Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation

Sander Hartjes; Marco van Hellenberg Hubar; H.G. Visser

doi:10.1007/978-3-319-65283-2_21

Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation

Sander Hartjes, Marco van Hellenberg Hubar, H.G. Visser

Air Transport & Operations

Research output: Chapter in Book/Conference proceedings/Edited volume › Chapter › Scientific › peer-review

Abstract

In this paper a tool is developed that optimizes the trajectories of multiple airliners that seek to join in formation to minimize overall fuel consumption or Direct Operating Cost (DOC). The developed optimization framework relies on optimal control theory to solve the multiple-phase optimization problem associated to flight formation assembly. A reduced-order point-mass formulation is employed for modelling of the aircraft dynamics within an extended flight formation, and of the solo flight legs that connect the flight formation to the origin and destination airports. When in formation, a discount factor is applied to simulate a reduction in the induced drag of the trailing aircraft. Using the developed tool a case study has been conducted pertaining to the assembly of two-aircraft formation flights across the North-Atlantic. Results are presented to illustrate the synthesis of the formation trajectories and to demonstrate the potential for reducing fuel and operating cost. The results of the various numerical experiments show that formation flight can lead to significant reductions in fuel consumption compared to flying solo, even when the original trip times are maintained. Also, the results clearly reveal how the performance and the characteristics of the flight formation mission - notably the location of rendezvous and splitting points - are affected when one aircraft seeking to join the formation suffers a departure delay.

Original language	English
Title of host publication	Advances in Aerospace Guidance, Navigation and Control
Subtitle of host publication	Selected Papers of the Fourth CEAS Specialist Conference on Guidance, Navigation and Control Held in Warsaw, Poland, April 2017
Editors	Bogusław Dołęga, Robert Głębocki, Damian Kordos, Marcin Żugaj
Publisher	Springer
Pages	389-405
ISBN (Electronic)	978-3-319-65283-2
ISBN (Print)	978-3-319-65282-5
DOIs	https://doi.org/10.1007/978-3-319-65283-2_21
Publication status	Published - 2018
Event	4th CEAS Specialist Conference on Guidance, Navigation and Control - Warsaw, Poland Duration: 25 Apr 2017 → 27 Apr 2017 Conference number: 4 http://eurognc.prz.edu.pl/

Conference

Conference	4th CEAS Specialist Conference on Guidance, Navigation and Control
Abbreviated title	Euro GNC 2017
Country/Territory	Poland
City	Warsaw
Period	25/04/17 → 27/04/17
Internet address	http://eurognc.prz.edu.pl/

Keywords

Aerospace
Air And Space
Aircraft
Guidance
Missile
Motion Planning
Multi-vehicle
Rotorcraft
Spacecraft
Transportatin
Unmanned Air-Vehicle

Access to Document

10.1007/978-3-319-65283-2_21

Cite this

Hartjes, S., van Hellenberg Hubar, M., & Visser, H. G. (2018). Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation. In B. Dołęga, R. Głębocki, D. Kordos, & M. Żugaj (Eds.), Advances in Aerospace Guidance, Navigation and Control: Selected Papers of the Fourth CEAS Specialist Conference on Guidance, Navigation and Control Held in Warsaw, Poland, April 2017 (pp. 389-405). Springer. https://doi.org/10.1007/978-3-319-65283-2_21

Hartjes, Sander ; van Hellenberg Hubar, Marco ; Visser, H.G. / Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation. Advances in Aerospace Guidance, Navigation and Control: Selected Papers of the Fourth CEAS Specialist Conference on Guidance, Navigation and Control Held in Warsaw, Poland, April 2017. editor / Bogusław Dołęga ; Robert Głębocki ; Damian Kordos ; Marcin Żugaj. Springer, 2018. pp. 389-405

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title = "Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation",

abstract = "In this paper a tool is developed that optimizes the trajectories of multiple airliners that seek to join in formation to minimize overall fuel consumption or Direct Operating Cost (DOC). The developed optimization framework relies on optimal control theory to solve the multiple-phase optimization problem associated to flight formation assembly. A reduced-order point-mass formulation is employed for modelling of the aircraft dynamics within an extended flight formation, and of the solo flight legs that connect the flight formation to the origin and destination airports. When in formation, a discount factor is applied to simulate a reduction in the induced drag of the trailing aircraft. Using the developed tool a case study has been conducted pertaining to the assembly of two-aircraft formation flights across the North-Atlantic. Results are presented to illustrate the synthesis of the formation trajectories and to demonstrate the potential for reducing fuel and operating cost. The results of the various numerical experiments show that formation flight can lead to significant reductions in fuel consumption compared to flying solo, even when the original trip times are maintained. Also, the results clearly reveal how the performance and the characteristics of the flight formation mission - notably the location of rendezvous and splitting points - are affected when one aircraft seeking to join the formation suffers a departure delay.",

keywords = "Aerospace, Air And Space , Aircraft, Guidance , Missile , Motion Planning , Multi-vehicle , Rotorcraft , Spacecraft, Transportatin, Unmanned Air-Vehicle ",

