各类老熟女老熟妇视频在线观看_国产农村妇女AAAAA视频_肥老熟妇伦子伦456视频_舌L子伦熟妇GV_艳妇乳肉豪妇荡乳AV无码福利_四LLL少妇BBBB槡BBBB

2024

2024

  • Record 61 of

    Title:Time-bin entangled photons for scalable quantum information processing
    Author Full Names:Sciara, Stefania(1); Yu, Hao(1,2); Chemnitz, Mario(1,3,4); Monika, Monika(1,5); Nosrati, Farzam(1,6); George, Agnes(1); Montaut, Nicola(1); Fischer, Bennet(1,3); Crockett, Benjamin(1); Helsten, Robin(1); Wetzel, Benjamin(7); Goebel, Thorsten A.(8); Kr?mer, Ria G.(4); Little, Brent E.(9); Chu, Sai T.(10); Nolte, Stefan(4,8); Wang, Zhiming(2); Aza?a, José(1); Munro, William J.(11); Moss, David J.(12); Peschel, Ulf(5); Franco, Rosario Lo(6); Morandotti, Roberto(1)
    Source Title:Signal Processing in Photonic Communications, SPPCom 2024 in Proceedings Advanced Photonics Congress 2024 - Part of Optica Advanced Photonics Congress
    Language:English
    Document Type:Conference article (CA)
    Conference Title:2024 Signal Processing in Photonic Communications, SPPCom 2024
    Conference Date:July 28, 2024 - August 1, 2024
    Conference Location:Quebec City, QC, Canada
    Abstract:Encoding information in photonic time bin enables quantum technologies compatible with both integrated and fiber frameworks. Here, we demonstrate time-bin entangled qudits in a programmable photonic chip and in a fully fibered coupled loop system. ? Optica Publishing Group 2024, ? 2024 The Author(s)
    Affiliations:(1) Institut National de la Recherche Scientifique, Centre énergie, Matériaux et Télécommunications, 1650 Lionel Boulet, Varennes; QC; J3X 1P7, Canada; (2) Shimmer Center, Tianfu Jiangxi Laboratory, Chengdu; 641419, China; (3) Leibniz Institute of Photonic Technology, Albert-Einstein Strasse 9, Jena; 07745, Germany; (4) Friedrich-Schiller-University, Abbe Center of Photonics, Institute of Applied Physics, Albert-Einstein-Strasse 15, Jena; 07745, Germany; (5) Institute of Solid State Theory and Optics, Friedrich Schiller University Jena, Max-Wien-Platz 1, Jena; 07743, Germany; (6) Dipartimento di Ingegneria, Università di Palermo, Viale delle Scienze, Palermo; 90128, Italy; (7) Xlim Research Institute, CNRS UMR 7252, University of Limoges, Limoges; 87000, France; (8) Fraunhofer Institute for Applied Optics and Precision Engineering IOF, Center of Excellence in Photonics, Albert-Einstein-Strasse 7, Jena; 07745, Germany; (9) QXP Technology Inc., 15 Shanglinyuan 1st RD, High-tech Zone, Xi'an, China; (10) Department of Physics, City University of Hong Kong, Tat Chee Avenue, Kowloon, Hong Kong; (11) Okinawa Institute of Science and Technology Graduate University, Okinawa, Onna-son; 904-0495, Japan; (12) Optical Sciences Centre, Swinburne University of Technology, Hawthorn; VIC; 3122, Australia
    Publication Year:2024
    數據庫ID(收錄號):20250417757864
  • Record 62 of

    Title:Time-bin entangled photons for scalable quantum information processing
    Author Full Names:Sciara, Stefania(1); Yu, Hao(1,2); Chemnitz, Mario(1,3,4); Monika, Monika(1,5); Nosrati, Farzam(1,6); George, Agnes(1); Montaut, Nicola(1); Fischer, Bennet(1,3); Crockett, Benjamin(1); Helsten, Robin(1); Wetzel, Benjamin(7); Goebel, Thorsten A.(8); Kr?mer, Ria G.(4); Little, Brent E.(9); Chu, Sai T.(10); Nolte, Stefan(4,8); Wang, Zhiming(2); Aza?a, José(1); Munro, William J.(11); Moss, David J.(12); Peschel, Ulf(5); Franco, Rosario Lo(6); Morandotti, Roberto(1)
    Source Title:Specialty Optical Fibers, SOF 2024 in Proceedings Advanced Photonics Congress 2024 - Part of Optica Advanced Photonics Congress
    Language:English
    Document Type:Conference article (CA)
    Conference Title:2024 Specialty Optical Fibers, SOF 2024
    Conference Date:July 28, 2024 - August 1, 2024
    Conference Location:Quebec City, QC, Canada
    Abstract:Encoding information in photonic time bin enables quantum technologies compatible with both integrated and fiber frameworks. Here, we demonstrate time-bin entangled qudits in a programmable photonic chip and in a fully fibered coupled loop system. ? Optica Publishing Group 2024, ? 2024 The Author(s)
    Affiliations:(1) Institut National de la Recherche Scientifique, Centre énergie, Matériaux et Télécommunications, 1650 Lionel Boulet, Varennes; QC; J3X 1P7, Canada; (2) Shimmer Center, Tianfu Jiangxi Laboratory, Chengdu; 641419, China; (3) Leibniz Institute of Photonic Technology, Albert-Einstein Strasse 9, Jena; 07745, Germany; (4) Friedrich-Schiller-University, Abbe Center of Photonics, Institute of Applied Physics, Albert-Einstein-Strasse 15, Jena; 07745, Germany; (5) Institute of Solid State Theory and Optics, Friedrich Schiller University Jena, Max-Wien-Platz 1, Jena; 07743, Germany; (6) Dipartimento di Ingegneria, Università di Palermo, Viale delle Scienze, Palermo; 90128, Italy; (7) Xlim Research Institute, CNRS UMR 7252, University of Limoges, Limoges; 87000, France; (8) Fraunhofer Institute for Applied Optics and Precision Engineering IOF, Center of Excellence in Photonics, Albert-Einstein-Strasse 7, Jena; 07745, Germany; (9) QXP Technology Inc., 15 Shanglinyuan 1st RD, High-tech Zone, Xi'an, China; (10) Department of Physics, City University of Hong Kong, Tat Chee Avenue, Kowloon, Hong Kong; (11) Okinawa Institute of Science and Technology, Graduate University, Onna-son, Okinawa; 904-0495, Japan; (12) Optical Sciences Centre, Swinburne University of Technology, Hawthorn; VIC; 3122, Australia
    Publication Year:2024
    數據庫ID(收錄號):20250417759984
  • Record 63 of

