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Designing Noise-Minimal Rotorcraft Approach Trajectories

Authors:

Matthew Johnson,

K. Brent Venable,

James LindseyAuthors Info & Claims

ACM Transactions on Intelligent Systems and Technology (TIST), Volume 7, Issue 4

Article No.: 58, Pages 1 - 25

https://doi.org/10.1145/2838738

Published: 25 April 2016 Publication History

Abstract

NASA and the international aviation community are investing in the development of a commercial transportation infrastructure that includes the increased use of rotorcraft, specifically helicopters and civil tilt rotors. However, there is significant concern over the impact of noise on the communities surrounding the transportation facilities. One way to address the rotorcraft noise problem is by exploiting powerful search techniques coming from artificial intelligence to design low-noise flight profiles that can be then validated though field tests. This article investigates the use of discrete heuristic search methods to design low-noise approach trajectories for rotorcraft. Our work builds on a long research tradition in trajectory optimization using either numerical methods or discrete search. Novel features of our approach include the use of a discrete search space with a resolution that can be varied, and the coupling of search with a robust simulator to evaluate candidates. The article includes a systematic comparison of different search techniques; in particular, in the experiments, we are able to do a trade study that compares complete search algorithms such as A^* with faster but approximate methods such as local search.

References

[1]

E. Atkins and M. Xue. 2004. Noise-sensitive final approach trajectory optimization for runway-independent aircraft. Journal of Aerospace Computation, Information and Communication 1 (2004), 269--287.

[2]

J. T. Betts. 1998. Survey of numerical methods for trajectory optimization. Journal of Guidance, Control and Dynamics 21, 2 (1998), 193--207.

[3]

A. Booker, J. E. Dennis, P. D. Frank, D. B. Serafini, V. Torczon, and M. W. Trosset. 1998. A Rigorous Framework for Optimization of Expensive Functions by Surrogates. Technical Report 98-47. National Aeronautics and Space Administration.

Digital Library

[4]

A. E. Bryson and Y.-C. Ho. 1975. Applied Optimal Control. Hemisphere Publishing Corp., New York.

[5]

P. Cheng and S. M. Lavalle. 2002. Resolution complete rapidly-exploring random trees. In Proceedings of the IEEE International Conference on Robotics and Automation. 267--272.

[6]

D. A. Conner, C. L. Burley, and C. D. Smith. 2006. Flight acoustic testing and data acquisition for the rotor noise model (RNM). In Proceedings of the 62nd Annual Forum of the American Helicopter Society. 1--17.

[7]

F. Fahroo and M. Ross. 2007. A perspective on methods for trajectory optimization. In AIAA/AAS Astrodynamics Specialist Conference and Exhibit, Monterey, California.

[8]

Federal Aviation Administration. 2007. Environmental Desk Reference for Airport Actions. Technical Report.

[9]

D. Ferguson and A. (T.) Stentz. 2005. The Field D^&ast; Algorithm for Improved Path Planning and Replanning in Uniform and Non-Uniform Cost Environments. Technical Report CMU-RI-TR-05-19. Robotics Institute, Pittsburgh, Pennsylvania.

[10]

G. Goplan, M. Xue, E. Atkins, and F. H. Schmitz. 2003. Longitudinal-plane simultaneous non-interfering approach trajectory design for noise minimization. In Proceedings of the 59th AHS International Forum and Technology Display. 1--18.

[11]

H. H. Hoos and T. Stutzle. 2004. Stochastic Local Search: Foundations and Applications. Elsevier - Morgan Kaufmann.

Digital Library

[12]

H. J. Horn. 1965. Application of an Iterative Guidance Mode to a Lunar Landing. National Aeronautics and Space Administration.

[13]

L. E. Kavraki, M. N. Kolountzakis, and J.-C. Latombe. 1998. Analysis of probabilistic roadmaps for path planning. IEEE Trans. Robotics and Automation 14, 1 (1998), 166--171.

[14]

S. M. LaValle. 2006. Planning Algorithms. Cambridge University Press, Cambridge, UK. http://planning.cs.uiuc.edu/.

Digital Library

[15]

S. M. LaValle, M. S. Branicky, and S. R. Lindemann. 2004. On the relationship between classical grid search and probabilistic roadmaps. International Journal of Robotics Research 23, 7-8 (2004), 673--692.

[16]

O. J. Mengshoel. 2008. Understanding the role of noise in stochastic local search: Analysis and experiments. Artificial Intelligence 172, 8-9 (2008), 955--990.

Digital Library

[17]

R. A. Morris, M. Donini, K. B. Venable, and M. Johnson. 2013. Designing quiet rotorcraft landing trajectories with probabilistic road maps. In Proceedings of the Scheduling and Planning Applications Workshop (SPARK’13). Rome, Italy.

[18]

R. A. Morris, K. B. Venable, and J. Lindsay. 2012a. Automated design of noise-minimal, safe rotorcraft trajectories. In Proceedings of the 68th American Helicopter Society Annual Forum & Technology Display.

[19]

R. A. Morris, K. B. Venable, and J. Lindsay. 2012b. Simulation to support local search in trajectory optimization planning. In Proceedings of the IEEE 2012 Aerospace Conference.

[20]

R. A. Morris, K. B. Venable, M. Pegoraro, and J. Lindsay. 2012c. Local search for designing noise-minimal rotorcraft approach trajectories. In Proceedings of the Twenty-Fourth Conference on Innovative Applications of Artificial Intelligence (IAAI'12).

