This paper traces the evolution of Quantum Computing, from its origins in the visionary ideas of physicists like Richard Feynman to the recent breakthroughs in quantum algorithms and hardware. It highlights how the limitations of classical computers in simulating quantum systems led to the birth of the concept of quantum computers, which can potentially solve certain problems exponentially faster than classical counterparts.
The paper then delves into the emerging field of Quantum Software Engineering (QSE), which aims to develop the principles, methodologies, and tools necessary to effectively leverage quantum computers. QSE seeks to address the unique challenges posed by quantum computing, such as the sensitivity of quantum systems, the limitations of current NISQ (Noisy Intermediate-Scale Quantum) devices, and the need for new programming abstractions and debugging techniques.
The authors discuss the key milestones in the history of QSE, including the seminal work by researchers like Jianjun Zhao and the Talavera Manifesto, which outline the core principles and commitments for this new discipline. They also highlight the ongoing research efforts in areas such as quantum software lifecycle models, testing and verification, and the adaptation of classical software engineering practices to the quantum domain.
Finally, the paper proposes several promising research directions for the future of QSE, including the development of higher-level language abstractions, advanced quantum software debugging and visualization tools, and the exploration of distributed quantum computations that leverage the heterogeneity of quantum hardware.
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