    Title:Space advanced technology demonstration satellite
    Author Full Names:Zhang, XiaoFeng(1); Chen, Wen(1); Zhu, XiaoCheng(1); Meng, Na(1); He, JunWang(1); Bi, XingZi(1); Zhang, YongHe(1); Shi, Qi(1); Li, Fei(1); Liu, Rui(1); Feng, ZhengGong(1); Liu, Liu(1); Li, JinSong(1); Wu, HaiChen(1); Xu, DongXiao(1); Li, TaiJie(1); Huang, JiangJiang(1); Liu, Shuo(1); Li, TianTong(1); Yu, XianSheng(1); Gao, Yang(1); Zhou, Heng(1); Ban, HanYu(1); Zhang, YanLi(1); Zhang, YueTing(1); Yang, YingQuan(1); He, Tao(1); Duan, XuLiang(1); Chen, Xin(1); Wang, YaMin(1); Sun, AnTai(1); Zhang, KuoXiang(1); Sun, Ying(1); Wang, YaoBin(1); Fan, ChengCheng(1); Xiong, ShaoLin(2); Li, XinQiao(2); Wen, XiangYang(2); Ling, ZhiXing(3); Sun, XiaoJin(4); Zhang, Chen(3); Bai, XianYong(3); Wang, ZhanShan(5); Deng, YuanYong(3); Tian, Hui(6); Yang, JianFeng(7); Xue, HongBo(8); Sang, Peng(8); Liu, JinGuo(9); Zheng, HuiLong(10); Zhu, Xiang(8); He, JianWu(11); Li, Hui(12); Xu, LuXiang(13); Xu, ShuYan(14); Chen, WenWu(15); Liu, ZhenDong(15); Wang, ZhaoLi(16); Mao, XiangLong(7); Gao, Rong(7); Li, ZongXuan(17); Ding, GuoPeng(1); Wang, XinYu(1); Dou, RunJiang(18); Weng, LuBin(19); Luo, Hao(20); Wang, YaPing(1); Liang, XianFeng(8); Fang, ZiRuo(1)
    Source Title:Science China Technological Sciences
    Language:English
    Document Type:Journal article (JA)
    Abstract:The Space Advanced Technology demonstration satellite (SATech-01), a mission for low-cost space science and new technology experiments, organized by Chinese Academy of Sciences (CAS), was successfully launched into a Sun-synchronous orbit at an altitude of ~500 km on July 27, 2022, from the Jiuquan Satellite Launch Centre. Serving as an experimental platform for space science exploration and the demonstration of advanced common technologies in orbit, SATech-01 is equipped with 16 experimental payloads, including the solar upper transition region imager (SUTRI), the lobster eye imager for astronomy (LEIA), the high energy burst searcher (HEBS), and a High Precision Magnetic Field Measurement System based on a CPT Magnetometer (CPT). It also incorporates an imager with freeform optics, an integrated thermal imaging sensor, and a multi-functional integrated imager, etc. This paper provides an overview of SATech-01, including a technical description of the satellite and its scientific payloads, along with their on-orbit performance. ? 2023, Science China Press.
    Affiliations:(1) Innovation Academy for Microsatellites, Chinese Academy of Sciences, Shanghai; 201203, China; (2) Institute of High Energy Physics, Chinese Academy of Sciences, Beijing; 100049, China; (3) National Astronomical Observatory of China, Beijing; 100101, China; (4) Shanghai Institute of Technical Physics, Chinese Academy of Sciences, Shanghai; 200083, China; (5) Institute of Precision Optical Engineering, School of Physics Science and Engineering, Tongji University, Shanghai; 200092, China; (6) School of Earth and Space Sciences, Peking University, Beijing; 100871, China; (7) Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (8) National Space Science Center, Chinese Academy of Sciences, Beijing; 100190, China; (9) Shenyang Institute of Automation, Chinese Academy of Sciences, Shenyang; 110016, China; (10) Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing; 100190, China; (11) Institute of Mechanics, Chinese Academy of Sciences, Beijing; 100190, China; (12) Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai; 200032, China; (13) Hangzhou Institute for Advanced Study, University of Chinese Academy of Sciences, Hangzhou; 310024, China; (14) Nanyang Technological University, Singapore; 569830, Singapore; (15) Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian; 116023, China; (16) Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, Beijing; 100049, China; (17) Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun; 130033, China; (18) Institute of Semiconductors, Chinese Academy of Sciences, Beijing; 100083, China; (19) Institute of Automation, Chinese Academy of Sciences, Beijing; 100190, China; (20) School of Aeronautics and Astronautics, Zhejiang University, Hangzhou; 310058, China
    Publication Year:2024
    Volume:67
    Issue:1
    Start Page:240-258
    DOI Link:10.1007/s11431-023-2510-x
    數據庫ID(收錄號):20240115304467
  • Record 64 of

    Title:Rotary error modeling and assembly optimization of parallel structure shafting
    Author Full Names:Dong, Yi-Ming(1,2,3); Jiang, Bo(1,3); Li, Xiang-Yu(1,3); Xie, You-Jin(1,3); Lv, Tao(1,3); Ruan, Ping(1,3)
    Source Title:Chinese Optics
    Language:Chinese
    Document Type:Journal article (JA)
    Abstract:In order to improve the shafting motion accuracy of two-dimensional turntables such as photoelectric theodolites, we establish a mathematical model considering both the structural error of parts and the coupling amplification effect based on Jacobian-Torsor theory. Aiming at a shafting structure with one fixed end and one swimming, an analysis method of partial parallel structure was proposed. Through numerical simulation analysis, the impact of each part’s structural errors on the motion accuracy of the shafting and the optimal shafting assembly scheme were obtained. The results of assembly and adjustment of a photoelectric theodolite with an optical diameter of 650 mm show that assembly optimization improved the motion accuracy of the shaft system by 32.1%. The precision model and optimization method of shafting motion provide a theoretical basis for the shafting adjustment and tolerance design of two-dimensional turntables such as photoelectric theodolites. ? 2024 Editorial Office of Chinese Optics. All rights reserved.
    Affiliations:(1) Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (2) University of Chinese Academy of Sciences, Beijing; 100049, China; (3) Key Laboratory of Space Precision Measurement Technology, Chinese Academy of Sciences, Xi’an; 710119, China
    Publication Year:2024
    Volume:17
    Issue:3
    Start Page:586-594
    DOI Link:10.37188/CO.2023-0171
    數據庫ID(收錄號):20242316212544
  • Record 65 of

    Title:Fast sampling based image reconstruction algorithm for sheared-beam imaging
    Author Full Names:Chen, Ming-Lai(1,2,3); Ma, Cai-Wen(1,2,3); Liu, Hui(1,2,3); Luo, Xiu-Juan(1,2,3); Feng, Xu-Bin(1,2); Yue, Ze-Lin(1,3); Zhao, Jing(1,3)
    Source Title:Wuli Xuebao/Acta Physica Sinica
    Language:Chinese
    Document Type:Journal article (JA)
    Abstract:Sheared-beam imaging (SBI) is an unconventional ground-based optical imaging technique. It breaks through the traditional optical imaging concept by using three coherent laser beams, which are laterally displaced at the transmit plane, to illuminate the target, reconstructing the target image from echo signals. However, the echo data sampling of the imaging system is still not fast enough to reconstruct the high resolution and clear image of the target when imaging the target that is at rapidly changing position and attitude. In order to solve this problem, in this work an image reconstruction method is proposed based on five-beam fast sampling. An emitted beam array arranged in the cross shape with a central symmetrical structure is proposed, and the encoding and decoding method of the imaging system are changed. With a single exposure, the echo signals carry more spectrum information of the target, and the number of reconstructed images can be increased from 1 to 8, which quickly suppresses the speckle effect of the reconstructed image. Firstly, the principle of the imaging technique based on fast sampling is presented. Then, an image reconstruction algorithm based on fast sampling is studied. Eight groups of phase differences and amplitude information of the target can be extracted from echo signals. The wavefront phases are solved by the least-squares method, and wavefront amplitude can be obtained by the algebraic operation of speckle amplitude. The target image is reconstructed by the inverse Fourier transform. The simulation results show that comparing with the traditional three-beam image reconstruction method, the sampling times of echo data needed to obtain the same quality image are reduced from 20 to 5, which greatly reduces the sampling times of echo data and improves the sampling rate of echo data. ? 2024 Chinese Physical Society.
    Affiliations:(1) Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (2) Key Laboratory of Space Precision Measurement Technology, Chinese Academy of Sciences, Xi’an; 710119, China; (3) University of Chinese Academy of Sciences, Beijing; 100049, China
    Publication Year:2024
    Volume:73
    Issue:2
    Article Number:024202
    DOI Link:10.7498/aps.73.20231254
    數據庫ID(收錄號):20240815605338
  • Record 66 of

