ANALYSIS OF THE ISSUES OF MODELING THE AIR TRAFFIC CONTROL PROCESS WITH INCREASING FLIGHT INTENSITY

Shukurova Saboxat Muratdjanovna; Rustamov Nozimjon  Samariddin o'g'li

The air traffic control (ATC) process is a complex and dynamic system that ensures the safe and efficient operation of aircraft in the airspace. The ATC process involves various actors, such as pilots, controllers, airports, airlines and regulators, who communicate and coordinate their actions through various systems and procedures. The ATC process is influenced by many factors, such as weather, traffic, technical conditions, human factors and others. The ATC process is also subject to changes and uncertainties, such as increasing demand for air travel, technological innovations, environmental regulations and security threats. The main contribution of this article is to provide a comprehensive and integrated approach for modeling the ATC process with an increase in the intensity of flights. The article demonstrates the applicability and usefulness of the proposed models for supporting decision-making and policy making in the field of air traffic management. The article also identifies the challenges and limitations of the current ATC process and suggests directions for future research and development.

Название журналаИнновацион технологиялар
Номер выпуска2023(Мaxsus son)
Количество просмотров 22

Ссылка в интернете

DOI

Дата создание в систему UzSCI 29-05-2024

Количество прочтений 22

Дата публикации 25-12-2023

Язык статьиIngliz

Страницы28-33

Ключевые слова

globalization

efficiency

flow

network

aircraft

air traffic

air traffic control

topology

runway

taxiway

English

The air traffic control (ATC) process is a complex and dynamic system that ensures the safe and efficient operation of aircraft in the airspace. The ATC process involves various actors, such as pilots, controllers, airports, airlines and regulators, who communicate and coordinate their actions through various systems and procedures. The ATC process is influenced by many factors, such as weather, traffic, technical conditions, human factors and others. The ATC process is also subject to changes and uncertainties, such as increasing demand for air travel, technological innovations, environmental regulations and security threats. The main contribution of this article is to provide a comprehensive and integrated approach for modeling the ATC process with an increase in the intensity of flights. The article demonstrates the applicability and usefulness of the proposed models for supporting decision-making and policy making in the field of air traffic management. The article also identifies the challenges and limitations of the current ATC process and suggests directions for future research and development.

Ключевые слова

globalization

efficiency

flow

network

aircraft

air traffic

air traffic control

topology

runway

taxiway

№ Имя автора Должность Наименование организации

1 Shukurova S.M. texnika fanlari bо‘yicha falsafa doktori (PhD), dotsent Toshkent davlat transport universiteti

2 Rustamov N.S. doktorant Toshkent davlat transport universiteti

№ Название ссылки

1 1. Zanin M., Lillo F., Patelli A. Structure and properties of the European Air Transport Network: a complex network analysis. // Journal of Transport Systems. 2013. - Vol. 17, No. 4. - pp. 180- 196.

2 2. A.A. Akhmedov. Modeling of the air traffic control process with an increase in the intensity of flights. - Tashkent: Tashkent State Technical University, 2023. - 180 p.

3 3. Wang Z., Zhang Y., Du G. Analysis of the resilience of Chinese air traffic management network using complex network theory. // Journal of Physics A: Mathematical and Theoretical. 2016. - Vol. 49, No. 22. - Article 225101.

4 4. Zhang R., Li M., Wang H. Multi-objective optimization of US air traffic management network based on complex network theory. // Expert Systems with Applications. 2019. - vol. 115. - pp. 462-474

5 5. Rytter A., Skorupski J. The concept of initial air traffic situation assessment as a stage of medium-term conflict detection. Procedia Eng. 2017, 187, pp. 420–424.

6 6. Gomes H.M., Barddal J.P., Enembreck F., Bifet A. A survey on ensemble learning for data stream classification. ACM Comput. Surv. 2017, 50, pp. 1–36

7 7. Mehmood Z., Asghar S. Customizing SVM as a base learner with adaboost ensemble to learn from multi-class problems: A hybrid approach adaboost-MSVM. Knowl. Based Syst. 2021, 217, 106845.

