尤物YW午夜国产精品视频,欧美亚洲日韩国产人成在线播放,97久久精品亚洲中文字幕无码,免费人成在线观看视频播放,无码精品日韩专区,亚洲AⅤ成人精品无码

2024

2024

  • Record 493 of

    Title:Output Facet Temperature of High-Power Semiconductor Lasers Using Optical-Thermal Reflection Method
    Author Full Names:Xu, Zibang(1,2,3); Miao, Xinlian(1,2,3); Liu, Yuxian(4); Lan, Yu(4); Zhao, Yuliang(4); Zhang, Xiang(1,2,3); Yang, Guowen(5); Yuan, Xiao(1,2,3)
    Source Title:Zhongguo Jiguang/Chinese Journal of Lasers
    Language:Chinese
    Document Type:Journal article (JA)
    Abstract:Objective Semiconductor lasers have been widely used in industrial, medical, and other fields owing to their high electro-optical conversion efficiency, wide spectrum, and high power-to-volume ratio characteristics. However, as the application field expanded, higher power and reliability requirements have been stated. When manufacturing a high-power semiconductor laser, catastrophic optical mirror damage (COMD) is a key factor limiting the output power and reliability characteristics. COMD occurs due to a local temperature rise at the facet, which exceeds the material damage threshold, and it denotes the irreversible physical damage inflicted on the facet. Note that the occurrence of COMD is closely related to the output facet temperature; thus, accurately measuring the temperature and plotting its distribution are crucial for assessing the failure characteristics of high-power semiconductor lasers. Methods This study is based on the optical thermal reflection method used to construct a semiconductor laser output surface temperature measurement system. Accordingly, the distribution characteristics of the output surface temperature are studied. First, the thermal reflection coefficient of the output facet material used in the semiconductor laser is measured, based on which the measurement system is calibrated. Second, the lock-in method is used to improve the signal-to-noise ratio of the measurement system by increasing the number of image acquisitions. Finally, the output facet temperatures are measured under different operating currents, and the temperature information along the fast and slow axes is extracted and analyzed. Results and Discussions The thermal reflection coefficient of the active region is 5.06 × 10-4 [Fig. 3(a)], and that of the substrate is 6.03 × 10-4 [Fig. 3(b)]. After 1000 iterations, the amplitude fluctuation of the thermal reflection signal tends to a smooth curve, causing a temperature fluctuation of less than 0.4 °C (Fig. 6). The output facet temperature under the 1-10 A current is measured; the output facet temperature of the active region of the semiconductor laser increases with an increase in the injection current (Fig. 8). The output facet temperature of the quantum well layer exhibits strong non-uniformity along the slow axis. At 10 A, the maximum temperature difference at the output facet is approximately 7.5 °C. However, at 1 A, the maximum difference exceeds 3 °C (Fig. 9). The output facet temperatures of the quantum well region under currents of 2, 4, 6, 8, and 10 A are 1.4, 3.1, 4.6, 6.9, and 8.7 °C higher than the junction temperature, respectively. In the region with an approximate thickness of 1.3 pun at both sides of the quantum well, the output facet temperature is higher than the junction temperature. However, in other regions, the output facet temperature is lower than the junction temperature (Fig. 11). Conclusions This article presents a study on the high-resolution measurement of the temperature distribution at the semiconductor laser output facet using the optical thermal reflection method. The temperature distribution information from the output facet of the semiconductor laser is collected under working currents of 1-10 A. The results indicate that the measurement method presented in this study can distinguish small temperature variations at the output facet of the semiconductor laser. Moreover, it is observed that the temperature distribution at the output facet of the semiconductor laser exhibits strong non-uniformity along the slow axis, primarily due to heat generation from light absorption and non-radiative recombination occurring at the facet defects. The highest temperature is observed near the quantum well layer at the output facet, which is consistent with the fact that COMD usually occurs in this region, indicating that abnormal temperatures exceeding the damage threshold are the direct cause of COMD failure in semiconductor lasers. The research method and results presented in this study contribute to obtaining a better understanding of the heat generation mechanism at the output facet of semiconductor lasers, which hold significant practical value for optimizing their design for improving their output performance and reliability. ? 2024 Science Press. All rights reserved.
    Affiliations:(1) School of Optoelectronic Science and Engineering, Soochow University, Jiangsu, Suzhou; 215006, China; (2) Key Lab of Advanced Optical Manufacturing Technologies of Jiangsu Province, Jiangsu, Suzhou; 215006, China; (3) Key Lab of Modern Optical Technologies of Education Ministry of China, Jiangsu, Suzhou; 215006, China; (4) State Key Laboratory of Transient Optics and Photonics, Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Shaanxi, Xi'an; 710119, China; (5) Dogain Optoelectronic Technology (Suzhou) Co., Ltd., Jiangsu, Suzhou; 215000, China
    Publication Year:2024
    Volume:51
    Issue:13
    Article Number:1301004
    DOI Link:10.3788/CJL231574
    數(shù)據(jù)庫ID(收錄號):20243216840207
  • Record 494 of

