TY - GEN
T1 - Function to Form Mapping and Search for Civil Aeroplane Energy Efficiency
AU - Joksimovic, Aleksandar
AU - Brazier, Frances
AU - Vingerhoeds, Rob
AU - Carbonneau, Xavier
PY - 2021
Y1 - 2021
N2 - The contemporary debate on the need for the civil aeronautical industry to reconcile its global warming impact and the continuous air traffic growth is gaining in prominence. While solutions exist to tackle different aspects of this complex problem individually, the core of the response lies in rethinking the conventional aeroplane architecture in order to reach new energy efficiency optima. This paper presents a function-to-form framework used for describing different aspects of architectural design of an aeroplane as technological system. Firstly, a brief overview of different existing ways to improve aeroplane architectures is given. With that background, a preliminary definition of multi-level system composition of an aeroplane is presented. A physics-based framework is then correlated to the Functional, Behavioural, Structural and Experiential requirement framework, in order to characterise the different physical phenomena experienced by an aeroplane for a single operating point. These provide basis for definition of a qualitative Figure of merit dubbed Integration Potential of an architecture, which serves as proxy for describing function-to-form mapping of aeroplane system architectures. Using both the historical, contemporary and projected tendencies of aeroplane technology advances, existence of an asymptotic limit of this parameter is inferred. This limit arguably indicates the extent to which it could still be possible to go in search for energy efficiency gains by virtue of system architecture design.
AB - The contemporary debate on the need for the civil aeronautical industry to reconcile its global warming impact and the continuous air traffic growth is gaining in prominence. While solutions exist to tackle different aspects of this complex problem individually, the core of the response lies in rethinking the conventional aeroplane architecture in order to reach new energy efficiency optima. This paper presents a function-to-form framework used for describing different aspects of architectural design of an aeroplane as technological system. Firstly, a brief overview of different existing ways to improve aeroplane architectures is given. With that background, a preliminary definition of multi-level system composition of an aeroplane is presented. A physics-based framework is then correlated to the Functional, Behavioural, Structural and Experiential requirement framework, in order to characterise the different physical phenomena experienced by an aeroplane for a single operating point. These provide basis for definition of a qualitative Figure of merit dubbed Integration Potential of an architecture, which serves as proxy for describing function-to-form mapping of aeroplane system architectures. Using both the historical, contemporary and projected tendencies of aeroplane technology advances, existence of an asymptotic limit of this parameter is inferred. This limit arguably indicates the extent to which it could still be possible to go in search for energy efficiency gains by virtue of system architecture design.
KW - Aircraft design
KW - Energy efficiency
KW - Function-to-form mapping
KW - Systems architecture
UR - http://www.scopus.com/inward/record.url?scp=85119097200&partnerID=8YFLogxK
U2 - 10.1109/ISSE51541.2021.9582490
DO - 10.1109/ISSE51541.2021.9582490
M3 - Conference contribution
AN - SCOPUS:85119097200
T3 - ISSE 2021 - 7th IEEE International Symposium on Systems Engineering, Proceedings
BT - ISSE 2021 - 7th IEEE International Symposium on Systems Engineering, Proceedings
PB - IEEE
T2 - 7th IEEE International Symposium on Systems Engineering, ISSE 2021
Y2 - 13 September 2021 through 15 September 2021
ER -