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Quantum Fourier analysis for multivariate functions and applications to a class of Schrödinger-type partial differential equations

Paula García-Molina, Javier Rodríguez-Mediavilla, Juan José García‐Ripoll

2022Physical review. A/Physical review, A22 citationsDOIOpen Access PDF

Abstract

In this work we develop a highly efficient representation of functions and differential operators based on Fourier analysis. Using this representation, we create a variational hybrid quantum algorithm to solve static, Schr\"odinger-type, Hamiltonian partial differential equations (PDEs), using space-efficient variational circuits, including the symmetries of the problem, and global and gradient-based optimizers. We use this algorithm to benchmark the performance of the representation techniques by means of the computation of the ground state in three PDEs, i.e., the one-dimensional quantum harmonic oscillator and the transmon and flux qubits, studying how they would perform in ideal and near-term quantum computers. With the Fourier methods developed here, we obtain low infidelities of order ${10}^{\ensuremath{-}4}--{10}^{\ensuremath{-}5}$ using only three to four qubits, demonstrating the high compression of information in a quantum computer. Practical fidelities are limited by the noise and the errors of the evaluation of the cost function in real computers, but they can also be improved through error mitigation techniques.

Topics & Concepts

Fourier transformMultivariate statisticsPartial differential equationClass (philosophy)MathematicsType (biology)Schrödinger's catFourier analysisMathematical physicsApplied mathematicsMathematical analysisStatisticsComputer scienceGeologyArtificial intelligencePaleontologyQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum Mechanics and Applications
Quantum Fourier analysis for multivariate functions and applications to a class of Schrödinger-type partial differential equations | Litcius