    Title:Cold shield matching of cooled infrared system based on telecentric optical structure
    Author Full Names:Hu, Xinrong(1); Wang, Jing(1); Chen, Su(1); Li, Jing(2); Feng, Ye(2)
    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:To solve the problem of cold shield matching in a cooled infrared (IR) imaging optical system with aperture stop placed away from the lens, a pupil matching method based on the telecentric optical structure is proposed. The formulae of Gaussian parameters between the relay lens and the objective lens are derived by using the ideal imaging process. A specific discussion and numerical analysis are carried out. The objective lens is designed as image-space telecentric and the relay lens is designed as object-space telecentric to achieve the requirement that the aperture stop far away from the objective lens. And a specific designing example is added to show the effectiveness of the analysis. ? COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.
    Affiliations:(1) China Academy of Space Technology (Xi'an), Xi'an; 710000, China; (2) Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi'an; 710119, China
    Publication Year:2024
    Volume:13104
    Article Number:131046Y
    DOI Link:10.1117/12.3023902
    數(shù)據(jù)庫ID(收錄號):20241816027603
  • Record 495 of

    Title:A 4×112Gbps Compact Polarization-Insensitive Silicon Photonic WDM Receiver
    Author Full Names:Xue, Jintao(1,2); Wu, Jinyi(1,3); Cheng, Chao(1,3); Zhang, Wenfu(1,2); Wang, Binhao(1,2)
    Source Title:2024 Optical Fiber Communications Conference and Exhibition, OFC 2024 - Proceedings
    Language:English
    Document Type:Conference article (CA)
    Conference Title:2024 Optical Fiber Communications Conference and Exhibition, OFC 2024
    Conference Date:March 24, 2024 - March 28, 2024
    Conference Location:San Diego, CA, United states
    Conference Sponsor:Acacia Communications, Inc.; acphotonics; Amphenol Communications Solutions; ATOP; Aurea Technology; et al.
    Abstract:A 4×112Gbps polarization-insensitive silicon photonic WDM receiver with a two-dimensional grating coupler, cascaded dual-ring filters and bidirectional photodiodes is demonstrated. A polarization-dependent loss of 0.45dB is achieved. ? 2024 OSA.
    Affiliations:(1) Chinese Academy of Sciences, State Key Laboratory of Transient Optics and Photonics, Xi 'An Institute of Optics and Precision Mechanics, Xi'an; 710119, China; (2) University of Chinese Academy of Sciences, School of Future Technology, Beijing; 100049, China; (3) University of Chinese Academy of Sciences, School of Optoelectronics, Beijing; 100049, China
    Publication Year:2024
    數(shù)據(jù)庫ID(收錄號):20242216177152
  • Record 496 of

    Title:1.9 μm ultra-narrow spectral width mode-locked pulsed laser based on femtosecond laser inscribed FBG
    Author Full Names:Guo, Xiaoxiao(1); Huang, Xiwei(1); Li, Xiaohui(1); Luo, Pengtao(2); Gao, Cunxiao(3); Wang, Ruohui(2); Wang, Yishan(3); Xi, Fei(4); Yin, Xiaoqiang(5); Zhang, Kai(6)
    Source Title:Optics and Lasers in Engineering
    Language:English
    Document Type:Journal article (JA)
    Abstract:The ultra-narrow spectral width laser with excellent temporal coherence is an important light source for microphysics, space detection, and high-precision measurements. However, less attention seems to be paid to mode-locked pulsed lasers in the ~ 1.9 μm. Due to the narrow bandwidth of femtosecond laser inscribed fiber Bragg gratings (FBG), the thulium-doped fiber laser (TDFL) can generate ultra-narrow spectral width pulse. The central wavelength and 3-dB bandwidth of the output soliton is 1877.938 nm and 0.044 nm. The linewidth of the output pulse reaches 3.7 GHz. To the best of our knowledge, this is the narrowest spectral width in 1.9 μm. Additionally, when the FBG is compressed or stretched, the central wavelength of pulses will be tuned. This work extends the application scope of FBG and provides a new and simple method for realizing an all-fiber mode-locked laser with ultra-narrow spectra width at 1.9 μm. ? 2024
    Affiliations:(1) School of Physics & Information Technology, Shaanxi Normal University, Xi'an; 710062, China; (2) School of Physics, Northwest University, Xi'an; 710127, China; (3) State Key Laboratory of Transient Optics and Photonics, Xi′an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi′an; 710119, China; (4) Shaanxi Runchenglai Optoelectric Science & Technology Co. Ltd, China; (5) Shenzhen BYD Lithium Battery Company Limited, China; (6) Suzhou Institute of Nano-Tech and Nano-Bionics, Chinese Academy of Sciences, Suzhou; 215123, China
    Publication Year:2024
    Volume:181
    Article Number:108441
    DOI Link:10.1016/j.optlaseng.2024.108441
    數(shù)據(jù)庫ID(收錄號):20243016751488
  • Record 497 of

