Advances and Prospects of Laser Measurement Technology for Air Motion Parameters（Invited）

Yazhou YUE; Bin LI; Hongjie LEI

doi:10.3788/gzxb20225104.0428001

[1] Yuefeng LI. Design and implementation of digital air data computer(2012).

[2] Feifei ZHU. Design of air data measurement system for small UAVs(2014).

[3] R M MUNIOZ, H W MOCKER, L KOEHLER. Airborne laser Doppler velocimeter. Applied Optics, 13, 2890-2898(1974).

[4] E S ANTHONY. Optical velocity sensor for air data applications(1991).

[5] T RUSSELL, G H JAMES, C S BRUCE et al. Airborne lidar wind detection at 2 μm(1995).

[6] Liang XIONG, Yiming LIU, Qiaoping HUANG. Research progress in air data sensor technology for attack helicopter. Transducer and Microsystem Technologies, 34, 5-8(2015).

[7] Youshi SUN. Progress of optical air data measurement systems. Measurement & Control Technology, 29, 6-9(2010).

[8] H W MOCKER, T J WAGENER. Laser Doppler optical air-data system: feasibility demonstration and systems specifications. Applied Optics, 33, 6457-6471(1994).

[9] Bin LI, Hongjie LEI. Analysis of data inversion accuracy of airborne optical air data system. Infrared and Laser Engineering, 50, 20200429(2021).

[10] L KRISTENSEN, D LENSCHOW. An airborne laser air motion sensing system. part II: design criteria and measurement possibilities. Journal of Atmospheric and Oceanic Technology, 4, 128-138(1987).

[11] R KEELER, R SERAFIN, R SCHWIESOW et al. Anairborne laser air motion sensing system. part I: concept and preliminary experiment. Journal of Atmospheric and Oceanic Technology, 4, 113-127(1987).

[12] K B RODNEY. Recent flight test results of optical air data techniques(1993).

[13] M PRIYAVADAN, A D ELIZABETH, C D DANIEL. LandSafe precision flight instrumentation system: the DVE solution(2012).

[14] M C LOREN, Y T SHOOU, O MARTIN. Optical air data systems and methods.

[15] M C LOREN, Y T SHOOU, O MARTIN. Optical air data systems and methods.

[16] M C LOREN, O MARTIN, S W CARL. Optical air data systems and methods.

[17] M C LOREN, Y T SHOOU, E A PHILLIP. Optical air data systems and methods.

[18] T J PETER, B W CHRISTOPHER, L SCOTT et al. Molecular Optical Air Data System (MOADS)(2001).

[19] C B WATKINS, C J RICHEY, P TCHORYK et al. Molecular Optical Air Data System (MOADS) flight experiment(2003).

[20] B W CHRISTOPHER, J R CHARLES, T PETE et al. Molecular Optical Air Data System (MOADS) prototype II(2004).

[21] Yingjian LIANG, Yunqiao MEI, Liyuan CHENG et al. Research on optical air data system based on Mie scattering. Measurement & Control Technology, 34, 32-34(2015).

[22] Xiaowei WANG, Yingjian LIANG, Xiang LI et al. Research of low-airspeed measurement based on optical Doppler frequency shift. Laser Technology, 40, 629-632(2016).

[23] Yanzhi LONG, Yingjian LIANG, Qiapping HUANG et al. Design of optical airspeed measurement system based on Doppler shift. Journal of Beijing University of Aeronautics and Astronautics, 44, 2521-2527(2018).

[24] Bin LI, Hongjie LEI, Wenhua JIN et al. Approach for measuring the optimal local optical power of coherent detection system (invited). Acta Photonica Sinica, 50, 1004005(2021).

[25] Huayong LIU, Li LIU, Fangfei CAO. Reference-air-data-boom method for air data svstem calibrations. Journal of Experiments in Fluid Mechanics, 27, 91-94(2013).

[27] L M RICK. Flight test results from a low-power Doppler optical air data sensor(1995).

[28] Lu QIU, Feizhou QU, Huihui HUI. Research on applications of airborne laser anemometry in air data calibration. Aeronautical Science & Technology, 30, 32-36(2019).

[29] K B ROEDNEY, W J HENK. Optical air flow measurements in flight.

[30] M J VERBEEK, H W JENTINK. Optical air data system flight testing, 2012-068.

[31] B AUGERE, B BESSON, D FLEURY et al. 1.5m lidar anemometer for true air speed, angle of sideslip and angle of attack measurements onboard piaggio P180 aircraft. Measurement Science and Technology, 27, 054002(2016).

[32] Hongna JIANG, Hongwei JIANG, Xue BAI. Research and application of airborne optical atmospheric data system. Foreign Electronic Measurement Technology, 40, 146-149(2021).

[34] Xiaodong JIA. Development of 1.55μm coherent lidar for wind sensing(2015).

[35] FAA . TSO-C117a Airbone wind shear warning and escape guidance system for tansport airplanes(1996).

[36] M S SCOTT, R DIRK, P S MICHAEL. Optical fiber-based laser remote sensor for airborne measurement of wind velocity and turbulence. Applied Optics, 50, 842-851(2011).

[37] P S NIKOLAUS, R WOLFGANG, P THOMAS et al. The AWIATOR airborne LIDAR turbulence sensor. Aerospace Science and Technology, 11, 546-552(2007).

[38] P S NIKOLAUS, P THOMAS, R WOLFGANG. Airborne lidar for automatic feed forward control of turbulent in-flight phenomena. Journal of Aircraft, 47, 392-403(2010).

[39] V PATRICK, W MARTIN, E GERHARD et al. Airborne forward-pointing UV Rayleigh lidar for remote clear air turbulence detection:system design and performance. Applied Optics, 55, 9314-9328(2016).

[40] O KLIEBISCH, P MAHNKE. Real-time laser Doppler anemometry for optical air data applications in low aerosol environments. Review of Scientific Instruments, 91, 095106(2020).

[41] Dalong WANG. Signal detection and retrieval algorithm for rotational raman temperature lidar of absolute remote sensing(2017).

[42] G BURDGE, G DEIBNER, J SHAPRIO et al. Quantum sensors program(2009).

[43] Z DUTTON, J H SHAPIRO, S GUHA. LADAR resolution improvement using receivers enhanced with squeezed-vacuum injection and phase-sensitive amplification. Journal of the Optical Society of America B, 27, 63-72(2010).

[44] Fei FENG, Jiangmeng XU, jingting MA et al. Quantum lidar based on squeezed states of light. Acta Photonica Sinica, 46, 0527001(2017).

[45] Jiandong ZHANG, Zijing ZHANG, Yuan ZHAO et al. Super-sensitivity interferometric quantum lidar with squeezedvacuum injection. Infrared and Laser Engineering, 46, 0730002(2017).

[46] Li GAO, Xiaoli ZHANG, Jingting MA et al. Quantum enhanced Doppler Lidar based on integrated quantum squeezed light source(Invited). Infrared and Laser Engineering, 50, 20210031(2021).

[47] Mingjia SHANGGUAN. Laser remote sensing with 1.5μm single photon detectors(2015).

[48] M SHCHERBATENKO, Y LOBANOV, A SEMENOV et al. Potential of a superconducting photon counter for heterodyne detection at the telecommunication wavelength. Optics Express, 24, 30474-30484(2016).