Azala

Quantum simulation of Burgers turbulence: Nonlinear transformation and direct evaluation of statistical quantities

Gorde:
Argitaratua izan da:arXiv.org (Dec 23, 2024), p. n/a
Egile nagusia: Uchida, Fumio
Beste egile batzuk: Miyamoto, Koichi, Yamazaki, Soichiro, Fujisawa, Kotaro, Yoshida, Naoki
Argitaratua:
Cornell University Library, arXiv.org
Gaiak:
Transformations (mathematics)
Quantum computing
Technology assessment
Quantum computers
Finite difference method
Fault tolerance
Partial differential equations
Fluid flow
Algorithms
Velocity distribution
Fluid dynamics
Burgers equation
Nonlinear equations
Nonlinear dynamics
Sarrera elektronikoa:Citation/Abstract
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Laburpena:Fault-tolerant quantum computing is a promising technology to solve linear partial differential equations that are classically demanding to integrate. It is still challenging to solve non-linear equations in fluid dynamics, such as the Burgers equation, using quantum computers. We propose a novel quantum algorithm to solve the Burgers equation. With the Cole-Hopf transformation that maps the fluid velocity field \(u\) to a new field \(\psi\), we apply a sequence of quantum gates to solve the resulting linear equation and obtain the quantum state \(\vert\psi\rangle\) that encodes the solution \(\psi\). We also propose an efficient way to extract stochastic properties of \(u\), namely the multi-point functions of \(u\), from the quantum state of \(\vert\psi\rangle\). Our algorithm offers an exponential advantage over the classical finite difference method in terms of the number of spatial grids when a perturbativity condition in the information-extracting step is met.
ISSN:2331-8422
Baliabidea:Engineering Database