曹长庆
最后更新时间:..
主要研究方向:
1.光电检测、目标识别技术:相干探测技术、大型目标光电特性外场检测、光电特性多数据融合目标识别技术
2.光通信:星间、星地相干光通信技术
3.光电成像及人工智能图像处理
4.强激光:时空特性检测及机理研究
最新动态:
1、闫旭,“Modulation Format Identification Technology Based on a Searching Cluster Boundary Clustering Algorithm”,Journal of Lightwave Technology, DOI : 10.1109/JLT.2022.3212042, 2023.1,恭喜闫旭。
2、李梦圆,“Remote Sensing Object Detection Based on Strong Feature Extraction and Prescreening Network”,IEEE Geoscience and Remote Sensing Letters, 2023.1, DOI: 10.1109/LGRS.2023.3236777,恭喜李梦圆。
3、王蕊,专利“基于微脉冲激光雷达测量云高的同轴光学系统”授权,2023.3,恭喜王蕊。
4、武增艳,“Beam Properties of a Partially Coherent Beam Propagating Horizontally in Atmospheric Turbulence”,Photonics,DOI:10.3390/photonics10040477,2023.4,恭喜武增艳。
5、雍嘉伟,“Research on Photon-Integrated Interferometric Remote Sensing Image Reconstruction Based on Compressed Sensing”,Remote sensing,DOI:10.3390/rs15092478,2023.5,恭喜雍嘉伟。
6、叶暑冰,"Properties of Scattering Fields from Gaussian Beam Incident on Rough Cylinders",Photonics,DOI:10.3390/photonics10060699,2023.6,恭喜叶暑冰。
7、宋保名,“Investigation polarimetric scattering of light from the randomly rough surface based on the calculation of the Mueller matrix”,Optics Express, DOI:10.1364/OE.492780,2023.6,恭喜宋保名。
8、於超然,“HB-YOLO: An improved YOLOv7 algorithm for dim object tracking in satellite remote sensing video”,Remote sensing,DOI:10.3390/rs15143551,2023.7,恭喜於超然。
9、卫润茜,“Optical Remote Sensing Image Target Detection Based on Improved Feature Pyramid”,IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing,DOI:10.1109/JSTARS.2023.3303692,2023.8,恭喜卫润茜。
10、武增艳,“Factors influencing the performance of optical heterodyne detection system”,Optics and Lasers in Engineering,DOI:10.1016/j.optlaseng.2023.107826,2023.9,恭喜武增艳。
11、武增艳,“Optical Heterodyne Detection System for High-Speed Camera Based on HSA Phase Compensation Method”,Optics Letters,DOI:10.1364/OL.500332,2023.9,恭喜武增艳。
12、周越冬,专利“一种基于遥感图像的舰船多目标跟踪方法”授权,2023.9,恭喜周越冬。
13、武增艳,“Improving distance imaging accuracy through temporal position correction with phase difference compensation”,Applied Optics, DOI:10.1364/AO.502508,2023.12,恭喜武增艳。
学术论文:
2022年:
1、尚亚洁,“A using remodulation filterless scheme of generating frequency 32-tupling millimeter-wave based on two DPMZMs”,Optics and Laser Technology, 148,2022,DOI: 10.1016/j.optlastec.2021.107793,恭喜尚亚洁。
2、王婷,“Aircraft Detection in Remote Sensing Images Based on Lightweight Convolutional Neural Network”,IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing ,2022,15 , pp.2805-2815,DOI:10.1109/JSTARS.2022.3159981,恭喜王婷。
3、雍嘉伟,“Photonic Integrated Interferometric Imaging Based on Main and Auxiliary Nested Microlens Arrays”,OPTICS EXPRESS,doi.org/10.1364/OE.463504,恭喜雍嘉伟,Vol. 30,Issue 16,pp. 29472-29484(2022)。
4、闫旭,“Modulation Format Identification Technology Based on a Searching Cluster Boundary Clustering Algorithm”,Journal of Lightwave Technology录用,DOI: 10.1109/JLT.2022.3212042, 2022.10,恭喜闫旭。
5、徐翔凯,“Multi-Object Tracking of Unmanned Aerial Vehicles by Swin Transformer Neck and New Data Association Method”,IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 录用, 2022.10,恭喜徐翔凯。
2021年:
1、张文睿,“Research on Simulation Methods for Doppler Frequency Shift of a Coherent Inter-satellite Laser Link in a Ground Test System”,Infrared Physics and Technology,v 113, March 2021; DOI: 10.1016/j.infrared.2020.103627。
2、苏晰园,“Application of DBN and GWO-SVM in Analog Circuit Fault Diagnosis”,Scientific Reports,11:1,2021.4,DOI:10.1038/s41598-021-86916-6。
3、吴启凡,“Improved Mask R-CNN for Aircraft Detection in Remote Sensing Images”,Sensors,21:8,2021.4,DOI:10.3390/s21082618。
4、冯嵩盟,“Greedy algorithm-based compensation for target speckle phase in heterodyne detection”,Infrared Physics & Technology,116,2021.4,doi:j.infrared.2021.103753。
5、黄自强,“A Filterless Radio-Over-Fiber System that Generates 80 and 160 GHz Millimeter Waves Based on Two MZMs”,60:16(4871-4877)Applied Optics,2021.5,DOI:10.1364/AO.424180。
6、张文睿,“Heterodyne Coherent Tracking Technology for Inter-satellite Laser Link During Direct Sunlight”,Infrared Physics and Technology,116,2021.6, DOI:10.1016/j.infrared.2021.103817。
7、闫旭,“Wavefront Detection and Compensation Technology Based on Signal Light Nutation under Atmospheric Turbulence”,IEEE Communications Letters,25 (10) , pp.3340-3344,2021.7,DOI:10.1109/LCOMM.2021.3100701。
8、吴锦,“Ship Multiple Object Tracking in Remote Sensing Images Using Deep Learning”,Remote Sensing,13:18,2021.9,DOI:10.3390/rs13183601。
9、闫旭,“Wavefront Coherent Compensation Technology under Direct Sunlight in Free Space Optical Communication System”,IEEE Photonics Journal,13:5,2021.9,DOI:10.1109/JPHOT.2021.3112489。
10、耿金妮,“Spatial decoherence compensation algorithm for target speckle field in heterodyne detection based on frequency analysis and time translation”,Optics Express29 (24) , pp.39016-39026,2021.10,DOI:10.1364/OE.441960。
11、徐翔凯,“An Improved Swin Transformer-Based Model for Remote Sensing Object Detection and Instance Segmentation”,Remote Sensing,13:23,2021.11,DOI:10.3390/rs13234779。
2020年:
1、刘宇韬,“Compensation for target speckle phase by use of the combination of the adaptive particle swarm optimization algorithm and the array detector method in heterodyne detection” ,Optics Communications, v 458, 1 March 2020。
2、武增艳,“An MDPSK homodyne receiver with adaptive phase-diversity”,Journal of Modern Optics,67(3):234-241,2020,DOI: 10.1080/09500340.2020.1713410。
3、苏晰园,“Compensation for the Decoherence Effect in Heterodyne Detection of Rough Targets and a Target Vibration Characteristic Measurement System”,Scientific Reports发表https://doi.org/10.1038/s41598-020-62966-0,2020.4。
4、武增艳,“Filterless radio-over-fiber system based on polarization multiplexing to generate an 80 GHz millimeter-wave”,Applied Optics发表,doi.org/10.1364/AO.399792,59(24):7455-7461,2020.
5、闫旭,“Low-complexity carrier phase estimation for M-ary quadrature amplitude modulation real-time optical communication based on dichotomy”,Optics Express发表doi.org/10.1364/OE.394330 ,28(17):25263-25277,2020.
6、王婷,“An Aircraft Object Detection Algorithm based on Small Sample in Optical Remote Sensing Image”,Applied Sciences发表,doi:10.3390/app10175778,doi:10.3390/app10175778。
7、吴锦,“Research on Airplane and Ship detection of Aerial Remote Sensing Images Based on Convolutional Neural Network”,Sensors发表,20, 4696; doi:10.3390/s20174696 .
8、武增艳,“Filterless radio-over-fiber system to generate 40 and 80GHz millimeter-wave”,IEEE Photonics Journal.