    Title:Switchable hybrid-order optical vortex lattice
    Author Full Names:Qin, Xueyun(1); Zhang, Hao(1); Tang, Miaomiao(1); Zhou, Yujie(1); Tai, Yuping(1,2); Li, Xinzhong(1,2)
    Source Title:Optics Letters
    Language:English
    Document Type:Journal article (JA)
    Abstract:Optical vortex (OV) modulation is a powerful technique for enhancing the intrinsic degrees-of-freedom in structured light applications. Particularly, the lattices involving multiple OVs have garnered significant academic interest owing to their wide applicability in optical tweezers and condensed matter physics. However, all OVs in a lattice possess the same order, which cannot be modulated individually, limiting its versatile application. Herein, we propose, to our knowledge, a novel concept, called the hot-swap method, to design a switchable hybrid-order OV lattice, in which each OV is easily replaced by arbitrary orders. We experimentally generated the switchable hybrid-order OV lattice and studied its characteristics, including interferograms, retrieved phase, energy flow, and orbital angular momentum. Furthermore, the significant advantages of the switchable hybrid-order OV lattice are demonstrated through the independent manipulation of multiple yeast cells. This study provides a novel scheme for accurate control and modulation of OV lattices, which greatly facilitates the diverse applications of optical manipulation and particle trapping and control. ? 2024 Optica Publishing Group.
    Affiliations:(1) School of Physics and Engineering, Henan University of Science and Technology, Luoyang; 471023, China; (2) State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics of CAS, Xi’an; 710119, China
    Publication Year:2024
    Volume:49
    Issue:9
    Start Page:2213-2216
    DOI Link:10.1364/OL.515906
    數據庫ID(收錄號):20241916073719
  • Record 67 of

    Title:Low-Light Image Enhancement Via Illumination Optimization and Color Correction
    Author Full Names:Zhang, Wenbo(1,7); Wu, Jianjun(3); Xu, Liang(2); Shi, Xiaofan(4); Huang, Wei(5); Li, Yanli(6)
    Source Title:SSRN
    Language:English
    Document Type:Preprint (PP)
    Abstract:The issue of low-light image enhancement is investigated in this paper. Specifically, a trainable low-light image enhancer based on illumination optimization and color correction, called LLOCNet, is proposed to enhance the visibility of such low-light image. First, an illumination correction network is designed, leveraging residual and encoding-decoding structure, to correct the illumination information of the $V$-channel for lighting up the low-light image. After that, the illumination difference map is derived by difference between before and after luminance correction. Furthermore, an illumination-guided color correction network based on illumination-guided multi-head attention is developed to fine-tune the $HS$ color channels. Finally, a feature fusion block with asymmetric parallel convolution operation is adopted to reconcile these enhanced features to obtain the desired high-quality image. Both qualitative and quantitative experimental results show that the proposed network favorably performs against other state-of-the-art low-light enhancement methods on both real-world and synthetic low-light image dataset. ? 2024, The Authors. All rights reserved.
    Affiliations:(1) Aeronautical Optoelectronic Technology Laboratory, Xi’an Institute of Optics and Precision Mechanics of CAS, Shaanxi, Xi’an; 710119, China; (2) Aeronautical Optoelectronic Technology Laboratory, Xi’an Institute of Optics and Precision Mechanics of CAS, Shaanxi, Xi’an; 710119, China; (3) Aeronautical Optoelectronic Technology Laboratory, Xi’an Institute of Optics and Precision Mechanics of CAS, Shaanxi, Xi’an; 710119, China; (4) Aeronautical Optoelectronic Technology Laboratory, Xi’an Institute of Optics and Precision Mechanics of CAS, Shaanxi, Xi’an; 710119, China; (5) Aeronautical Optoelectronic Technology Laboratory, Xi’an Institute of Optics and Precision Mechanics of CAS, Shaanxi, Xi’an; 710119, China; (6) School of Marine Science and Technology, Northwestern Polytechnical University (NWPU), Xi’an; 710072, China; (7) Northwestern Polytechnical University, China
    Publication Year:2024
    DOI Link:10.2139/ssrn.4921609
    數據庫ID(收錄號):20240334109
  • Record 68 of

    Title:Design of an optical passive semi-athermalization zoom lens
    Author Full Names:Yan, Aqi(1,2); Chen, Weining(1,2); Li, Qianxi(1,3); Guo, Min(1); Wang, Hao(1,2)
    Source Title:Applied Optics
    Language:English
    Document Type:Journal article (JA)
    Abstract:Traditional zoom lenses cannot clearly image during the entire zoom process when the ambient temperature changes and needs to focus frequently at middle focal length positions. An innovative design method called the optical passive semi-athermalization (OPSA) design for zoom optical systems is proposed which, based on the difference in the focusing sensitivity of the focusing group at short and long focal length positions, seeks out sensitive groups that have a greater impact on the imaging quality at the short focal position. By changing the temperature characteristics of the temperature-sensitive lenses in these groups, an OPSA zoom optical system can be realized, which exhibits a compact structure and excellent imaging quality. Under the ambient temperature of ?40?C to +60?C, the OPSA zoom lens needs to refocus only once at the long focal length position, which can ensure an image clearly during the entire zoom process. Remarkably, this innovative method not only mitigates the frequent focusing challenges in traditional zoom lenses, but also contributes to the diminutive size. ? 2024 Optica Publishing Group (formerly OSA). All rights reserved.
    Affiliations:(1) Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Shaanxi, Xi’an; 710119, China; (2) Xi’an Key Laboratory of Aircraft Optical Imaging and Measurement Technology, Shaanxi, Xi’an; 710119, China; (3) University of Chinese Academy of Sciences, Beijing; 100049, China
    Publication Year:2024
    Volume:63
    Issue:13
    Start Page:3479-3488
    DOI Link:10.1364/AO.517025
    數據庫ID(收錄號):20242016084730
  • Record 69 of

    Title:SMALE: Hyperspectral Image Classification via Superpixels and Manifold Learning
    Author Full Names:Liao, Nannan(1); Gong, Jianglei(1,2); Li, Wenxing(1); Li, Cheng(3); Zhang, Chaoyan(1); Guo, Baolong(1)
    Source Title:Remote Sensing
    Language:English
    Document Type:Journal article (JA)
    Abstract:As an extremely efficient preprocessing tool, superpixels have become more and more popular in various computer vision tasks. Nevertheless, there are still several drawbacks in the application of hyperspectral image (HSl) processing. Firstly, it is difficult to directly apply superpixels because of the high dimension of HSl information. Secondly, existing superpixel algorithms cannot accurately classify the HSl objects due to multi-scale feature categorization. For the processing of high-dimensional problems, we use the principle of PCA to extract three principal components from numerous bands to form three-channel images. In this paper, a novel superpixel algorithm called Seed Extend by Entropy Density (SEED) is proposed to alleviate the seed point redundancy caused by the diversified content of HSl. It also focuses on breaking the dilemma of manually setting the number of superpixels to overcome the difficulty of classification imprecision caused by multi-scale targets. Next, a space–spectrum constraint model, termed Hyperspectral Image Classification via superpixels and manifold learning (SMALE), is designed, which integrates the proposed SEED to generate a dimensionality reduction framework. By making full use of spatial context information in the process of unsupervised dimension reduction, it could effectively improve the performance of HSl classification. Experimental results show that the proposed SEED could effectively promote the classification accuracy of HSI. Meanwhile, the integrated SMALE model outperforms existing algorithms on public datasets in terms of several quantitative metrics. ? 2024 by the authors.
    Affiliations:(1) Institute of Intelligent Control and Image Engineering, Xidian University, Xi’an; 710071, China; (2) China Academy of Space Technology, Beijing; 100094, China; (3) Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China
    Publication Year:2024
    Volume:16
    Issue:18
    Article Number:3442
    DOI Link:10.3390/rs16183442
    數據庫ID(收錄號):20244017136858
  • Record 70 of

