Variational Quantum Circuit Design for Quantum Reinforcement Learning on Continuous Environments

Quantum Reinforcement Learning (QRL) emerged as a branch of reinforcement learning (RL) that uses quantum submodules in the architecture of the algorithm. One branch of QRL focuses on the replacement of neural networks (NN) by variational quantum circuits (VQC) as function approximators. Initial wor...

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Veröffentlicht in:	arXiv.org 2023-12
Hauptverfasser:	Kruse, Georg, Theodora-Augustina Dragan, Wille, Robert, Lorenz, Jeanette Miriam
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Circuit design Machine learning Neural networks Physics - Quantum Physics Reagents
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creator	Kruse, Georg Theodora-Augustina Dragan Wille, Robert Lorenz, Jeanette Miriam
description	Quantum Reinforcement Learning (QRL) emerged as a branch of reinforcement learning (RL) that uses quantum submodules in the architecture of the algorithm. One branch of QRL focuses on the replacement of neural networks (NN) by variational quantum circuits (VQC) as function approximators. Initial works have shown promising results on classical environments with discrete action spaces, but many of the proposed architectural design choices of the VQC lack a detailed investigation. Hence, in this work we investigate the impact of VQC design choices such as angle embedding, encoding block architecture and postprocessesing on the training capabilities of QRL agents. We show that VQC design greatly influences training performance and heuristically derive enhancements for the analyzed components. Additionally, we show how to design a QRL agent in order to solve classical environments with continuous action spaces and benchmark our agents against classical feed-forward NNs.
doi_str_mv	10.48550/arxiv.2312.13798
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subjects	Algorithms Circuit design Machine learning Neural networks Physics - Quantum Physics Reagents
title	Variational Quantum Circuit Design for Quantum Reinforcement Learning on Continuous Environments
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