2019年:
【1】樊爽林,“A RoF System Based on Polarization Multiplexing and Carrier Suppression to Generate Frequency Eightfold Millimeter-Wave” , DOI:10.1016/j.rinp.2019.01.052,Results in Physics。
【2】刘宇韬,“The quantitative relationship between the target surface speckle phase parameters and heterodyne efficiency” ,Optics Communications, v 440, p 171-176, 1 June 2019。
【3】申景诗,“Study on the influence of transverse effect on strain monitoring of space station” ,DOI: 10.1016/j.ijleo.2018.09.087,OPTIK, v 178, p 794-801, February 2019。
【4】刘宇韬,“Modeling the heterodyne efficiency of array detector systems in the presence of target speckle” ,DOI: 10.1109/JPHOT.2019.2925846,IEEE Photonics Journal, v 11, n 4, August 2019 。
【6】王婷,“Analysis of divergence angles of truncated and untruncated beams in collimation system” ,Optik, v 194, October 2019。
【6】王博,“An improved Faster R-CNN for small object detection” IEEE Access, v 7, p 106838-106846, 2019 。
【7】宁金娜,“Collimation of Laser Diode Beams for Free Space Optical Communications” , Infrared Physics and Technology, v 102, November 2019。
【8】刘宇韬,“Target speckle correction using an array detector in heterodyne detection” ,Optics Letters, v 44, n 24, p 5896-5899, December 15, 2019 。
2018年:
【1】闫旭,“Tracking error compensation technology for coherent tracking system” ,Infrared Physics & Technology。
【2】申景诗,“Research on Strain Measurements of Core Positions for the Chinese Space Station” DOI10.3390s18061834,Sensors 。
【3】曹长庆,王婷,曾晓东,Vectorial analysis of the collimated beam of a small Gaussian source. Infrared Physics & Technology ,https://doi.org/10.1016/j.infrared.2017.12.013 2018
【4】张晓兵,曹长庆,曾晓东,An identification technology for crude oil and lubricant onsimulated sea surface. DOI 10.1016j.ijleo.2017.11.167 157 :1194–1198, Optik, 2018.
【5】曹长庆,王婷,曾晓东,Accurate evaluation of the far field error of the semiconductor laserdoi.org10.1016j.ijleo.2017.10.172, Optik, 2018
【6】申景诗,曾晓东,曹长庆,Research on Strain Measurements of Core Positions for the Chinese Space StationDOI10.3390s18061834,Sensors, 2018
【7】张文睿,曹长庆,曾晓东,Disturbance Compensation Technology of Space Optical Communication Based on RLS Lattice Filtering Algorithm,AD HOC NETWORKS,2018
【8】张文睿,曹长庆,曾晓东,Photonic-assisted radio frequency waveform generation for high range resolution microwave radar, doi.org/10.1117/1.OE.57.11.114103在Optical Engineering 发表,2018
2017年:
【1】曹长庆,王婷,曾晓东,The analysis of divergence of collimated beams, Optik, 2017,135(4):305-307.WOS000396960600037DOI 10.1016j.ijleo.2017.01.095
【2】王香,曹长庆,曾晓东,A High-quality 120 GHz Millimeter-wave Generation without Laser Phase Noise,Journal of Modern Optics,2017,64(1):46-51。WOS000386204300006DOI 10.108009500340.2016.1206217
【3】王香,曹长庆,曾晓东,A millimeter wave system based on forward modulation and novel double sideband modulation,Journal of Modern Optics,2017,DOI:10.1080/09500340.2017.1343501
【4】陈堃,曹长庆,曾晓东,Tri-detector heterodyne receiver for noise suppression, Optik, 2017,DOI:org/10.1016/j.ijleo.2017.07.021.
【5】范照晋,曾晓东,曹长庆,Microwave generation with an inner-modulated laser and parallel Mach–Zehnder interferometers, Optics Communications, 2017, DOI:org/10.1016/j.optcom.2017.07.002.
