Acta Optica Sinica, Volume. 41, Issue 9, 0901001(2021)
Observation of Aircraft Wake Vortex Based on Coherent Doppler Lidar
[1] Gerz T, Holzäpfel F, Darracq D et al. Commercial aircraft wake vortices[J]. Progress in Aerospace Sciences, 38, 181-208(2002).
[3] Hallock J N, Greene G C, Tittsworth J et al. Use of simple models to determine wake vortex categories for new aircraft (invited). [C]∥7th AIAA Atmospheric and Space Environments Conference, June 22-26, 2015, Dallas, TX. Reston, Virginia: AIAA, 3172(2015).
[4] Holzäpfel F, Schwarz C, Dengler K et al. Prediction of dynamic pairwise wake vortex separations for approach and landing. [C]∥3rd AIAA Atmospheric Space Environments Conference, June 27-30, 2011, Honolulu, Hawaii, USA. Reston, Virginia: AIAA, 3037(2011).
[5] Treve V, Rooseleer F. RECAT-EU proposal, validation and consultation[R]. Brétigny: Eurocontrol Experimental Centre(2014).
[7] Cheng J L, Hoff A, Tittsworth J et al. The development of wake turbulence re-categorization in the United States. [C]∥8th AIAA Atmospheric and Space Environments Conference, June 13-17, 2016, Washington, D. C. Reston, Virginia: AIAA, 3434(2016).
[13] Köpp F, Smalikho I, Rahm S et al. Characterization of aircraft wake vortices by multiple-lidar triangulation[J]. AIAA Journal, 41, 1081-1088(2003).
[15] Rahm S, Smalikho I, Köpp F et al. Characterization of aircraft wake vortices by airborne coherent Doppler lidar[J]. Journal of Aircraft, 44, 799-805(2007).
[19] Jacob D, Lai D Y, Pruis M J et al. Assessment of WakeMod 4: a new standalone wake vortex algorithm for estimating circulation strength and position. [C]∥7th AIAA Atmospheric and Space Environments Conference, June 22-26, 2015, Dallas, TX. Reston, Virginia: AIAA, 3176(2015).
[20] Jacob D, Lai D, Delisi D et al. Assessment of lockheed Martin's aircraft wake vortex circulation estimation algorithms using simulated lidar data. [C]∥3rd AIAA Atmospheric Space Environments Conference, June 27-30, Honolulu, Hawaii. Reston, Virginia: AIAA, 3196(2011).
[23] Hallermeyer A, Bouteyre A D, Valla M et al. Development and assessment of a wake vortex characterization algorithm based on a hybrid LIDAR signal processing. [C]∥8th AIAA Atmospheric and Space Environments Conference, June 13-17, 2016, Washington, D. C. Reston, Virginia: AIAA, 3272(2016).
[26] Smalikho I N. Taking into account the ground effect on aircraft wake vortices when estimating their circulation from lidar measurements[J]. Atmospheric and Oceanic Optics, 32, 686-700(2019).
[27] Gao H, Li J B, Chan P W et al. Parameter-retrieval of dry-air wake vortices with a scanning Doppler Lidar[J]. Optics Express, 26, 16377-16392(2018).
[31] Zhai X C, Wu S H, Liu B Y et al. Doppler lidar investigation of wind turbine wake characteristics and atmospheric turbulence under different surface roughness[J]. Optics Express, 25, A515-A529(2017).
[35] Burnham D C, Hallock J N. Chicago monostatic acoustic vortex sensing system: volume IV: wake vortex decay Cambridge,[R]. MA: Transportation systems Center(1982).
[36] Holzäpfel F, Gerz T, Köpp F et al. Strategies for circulation evaluation of aircraft wake vortices measured by lidar[J]. Journal of Atmospheric and Oceanic Technology, 20, 1183-1195(2003).
[38] Harvey J K, Perry F J. Flowfield produced by trailing vortices in the vicinity of the ground[J]. AIAA Journal, 9, 1659-1660(1971).
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Xiaoye Wang, Songhua Wu, Xiaoying Liu, Jiaping Yin, Weijun Pan, Xuan Wang. Observation of Aircraft Wake Vortex Based on Coherent Doppler Lidar[J]. Acta Optica Sinica, 2021, 41(9): 0901001
Category: Atmospheric Optics and Oceanic Optics
Received: Nov. 2, 2020
Accepted: Dec. 2, 2020
Published Online: May. 8, 2021
The Author Email: Wu Songhua (wush@ouc.edu.cn)