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Policy Gradients using Variational Quantum Circuits

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arxiv 2203.10591 v3 pith:OZHBN32R submitted 2022-03-20 quant-ph cs.LG

Policy Gradients using Variational Quantum Circuits

classification quant-ph cs.LG
keywords quantumlearningpolicyvariationalcircuitsgradientsmodelsnumber
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Variational Quantum Circuits are being used as versatile Quantum Machine Learning models. Some empirical results exhibit an advantage in supervised and generative learning tasks. However, when applied to Reinforcement Learning, less is known. In this work, we considered a Variational Quantum Circuit composed of a low-depth hardware-efficient ansatz as the parameterized policy of a Reinforcement Learning agent. We show that an $\epsilon$-approximation of the policy gradient can be obtained using a logarithmic number of samples concerning the total number of parameters. We empirically verify that such quantum models behave similarly or even outperform typical classical neural networks used in standard benchmarking environments and in quantum control, using only a fraction of the parameters. Moreover, we study the Barren Plateau phenomenon in quantum policy gradients using the Fisher Information Matrix spectrum.

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    quant-ph 2024-12 unverdicted novelty 3.0

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