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Modeling and Analysis of Gate to Gate Flight Process Based on SysML in Commercial Aircraft

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Proceedings of the International Conference on Aerospace System Science and Engineering 2020 (ICASSE 2020)

Abstract

The design and development of commercial aircraft is a complex system engineering. At present, operational scenario analysis is gradually used for aircraft function identification and requirement capture. In the analysis process, the time dimension factors of the aircraft in civil aviation operations must be considered, that is, the complete process of aircraft operation must be defined. Guided by the idea of system modeling, this paper presents research on the modeling method of Gate to Gate flight process. The basic elements and hierarchical division of flight process models are constructed. Finally, the paper proposes the method and procedure of establishing Gate to Gate model based on SysML. Based on the previously proposed method and a complete description of commercial aircraft operation process, this paper establishes a summary behaviour model of aircraft's Gate to Gate flight process, covering the preparation before takeoff, push back, taxi out, taxi before takeoff, takeoff roll, takeoff, climb, ocean-based cruise, land-based cruise, descent, approach, final approach, landing, taxi after landing, and taxi to aircraft stand. SysML is used to model the flight process, which includes aircraft itself, ATC, AOC, airport tower and other models. The model is drawn to form Use Case diagrams, Activity diagrams, State Machine diagrams, and Sequence diagrams under each flight phase. The model mainly focuses on the collaborative process between aircraft and various stakeholders, such as the collaborative interaction process between aircraft and ATC, AOC, as well as the collaborative interaction process between aircraft and airport tower during the takeoff and landing phase. This paper provides a method to describe the flight process systematically and graphically. It can also be used as an exploration of function identification and requirements capture methods.

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References

  1. Qiao WF, Li ZQ, Huang S, Yao ZC (2015) Research on model-based integrated design of civil aircraft. Aviat Manufact Technol 2015(04):72–77

    Google Scholar 

  2. Xu YZ (2018) Application of model-based requirements-function-logic-physical system engineering method in aeronautical system design. Chinese Aeronaut Soc. Proceedings of the 8th China aeronautical society youth science and technology forum 2018: 1386–1391

    Google Scholar 

  3. Zhang SJ, Li ZQ, Hai XH et al (2018) Design of safety critical system for civil aircraft based on MBSE. Chin Sci: Tech Sci 2018(3):299–311

    Google Scholar 

  4. Mei Q, Huang D, Lu Y (2018) Design method of civil aircraft functional architecture based on MBSE. J Beijing Univer Aeronaut Astronaut 2019 45(05): 1042–1051

    Google Scholar 

  5. Ren BX, Lu Y, Fu S, Huang D (2019) Identification and confirmation of civil aircraft functional requirements based on MBSE. Syst Eng Elect Technol 41(09): 2016–2024

    Google Scholar 

  6. Zhu HY (2019) Research on the evaluation method of the minimum crew workload of civil aircraft. Int Combust Engine Parts 2019(08):185–187

    Google Scholar 

  7. Lenny D (2014) SysML distilled: A brief guide to the systems modelling language, 1st edn. Addison-Wesley Professional

    Google Scholar 

  8. Graves H, Bijan Y (2011) Using formal methods with SysML in aerospace design and engineering. Ann Math Artif Intell 2011(63):53–102

    Article  MathSciNet  Google Scholar 

  9. Friedenthal S (2015) A practical guide to SysML: the systems modeling language, 2nd edn. Morgan Kaufmann

    Google Scholar 

  10. Weilkiens T (2008) Systems engineering with SysML/UML. Burlington: Morgan Kanfmann SMG Press, pp 18–22

    Google Scholar 

  11. Holt J, Perry S (2008) SysML for systems engineering, 2nd edn: A model-based approach[M]. London: The Institution of Engineering and Technology, pp 121–222

    Google Scholar 

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Acknowledgements

The project is supported by National Program on Key Basic Research Project (2014CB744903), National Natural Science Foundation of China (61673270), New Young Teachers Launch Program of Shanghai Jiaotong University (20X100040036), Shanghai Pujiang Program (16PJD028), Shanghai Industrial Strengthening Project (GYQJ-2017-5-08), Shanghai Science and Technology Committee Research Project (17DZ1204304) and Shanghai Engineering Research Center of Civil Aircraft Flight Testing.

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Correspondence to Miao Wang .

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Li, H., Wang, M., Xiao, G., Wang, G., Tian, B., Chen, Z. (2021). Modeling and Analysis of Gate to Gate Flight Process Based on SysML in Commercial Aircraft. In: Jing, Z., Zhan, X. (eds) Proceedings of the International Conference on Aerospace System Science and Engineering 2020. ICASSE 2020. Lecture Notes in Electrical Engineering, vol 680. Springer, Singapore. https://doi.org/10.1007/978-981-33-6060-0_18

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  • DOI: https://doi.org/10.1007/978-981-33-6060-0_18

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  • Publisher Name: Springer, Singapore

  • Print ISBN: 978-981-33-6059-4

  • Online ISBN: 978-981-33-6060-0

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