2016年:
【1】曹长庆,王香,曾晓东,The problem with beam quality for semiconductor laser,Optik,2016,127(8):3701-3702。WOS000371559700001DOI 10.1016j.ijleo.2016.01.046
【2】曹长庆,王香,曾晓东,A new beam parameter product for the collimating and focusing lenses' impact on semiconductor laser,Optik,2016,127:10926-10929。WOS000385596100082DOI 10.1016j.ijleo.2016.09.018
【3】范照晋,曾晓东,曹长庆,Novel structure of an ultra-narrow-bandwidth fibre laser based on cascade filters: PgFBG and SA,OpticsCommunications,2016,38:150-154。WOS000371132000025DOI 10.1016j.optcom.2016.02.013
2011-2015年:
【1】曹长庆,曾晓东.,半导体激光器光束质量评价方法探讨,红外与毫米波学报,2011,30(3):276-278。WOS000292578800020
【2】姚呈康,曾晓东,曹长庆.,Study on the output signal modulation for laser gyro with mechanical dither bias.,Applied Mechanics and Materials,,2013,303(6):1752-1758。
【3】姚呈康,曾晓东,曹长庆.,Polarization properties in prism laser gyro with mechanical dither bias,Chin. Phys.B,2012,21(12):124205。
【4】姚呈康,曾晓东,曹长庆.,机械抖动棱镜式激光陀螺出射光强度特性,物理学报,2012,61(9):094216。
【5】曹长庆 ,曾晓东,范照晋,Measurement and Analysis of Aircraft and Vehicle LRCS in Outfield Test,, Proc.SPIE 2014,952222-952225,2014.8.1。WOS000354371100072DOI 10.111712.2180322
【6】曹长庆 ,曾晓东,王香,Discussion of Beam Quality of Semiconductor Lasers,, Proc.SPIE 2014,8.1。 WOS000354371100066DOI 10.111712.2180240
申请专利:
[1]曹长庆,曾晓东,刘虎,激光目标退偏参数外场测试系统,2015.2.11,中国,ZL201310299006.9。
[2]曹长庆,曾晓东,刘虎,一种异形棱镜及半导体激光器列阵评定光束整形器,2015.8.5,中国,ZL201310299008.8。
[3]曹长庆,曾晓东,王香,一种舰载液面油污对比法测量系统,中国,ZL201410640916.3
[4]曹长庆,王香,曾晓东,一种用于集成的异形端面光纤耦合器,中国,ZL2015109895098
[5]曹长庆,王香,曾晓东,基于声光移频器的收发式一体逆合成孔径激光雷达系统,中国,ZL2015109926058。
[6]曹长庆,陈堃,曾晓东,基于相位差光栅和马赫增德尔滤波器超窄线宽激光器,中国,ZL2017105775861
[7]曹长庆,王香,曾晓东,一种基于马赫增德尔调制器8倍频产生120GHz毫米波的方法,中国,ZL201610268245.1。
[8]曹长庆,王香,曾晓东,基于新型双边带马赫增德尔调制器产生60GHz毫米波的方法,中国,ZL201610268256.x。
[9]曹长庆,张晓兵,曾晓东,基于自动相位分集的相位噪声消除系统及方法,中国,2017106682370
[10]曹长庆,宁金娜,曾晓东,一种高动态光通信多普勒频移模拟器,中国,2017110922540
[11]曹长庆,宋琦,曾晓东,一种高精度瞬时微波频率测量装置,中国,201711089047x
[12]曹长庆,樊爽林,曾晓东,基于内调制激光器和平行马赫增德尔干涉仪的微波系统,中国,201711091245x
[13]曹长庆,王香,曾晓东,一种利用宽带光源产生毫米波信号的装置,中国,201510371743.4。
[14]曹长庆,王香,曾晓东,一种利用双独立可调谐光纤激光器产生毫米波信号的装置,中国,201510386305.5。
[15]曹长庆,曾晓东,王香,一种舰载液面油污双光源测量系统,中国,CN201410641554.X。
[16]曹长庆,曾晓东,刘虎,一种收发分离式激光振动测量系统,中国,CN201410140731.6。
[17]曹长庆,曾晓东,刘虎,.一种DPL电流驱动保护电路,中国,CN201410140821.5。
[18]王蕊 曹长庆 曾晓东 。基于自由空间光通信的相干跟踪系统及补偿方法,CN201810998215.5。
[19]陈堃 曹长庆 吴晓鹏 .基于稀疏字典学习和剪切波的图像融合方法,CN201810998219.3.
[20]闫旭 曹长庆 曾晓东 .空间光通信的相干跟踪及视轴误差补偿系统,CN201810798534.1.
[21]王蕊 曹长庆 曾晓东 .基于微脉冲激光雷达测量云高的同轴光学系统,CN201810998205.1.
[22]刘宇韬 曹长庆 曾晓东.基于CCD相机的抑制外差探测中退相干效应的装置和方法,CN201810798530.3.
[23]申景诗 呼夏苗 曹长庆 ,亚微米量级的高精度探测系统及位置角度探测方法,CN201810371395.4.
[24]曹长庆 樊爽林 冯喆珺 .基于载波抑制产生八倍频毫米波的光载无线通信系统,CN201810362552.5.
[25]申景诗 陈堃 曹长庆 .多光谱复合检测系统,CN201810385267.5.
