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arxiv_ml 70% Match Research Paper Quantum computing researchers,Quantum software engineers,ML researchers interested in quantum applications 2 weeks ago

FIDDLE: Reinforcement Learning for Quantum Fidelity Enhancement

reinforcement-learning › robotics-rl
📄 Abstract

Abstract: Quantum computing has the potential to revolutionize fields like quantum optimization and quantum machine learning. However, current quantum devices are hindered by noise, reducing their reliability. A key challenge in gate-based quantum computing is improving the reliability of quantum circuits, measured by process fidelity, during the transpilation process, particularly in the routing stage. In this paper, we address the Fidelity Maximization in Routing Stage (FMRS) problem by introducing FIDDLE, a novel learning framework comprising two modules: a Gaussian Process-based surrogate model to estimate process fidelity with limited training samples and a reinforcement learning module to optimize routing. Our approach is the first to directly maximize process fidelity, outperforming traditional methods that rely on indirect metrics such as circuit depth or gate count. We rigorously evaluate FIDDLE by comparing it with state-of-the-art fidelity estimation techniques and routing optimization methods. The results demonstrate that our proposed surrogate model is able to provide a better estimation on the process fidelity compared to existing learning techniques, and our end-to-end framework significantly improves the process fidelity of quantum circuits across various noise models.
Authors (3)
Hoang M. Ngo
Tamer Kahveci
My T. Thai
Submitted
October 17, 2025
arXiv Category
cs.LG
arXiv PDF

Key Contributions

FIDDLE is a novel learning framework that directly maximizes process fidelity during quantum circuit transpilation's routing stage. It combines a Gaussian Process surrogate model for efficient fidelity estimation with an RL module for optimization, outperforming methods relying on indirect metrics like circuit depth.

Business Value

Increases the reliability and accuracy of quantum computations, accelerating progress in quantum computing applications like optimization and machine learning.

Paper Metadata

Innovation Type

Novel Framework / Hybrid Approach

Deployment Feasibility

Moderate. Requires integration into quantum computing software stacks (compilers/transpilers). The underlying quantum hardware is still nascent.

Limitations Addressed

Noise and decoherence in quantum hardware,Indirect optimization metrics (depth, gate count) not always correlating with fidelity,Limited training samples for fidelity estimation

Performance Gains

Outperforms traditional methods that rely on indirect metrics by directly maximizing process fidelity.

Technical Tags

Quantum ComputingQuantum Fidelity EnhancementTranspilationRouting StageGaussian Process Surrogate ModelReinforcement LearningProcess Fidelity MaximizationCircuit DepthGate CountFIDDLE framework

Research Topics

Quantum Computing ReliabilityQuantum Algorithm OptimizationMachine Learning for Quantum SystemsOptimization Techniques

Methods & Architectures

Gaussian Process (GP) surrogate modelReinforcement Learning (RL) moduleFIDDLE framework Gaussian Process modelsReinforcement Learning agents

Applications & Tasks

Quantum Computing Quantum Information Science High-Performance Computing Noise in quantum devices reducing reliabilityImproving reliability of quantum circuits during transpilationOptimizing the routing stageMaximizing process fidelity directly Maximizing Process Fidelity in Routing Stage (FMRS)Optimizing quantum circuit routingEnhancing quantum gate reliability

Related Fields

Quantum InformationQuantum ComputingMachine LearningOptimizationControl Theory

Keywords

quantum computingfidelitytranspilationroutingreinforcement learningsurrogate modelingGaussian processesquantum noisequantum circuitsoptimizationquantum machine learningFIDDLE

Academic Context

#Quantum Computing Reliability#Quantum Algorithm Optimization#Machine Learning for Quantum Systems#Optimization Techniques

Commercial Potential

Potential Products
Quantum transpilation optimization toolsSoftware libraries for improving quantum circuit fidelity
Target Industries
Quantum ComputingTechnologyResearch & Development
Use Case Examples
Improving the accuracy of quantum algorithms for drug discoveryEnhancing the reliability of quantum machine learning models
Competitive Edge
First approach to directly maximize process fidelity during routing, offering a more targeted optimization than methods focusing solely on circuit depth or gate count.

Resource Requirements

Compute Needs
Significant for training the GP surrogate and RL agent, especially with complex quantum circuits.
Data Requirements
Requires data from quantum circuit simulations or experiments to train the fidelity estimation model.
Deployment Constraints
Dependent on the maturity of quantum hardware and software stacks. The computational cost of the optimization process might be a factor.
Scalability
Scalability to larger quantum circuits and more complex routing problems is a key research question.

Production Readiness

Maturity Level

Research

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