    Title:Fabrication of large aspect ratio single crystal diamond microchannel by femtosecond laser
    Author Full Names:Wang, Ning(1,2); Zhang, Jingzhou(1,2); Zhao, Hualong(1,2); Zhao, Wei(1)
    Source Title:Proceedings of SPIE - The International Society for Optical Engineering
    Language:English
    Document Type:Conference article (CA)
    Conference Title:2023 Advanced Fiber Laser Conference, AFL 2023
    Conference Date:November 10, 2023 - November 12, 2023
    Conference Location:Shenzhen, China
    Conference Sponsor:Chinese Society for Optical Engineering
    Abstract:As heat dispersing materials, Diamond has high thermal conductivity, extremely low coefficient of thermal expansion, low coefficient of friction, and good chemical stability, which have broad application prospects in the field of high-power device heat dissipation. This study aims to address the inability of traditional laser processing methods to meet the processing requirements of high aspect ratio diamond heat dissipation microchannels. Based on a femtosecond laser fiveaxis machining system, a five-axis attitude alternating machining method is used to study the forming size, surface roughness, and aspect ratio of femtosecond laser surface microchannels, and to compare it with the direct machining method using a galvanometer. The experimental results show that using a super depth of field optical microscope for detection, the cross-sectional shape of diamond microchannels processed using a galvanometer direct machining method is triangular, with an edge unilateral taper of 62°. The cross-sectional shape of diamond microchannels processed using a five axis attitude alternating machining method is ladder shaped, with a maximum edge unilateral taper of 88°, approaching a vertical state of 90°. As the width of microchannels increases, the unilateral taper value increases. By using a confocal microscope, the roughness of diamond microchannels processed using a galvanometer direct machining method is Ra0.88, and the optimal roughness of diamond microchannels processed using a five axis attitude alternating machining method is Ra0.29. The use of five-axis attitude alternating machining method is superior to the use of galvanometer direct machining in terms of unilateral taper and roughness. Finally, diamond rectangular microchannels were prepared using a five axis attitude alternating machining method, with a maximum aspect ratio of 10.7:1 and a maximum depth of 1.072mm. ? COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.
    Affiliations:(1) Xi an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi an; 710119, China; (2) Photonic Manufacturing Systems and Applications Research Center, Xi an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi an; 710119, China
    Publication Year:2024
    Volume:13104
    Article Number:131040B
    DOI Link:10.1117/12.3016198
    數據庫ID(收錄號):20241816027699
  • Record 71 of

    Title:Non-Cooperative Target Ranging Based on High-Orbit Single-Star Temporal–Spatial Characteristics
    Author Full Names:Zhang, Derui(1,2,3); Wang, Hao(1); Zhao, Qing(1)
    Source Title:Applied Sciences (Switzerland)
    Language:English
    Document Type:Journal article (JA)
    Abstract:A visible light camera payload with star-sensitive functionality was installed to measure the distance between a non-cooperative target satellite and a high-orbit satellite. The rotation matrix was used to calculate the pointing vector from the center of the satellite’s star-sensitive camera axis to the target satellite. Multiple position imaging was achieved, and the moving window approach was used to establish two sets of equations relating the pointing vectors to the positions of binary satellites. To simplify the calculations, the target satellite’s eccentricity was assumed to be small (0 to 0.001), allowing elliptical orbits to be approximated as circular. Additionally, short-interval (1-min) imaging measurements were taken, assuming a small inclination of the target satellite (0.0° to 0.4°). This resulted in the construction of a ranging model with high accuracy, producing a ranging error of less than 5% of the actual distance. ? 2024 by the authors.
    Affiliations:(1) Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (2) School of Electronics and Information Engineering, Xi’an Jiaotong University, Xi’an 710049, China; (3) University of Chinese Academy of Sciences, Beijing; 100049, China
    Publication Year:2024
    Volume:14
    Issue:23
    Article Number:11232
    DOI Link:10.3390/app142311232
    數據庫ID(收錄號):20245117562938
  • Record 72 of

