LAPSE:2025.0377
Published Article
LAPSE:2025.0377
Enhanced Reinforcement Learning-driven Process Design via Quantum Machine Learning
June 27, 2025
Abstract
In this work, we introduce a quantum-enhanced reinforcement learning (RL) framework for process design synthesis. RL-driven methods for generating process designs have gained momentum due to their ability to intelligently identify optimal configurations without requiring pre-defined superstructures or flowsheet configurations. This eliminates reliance on prior expert knowledge, offering a comprehensive and robust design strategy. However, navigating the vast combinatorial design space poses computational challenges. To address this, a novel approach integrating RL with quantum machine learning (QML) is proposed. QML leverages theoretical advantages over classical methods to accelerate searches in large spaces. Built upon our prior work, the approach begins with a maximum set of available unit operations, represented in a flowsheet structure using an input-output stream matrix as RL observations. A Deep Q-Network (DQN) algorithm trains a parameterized quantum circuit (PQC) in place of a classical neural network (NN). The design structures generated by the RL agent are optimized using the IDAES Process Systems Engineering Framework, with the optimization objectives used as rewards to RL (e.g., cost, productivity). This quantum-enhanced algorithm is performed on a hydrodealkylation process case study, showcasing its efficiency and improved performance in navigating complex design spaces.
In this work, we introduce a quantum-enhanced reinforcement learning (RL) framework for process design synthesis. RL-driven methods for generating process designs have gained momentum due to their ability to intelligently identify optimal configurations without requiring pre-defined superstructures or flowsheet configurations. This eliminates reliance on prior expert knowledge, offering a comprehensive and robust design strategy. However, navigating the vast combinatorial design space poses computational challenges. To address this, a novel approach integrating RL with quantum machine learning (QML) is proposed. QML leverages theoretical advantages over classical methods to accelerate searches in large spaces. Built upon our prior work, the approach begins with a maximum set of available unit operations, represented in a flowsheet structure using an input-output stream matrix as RL observations. A Deep Q-Network (DQN) algorithm trains a parameterized quantum circuit (PQC) in place of a classical neural network (NN). The design structures generated by the RL agent are optimized using the IDAES Process Systems Engineering Framework, with the optimization objectives used as rewards to RL (e.g., cost, productivity). This quantum-enhanced algorithm is performed on a hydrodealkylation process case study, showcasing its efficiency and improved performance in navigating complex design spaces.
Record ID
Keywords
Process Design, Process Synthesis, Quantum Computing, Reinforcement Learning
Subject
Suggested Citation
Braniff A, You F, Tian Y. Enhanced Reinforcement Learning-driven Process Design via Quantum Machine Learning. Systems and Control Transactions 4:1403-1408 (2025) https://doi.org/10.69997/sct.149501
Author Affiliations
Braniff A: Department of Chemical and Biomedical Engineering, West Virginia University, Morgantown, WV, United States
You F: Smith School of Chemical and Biomolecular Engineering, Cornell University, Ithaca, NY, United States
Tian Y: Department of Chemical and Biomedical Engineering, West Virginia University, Morgantown, WV, United States
You F: Smith School of Chemical and Biomolecular Engineering, Cornell University, Ithaca, NY, United States
Tian Y: Department of Chemical and Biomedical Engineering, West Virginia University, Morgantown, WV, United States
Journal Name
Systems and Control Transactions
Volume
4
First Page
1403
Last Page
1408
Year
2025
Publication Date
2025-07-01
Version Comments
Original Submission
Other Meta
PII: 1403-1408-1354-SCT-4-2025, Publication Type: Journal Article
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LAPSE:2025.0377
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https://doi.org/10.69997/sct.149501
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Jun 27, 2025
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References Cited
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