    Title:Rapid and Nanometric-Precision Distance Measurement with Hybrid Comb Lasers
    Author Full Names:Zhi, Jiawen(1); Wang, Zhichuang(2,3); Wu, Hanzhong(1); Little, Brent E.(2); Chu, Sai T.(4); Wang, Panpan(1); Shao, Chenggang(1); Wang, Weiqiang(2,3); Zhang, Wenfu(2,3)
    Source Title:Conference on Lasers and Electro-Optics/Pacific Rim, CLEO-PR 2024 in Proceedings 2024 Conference on Lasers and Electro-Optics Pacific Rim (CLEO-PR)
    Language:English
    Document Type:Conference article (CA)
    Conference Title:2024 Conference on Lasers and Electro-Optics/Pacific Rim, CLEO-PR 2024
    Conference Date:August 4, 2024 - August 8, 2024
    Conference Location:Incheon, Korea, Republic of
    Abstract:We demonstrate a dual-hybrid-comb distance meter with a fully-stabilized microcomb, enabling ultra-rapid and nanometric-precision distance measurement. The precision can reach 3.572 μm at 4.136 μs and 432 nm at 827.2 μs averaging time. ? 2024 The Author(s)
    Affiliations:(1) MOE Key Laboratory of Fundamental Physical Quantities Measurements, Hubei Key Laboratory of Gravitation and Quantum Physics, PGMF and School of Physics, Huazhong University of Science and Technology, Wuhan; 430074, 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; (3) University of Chinese Academy of Sciences, Beijing; 100049, China; (4) Department of Physics and Materials Science, City University of Hong Kong, Hong Kong
    Publication Year:2024
    數(shù)據(jù)庫ID(收錄號):20250517776785
  • Record 498 of

    Title:Research on Rough Road Detection Link Model
    Author Full Names:Yang, Yi(1); Zhang, Leilei(1); Ruan, Chi(2); He, Fengtao(1); Zhao, Zixuan(1); Jiao, Liang(1)
    Source Title:Guangzi Xuebao/Acta Photonica Sinica
    Language:Chinese
    Document Type:Journal article (JA)
    Abstract:Non-contact road surface meteorological detection technologies have emerged as a significant area of development due to their non-destructive impact on the road foundation and the simplicity of installation and maintenance. Typically, these non-contact road surface meteorological detection technologies utilize optical detection methods,and factors such as the roughness of the road surface and the optical angle of incidence significantly influence the system's performance and the accuracy of the meteorological measurements. According to the optical geometric ray method,an improved microfacet model is proposed,which introduces multiple random parameters generated by the reflection of light from rough road surfaces, and establishes a hemispherical equivalent simulation model. This model microscopically elucidates the reflective properties of photons when interacting with rough road surfaces,and it allows for the convenient and precise simulation and analysis of the distribution of photons after reflecting off rough surfaces. Building on this,a rough road surface link transmission model based on wireless laser transmission theory has been developed to study and simulate the optical power characteristics received by the detection system under different road roughness levels and angles of incidence. The random distribution function of the normals of road microfacets under varying degrees of roughness is obtained by using refusal sampling technique,which determines the changes in photon reflection direction, and the distribution state of photons after reflection from the rough surface is statistically analyzed by using the Monte Carlo method,which derived the variations in reflected optical power under different angles of incidence and road roughness conditions. Subsequently,the validity of the model is confirmed. For the experimental design,a non-contact laser-based road surface meteorological condition detection system operating at a wavelength of 850 nm is constructed,which mainly consists of the light source drive circuit with emitting the light power of 50 mW,the laser receiving unit,and the optical system(including an optical antenna,the optical filters,and an optical collimator,etc.). The system is positioned at a vertical height of 2 m from the road surface to be measured,which is capable of not only monitoring road conditions in real time but also validating the photon distribution and optical power variation predicted by the simulation model. The simulation results and experimental data both reveal a trend where the received optical power gradually decreases as the incident angle between the incident light and the road surface normal increases. Notably,at an incidence angle less than 15°,the greater the road surface roughness,the lower the received optical power. Conversely,at angles greater than 15°,the trend reverses—the greater the road surface roughness,the higher the optical power,and this relationship tends to become linear at certain roughness levels. When the incidence angle reaches 60°,the received optical power stabilizes and undergoes minimal further change. Additionally,the experimental results indicate that the signal-to-noise ratio of the received optical signal does not change with the variation of road roughness,but closely correlates with the incident angle. This study presents and validates an equivalent simulation model for the reflection of light from rough road surfaces, and confirms the model's accuracy and feasibility in practical applications through experiments with an actual non-contact road surface meteorological detection system. The findings not only enhance our understanding of road surface reflective properties but also offer practical insights for the optimization of road detection techniques and meteorological condition monitoring. Thus,the research provides a theoretical and technical support for further improving road detection technology and monitoring meteorological conditions,ultimately contributing to the advancement of road safety measures. ? 2024 Chinese Optical Society. All rights reserved.
    Affiliations:(1) School of Electronic Engineering, Xi'an University of Posts and Telecommunications, Xi'an; 710121, China; (2) Xi'an Institute of Optics and Precision Mechanics of CAS, Xi'an; 710119, China
    Publication Year:2024
    Volume:53
    Issue:7
    Article Number:0712005
    DOI Link:10.3788/gzxb20245307.0712005
    數(shù)據(jù)庫ID(收錄號):20243116788002
  • Record 499 of

