Related papers: Utilizing classical programming principles in the Intel Quantum SDK: implementation of quantum lattice Boltzmann method

Utilizing classical programming principles in the Intel Quantum SDK: implementation of quantum lattice Boltzmann method

URL: http://arxiv.org/abs/2407.04311v1
Date: Fri, 5 Jul 2024 07:30:25 GMT
Title: Utilizing classical programming principles in the Intel Quantum SDK: implementation of quantum lattice Boltzmann method
Authors: Tejas Shinde, Ljubomir Budinski, Ossi Niemimäki, Valtteri Lahtinen, Helena Liebelt, Rui Li,
Abstract summary: We explore the use of classical programming techniques in implementing the quantum lattice Boltzmann method in the Intel Quantum SDK. The novelty of this work lies in leveraging classical techniques for the implementation of quantum algorithms.
Score: 1.4426921903884633
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We explore the use of classical programming techniques in implementing the quantum lattice Boltzmann method in the Intel Quantum SDK -- a software tool for quantum circuit creation and execution on Intel quantum hardware. As hardware access is limited, we use the state vector simulator provided by the SDK. The novelty of this work lies in leveraging classical techniques for the implementation of quantum algorithms. We emphasize the refinement of algorithm implementation and devise strategies to enhance quantum circuits for better control over problem variables. To this end, we adopt classical principles such as modularization, which allows for systematic and controlled execution of complex algorithms. Furthermore, we discuss how the same implementation could be expanded from state vector simulations to execution on quantum hardware with minor adjustments in these configurations.

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