TY - GEN
T1 - Insights on Quantum Software Functional Size Measurement
T2 - 2025 Global Congress on Emerging Technologies, GCET 2025
AU - Hacaloglu, Tuna
AU - Soubra, Hassan
AU - Adel, Youssef
AU - Bourque, Pierre
AU - Abran, Alain
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - The rapid evolution of quantum computing has led to growing interest in the development of systematic approaches to assess and manage quantum software. Among these, functional size measurement (FSM) offers a promising pathway for establishing metrics that can support project estimation, benchmarking, and quality assessment. This paper provides an overview of emerging efforts in quantum software functional size measurement with a focus on key concepts, challenges, and motivations. First, we examine the foundational principles of quantum computing in relation to the existing FSM methods, identifying both compatibilities and unique constraints. Building on this, we discuss the challenges that arise when applying FSM to quantum software, including the hardware-coupled nature of functionality, evolving semantics of data and measurement abstractions, gaps in tooling and standardization, and evolving role of FSM across the Noisy Intermediate-Scale Quantum (NISQ) and future faulttolerant eras. We then outline community-driven initiatives, such as the COSMIC Quantum Software Taskforce and the Fall 2024 Workshop, which highlight the increasing demand for structured measurement practices. By articulating these issues, this paper aims to present initial research efforts for quantum software functional size measurement and stimulate further exploration of measurement approaches that are both theoretically grounded and practically applicable in quantum software engineering.
AB - The rapid evolution of quantum computing has led to growing interest in the development of systematic approaches to assess and manage quantum software. Among these, functional size measurement (FSM) offers a promising pathway for establishing metrics that can support project estimation, benchmarking, and quality assessment. This paper provides an overview of emerging efforts in quantum software functional size measurement with a focus on key concepts, challenges, and motivations. First, we examine the foundational principles of quantum computing in relation to the existing FSM methods, identifying both compatibilities and unique constraints. Building on this, we discuss the challenges that arise when applying FSM to quantum software, including the hardware-coupled nature of functionality, evolving semantics of data and measurement abstractions, gaps in tooling and standardization, and evolving role of FSM across the Noisy Intermediate-Scale Quantum (NISQ) and future faulttolerant eras. We then outline community-driven initiatives, such as the COSMIC Quantum Software Taskforce and the Fall 2024 Workshop, which highlight the increasing demand for structured measurement practices. By articulating these issues, this paper aims to present initial research efforts for quantum software functional size measurement and stimulate further exploration of measurement approaches that are both theoretically grounded and practically applicable in quantum software engineering.
KW - COSMIC ISO 19761
KW - functional size measurement
KW - Quantum software
UR - https://www.scopus.com/pages/publications/105036389404
U2 - 10.1109/GCET68529.2025.11450896
DO - 10.1109/GCET68529.2025.11450896
M3 - Contribution to conference proceedings
AN - SCOPUS:105036389404
T3 - 2025 Global Congress on Emerging Technologies, GCET 2025
SP - 94
EP - 98
BT - 2025 Global Congress on Emerging Technologies, GCET 2025
A2 - Benkhelifa, Elhadj
A2 - Ghedira, Chirine
A2 - Gupta, Brij B.
A2 - Zhukabayeva, Tamara
A2 - Bani-Hani, Anoud
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 2 December 2025 through 5 December 2025
ER -