Learning-Optimized Qubit Mapping and Reuse to Minimize Inter-Core Communication in Modular Quantum Architectures
Sokea Sang, Leanghok Hour, Youngsun Han
TL;DR
This paper introduces QARMA, a deep reinforcement learning-based qubit mapping method for modular quantum architectures, which significantly reduces inter-core communication and enables more scalable quantum computing.
Contribution
It proposes a novel attention-based DRL approach with graph neural networks and dynamic qubit reuse, advancing quantum circuit compilation for modular systems.
Findings
QARMA-R reduces inter-core communication by up to 100%.
QARMA achieves 15-40% improvement over existing methods for larger circuits.
97-100% reduction in inter-core operations compared to traditional mapping.
Abstract
Modular quantum architectures have emerged as a promising approach for scaling quantum computing systems by connecting multiple Quantum Processing Units (QPUs). However, this approach introduces significant challenges due to costly inter-core operations between chips and quantum state transfers, which contribute to noise and quantum decoherence. This paper presents QARMA, a novel Qubit mapping using Attention-based deep Reinforcement learning (DRL) for Modular quantum Architectures, along with its extension QARMA-R that incorporates dynamic qubit reuse capabilities. Our approach combines an attention-based mechanism with Graph Neural Networks (GNN) to learn optimal qubit allocation, routing, and reuse strategies that minimize inter-core communications. We introduce two key innovations: (1) a transformer-based encoder that captures both the global circuit structure and local qubit…
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