Abstract

Quantum computing is important for science and industry as it offers the potential to solve certain complex problems and perform calculations significantly faster than classical computers. Quantum computing systems evolved from monolithic systems towards modular architectures comprising multiple quantum processing units (QPUs) coupled to classical computing nodes (HPC). With the increasing scale, middleware systems that facilitate the efficient coupling of quantum-classical computing are becoming critical. Through an in-depth analysis of quantum applications, integration patterns and systems, we identified a gap in understanding Quantum-HPC middleware systems. We present a conceptual middleware to facilitate reasoning about quantum-classical integration and serve as the basis for a future middleware system. A key contribution of this paper lies in leveraging well-established high-performance computing abstractions for managing workloads, tasks, and resources to seamlessly integrate quantum computing into HPC systems.