Related papers: Quantum Software Ecosystem Design

Quantum Software Ecosystem Design

URL: http://arxiv.org/abs/2405.13244v1
Date: Tue, 21 May 2024 23:11:11 GMT
Title: Quantum Software Ecosystem Design
Authors: Achim Basermann, Michael Epping, Benedikt Fauseweh, Michael Felderer, Elisabeth Lobe, Melven Röhrig-Zöllner, Gary Schmiedinghoff, Peter K. Schuhmacher, Yoshinta Setyawati, Alexander Weinert,
Abstract summary: The rapid advancements in quantum computing necessitate a scientific and rigorous approach to the construction of a corresponding software ecosystem. This chapter presents scientific considerations essential for building a quantum software ecosystem that makes quantum computing available for scientific and industrial problem solving.
Score: 35.12790469199701
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The rapid advancements in quantum computing necessitate a scientific and rigorous approach to the construction of a corresponding software ecosystem, a topic underexplored and primed for systematic investigation. This chapter takes an important step in this direction: It presents scientific considerations essential for building a quantum software ecosystem that makes quantum computing available for scientific and industrial problem solving. Central to this discourse is the concept of hardware-software co-design, which fosters a bidirectional feedback loop from the application layer at the top of the software stack down to the hardware. This approach begins with compilers and low-level software that are specifically designed to align with the unique specifications and constraints of the quantum processor, proceeds with algorithms developed with a clear understanding of underlying hardware and computational model features, and extends to applications that effectively leverage the capabilities to achieve a quantum advantage. We analyze the ecosystem from two critical perspectives: the conceptual view, focusing on theoretical foundations, and the technical infrastructure, addressing practical implementations around real quantum devices necessary for a functional ecosystem. This approach ensures that the focus is towards promising applications with optimized algorithm-circuit synergy, while ensuring a user-friendly design, an effective data management and an overall orchestration. Our chapter thus offers a guide to the essential concepts and practical strategies necessary for developing a scientifically grounded quantum software ecosystem.

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