author = "Sander Hartjes and {van Hellenberg Hubar}, Marco and H.G. Visser",

year = "2018",

doi = "10.1007/978-3-319-65283-2_21",

language = "English",

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booktitle = "Advances in Aerospace Guidance, Navigation and Control",

publisher = "Springer",

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Hartjes, S, van Hellenberg Hubar, M & Visser, HG 2018, Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation. in B Dołęga, R Głębocki, D Kordos & M Żugaj (eds), Advances in Aerospace Guidance, Navigation and Control: Selected Papers of the Fourth CEAS Specialist Conference on Guidance, Navigation and Control Held in Warsaw, Poland, April 2017. Springer, pp. 389-405, 4th CEAS Specialist Conference on Guidance, Navigation and Control, Warsaw, Poland, 25/04/17. https://doi.org/10.1007/978-3-319-65283-2_21

Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation. / Hartjes, Sander; van Hellenberg Hubar, Marco; Visser, H.G.
Advances in Aerospace Guidance, Navigation and Control: Selected Papers of the Fourth CEAS Specialist Conference on Guidance, Navigation and Control Held in Warsaw, Poland, April 2017. ed. / Bogusław Dołęga; Robert Głębocki; Damian Kordos; Marcin Żugaj. Springer, 2018. p. 389-405.

Research output: Chapter in Book/Conference proceedings/Edited volume › Chapter › Scientific › peer-review

TY - CHAP

T1 - Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation

AU - Hartjes, Sander

AU - van Hellenberg Hubar, Marco

AU - Visser, H.G.

N1 - Conference code: 4

PY - 2018

Y1 - 2018

N2 - In this paper a tool is developed that optimizes the trajectories of multiple airliners that seek to join in formation to minimize overall fuel consumption or Direct Operating Cost (DOC). The developed optimization framework relies on optimal control theory to solve the multiple-phase optimization problem associated to flight formation assembly. A reduced-order point-mass formulation is employed for modelling of the aircraft dynamics within an extended flight formation, and of the solo flight legs that connect the flight formation to the origin and destination airports. When in formation, a discount factor is applied to simulate a reduction in the induced drag of the trailing aircraft. Using the developed tool a case study has been conducted pertaining to the assembly of two-aircraft formation flights across the North-Atlantic. Results are presented to illustrate the synthesis of the formation trajectories and to demonstrate the potential for reducing fuel and operating cost. The results of the various numerical experiments show that formation flight can lead to significant reductions in fuel consumption compared to flying solo, even when the original trip times are maintained. Also, the results clearly reveal how the performance and the characteristics of the flight formation mission - notably the location of rendezvous and splitting points - are affected when one aircraft seeking to join the formation suffers a departure delay.

AB - In this paper a tool is developed that optimizes the trajectories of multiple airliners that seek to join in formation to minimize overall fuel consumption or Direct Operating Cost (DOC). The developed optimization framework relies on optimal control theory to solve the multiple-phase optimization problem associated to flight formation assembly. A reduced-order point-mass formulation is employed for modelling of the aircraft dynamics within an extended flight formation, and of the solo flight legs that connect the flight formation to the origin and destination airports. When in formation, a discount factor is applied to simulate a reduction in the induced drag of the trailing aircraft. Using the developed tool a case study has been conducted pertaining to the assembly of two-aircraft formation flights across the North-Atlantic. Results are presented to illustrate the synthesis of the formation trajectories and to demonstrate the potential for reducing fuel and operating cost. The results of the various numerical experiments show that formation flight can lead to significant reductions in fuel consumption compared to flying solo, even when the original trip times are maintained. Also, the results clearly reveal how the performance and the characteristics of the flight formation mission - notably the location of rendezvous and splitting points - are affected when one aircraft seeking to join the formation suffers a departure delay.

KW - Aerospace

KW - Air And Space

KW - Aircraft

KW - Guidance

KW - Missile

KW - Motion Planning

KW - Multi-vehicle

KW - Rotorcraft

KW - Spacecraft

KW - Transportatin

KW - Unmanned Air-Vehicle

U2 - 10.1007/978-3-319-65283-2_21

DO - 10.1007/978-3-319-65283-2_21

M3 - Chapter

SN - 978-3-319-65282-5

SP - 389

EP - 405

BT - Advances in Aerospace Guidance, Navigation and Control

A2 - Dołęga, Bogusław

A2 - Głębocki, Robert

A2 - Kordos, Damian

A2 - Żugaj, Marcin

PB - Springer

T2 - 4th CEAS Specialist Conference on Guidance, Navigation and Control

Y2 - 25 April 2017 through 27 April 2017

ER -

Hartjes S, van Hellenberg Hubar M, Visser HG. Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation. In Dołęga B, Głębocki R, Kordos D, Żugaj M, editors, Advances in Aerospace Guidance, Navigation and Control: Selected Papers of the Fourth CEAS Specialist Conference on Guidance, Navigation and Control Held in Warsaw, Poland, April 2017. Springer. 2018. p. 389-405 doi: 10.1007/978-3-319-65283-2_21

Multiple-Phase Trajectory Optimization for Formation Flight in Civil Aviation

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