    Title:Spectral-interferometry-based diff-iteration for high-precision micro-dispersion measurement
    Author Full Names:Du, Wei(1); Huang, Jingsheng(1); Wang, Yang(2); Zhao, Maozhong(1); Li, Juan(1); He, Juntao(1); Wang, Jindong(1); Zhang, Wenfu(2); Zhu, Tao(1)
    Source Title:Photonics Research
    Language:English
    Document Type:Journal article (JA)
    Abstract:Precise measurement of micro-dispersion for optical devices (optical fiber, lenses, etc.) holds paramount significance across domains such as optical fiber communication and dispersion interference ranging. However, due to its complex system, complicated process, and low reliability, the traditional dispersion measurement methods (interference, phase shift, or time delay methods) are not suitable for the accurate measurement of micro-dispersion in a wide spectral range. Here, we propose a spectral-interferometry-based diff-iteration (SiDi) method for achieving accurate wide-band micro-dispersion measurements. Using an optical frequency comb, based on the phase demodulation of the dispersion interference spectrum, we employ the carefully designed SiDi method to solve the dispersion curve at any position and any order. Our approach is proficient in precisely measuring micro-dispersion across a broadband spectrum, without the need for cumbersome wavelength scanning processes or reliance on complex high-repetition-rate combs, while enabling adjustable resolution. The efficacy of the proposed method is validated through simulations and experiments. We employed a chip-scaled soliton microcomb (SMC) to compute the dispersion curves of a 14 m single-mode fiber (SMF) and a 0.05 m glass. Compared to a laser interferometer or the theoretical value given by manufacturers, the average relative error of refractive index measurement for single-mode fiber (SMF) reaches 2.8 × 10-6 and for glass reaches 3.8 × 10-6. The approach ensures high precision, while maintaining a simple system structure, with realizing adjustable resolution, thereby propelling the practical implementation of precise measurement and control-dispersion. ? 2024 Chinese Laser Press.
    Affiliations:(1) Key Laboratory of Optoelectronic Technology & System (Ministry of Education), Chongqing University, Chongqing; 400044, China; (2) State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China
    Publication Year:2024
    Volume:12
    Issue:6
    Start Page:1362-1370
    DOI Link:10.1364/PRJ.523314
    數據庫ID(收錄號):20242416255043
99精品视频网站| 天天插天天插天天操| 五月天狠狠草| 久久久久9久无码视频| av婷婷丁香 六月| 二色AV| a在线免费v| 天天日夜夜拍| 玖色色综合| 99视频网| 色色97丁香婷婷五月天| 六月丁香好婷婷| 欧美特大片黄| hd五月婷婷在线| 99精品国产在热久久| 麻豆科斗777| 色婷婷狠狠| 色99在线| 丁香六月激情| 久热精品视频在线观| 在线成人网址| 五月激情丁香六月狠狠干| 玖玖婷婷五月天| 中海油常州环保涂料有限公司| 日本婷久久| 日本啪啪网| 色久影院| 丁香五月色| 五月丁香六月激情欧美综合| 玖月婷婷爱丁香| site:pnnrt.com| 六月婷婷深深爱| 五月天开心网| se99在线| 久久视9精| 五月天婷婷高清无码| 五月婷狠狠| 色综合射婷婷| 性色综合网| 九九在线视频| 欧美在线97| 思思热久久艹| 成人五月天婷婷| 99热只有| 日本噜噜色网| 久9热视频在线| 婷婷丁香五月综合网上| 在线中文字幕视频| 精品久久人妻| 只有久久精品免费| 亚洲性爱AV| 这里只有精品免费视频| 日本免费91| 久热99热| ay2区| 国产精品扒开腿做爽爽爽A片唱戏 欧美成人AAA片一区国产精品 | 色婷婷狠狠久久综合五月| 国产精品香蕉| 九久久精品视频99| 婷婷丁香宗合888| 丁香五月婷婷啪啪| 久久久久久欧美精品se一二三四| 五月天激情网页| 日韩AV中文字幕在线| 五月色综合| 激情五月婷| 日本色五月| 天天做天天爰天天爽天天无遮挡| 亚洲免费综合一区| 五月婷婷啪啪| 伊人婷婷五月天| 丁香五月激情综合| 色五月视频,小说| 五月丿香啪啪| 99精品久久久久久久婷婷| 日韩无码一区二区三区四区| 人妻日日日| 五月丁香亚洲婷婷| 五月丁香婷婷久久| 国产精产国品一二三在观看| 激情综合五月婷婷六月丁香| 欧美日综合| 无码激情AAAAA片-区区| 5月丁香婷婷激情网| 人妻激情综合| 嫩草AV久久伊人妇女超级A| 五月丁香六月综合激情网| AV免费在线网站| 99热主页日本| 婷婷五月精品在线| 久久国产高清| 久热免费| 久久久久人妻精选| 99热青青草| 亚洲精品久久久久久久久久吃药| 俺也高清无码高清视频| 亚洲AV网站在线观看| www.