Multi-Agent Quantum Reinforcement Learning Using Evolutionary Optimization

Michael Kölle; Felix Topp; Thomy Phan; Philipp Altmann; Jonas Nüßlein; Claudia Linnhoff-Popien

Multi-Agent Quantum Reinforcement Learning Using Evolutionary Optimization

Michael Kölle, Felix Topp, Thomy Phan, Philipp Altmann, Jonas Nüßlein, Claudia Linnhoff-Popien

Published: 01 Jan 2024, Last Modified: 03 Sept 2024ICAART (1) 2024EveryoneRevisionsBibTeXCC BY-SA 4.0

Abstract: Multi-Agent Reinforcement Learning is becoming increasingly more important in times of autonomous driving and other smart industrial applications. Simultaneously a promising new approach to Reinforcement Learning arises using the inherent properties of quantum mechanics, reducing the trainable parameters of a model significantly. However, gradient-based Multi-Agent Quantum Reinforcement Learning methods often have to struggle with barren plateaus, holding them back from matching the performance of classical approaches. We build upon an existing approach for gradient free Quantum Reinforcement Learning and propose tree approaches with Variational Quantum Circuits for Multi-Agent Reinforcement Learning using evolutionary optimization. We evaluate our approach in the Coin Game environment and compare them to classical approaches. We showed that our Variational Quantum Circuit approaches perform significantly better compared to a neural network with a similar amount of trainable paramete

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