    Title:The temperature variation of different cooling methods for the preparation of chalcogenide glasses
    Author Full Names:Fan, Wenwen(1); Xu, Junfeng(1); Yao, Zhirui(1); Li, Na(1); Li, Xuyang(2)
    Source Title:Infrared Physics and Technology
    Language:English
    Document Type:Journal article (JA)
    Abstract:The cooling rate has a great influence on the performance of chalcogenide glass, but it is unclear how much the actual cooling rate changes with different cooling methods. In this study, the infrared thermal imaging technology was employed to observe the temperature change in various cooling methods. The temperature curves and the cooling rates between different cooling methods were analyzed from the infrared images. The results show that at 250 °C, the cooling rates follow the order: water quenching > air compressor cooling > salt bath cooling > air cooling > asbestos wrapping cooling; whereas at 150 °C, the sequence is: water quenching > air compressor cooling > air cooling > asbestos wrapping cooling > salt bath cooling. Then the temperature changes inside the sample was simulated and the result shows that the temperature gradient of water quenching is much greater than that of air cooling method, which is why cracks often appear in the glass prepared by water quenching. Finally, Gex-S(90-x)-Sb10 glass was successfully prepared using the air cooling method and it shows excellent optical properties that can transmit both visible and infrared light. ? 2023 Elsevier B.V.
    Affiliations:(1) School of Materials and Chemical Engineering, Xi'an Technological University, 710021, China; (2) Xi'an Institute of Optics and Precision Machanicas, CAS Shaanxi, Xi'an; 710119, China
    Publication Year:2024
    Volume:136
    Article Number:105083
    DOI Link:10.1016/j.infrared.2023.105083
    數(shù)據(jù)庫ID(收錄號):20240115321626
  • Record 500 of

    Title:Generation of chiral optical vortex lattice for controlled aggregation of particles
    Author Full Names:Yang, X.B.(1); Zhang, H.(1); Tang, M.M.(1); Ma, H.X.(2); Tai, Y.P.(1,3,4); Li, X.Z.(1,3,4)
    Source Title:Applied Physics Letters
    Language:English
    Document Type:Journal article (JA)
    Abstract:The chiral light field has attracted great attention owing to its interaction with chiral matter. The generation of chiral light fields with rich structures has become crucial as it can expand application scenarios. Herein, we introduce a chiral optical vortex lattice. As a whole, the optical vortex lattice has a chiral intensity distribution, with each spiral arm having sub-vortices (chiral phase). By using an expansion factor to adjust the involute of a circular lattice, this helical optical vortex lattice can be continuously varied from a circular lattice. The chirality of intensity and phase can be controlled independently. Furthermore, the optical tweezers using the lattice demonstrate the capability of sub-vortices to manipulate particle movement, with the chiral intensity determining the trajectory of particle motion. As the lattice possesses both intensity and phase chirality, it may also find potential applications in tasks such as chiral structure microfabrication. ? 2024 Author(s).
    Affiliations:(1) School of Physics and Engineering, School of Chemistry and Chemical Engineering, Henan University of Science and Technology, Luoyang; 471023, China; (2) Research Center for Frontier Fundamental Studies, Zhejiang Lab, Hangzhou; 311100, China; (3) State Key Laboratory of Transient Optics and Photonics, Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi'an; 710119, China; (4) Provincial and Ministerial Co-construction of Collaborative Innovation Center for Non-ferrous Metal New Materials and Advanced Processing Technology, Luoyang; 471023, China
    Publication Year:2024
    Volume:125
    Issue:1
    Article Number:011106
    DOI Link:10.1063/5.0214498
    數(shù)據(jù)庫ID(收錄號):20242816677455
  • Record 501 of