婷婷.com| cc精品国产性传播| 婷婷综合激情| 在线精品97| 驯服上司人妻HD中字日本| 就要爱综合| 超极99精品| 久9热视频| 天天综合天天做天天综合| 日韩有码一区| 97久久人人| 五月婷婷激清网| 日韩啪| 超碰国产在线播放| 色婷婷精品视频| 欧美激情Va| 大香人妻| 亚洲国产99| 五月丁香六月婷婷网站| 五月天激情综合网站| 热久久婷婷| 超碰成人免费| 骚。com| 综合网色| 丁香婷婷五月天成人| 中文无码婷婷| 五月综合色播播丁香婷婷| 操99| 婷婷九月丁香中文| 九九碰九九爱97超碰| 亚洲性色XXXXX| 99热丁香| A短视频免费在线观看| 无码少妇高潮喷水A片免费 | 国产精品久久久久久妇女6080 | 久久婷婷影院| 午夜激情五月天| 91丨九色丨国产打屁股| 在线综合啪| 久久这里只有精品热在99| 激情五月丁香六月综合AVXXXX| 五月总合激情网| 婷婷激情五月天激情小说| 久久久精品色| 天天干天天干天天干天天干天天干| 再綫Av免费視品| 丁香激情五月少妇| 狠狠色丁香| 99九无网码| 色爱终和网| 91操碰| 丁香色情五月综合激情| 日本熟妇乱妇熟色A片蜜桃| 天天综合色| 激情WWW| 日韩久久视频| 亚洲欧洲午夜成人精品av| 强壮的公次次弄得我高潮A片日本 | 亚洲色网址| 色的色综合| 丁香婷婷网| 亚洲天堂有码| 激情 久久 婷婷| 99这里只有精品|v| 91大神操美女| 婷婷激情图片| www激情网| 五月天婷婷基地| 婷婷狠狠狠爱| 26uuu成人网| 亚洲精品又粗又大又爽A片 | 五月人妻婷婷视频| 思思热精品免费视频| 少妇激情基地| 性高潮久久久久久-九九九九九九九九九九热-成人AV | 综合婷| 91 九色大美女| 色999五月色| 狠狠草在线观看| 久久五月婷婷开心网| 五月丁香婷婷爱激情综合网| 婷婷五月色色| 久久久久久久久久久月丁| 成人在线观看国产| 国产精品久久久久久久久久免费 | 欧美综合激情五月丁香| 色优久久| 91黄操| 日韩成人电影av| 91午夜婷婷狠狠久久综合9色| 99这里只有精品视频| 午夜丁香综合婷婷| 激情五月天com| 婷婷五月天成人综合网| 婷婷色香六月综合激情| 激情99热| 五月婷婷干干干| 九九热re99re6在线精品| 日韩性爱无码| 亚洲AV成人一区二区在线观看| 成人做爰高潮A片免费视频| 五月天色社区| 99久久99九九99九九九| 香焦网五月天| 四房婷婷| 99re热视频这里只精品| 99色网站| 天天骑天天操| 丁香五月六月综合欧美| 人草人人| 婷婷情色激情| 婷婷五月天亚洲综合| 丁香五月AV综合激情| 99热99ai| 色欲Av五月天| 欧美99热| 天天拍夜夜爽日日| 热99热| www色婷婷久久综合久色| 丁香五月成人| 丁香五月天堂| 在线成人网站| 99久久99视频只有精品| 日木狠狠干| 97人人操人人干| 色九网| 色婷婷婷婷| 嫩模aV在线| 97婷婷丁香| 成人中文字幕在线| 五月丁香免费视频| 91Chinese在线| 婷婷精品视频| 色噜噜狠狠色综| 影音先锋按摩| 人妻内射麻豆视频| 男人综合网| 五月天婷婷色播在线网| 色婷婷六月精品| 五月天激情小说婷婷基地| 99精品久久久久久久婷婷久久| 只有久久精品免费| 婷婷五月天激情网站| 婷婷丁香人妻天天| 婷婷五月av| 51国精产品自偷自偷综合| 亚洲操操| 亚洲五月色| 色五月丁香激情视频| 精品一区二区三区木瓜| 久久综合影院| 牛牛澡牛牛爽| 久久五月综合| 久久人妻www| 综合激情站| 丁香深五月婷婷| 色欲婷婷五月天| 久久99色色| 久久五月激情综合| 婷婷五月丁香第四色超碰在线 | 东京热人妻一区二区三区在线| www色色com| 天天操夜夜肏| 五月色网| 另类图片五月天婷婷| 色很很96| 天天影院色| 国产精品一区在线观看你懂的| 久久婷婷激情四射五月天| 色婷婷婷av| 日本人人xxx| 天堂无码人妻精品AV一区| 五月天激情图片网| 五月情四婷婷| 丁香婷婷五月色成人网站| 99热热热99精品丁香| 黄色片精品| 婷婷丁香亚洲五月天| 久久婷婷五月天激情四射| 97日本在线播放| 超碰人人色| 欧州色色| 大学生高潮无套内谢视频| 色情五月天。| 色婷婷色五月综合| 99精品在线观看视频| 婷婷五月色情| 婷婷色丁香六月| 九九热最新| AAA久久久AAA久久久AAA| 九六五月天婷婷| 色999五月色| 五月开心啪啪| 天天成人丁香美女AV| 99色婷婷视频| 1024成人在线观看| 国产精品热搜丁香五月婷婷| 国产古装妇女野外A片| 99ri在线播放| 亚洲色无码| 99久热| 色色五月天网站| 思思国产99| 熟妇人妻中文字幕无码老熟妇| 狠狠狠狠狠狠色| 都市激情小说婷婷| 国自产拍偷拍精品啪啪一区二区| 99re热在线视频| 五月丁香六月色| 日韩无码AV电影网站| 五月婷婷xxx| 97超碰在线免费观看| 五月丁香婷婷伊人日韩| 婷婷黄色五月天在线视频| 99色综合网| 久久五月天网| 天天激情站| 久九男女天堂| 色五月久久成人婷婷| 久久婷婷婷| 婷婷激情五月天小说| 五月香六月婷| 热热色色五月天婷婷| 色婷婷狠狠干| 婷婷大香蕉| 午夜爱爱网站| 激情小说婷婷| 墨西哥毛片内射精| 五月丁香无码| 一本色道久久88加勒比| 亚洲激情网站无码| 五月天婷婷丁香| 开心五月婷婷激情| 亚洲五月天婷婷| 性色av大香综合| 久久黄色片| 操大屄五月天视频| 国产精品-91JQ就要激情网91JQ6.91JQ27.CASA:16888 | 9色在线| 久热中文字幕| 婷婷大乡焦噜噜| 日韩无码系列| 亚洲天天操| 9999热在线| 午夜电影网VA内射| 先锋影音av色五月天资源站| 另类图片五月天婷婷| 99A片| 色色婷婷五月天| 五月丁香啪综合| 婷婷五月天中文字幕| 五月丁花六月丁香综合| 啪啪视频99| 丁香五月欧美色综合| 黄色中文字目| 色五月天激情| 337久久| 五月天婷婷黄色| www.夜夜操| va中文资源在线观看| 五月天综合久久| 操碰97| 天堂A∨在线| 五月婷婷激情网| 丁香九月婷婷综合| 九九色中文| 亚洲AV成人在线| 婷婷五月激情综合| 国产午夜一区二区三区| 欧美日本综合网| 五月婷婷在线免费观看| 成人婷婷桔色| 丁香五月婷婷啪啪| A色色| 亚洲第一成人AV| 秋霞影音91人妻久久| 婷婷五月丁香五月| 天天天添天天操| 国产91资源在线| 五月丁香色婷婷熟女| 琪琪布丁香社区激情五月天| 五月婷婷视频28| 1024欧美看片| 99热免费在线| 91九色无码日韩| 婷婷综合视频| www久| 99无码视频| 国产阿姨日皮艹逼内射视频| 日日干四虎| 永久AⅤ1| 99视频在线观看视频| 五月丁香成人小说| 天天综合网91| 99热都是精品| 天天综合图片| 五月天婷婷色综合| 五月天亭亭俺也| 日本女人久久| 亚洲成人在线免费| 丁香五月婷婷亚洲色图| 精品色色| 99色免费观看全部| 五月天丁香综合久久国产| 五月天婷婷影院| 九九激情网| 五月婷婷丁香| 播四月婷婷六月丁香| 九九性爱网| 久久九区| 97深爱伊人综合| 日本色啪| 婷婷久久综合| 狠狠操狠狠爱| 9999久久久久| 久草热视频在线观看| 97九色视频| 亚洲99热| 人人操超踫| www,色综合| 亚洲美女高潮久久久久久69| 亚洲色婷婷激情| 亚洲AV成人无码精品| 开心网五月色婷婷| 日韩啪啪视频| 九月丁香| 五月婷婷免费在线视频| 色五月网址| 影音先锋男人女人| 夜夜骑天天操| 天天操夜夜爽天天操| 婷婷五月影院| 免费无码又爽又刺激A片涩涩直播| 操操碰| 性爱综合网| 国产无套精品一区二区| 99天堂网| 碰碰碰97国产| 免费AV在线| 亚洲 25P| 欧美69色| 色婷视频| 婷婷五月色丁香在线看| 大香蕉久久婷婷| 思思热在线观看| 丁香五月婷婷色播艳门照| 欧美日韩国产一区| 精品人妻伦九区久久AAA片| 开心五月天激情网站| 久热中文字幕| www,婷婷,com| 九九青草热| ,99视频久久| 激情五月狠狠喔| 九九色精品| 婷婷五月天另类网站| 99九九精品视频| 久操操| 欧洲色| 激情综合自拍五月婷婷色五月| 久久五月婷天天干| 亚洲六月色婷婷| 亚洲女婷婷五月基地综合久久久| 