which allows us to solve multi-objective optimization problems using NISQ computers. At the core of the algorithm is a variational quantum circuit (VQC) tuned to produce a quantum state which is a superposition of Pareto-optimal solutions, solving the original multi-objective optimization problem. The VQC achieves this by incorporating all cost Hamiltonians representing the classical objective functions. We retrieve a set of solutions from the quantum state prepared by the VQC, and utilize the widely-applied hypervolume indicator to determine the quality of it as approximation to the Pareto-front. The variational parameters of the VQC are tuning by maximizing the hypervolume indicator. As many realistic problems are integer optimization problems we formulate the whole scheme for qudit quantum systems. We show the effectiveness of the proposed algorithm on several benchmark problems with up to five objectives.