Digital Library

[21]

Federal Interagency Committee on Noise. 1992. 1992 Federal Interagency Commitee on Noise (FICON) Report-Federal Agency Review of Selected Airport Noise Analysis Issues. Technical Report.

[22]

S. L. Padula, C. L. Burley, D. D. Boyd Jr., and M. A. Marcolini. 2009. Design of Quiet Rotorcraft Approach Trajectories. Technical Report NASA/TM-215771. Langley Research Center.

[23]

J. Page, C. Wilmer, and K. J. Plotkin. 2007. Rotorcraft Noise Model Technical Reference and User Manual (Version 7). Technical Report WR 07-04. Wyle Laboratories for NASA Langley Research Center.

[24]

P. O. Pettersson and P. Doherty. 2006. Probabilistic roadmap based path planning for an autonomous unmanned helicopter. Journal of Intelligent and Fuzzy Systems 17, 4 (2006), 395--405.

Digital Library

[25]

B. W.-C. Sim, F. H. Schmitz, and G. Gopalan. 2002. Flight-path management/control methodology to reduce helicopter blade-vortex interaction noise. Journal of Aircraft 39, 2 (2002), 193--205.

[26]

K. B. Venable, R. A. Morris, M. Johnson, A. Mousavi, and N. Oza. 2014. A machine learning surrogate for rotorcraft noise optimization. In Proceedings of the Scheduling and Planning Applications Workshop (SPARK’14).

[27]

M. Xue. 2006. Real-Time Terminal Area Trajectory Planning for Runway Independent Aircraft. Ph.D. Dissertation. University of Maryland.

Digital Library

[28]

M. Xue and E. M. Atkins. 2006a. Noise-minimum runway-independent aircraft approach design for baltimore-washington international airport. Journal of Aircraft, American Institute of Aeronautics and Astronautics (AIAA) 43, 1 (2006), 39--51.

[29]

M. Xue and E. M. Atkins. 2006b. Terminal area trajectory optimization using simulated annealing. In Proceedings of the 44th AIAA Aerospace Sciences Meeting and Exhibit. AIAA, Reno, Nevada.

Cited By

Piao HYang SChen HLi JYu JPeng XYang XYang ZSun ZChang Y(2024)Discovering Expert-Level Air Combat Knowledge via Deep Excitatory-Inhibitory Factorized Reinforcement LearningACM Transactions on Intelligent Systems and Technology10.1145/365397915:4(1-28)Online publication date: 27-Mar-2024
https://dl.acm.org/doi/10.1145/3653979
Dieumegard PCafieri SDelahaye DHansman R(2023)Rotorcraft low-noise trajectories design: black-box optimization using surrogatesOptimization and Engineering10.1007/s11081-022-09781-w24:4(2475-2512)Online publication date: 20-Jan-2023
https://doi.org/10.1007/s11081-022-09781-w
Greenwood EBrentner KRau RTed Gan Z(2022)Challenges and opportunities for low noise electric aircraftInternational Journal of Aeroacoustics10.1177/1475472X221107377(1475472X2211073)Online publication date: 28-Jun-2022
https://doi.org/10.1177/1475472X221107377

Index Terms

Designing Noise-Minimal Rotorcraft Approach Trajectories
1. Computing methodologies
  1. Artificial intelligence
    1. Planning and scheduling
    2. Search methodologies
      1. Discrete space search
      2. Heuristic function construction

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AAAI'12: Proceedings of the Twenty-Sixth AAAI Conference on Artificial Intelligence

NASA and the international community are investing in the development of a commercial transportation infrastructure that includes the increased use of rotorcraft, specifically helicopters and civil tilt rotors. However, there is significant concern over ...
Noise Prediction for Maneuvering Rotorcraft
Unmanned Rotorcraft Systems

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Published In

cover image ACM Transactions on Intelligent Systems and Technology

ACM Transactions on Intelligent Systems and Technology Volume 7, Issue 4

Special Issue on Crowd in Intelligent Systems, Research Note/Short Paper and Regular Papers

July 2016

498 pages

ISSN:2157-6904

EISSN:2157-6912

DOI:10.1145/2906145

Editor:
Yu Zheng
Microsoft Research, China

Issue’s Table of Contents

Copyright © 2016 ACM.

© 2016 Association for Computing Machinery. ACM acknowledges that this contribution was authored or co-authored by an employee, contractor or affiliate of the United States government. As such, the United States Government retains a nonexclusive, royalty-free right to publish or reproduce this article, or to allow others to do so, for Government purposes only.

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 25 April 2016

Accepted: 01 October 2015

Revised: 01 August 2015

Received: 01 August 2014

Published in TIST Volume 7, Issue 4

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Cited By

Piao HYang SChen HLi JYu JPeng XYang XYang ZSun ZChang Y(2024)Discovering Expert-Level Air Combat Knowledge via Deep Excitatory-Inhibitory Factorized Reinforcement LearningACM Transactions on Intelligent Systems and Technology10.1145/365397915:4(1-28)Online publication date: 27-Mar-2024
https://dl.acm.org/doi/10.1145/3653979
Dieumegard PCafieri SDelahaye DHansman R(2023)Rotorcraft low-noise trajectories design: black-box optimization using surrogatesOptimization and Engineering10.1007/s11081-022-09781-w24:4(2475-2512)Online publication date: 20-Jan-2023
https://doi.org/10.1007/s11081-022-09781-w
Greenwood EBrentner KRau RTed Gan Z(2022)Challenges and opportunities for low noise electric aircraftInternational Journal of Aeroacoustics10.1177/1475472X221107377(1475472X2211073)Online publication date: 28-Jun-2022
https://doi.org/10.1177/1475472X221107377

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