五月久久网| 最近中文字幕大全免费版在线| 亚洲视色| 韩国情人在线电视剧免费观看高清版全集| 丁香九色不卡aaa | 亚洲色99| 色婷婷六月丁香综合欲精品| 天天爽夜夜爽夜夜爽精品| 99re资源在线视频导航| 日本精品99| 婷婷五月骚厕所| 丁香五月色色| 亚洲电影中文字幕| 婷婷五月天色播| 无码人妻一区| 欧美日韩大黄| 色七七九九| yazhoujiqingav| 五月天丁香成人| 99久久综合精品五月天| 成人午夜无码视频| 综合久久综合五月天婷婷| 丁香五月六月综合激情| 天天干天天干天天干天天干天天干| 99精品这里只有免费视频 | 成人色五月天婷婷| 丁香花操逼| 中文幕无线码中文字蜜桃| 婷婷四房播播| 色五月成人网| 丁香五月自拍| 啪啪夜久久| 狠狠干.com| 九九亚洲视频| 66色在线日韩| 天天狠狠色| 亚洲激情综合| 五月天婷综合| 刘玥精品一区| 天天爽天天爽| 天天综合久久| 日夜夜久久| 婷婷丁香五月激情综合站_久久五月丁香激情综合_开心五月综合激情综合五月_婷 | 91久久综合| 欧美A A A A A| EEUSS鲁片一区二区三区| 开心四房播播| 深夜A片| 久色姿源| 99ri在线| 色综合偷拍| 丁香五月婷婷社区| 国产精品第一国产精品| 五月丁香啪啪综合| 婷婷五月天激情电影小说| 中文不卡一二三区| 99热福利| 久久婷婷五月综合激情国产| 国产女生爱爱AA| 最近免费中文字幕大全高清大全1 欧美丰满熟妇BBB久久久 | www.久久99| 综合网狠狠| 视频一区二区在线| 成人综合网站| 五月丁香| 婷婷99视频精品| 六月天婷婷| 五月婷婷精品无在线| 色吧五月婷婷六月丁香| 99精品久久| 色播播婷婷| 五月激情久久| 激情综合网激情五月丁香五月俺也去| 国产精品人人做人人爽人人添| 99丁香五月婷| 日本欧美成人片AAAA| 欧美色色色色色色色| 天天操九九插| 色A网| 依人大香蕉| 精品成人在线观看| 91久久久久久久91| 九九精品少妇| 国产一级黄色影片,| 伊人五月天| 欧美性猛交AAAA片黑人 | 久久99网站| 亚洲无线视频| 在线观看免费狠狠色丁香香综合| 丁香五月婷婷网| 五月婷婷丁香社区| 日日爱699| 亚洲激情区| 色综合五月婷婷狠狠干| 99在线观看视频精品| 婷婷五月色| 67194成I人在线观看线路1| 亚州操逼网| 超碰国产AV| 亚州色综合| 综合久久综合五月天婷婷| 羞羞嫩草视频| 人操综合| 99热人人艹| 久久六月婷婷| 婷婷五月丁香综合网| 五月天激情小说网| a网站免费观看| 熟女人妻一区二区三区免费看| 国产在这里只有精品| www久久久| 中文字幕成人| 九月婷婷综合| 色婷婷视频在线| 97色色综合| 亚洲久久激情| 色婷婷五月天| 欧美色综合天天久久综合精品| 99热这里有精品| 26UUU精品一区二区| 婷婷狠狠操| 激情五月天婷婷丁香| 性色五月天| 五月天成人在线视频网站| 久久精品人妻| 色色色综合| 亚洲乱码日产精品BD| 男女啪啪做爰高潮无遮挡| 欧美成人AAA片一区国产精品| 五月天电影网| 一本色道久久88加勒比| 色婷婷很很丝袜| 五月激情婷婷偷拍| 中文在线视频久9| 欧美 日韩 成人| www.97碰碰com| 另类图片色五月| aaaaa不卡| 狠狠夜夜五月丁香| 第四色婷婷色五月| 欧美婷婷五月| 色香欲综合| 欧美成人日韩| 婷婷亚洲综合| 噜噜噜久久| 婷婷色在线| 第九色区AV在线| 熟女国产在线一区二区三区四区| 色色九区| 婷婷精品在线| 涩综合在线 | 桔色成人在线| 激情综合一| 日本啪啪网| 五月天精品| 婷婷导航| 精品无码片| 91人人超碰在线| 二色av| 五月激情精品视频| 五月丁香基地| 99色色网| 丁香大香蕉| 极品人妻VIDEOSSS人妻| 亚洲狠狠丁香婷婷香蕉| 亚州婷婷五月激情综合| 九九99九九99九九99视频网| 538午夜激情| 丁香五月宝贝激情网| 色欲AV导航| 日韩成人无码| 激情五月久久| 9 7总站超级碰免费视频| 色婷婷丁香社综合| 色色五月天激情| www.五月天性.com| 五月丁香婷婷激情视频| 91综合在线观看首页| 97久久超级| 久综合| WWW五月婷婷| 婷婷四色成人综合色视| 五月丁香六月激情综合| 操一区| 亚洲黄网AV| 99热 在线播放| 级情九色| 先锋av性爱成人电影| 97色色色| 狠狠插狠狠操| 国内精品免费一区二区2009| 96精品久久久久久久久| 欧美日韩AAAAA| 婷婷色狠狠| 五月天操逼网| 在线理论片| 一级性感毛片| 中文激情网| 开心激情久久久久久久| 天天干天天插| 色五月婷婷老师| 涩涩激情五月婷婷| 久草五月| 99热这里只有精品无码| 久久久ww| 夜夜嗨一区二区三区直播内容| 四射综合网| 丁香五月天激情网址| 婷婷十月丁香| 91丨九色丨熟女|新版| 色色激情五月天| 欧美天天搞| 99在线视频免费| 深爱激情综合网| 99热这里精品| 97男人天堂| 操91| www激情五月天| 色五月色五天色情网| 激情综合色婷婷啪啪五月天| 大香蕉伊人99| 五月天成人手机在线视频| 五月婷婷六月丁香五月| 欧美韩国日本| 99久久.www| 五月丁香拍拍激情综合| 九九在线精品| 91丨九色丨东北熟女| 99ri在线播放| 天天爱天天做天天爽| 日本在线99| 激情玖玖sh| 99久热在线精品| 色播丁香婷婷五月激情| 亚洲AV日韩无码| 综合色七七| 色99在线| 久久久久久性爱视频| 色色亚洲视频| 色婷婷AⅤ| 五月天欧美 另类小说| 四房婷婷| 97操在线| 免费国产VA国产免费| 第五色色色婷婷| 日日鲁鲁鲁夜夜爽爽狠狠视频97| 婷婷狠狠18禁久久| 开心五月婷婷99| 欧美日韩一区二区三区四区| 99久久五月丁香野外| 婷婷五月天亚洲色| 色私五月婷婷| 高清 码 免费看片短视频| 99这里精品| 六月婷婷久久| www网站在线观看| 五月天婷婷自拍图片在线观看| 亚洲色无码A片一区二区麻豆 | 停停六月 综合| 狠狠操天天操综合| 精品久久久999| AV中文字幕夜夜操b天天摸bb| 激情com| 久久五月天网| 色婷婷狠狠久久综合五月| www.婷婷网| 久久婷婷五月天激情| 超碰操日| 婷婷五月丁香影院| 五月丁香六月色| 亚洲区1| a v色婷婷| 91久久婷婷| 在线伦子99热| 99热这里只有的精品视| 亚洲无AV在线中文字幕| 久草 天堂| 激情五月天婷婷五月天| ..真实国产乱子伦毛片 | 中字幕视频在线永久在线观看免费| 成人综合AV| 天天夜夜爽| 婷婷伊人綜合中文字幕| 激情婷婷五月天| 四LLLBBBB槡BBBB| 久久男人网婷婷| 狠狠色情婷婷| 人人摸人人摸| 色色免费网站| www.夜夜操| 婷婷94s| 深爱丁香激情| 婷婷在线播放| 99re在线观看| 婷婷综合97| 精品九九网| 婷婷五月深深爱| 99re在线观看| 婷婷伊人无码| 成人在线网址| 超碰97干| 夜夜骑天天操| 久久久噜噜噜操操操| 九九爱看亚洲| 免费看欧美成人A片无码| 色色99| 欧美日本国产欧美日本韩国99| 丁香五月www| 女力报到正好爱上你| 丁香五月激情啪啪| 婷婷97狠狠干| 婷婷啪啪| 91一起操| 色老久久| 夜夜躁婷婷AV| 丁香五月成人网| www.激情五月天.com| 婷婷五月天六月| 成人无码免费一区二区中文| 激情播丁香| 亚洲精品无码一区二区| 日日爱678| 色啪综合| 五月天综合久久| 丁香六月激情四射| 日韩成人电影在线播放| 婷婷激情五月| 五月丁香综合成人社区| 欧美日本另类| 91嫩草久久| 99热国产免费| 五月婷婷日| 激情影院丁香五月| 婷婷丁香91| 色噜噜狠狠色综合日日| 欧美月久久| 天天操天天曰| 99碰在线视频| 五月色婷婷综合| 婷婷激情四射五月天| 日本人人xxx| 婷婷丁香五月天色色| 丁香五月婷婷激情蜜桃| 91美女啪啪| 天堂草在线看www| 婷婷五月开心六月AV| www.深爱激情| 9久热在线精品| 噜噜五月天综合| 99热一本久道| 五月丁香六月综合激情| 91视频免费后入强操| www.