    Title:An Infrared Evanescent Wave Sensor for Detection of Ascorbic Acid in Food and Drugs
    Author Full Names:You, Tianxiang(1); Zhao, Yongkun(1); Xu, Yantao(2); Guo, Haitao(2); Zhu, Jihong(3); Tao, Haizheng(1); Zhang, Xianghua(4); Xu, Yinsheng(1)
    Source Title:Journal of Lightwave Technology
    Language:English
    Document Type:Journal article (JA)
    Abstract:An infrared evanescent wave sensor was developed to accurately detect ascorbic acid (vitamin C) in food and drugs. The sensor was fabricated by tapering and bending of As2S3 infrared fibers. Due to the broad transmission range (5000-1500 cm-1) of the infrared fibers, covering the characteristic absorption peak of ascorbic acid (C = O at 1760 cm-1 and C = C at 1690 cm-1), the sensor is capable of accurately identifying and detecting the concentration of ascorbic acid. Experimental results demonstrated that a conically tapered fiber sensor with a waist diameter of 50 μm, waist length of 30 mm, and a radius of 2 mm achieved a maximum sensitivity of 0.1257 (a.u./(mg·ml-1)) and a limit of detection (LoD) of 0.917 mg/ml. Furthermore, the application of this fiber sensor in various vitamin C-containing tablets and juices validated its high accuracy and minimal measurement deviation (as low as 0.19 mg/ml). Compared to traditional detection methods, the sensor not only provides a faster and cost-effective solution to identify the substance but also maintains high accuracy. It offers a new approach to quantitative and qualitative analysis of food and drugs. ? 1983-2012 IEEE.
    Affiliations:(1) Wuhan University of Technology, State Key Laboratory of Silicate Materials for Architectures, Wuhan; 430070, China; (2) Chinese Academy of Sciences (CAS), State Key Laboratory of Transient Optics and Photonics, Xi'an Institute of Optics and Precision Mechanics, Xi'an; 710119, China; (3) Yangtze Optical Fibre and Cable Joint Stock Limited Company (YOFC), State Key Laboratory of Optical Fiber and Cable Manufacture Technology, Wuhan; 430073, China; (4) Institut des Sciences Chimiques de Rennes Umr 6226, Rennes; 35042, France
    Publication Year:2024
    Volume:42
    Issue:9
    Start Page:3494-3500
    DOI Link:10.1109/JLT.2024.3357491
    數(shù)據(jù)庫ID(收錄號):20240615489260
  • Record 502 of

    Title:Underwater Blue-green Light Weak Signal Detection Based on Adaptive Stochastic Resonance
    Author Full Names:Zhang, Jianlei(1); Zhang, Juan(1); Zhu, Yunzhou(2); Yao, Xinyu(1); Wu, Qianqian(1); Yang, Yi(1); He, Fengtao(1)
    Source Title:Guangzi Xuebao/Acta Photonica Sinica
    Language:Chinese
    Document Type:Journal article (JA)
    Abstract:The optical signal is easy to be absorbed and scattered during transmission with Underwater Optical Wireless Communication(UWOC)technology,resulting in serious optical power attenuation and further affecting the signal quality. In order to realize long-distance data transmission,it is very important to recognize,enhance and extract weak light signal under low Signal-to-Noise Ratio(SNR). Stochastic resonance produces synergistic effect through nonlinear system,weak driving signal and appropriate amount of noise under certain conditions,which not only improves the output signal-to-noise ratio,but also detects useful signals. However,the current parameter selection of stochastic resonance system depends on artificial setting,which is not flexible enough to give full play to the advantages of stochastic resonance signal detection. In this paper,an adaptive stochastic resonance detection scheme based on multi-strategy fusion particle swarm optimization is proposed by analyzing the characteristics of weak underwater light signals and the conditions of stochastic resonance generation. It solves the problem that traditional particle swarm optimization is easy to fall into local optimization resulting in low convergence accuracy and difficult convergence. By introducing adaptive inertia weights to dynamically adjust the local search ability and global search ability of particles,the convergence speed of the algorithm is accelerated. In the process of particle evolution,neighborhood detection is used to strengthen the detection of local extremum location neighborhood,which makes the search radius of the algorithm larger in the initial stage of evolution,and gradually decreases with the increase of iteration times,which increases the refinement ability of the algorithm. Using Cauchy variation and reverse learning interactive strategy to mutate the optimal solution,the local optimal solution in Particle Swarm Optimization is broken,and the ability of the algorithm to escape from local space is effectively improved. In order to evaluate the feasibility and effectiveness of the proposed algorithm,simulation is carried out under the established UWOC weak signal detection system. Considering the special property of pilot signal,that is,some known data is inserted at the sending end and can be accurately extracted at the receiving end,it can be used as a reliable reference signal for parameter estimation. Therefore,this paper selects a specific number of code elements for parameter optimization. By taking the output SNR of the system as the selection index,the optimal system parameter which makes the output SNR maximum is searched and iterated continuously within the preset algorithm parameter range. The optimal system parameters are substituted into the fourth-order Runge-Kutta equation,the output response is obtained by discretization,and the weak light signal is detected. Finally,the error performance of bipolar non-return-to-zero signal with white Gaussian noise is compared under four detection schemes:non-stochastic resonance,fixed parameter stochastic resonance,adaptive stochastic resonance based on particle swarm optimization algorithm and multi-strategy fusion particle swarm optimization algorithm. The simulation results show that the bit error rate performance of the non-stochastic resonance system is worse than that of the other three detection schemes,and the bit error rate performance of the fixed parameter stochastic resonance system has limitations. Adaptive stochastic resonance can significantly improve the bit error rate performance of the system,especially above -6 dB,and the improvement effect is very obvious. Compared with the adaptive stochastic resonance based on particle swarm optimization algorithm,the proposed algorithm has faster convergence speed, more accurate optimization results and less error performance. In order to verify the effectiveness and feasibility of the proposed method, a UWOC experimental system is established. The experimental results show that when the received signal-to-noise ratio is - 1.7 dB,the bit error rate of the proposed algorithm can reach 2×10-4,and its performance is better than that of NO-SR and F-SR, which once again verifies the effectiveness of the proposed algorithm. ? 2024 Chinese Optical Society. All rights reserved.
    Affiliations:(1) School of Electronic Engineering, Xi'an University of Posts and Telecommunications, Xi'an; 710121, China; (2) Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi'an; 710119, China
    Publication Year:2024
    Volume:53
    Issue:3
    Article Number:0301003
    DOI Link:10.3788/gzxb20245303.0301003
    數(shù)據(jù)庫ID(收錄號):20241215774978
  • Record 503 of