8 8. Rodríguez-Sanz Á., Andrada L.R. Managing airport capacity and demand: An economic approach. IOP Conf. Ser. Mater. Sci. Eng. 2022, 1226, 012024

9 9. Angélica Sousa da Mata. Complex Networks: a Mini-review. Brazilian Journal of Physics, Vol. 50, 2020, pp. 658-672. DOI: 10.1007/s13538-020-00772-9

10 10. Zhiyong Sun, Xiangyu Meng, Brian D.O. Coordination and Control of Complex Network Systems With Switching Topologies: A Survey. IEEE Transactions on Systems Man and Cybernetics Systems. 2020, pp. 1-16. DOI: 10.1109/TSMC.2019.2961753

11 11. Lun Li. Topologies of Complex Networks: Functions and Structures. California Institute of Technology. 2005, doi: 10.7907/9G3P-7F13.

12 12. Ranjan, E., Sanyal S., Talukdar P. ASAP: Adaptive Structure Aware Pooling for Learning Hierarchical Graph Representations. Proc. AAAI Conf. Artif. Intell. 2020, 34, 5470–5477.

13 13. Hamilton W., Ying R., Leskovec J. Inductive Representation Learning on Large Graphs. archive 2017, archive:1706.02216

В ожидании

№	Имя автора	Должность	Наименование организации
1	Shukurova S.M.	texnika fanlari bо‘yicha falsafa doktori (PhD), dotsent	Toshkent davlat transport universiteti
2	Rustamov N.S.	doktorant	Toshkent davlat transport universiteti

№	Название ссылки
1	1. Zanin M., Lillo F., Patelli A. Structure and properties of the European Air Transport Network: a complex network analysis. // Journal of Transport Systems. 2013. - Vol. 17, No. 4. - pp. 180- 196.
2	2. A.A. Akhmedov. Modeling of the air traffic control process with an increase in the intensity of flights. - Tashkent: Tashkent State Technical University, 2023. - 180 p.
3	3. Wang Z., Zhang Y., Du G. Analysis of the resilience of Chinese air traffic management network using complex network theory. // Journal of Physics A: Mathematical and Theoretical. 2016. - Vol. 49, No. 22. - Article 225101.
4	4. Zhang R., Li M., Wang H. Multi-objective optimization of US air traffic management network based on complex network theory. // Expert Systems with Applications. 2019. - vol. 115. - pp. 462-474
5	5. Rytter A., Skorupski J. The concept of initial air traffic situation assessment as a stage of medium-term conflict detection. Procedia Eng. 2017, 187, pp. 420–424.
6	6. Gomes H.M., Barddal J.P., Enembreck F., Bifet A. A survey on ensemble learning for data stream classification. ACM Comput. Surv. 2017, 50, pp. 1–36
7	7. Mehmood Z., Asghar S. Customizing SVM as a base learner with adaboost ensemble to learn from multi-class problems: A hybrid approach adaboost-MSVM. Knowl. Based Syst. 2021, 217, 106845.
8	8. Rodríguez-Sanz Á., Andrada L.R. Managing airport capacity and demand: An economic approach. IOP Conf. Ser. Mater. Sci. Eng. 2022, 1226, 012024
9	9. Angélica Sousa da Mata. Complex Networks: a Mini-review. Brazilian Journal of Physics, Vol. 50, 2020, pp. 658-672. DOI: 10.1007/s13538-020-00772-9
10	10. Zhiyong Sun, Xiangyu Meng, Brian D.O. Coordination and Control of Complex Network Systems With Switching Topologies: A Survey. IEEE Transactions on Systems Man and Cybernetics Systems. 2020, pp. 1-16. DOI: 10.1109/TSMC.2019.2961753
11	11. Lun Li. Topologies of Complex Networks: Functions and Structures. California Institute of Technology. 2005, doi: 10.7907/9G3P-7F13.
12	12. Ranjan, E., Sanyal S., Talukdar P. ASAP: Adaptive Structure Aware Pooling for Learning Hierarchical Graph Representations. Proc. AAAI Conf. Artif. Intell. 2020, 34, 5470–5477.
13	13. Hamilton W., Ying R., Leskovec J. Inductive Representation Learning on Large Graphs. archive 2017, archive:1706.02216