Reinforcement Learning for Optimizing Large Qubit Array based Quantum Sensor Circuits
By: Laxmisha Ashok Attisara, Sathish Kumar
Potential Business Impact:
Makes quantum computers work better and faster.
As the number of qubits in a sensor increases, the complexity of designing and controlling the quantum circuits grows exponentially. Manually optimizing these circuits becomes infeasible. Optimizing entanglement distribution in large-scale quantum circuits is critical for enhancing the sensitivity and efficiency of quantum sensors [5], [6]. This paper presents an engineering integration of reinforcement learning with tensor-network-based simulation (MPS) for scalable circuit optimization for optimizing quantum sensor circuits with up to 60 qubits. To enable efficient simulation and scalability, we adopt tensor network methods, specifically the Matrix Product State (MPS) representation, instead of traditional state vector or density matrix approaches. Our reinforcement learning agent learns to restructure circuits to maximize Quantum Fisher Information (QFI) and entanglement entropy while reducing gate counts and circuit depth. Experimental results show consistent improvements, with QFI values approaching 1, entanglement entropy in the 0.8-1.0 range, and up to 90% reduction in depth and gate count. These results highlight the potential of combining quantum machine learning and tensor networks to optimize complex quantum circuits under realistic constraints.
Similar Papers
Quantum Machine Learning for Optimizing Entanglement Distribution in Quantum Sensor Circuits
Quantum Physics
Makes super-sensitive sensors work better and faster.
Quantum Circuit Structure Optimization for Quantum Reinforcement Learning
Machine Learning (CS)
Makes computers learn faster in complex worlds.
Reinforcement Learning for Quantum Circuit Design: Using Matrix Representations
Quantum Physics
Makes quantum computers design themselves faster.