夜夜撸.com| 99操无码视频观看| 色哟哟精品| 东京热免费视频| 五月天婷婷在线AN| 深爱五月激情网| 精品国产一区二区三区四区阿崩| 激情五月天开心网丁香无码| 色综合久| 国色天香伊人狠狠色| 婷婷五月丁香色色| 色婷婷成人五月| 激情四射婷婷色色色| 大地资源色婷婷视频在线| 亚洲第一成人无码A片| 成人 在线 日韩| 九九熱最新視頻| a久久| 色丁香综合影院| 亚洲视频综合网| 亚洲激情免费视频| 五月久久| 婷婷四房播播| 99在线观看视频| 五月丁香六月欧美综合网站| 综合xx网| 九九爱激情| 免费不卡狠操美女视频网| 人人操人人爰人人一天天碰夜夜拍夜夜爽-中国A级毛片天天看天天谢… | 9色在线视频| 五月丁香啪啪啪| 99热这里有精品| 天天色天天噜| 久久99久久99www| 色五月av| 99热都是精品| WWW.桔色成人.COM| 人人看人人草人人摸| 99热色综合| 无套内谢少妇毛片A片樱花| 精品成人久久久久久久_一二三四视| 色五月六月| 这里只有精品99www| av不卡网站| 五月丁香亭亭| 超碰在线看| 少妇水多A片太爽了| 丁香婷婷久久综合在线| 亚洲另类毛片| 爆乳熟妇一区二区三区爆乳| 色婷婷五月天天天天天| 婷婷色色网站| 色狠狠婷婷| 丁香大香蕉| 性做久久久久久久免费看| 激情美女五月天激情在线| 精品九九网| 丁香六月久久| 色五月婷婷五月久久| 五月天啪啪网| 青草青草视频2免费观看| 色五月天影视| 中文字幕婷婷9月天| 人人舔人人| 综激情网| 欧美日韩精品人妻狠狠躁免费视频| 久色国产| 色婷婷免费视频| 99这里有精品视频| 五月天久久丁香| 婷婷内射视频在线| 八戒青柠影视剧在线观看| 丁香六月天堂| 日本婷久久| 成人综合网站| 欧美α√| 青青热视频| 婷婷中文字幕网站| 99.N在线视频| 另类图片激情五月天| 殴美97色| 久操无码| 色色婷婷综合网| 神马欧美精| 婷婷在线视频| 五月天啪啪| 色五月婷婷久久| 色婷婷综合久久| 97欧美在线| 婷婷六月网| 成人色图情色成人网 www.5b5b5bcom 五月天 | 这里只有精品久久| 香蕉AV777XXX色综合一区| 久久久99久久| 美女婷婷激情亚洲| 日韩另类在线观看| 天天综合图片| 91色在线| 99精品在线播放| 九九这里只有精品| 色婷婷在线视频久| 久热re在线视频| 久久精彩视频| 开心激情五月天网| 丁香五月 综合| 婷婷五月六月丁香| 色婷婷综合网| 玖玖热视频| 激情综合女人网五月播播| 噜噜五月天综合| 色色五月婷婷| 99re热视频这里只精品5| 婷婷五月激情的图片| 久久婷婷艹| 久久婷婷六月综合| 五月婷婷啪啪啪啪| a色色片| 丁香六月婷婷社区| 一本大道伊人AV久久综合| 日本va欧美va国产激情| 婷婷五月丁香狠狠| 超碰在线综合| 丁香五月天视频| 狠狠狠狠狠狠色| 日日操,夜夜撸| 99综合视频| 无码人妻一区二区一牛影视| 99这里都是精品6| XX色综合| 综合久久丁香婷婷,五月婷婷六月丁香,开心激情综合网,六月丁香在线观看,婷婷丁 | 欧美日韩一区二区三区四区| 岛国AV网| 狠狠干天天内射| 日韩黄色电影| 日本操B视频| 久久九九爽| 五月婷婷在线播放| 五月天婷婷色紫薇阁| 大香线蕉伊人| 婷婷福利影院| 日日夜夜干| 欧美成人猛片AAAAAAA| 五月丁香久久激情网| 少妇高潮一区二区三区99欧美| 天天视频精品9| 欧美内射AAAAAAXXXXX| 五月婷婷成人| 色五月亚洲开心网| 丁香六月AV| 99资源在线视频| 亚洲天堂色色| 高潮A片揉搓乳尖乱颤视频| 天天射影视综合网| 丁香五月婷婷亚洲人| 色婷婷AⅤ| 婷色影院| 天天综合网在线| 久久九精品| 都市激情五月婷婷亚洲| 亚洲色激婷| 久久狼人天堂| 99在线爽| 久久无码成人| 狠狠狠狠狠狠狠狠| 亚洲色婷婷久久精品AV蜜桃| 久久久久久丁香五月| 色综久久AV| 亚洲一级色电影| 久久一级免费黄色片| 丁香五月天视频| 久热婷婷| 99re在线播放| 婷婷色情六月| 精品99爱免费视频在线观看| 丁香五月婷婷六月婷婷| 久久免费丁香| 久9热在线免费观看| 欧美成人精品A片免费一区99 | 男女99免费视频| 国产4P视频精品五区| 大香蕉AV电影在线| 99国产精品白浆在线观看免费| 综合久久高清| 精品人妻一区| 五月天婷婷丁香六月| 五月情婷婷五月| 天天综合网、天天综合色| 色婷婷五月综合在线| 婷婷基地成人五月天| 综合欧美五月婷婷| 粉嫩AV久久一区二区三区| 婷婷色丁香五月| 国产丝袜美女| 五月婷婷在线播放| 久久五月婷天天干| 五月丁六月香av| 天天 青草 制服丝袜 在线| 色婷操逼| 色五月婷婷操逼| 九9九9无码| 中文字幕av网站| 万月丁香狠狠爱| 91碰碰碰| 江苏少妇性BBB搡BBB爽爽爽| 五月婷在线| 91丨九色丨熟女|新版| A片试看120分钟做受视频红杏| 五月丁香人妻| 丁香五月婷婷色| 色五月婷婷久久大| 六月天无码网址| 婷婷丁香五月天在线视频| site:901-07.com| 日本三级中国三级99人妇网站| 99色中文| 99热99久久| 婷婷五月天网址| 欧美天天搞| 亚洲精品成人片在线播| 亚洲成人av在线观看| avh片在线观看| 啪啪日本欧美| 伊人网色婷婷五月天| 91色色五月天| 婷婷综合久久| 99热这里是精品| 亚洲亚洲人成综合网络| 亚洲激情久久| 99久久网站| 色色com| 五月婷婷香| 五月丁香婷婷成人网| 99热在线精品观看| 国产亚洲色婷婷久久99精品91| 97碰碰视频在线观看免费| 五月天婷婷网站888| 亚洲无线视频| 另类A片| 超碰chaompinm| 二色av| 九九热免费| 五月天六月色| 色婷婷五月天| 99精品偷自拍| 香蕉久久国产AV一区二区| 亚洲精品V天堂中文字幕| 亚洲乱码日产精品BD| 九九激情网| 婷婷五月花| 大香伊人久色| 亚洲AV日韩在线观看| 狠狠色综合久久久久| 五月天丁香啪啪啪啪| 久久五月天激情婷婷| 婷婷综合九月| 国产激情在线| 丁香九九九九| 丁香婷婷久久| 99久久丝| 日韩黄黄| 色婷婷六月综合| 色 五月婷婷基地| 色色丁香激情五月| 99热这里只有精品22| 五月天婷婷7米| 激情久久丁香| 日韩综合久久| 99性视频| 国产精品99久久久久久久女警| 丰满少妇乱A片无码| wwwav大香蕉| 五月刺激丁香月综合| 爆乳熟女-区二区三区| 婷婷激情五月视频| 日韩人妻无码精品| 色综合久久久久| 久久久久久久久久久久久久人妻视频| 五月激情综合婷婷| 日本成人小说婷婷六月| 五月天激情亚洲| 男人天堂网2017| 五月丁香琪琪| 久色视频| 刘玥av在线| 殴美97色| 欧美性猛交99久久久99| 大香蕉五月天婷婷| 婷婷丁香五月激情综合站_久久五月丁香激情综合_开心五月综合激情综合五月_婷 | 五月花婷婷在线精品视频| 青草视频在线蜜臀| 99热成人在线观看| 夜夜骑夜夜操| 六月丁香av| 亚洲乱码日产精品BD| 成人αV视频免费观看| 婷婷WWW久久| 亚洲视频操| 激情五月激情综合俺也去婷婷小说| 日 日干 日日做| 色情五月停停丁香| 色五月情| 人妻久久久久久久| 婷婷D区| 丁香婷婷午夜| 色五月综合激情| 开心四月婷婷在线色播播| 成人电影丁香六月天| 六月婷婷激情| 第四色激情网| 青柠影视免费高清电视剧| 91男人资源站| 1024婷婷综合久久五月天| 久久永久网址| 一级A片天天操夜夜操| 在线只有精品| 色香蕉影院| 高清无码网址| 99er热精品视频| 婷婷丁香在线| 婷婷 亚洲图片 丁香| 国产视频婷婷| 99精品自拍| 99燥99日| 金品在线视频99| 那里有AV网址| 五月婷六月天| 六月激情网| 五月天婷婷在线观看| 无码视频国内精品久久久| 日本三级毛片| 丁香亭亭久久| 99色视频免费在线规看| 97欧美在线| 图片区 小说区 区 亚洲五月 | 91av传媒高清在线视频网| 久久中国毛毛片爱久久| 亚洲免费看片| 在线A色| 99re在线播放| 开心五月色婷婷综合开心网| 大香人妻| 噜噜噜狠狠色综合| 婷婷五月偷拍| 日韩av在线免费观看| 三年高清大片免费观看国语| 综合网网欲色| 久久五月丁香婷婷| 天天色激情|