    Title:Ultrafast laser triggering nanocrystallization inside Nd-doped photo-thermo-refractive glass and its application in Q-switched laser
    Author Full Names:Wang, Xu(1); Li, Guangying(2); Zhang, Guodong(3); Wang, Jiang(3); Zhang, Yunjie(4); Cheng, Guanghua(3)
    Source Title:Optics Express
    Language:English
    Document Type:Journal article (JA)
    Abstract:Photo-thermo-refractive (PTR) glass doped with rare-earth ions has attracted considerable attention due to its excellent linear photosensitivity and laser performance. This study investigates the nonlinear photosensitive nanocrystallization induced by ultrafast laser irradiation in Nd-doped PTR glass. Phase contrast microscopy reveals that both Gaussian and Gaussian-Bessel beams can modulate the refractive index positively or negatively, depending on specific conditions. Notably, Gaussian-Bessel beams can significantly extend the thickness of the laser-modified layer. Optical spectra indicate the formation of silver nanoparticles, with concentration increasing as pulse energy increases. Furthermore, X-ray diffraction and transmission electron microscopy confirm the precipitation of nanocrystals with the composition of NaF following laser irradiation and thermal treatment, consistent with conventional PTR glass. The nonlinear optical characteristics of the treated sample are evaluated and successfully applied in a passive Q-switched laser, exhibiting both gain characteristics and saturable absorption. This study provides an effective strategy for multifunctional integrated on-chip devices that possess high damage thresholds and enhanced stability. ? 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.
    Affiliations:(1) School of Science, Xi’an Shiyou University, Xi’an; 710065, 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; (3) School of Artificial Intelligence, Optics and Electronics, Northwestern Polytechnical University, Xi’an; 710072, China; (4) School of Science, Xi’an Polytechnic University, Xi’an; 710048, China
    Publication Year:2024
    Volume:32
    Issue:22
    Start Page:38931-38941
    DOI Link:10.1364/OE.537472
    數(shù)據(jù)庫ID(收錄號):20244317271267
  • Record 504 of

