Litcius/Paper detail

Linear embedding of nonlinear dynamical systems and prospects for efficient quantum algorithms

Alexander Engel, Graeme Smith, Scott E. Parker

2021Physics of Plasmas37 citationsDOIOpen Access PDF

Abstract

The simulation of large nonlinear dynamical systems, including systems generated by discretization of hyperbolic partial differential equations, can be computationally demanding. Such systems are important in both fluid and kinetic computational plasma physics. This motivates exploring whether a future error-corrected quantum computer could perform these simulations more efficiently than any classical computer. We describe a method for mapping any finite nonlinear dynamical system to an infinite linear dynamical system (embedding) and detail three specific cases of this method that correspond to previously studied mappings. Then we explore an approach for approximating the resulting infinite linear system with finite linear systems (truncation). Using a number of qubits only logarithmic in the number of variables of the nonlinear system, a quantum computer could simulate truncated systems to approximate output quantities if the nonlinearity is sufficiently weak. Other aspects of the computational efficiency of the three detailed embedding strategies are also discussed.

Topics & Concepts

PhysicsNonlinear systemDynamical systems theoryLinear dynamical systemDiscretizationEmbeddingLogarithmQuantum systemQuantum algorithmStatistical physicsQuantum computerApplied mathematicsQubitQuantumPartial differential equationDynamical system (definition)AlgorithmLinear systemRandom dynamical systemPhysical systemQuantum error correctionFinite setNumerical analysisQuantum stateQuantum algorithm for linear systems of equationsQuantum processQuantum dynamicsDifferential equationQuantum Computing Algorithms and ArchitectureSpectroscopy and Quantum Chemical StudiesQuantum Information and Cryptography
Linear embedding of nonlinear dynamical systems and prospects for efficient quantum algorithms | Litcius