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Quantum-inspired framework for computational fluid dynamics

Raghavendra Dheeraj Peddinti, Stefano Pisoni, Alessandro Marini, P. Aaron Lott, Henrique Argentieri, Egor Tiunov, Leandro Aolita

2024Communications Physics36 citationsDOIOpen Access PDF

Abstract

Abstract Computational fluid dynamics is both a thriving research field and a key tool for advanced industry applications. However, the simulation of turbulent flows in complex geometries is a compute-power intensive task due to the vast vector dimensions required by discretized meshes. We present a complete and self-consistent full-stack method to solve incompressible fluids with memory and run time scaling logarithmically in the mesh size. Our framework is based on matrix-product states, a compressed representation of quantum states. It is complete in that it solves for flows around immersed objects of arbitrary geometries, with non-trivial boundary conditions, and self-consistent in that it can retrieve the solution directly from the compressed encoding, i.e. without passing through the expensive dense-vector representation. This framework lays the foundation for a generation of more efficient solvers of real-life fluid problems.

Topics & Concepts

Computer scienceComputational fluid dynamicsQuantumDynamics (music)PhysicsQuantum mechanicsMechanicsAcousticsQuantum many-body systemsTensor decomposition and applicationsQuantum Computing Algorithms and Architecture
Quantum-inspired framework for computational fluid dynamics | Litcius