    Title:Efficient generation of broadband photon pairs in shallow-etched lithium niobate nanowaveguides
    Author Full Names:Fang, Xiao-Xu(1,2); Wang, Leiran(3,4); Lu, He(1,2)
    Source Title:Optics Express
    Language:English
    Document Type:Journal article (JA)
    Abstract:We design and fabricate shallow-etched periodically poled lithium niobate waveguides to realize highly efficient broadband spontaneous parametric down-conversion (SPDC) on nanophotonic chips. The shallow-etched waveguide can tolerate the non-uniformities of waveguide width induced by fabrication imperfections, enabling the generation of photon pairs with high count rate and bandwidth. We demonstrate photon-pair generation with a high brightness of 11.7 GHz/mW and bandwidth of 22 THz in a 5.7-mm-long PPLN waveguide. The generated photon pairs exhibit a strong temporal correlation with a coincidence-to-accidental ratio of up to 16262±850. Our results confirm the feasibility of shallow etching in the fabrication of an efficient SPDC device on the platform of lithium niobate on an insulator, and benefit quantum information processing with a broadband photon source. ? 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.
    Affiliations:(1) School of Physics, State Key Laboratory of Crystal Materials, Shandong University, Jinan; 250100, China; (2) Shenzhen Research Institute of Shandong University, Shenzhen; 518057, China; (3) State Key Laboratory of Transient Optics and Photonics, Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi’an; 710119, China; (4) University of Chinese Academy of Sciences, Beijing; 100049, China
    Publication Year:2024
    Volume:32
    Issue:13
    Start Page:22945-22954
    DOI Link:10.1364/OE.519265
    數(shù)據(jù)庫ID(收錄號):20242616354357
特级毛片AAAAAA| 激情久久丁香| hd五月婷婷在线| www色五月| 色婷五月| 五月婷啪啪| 九九综合网色全集 | 色综合久久伊伊婷婷五月| 久久久久9999| 99久在线视频| 五月婷婷九九热| 五月丁香成年黄色| 九九热在线精品视频| 国产91在线视频| 天天爽天天爽夜夜爽| 成人做爰A片免费看视频| 丁香综合婷婷开心激情网| 五月天伊人久久久久| 久久99三级在线视频| 婷婷综合色播网| 91男同视频| 狠狠操天天操天天操| 五月天伊人| 激情久久久| 99九色视频在线观看| www.射伊蕉婷婷| 99∨VTV| 国产资源在线视频| 少妇人妻人伦A片| 久久艹99| 久久草中文日韩欧美| 2017人人操| 麻豆AV一区二区三区| 日本色色网站| 999激情视频| 婷婷天堂综合| 99爱在线精品视频免费观看| 天天五月丁香五月| 天天拍天天操| 亚洲AAAA网| 成人日韩欧美| 久久欧洲综合网| 伊大人久久| 国产精品成人av在线观看春天| 成人免费黄色短视频| 狠狠操在线视频| 老妇六区| 色性日本| 97久久精品视频| 色婷婷九月| 成人久碰| 丁香五月六月综合激情| 97亚洲婷婷| 欧美日本黄色| 日日婷婷不卡| 啪啪啪丁香五月| 亚洲日韩欧美综合VA| 一级二级色大片| 97操碰在线视频| 91干视频| 婷婷五月情| 精品视频99看在线视频| 人人色人人弄人人操| 五月婷婷久草在线视频综合| 婷婷丁香五月天熟女丝袜| 五月婷婷视频| 日本综合久| 日日干日日| 五月色情网| 在线中文字幕免费视频| 色色色地址| 99视频色在线观看| 曰韩五月丁香色婷婷无码| 婷婷激情丁香六月| 日本99在线视频| 婷婷丁香五月亚洲| 六月丁香综合网| 久久久五月天婷婷| 久久婷婷五月综合激情国产| 国产精品久久久99视频| 99年操人人爽| 荔枝视频app污| 大香蕉五月丁香| 夜夜操狠狠操| 岛国av电影网站| 免费在线a| 久99久视频| www。