Quantum Carleman linearisation efficiency in nonlinear fluid dynamics
- URL: http://arxiv.org/abs/2410.23057v1
- Date: Wed, 30 Oct 2024 14:32:18 GMT
- Title: Quantum Carleman linearisation efficiency in nonlinear fluid dynamics
- Authors: Javier Gonzalez-Conde, Dylan Lewis, Sachin S. Bharadwaj, Mikel Sanz,
- Abstract summary: One promising avenue to enhance Computational fluid dynamics is the use of quantum computing.
We propose a connection between the numerical parameter, $R$, that guarantees efficiency in the truncation of the Carleman linearisation.
We also introduce the formalism for vector field simulation in different spatial dimensions.
- Score: 0.2624902795082451
- License:
- Abstract: Computational fluid dynamics (CFD) is a specialised branch of fluid mechanics that utilises numerical methods and algorithms to solve and analyze fluid-flow problems. One promising avenue to enhance CFD is the use of quantum computing, which has the potential to resolve nonlinear differential equations more efficiently than classical computers. Here, we try to answer the question of which regimes of nonlinear partial differential equations (PDEs) for fluid dynamics can have an efficient quantum algorithm. We propose a connection between the numerical parameter, $R$, that guarantees efficiency in the truncation of the Carleman linearisation, and the physical parameters that describe the fluid flow. This link can be made thanks to the Kolmogorov scale, which determines the minimum size of the grid needed to properly resolve the energy cascade induced by the nonlinear term. Additionally, we introduce the formalism for vector field simulation in different spatial dimensions, providing the discretisation of the operators and the boundary conditions.
Related papers
- Towards Variational Quantum Algorithms for generalized linear and nonlinear transport phenomena [0.0]
This article proposes a Variational Quantum Algorithm (VQA) to solve linear and nonlinear thermofluid dynamic transport equations.
The hybrid classical-quantum framework is applied to problems governed by the heat, wave, and Burgers' equation in combination with different engineering boundary conditions.
arXiv Detail & Related papers (2024-11-22T13:39:49Z) - Demonstration of Scalability and Accuracy of Variational Quantum Linear Solver for Computational Fluid Dynamics [0.0]
This paper presents an exploration of quantum methodologies aimed at achieving high accuracy in solving such a large system of equations.
We consider the 2D, transient, incompressible, viscous, non-linear coupled Burgers equation as a test problem.
Our findings demonstrate that our quantum methods yield results comparable in accuracy to traditional approaches.
arXiv Detail & Related papers (2024-09-05T04:42:24Z) - Improving Pseudo-Time Stepping Convergence for CFD Simulations With
Neural Networks [44.99833362998488]
Navier-Stokes equations may exhibit a highly nonlinear behavior.
The system of nonlinear equations resulting from the discretization of the Navier-Stokes equations can be solved using nonlinear iteration methods, such as Newton's method.
In this paper, pseudo-transient continuation is employed in order to improve nonlinear convergence.
arXiv Detail & Related papers (2023-10-10T15:45:19Z) - Physics-Informed Quantum Machine Learning: Solving nonlinear
differential equations in latent spaces without costly grid evaluations [21.24186888129542]
We propose a physics-informed quantum algorithm to solve nonlinear and multidimensional differential equations.
By measuring the overlaps between states which are representations of DE terms, we construct a loss that does not require independent sequential function evaluations on grid points.
When the loss is trained variationally, our approach can be related to the differentiable quantum circuit protocol.
arXiv Detail & Related papers (2023-08-03T15:38:31Z) - Wasserstein Quantum Monte Carlo: A Novel Approach for Solving the
Quantum Many-Body Schr\"odinger Equation [56.9919517199927]
"Wasserstein Quantum Monte Carlo" (WQMC) uses the gradient flow induced by the Wasserstein metric, rather than Fisher-Rao metric, and corresponds to transporting the probability mass, rather than teleporting it.
We demonstrate empirically that the dynamics of WQMC results in faster convergence to the ground state of molecular systems.
arXiv Detail & Related papers (2023-07-06T17:54:08Z) - Machine learning of hidden variables in multiscale fluid simulation [77.34726150561087]
Solving fluid dynamics equations often requires the use of closure relations that account for missing microphysics.
In our study, a partial differential equation simulator that is end-to-end differentiable is used to train judiciously placed neural networks.
We show that this method enables an equation based approach to reproduce non-linear, large Knudsen number plasma physics.
arXiv Detail & Related papers (2023-06-19T06:02:53Z) - Potential quantum advantage for simulation of fluid dynamics [1.4046104514367475]
We show that a potential quantum exponential speedup can be achieved to simulate the Navier-Stokes equations governing turbulence using quantum computing.
This work suggests that an exponential quantum advantage may exist for simulating nonlinear multiscale transport phenomena.
arXiv Detail & Related papers (2023-03-29T09:14:55Z) - Deep Random Vortex Method for Simulation and Inference of Navier-Stokes
Equations [69.5454078868963]
Navier-Stokes equations are significant partial differential equations that describe the motion of fluids such as liquids and air.
With the development of AI techniques, several approaches have been designed to integrate deep neural networks in simulating and inferring the fluid dynamics governed by incompressible Navier-Stokes equations.
We propose the emphDeep Random Vortex Method (DRVM), which combines the neural network with a random vortex dynamics system equivalent to the Navier-Stokes equation.
arXiv Detail & Related papers (2022-06-20T04:58:09Z) - Designing Kerr Interactions for Quantum Information Processing via
Counterrotating Terms of Asymmetric Josephson-Junction Loops [68.8204255655161]
static cavity nonlinearities typically limit the performance of bosonic quantum error-correcting codes.
Treating the nonlinearity as a perturbation, we derive effective Hamiltonians using the Schrieffer-Wolff transformation.
Results show that a cubic interaction allows to increase the effective rates of both linear and nonlinear operations.
arXiv Detail & Related papers (2021-07-14T15:11:05Z) - Linear embedding of nonlinear dynamical systems and prospects for
efficient quantum algorithms [74.17312533172291]
We describe a method for mapping any finite nonlinear dynamical system to an infinite linear dynamical system (embedding)
We then explore an approach for approximating the resulting infinite linear system with finite linear systems (truncation)
arXiv Detail & Related papers (2020-12-12T00:01:10Z) - Solving nonlinear differential equations with differentiable quantum
circuits [21.24186888129542]
We propose a quantum algorithm to solve systems of nonlinear differential equations.
We use automatic differentiation to represent function derivatives in an analytical form as differentiable quantum circuits.
We show how this approach can implement a spectral method for solving differential equations in a high-dimensional feature space.
arXiv Detail & Related papers (2020-11-20T13:21:11Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.