Performance Analysis and Flight Testing for Low Altitude Long Endurance Unmanned Aerial Vehicles

The objective of this paper is to study the performance of a low altitude long endurance UAV. One of the important aspects of performance analysis is the optimal speeds for maximum endurance and/or maximum range. With DATCOM method, although the drag coefficient of the UAV can be determined, the resulted maximum endurance is found to be much longer than the data obtained from the flight tests. The problem is caused by the landing gears of which the drag is not counted in the DATCOM analysis. To eliminate the error, by referring to results of flight tests, a correction method for the drag coefficient to include the effect of the landing gears is suggested and the optimal cruise speeds for the maximum endurance and the maximum range are determined accordingly. It is found that the speeds should be as slow as possible. This result is quite different from the typical case in which the optimal speed usually lies in between the minimum and the maximum possible ones.

並列關鍵字

Performance analysis ； Maximum endurance ； Maximum range

參考文獻

Martinez-Val, R. and Hernandez, C., “Preliminary design of a low speed, long endurance remote piloted vehicles (RPV) for civil applications,” Aircraft Design 2, 1999, pp. 167-182.

Goraj, Z., Frydrychewicz, A., and Winiecki, J., “Design concept of a high altitude long endurance unmanned aerial vehicle,” Aircraft Design – An International Journal 2, 1999, pp. 19-44.

Cestino, E., “Design of solar high altitude long endurance aircraft for multi payload and operations,” Aero. Sci. Tech., Vol. 10, No. 6, 2006, pp. 541-550.

Savla, K., Nehme, C., Temple, T., and Frazzoli, E., “On efficient cooperative strategies between humans and uavs in a dynamic environment,” in AIAA Conference on Guidance, Navigation and Control, Honolulu, HI, USA, 2008.

Dalamagkidis, K., Valavanis, K. P., and Piegl, L. A., “Current status and future perspectives for unmanned aircraft system operations in the US,” Journal of Intelligent and Robotic Systems, Vol. 52, No. 2, 2007, pp. 313-329.

延伸閱讀

胡琮琛（2021）。Research on the application of unmanned aerial vehicles to give priority to slope prevention and avoidance〔碩士論文，國立宜蘭大學〕。華藝線上圖書館。https://doi.org/10.6820/niu202100096
劉哲宇（2020）。Preliminary Design and Simulation ofUnmanned Aerial Vehicles (UAV)〔碩士論文，逢甲大學〕。華藝線上圖書館。https://doi.org/10.6341/fcu.M0791621
Chuang, F. C., & Tsai, Y. N. (2019). The Design of Unmanned Aerial Vehicle with Both Vertical Take-off And Landing and High Speed Level Flight Function. International Journal of Uncertainty and Innovation Research, 1(2), 167-176. https://www.airitilibrary.com/Article/Detail?DocID=P20190619001-201908-201908140006-201908140006-167-176
Hsiao, F. B., Lee, M. T., Chien, Y. H., Chang, W. Y., Payne, U. J., & Liu, T. L. (2003). The Development of a Low Cost Autonomous Surveillance Unmanned Aerial Vehicle System. 中國航空太空學會學刊, 35(4), 307-316. https://doi.org/10.6124/TAASRC.200312_35(4).01
Zikri, M. H., Gires, E., & Harithuddin, A. (2020). Range and Endurance Analysis of a Conceptual Lighter-than-air All-electric Unmanned Aerial Vehicle. Journal of Aeronautics, Astronautics and Aviation, 52(1), 1-13. https://doi.org/10.6125/JoAAA.202003_52(1).01

國際替代計量

Performance Analysis and Flight Testing for Low Altitude Long Endurance Unmanned Aerial Vehicles

全文下載

主題瀏覽