TY - GEN
T1 - Optimizing Initial Qubit Mappings Under Fixed Gate Error Rates Using Deep Reinforcement Learning
AU - Oancea, Rares Adrian
AU - van der Linde, Stan
AU - de Kok, Willem
AU - Sabatelli, Matthia
AU - Feld, Sebastian
N1 - Green Open Access added to TU Delft Institutional Repository as part of the Taverne amendment. More information about this copyright law amendment can be found at https://www.openaccess.nl. Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.
PY - 2025
Y1 - 2025
N2 - Quantum computing promises to execute some tasks exponentially faster than classical computers. Quantum compilation, which transforms algorithms into executable quantum circuits, involves solving the initial mapping problem, crucial for optimizing qubit assignment and minimizing gate error rates. This study explores Deep Reinforcement Learning (DRL) for initial mapping across various qubit topologies, considering fixed gate error rates. Previous DRL approaches have succeeded but didn’t account for fixed error rates, used only one algorithm (PPO), and focused on a single topology with 20 qubits. The trial-and-error nature of Reinforcement Learning makes it ideal for initial mapping. DRL agents, using multiple policy gradient algorithms (A2C, PPO with and without action masking, and TRPO), compute high-quality mappings for small- and medium-scale quantum architectures. While effective, their efficiency decreases with larger systems, necessitating further optimization. Fine-tuning hyperparameters and action masking prevent illegal actions and enhance accuracy. Although currently not surpassing tools like Qiskit or achieving scalability for larger systems, this study highlights DRL’s potential for initial mapping in quantum computing, encouraging further innovation and refinement.
AB - Quantum computing promises to execute some tasks exponentially faster than classical computers. Quantum compilation, which transforms algorithms into executable quantum circuits, involves solving the initial mapping problem, crucial for optimizing qubit assignment and minimizing gate error rates. This study explores Deep Reinforcement Learning (DRL) for initial mapping across various qubit topologies, considering fixed gate error rates. Previous DRL approaches have succeeded but didn’t account for fixed error rates, used only one algorithm (PPO), and focused on a single topology with 20 qubits. The trial-and-error nature of Reinforcement Learning makes it ideal for initial mapping. DRL agents, using multiple policy gradient algorithms (A2C, PPO with and without action masking, and TRPO), compute high-quality mappings for small- and medium-scale quantum architectures. While effective, their efficiency decreases with larger systems, necessitating further optimization. Fine-tuning hyperparameters and action masking prevent illegal actions and enhance accuracy. Although currently not surpassing tools like Qiskit or achieving scalability for larger systems, this study highlights DRL’s potential for initial mapping in quantum computing, encouraging further innovation and refinement.
KW - Deep reinforcement learning
KW - Quantum compilation
UR - http://www.scopus.com/inward/record.url?scp=105008267330&partnerID=8YFLogxK
U2 - 10.1007/978-3-031-94263-1_12
DO - 10.1007/978-3-031-94263-1_12
M3 - Conference contribution
AN - SCOPUS:105008267330
SN - 978-3-031-94262-4
T3 - Communications in Computer and Information Science
SP - 189
EP - 208
BT - Innovations for Community Services - 25th International Conference, I4CS 2025, Proceedings
A2 - Zielinski, Sebastian
A2 - Eichler, Gerald
A2 - Erfurth, Christian
A2 - Fahrnberger, Günter
PB - Springer
CY - Cham
T2 - 25th International Conference on Innovations for Community Services, I4CS 2025
Y2 - 11 June 2025 through 13 June 2025
ER -