88热在线视频免费观看| 99精品在线观看| 婷婷午夜天| 成人短视频在线| 99色视频| 国产成人99久久亚洲综合精品| 婷婷五月天久久综合88| 五月丁香影视| 色99欧洲色19| 九九99九九99九九99视频网| 婷婷亚洲天堂| 色五月激情| 性婷婷| Www.久久| 色情五月综合婷婷| av性爱在线| 91精产一区三区免费观看| 日日天天干| 天天狠狠色| 91日日日| 深夜婷婷 丁香| www.操.com| 色婷婷电影| 婷婷综合仓库中文| 99狠狠操一| 丁香六月av| www亚洲无码| 欧美内射AA| 五月开心激情网| 色五月婷婷操逼| 福利视频在线播放| 精品久久这里热66| 99在线er热| 七月丁香婷婷 色色| 婷婷五月天在线观看| 欧日美女Va| 婷婷激情97| 五月天激情电影| 丁香五月开心五月激情| 久久久97| 新男人天堂人妻| 久机视频这只有精品| 开心五月深爱五月丁香五月激情五月| 日本久久婷| 天堂久热| 99热精品在线| 六月婷婷久久| 国产激情综合五月| 大香蕉啪啪| 综合狠久久| 久久精品4| 婷婷丁香色情| 婷婷五月丁香狠狠| 国产成人在线精品| 五月丁香综合网| 色99在线视频| 俺去也婷婷| 色婷婷婷综合五月天| 天堂综合久| 人妻体体内射精一区二区| 婷婷激情五月| 99精品久久久久久久婷婷久久| 国产9色在线/日韩| 一级片无码| 亚洲AV成人精品日韩在线播放| 开心五月综合| www.com.色色| 99噜噜噜在线播放| 亚洲综合五月天婷婷丁香| 日日夜夜小色哥| 色狠狠五月天| 婷婷的色色五月天| 婷婷综合中文字幕| 日本五月婷婷| 激情爱爱网站| 九九99一区| 久久99热免费| av九九| 综合九九久久| 亚洲岛国电影| 搡BBBB搡BBB搡18 | 超碰成人在线观看| 婷婷丁香五月亚洲17cao| 亚洲激情高潮| 亚洲视99| 久久多色| 婷婷国产欧美97| 色综合色色| 欧洲毛片基地c区| 中文av网站| 亚洲男人的天堂婷婷色五月| 婷婷基地成人五月天| 国产视频福利| 五月天婷婷激情四射综合| 天天操夜夜操| 极品少妇高潮啪啪AV无码| 激情综合网五月丁香| 日本色色视频| AV天堂婷婷五月天| 深爱激情九九五月天 | 色停停香蕉视频| 激情丁香五月天图片| 色综合五月婷婷狠狠干| 久久五月天合网| 婷婷综合色| 午夜色丁香| 亚洲久久天堂| 99综合网| 国产成人精品一区二三区熟女在线| 激情五月色婷婷| 日日干天天| 色五月亚洲开心网| 欧美va亚洲va在线播放| 五月丁香六月婷婷久久久综合| 五月丁香色婷婷伊人| 超碰chaompinm| 婷婷欧美激情| 超碰在线网站| 亚洲激情| www久久久久久久| 超碰人人在线观看| 五月天婷a在线| 无码成人AAAAA毛片AI换脸| 97人人干人人操| 超碰99资源站| 色婷婷五月天| 五月网| 色婷婷五月天偷拍| 色色色综合色| 亚洲精品V天堂中文字幕| 婷婷狠狠色| 丁香六月婷婷激情| 五月情婷婷| 99热成人在线| 色五月婷婷五月丁香五月| 狠狠干青青草| 婷婷丁香人妻久久在线观看| 好激情在线综合网| 五月亭亭综合五码| 色五狠狠| 日婷婷久久开心| 五月丁香六月婷婷开心网| 九九综合久久| 五月婷婷六月丁香在线| 日狠狠| 另类激情综合| 国产精品国产成人国产三级| www热久久yy9| 99re在线精品视频| 欧美日韩99| 久热91| 色色色色色色色色综合网| 久热婷婷| 色五月网址| 99热在线只有精品| 爱久久小说下载网| wwwss在线观看| 91狠狠色丁香婷婷综合久久精品| 久久99热网| 超碰在线免费观看日韩| 夂夂夂夂夂夂夂夂夂夂夂夂夂夂夂夂夂夂夂亚洲亚洲亚洲亚洲亚洲亚洲亚洲亚洲色 | 美国天天操无码| 亚洲热久| 黄色成人网站在线播放| www激情| 五月天激情综合首页| 99久久66| 五月丁香六月婷精品视频| 少妇久久诱惑视频| 亚洲激情免费视频观看| 九九精品免费| 玖玖在线| 五月婷婷香| 成人做爰A片免费看网站找不到了| 无码 av电影| 国产AV成人精品| 狠狠色九月| 丁香五月激情网| 丁香五月影院| 99热精品在线播放观看| 人人干Av| 丁香六月婷婷色XXXXX| 欧美激情VA永久在线播放| 91日日日| 婷婷爱五月天| 色网五月婷婷| 4399高清无码视频| 丁香五月天无码AV| 玖玖九九99| 99久久激情视频| 国产凸凹视频熟女A片| 色啪影院| 91五月天| 热久久色| 99色在线| 伊人久久五月天| 这里只有精品视频| 五月丁香六月激情欧美综合| 久爱综合| www.97干视频| 丁香六月AV| 国产高清精品色| 久色五月丁香视频| 欧美激情五月天| 色婷婷狠狠禁18久久| 欧美月久久| 99久在线精品99re8| 日本色婷婷五月天成人电影| 视色综合| 五月婷六月| 少妇高潮A片无套内谢麻豆传 | 无码激情AAAAA片-区区| 夜色.cnm| 婷婷五月激情综合| 五月天久久www| 五十六十老熟女HD60| 97天堂| 婷婷狠狠干| 亚洲操B视频| 婷婷五月激情四月综合| 五月丁香六月花| 超碰高清在线| AA片在线观看视频在线播放| 99re视频在线| 天天狠天天狠| ji'qi'luan'ren'lun| 日韩色五月| 激情婷婷五月天| 五月丁香888| 亚洲五月丁香综合网| 色色综合视频| 五月天久久久| 玖玖综合色区在线观看| 五月天激情综合在线| 欧美综合五月丁香六月婷| 五月丁香婷婷深深爱| 人妻少妇色综合| 青青色com久久| 天天久久人人| 欧州色色| 精品色色| 丁香五月婷婷亚洲另类| 国产视频久色| www.色婷婷| 风流少妇A片一区二区蜜桃| 亚洲五月天色色| 无码地址| 色久丁香五| 日欧一片内射VA在线影院| 月色色综合婷婷网| 五月天婷婷激情小说| 丁香五月天婷婷中文字幕| 欧美电影在线观看| 日韩操逼大片| 噜噜噜噜噜色| 色五月婷婷五月天| 丁香五月婷婷天堂大香蕉| sisi热国产| 激情亭亭五月| 国产99久| 99在线er热| 亚洲精品永久久久久久| 开心五月婷婷激情| 色玖玖爱| 人人爽欧美婷婷久久久五月丁香| 九九在线视频| 欧美啪啪9| 色婷婷先锋| 开心五月婷婷激情| 九草性爱| 色操b| 99热精品在线播放| 五月丁香少妇| 亚艹艹| 狠狠精品干练久久久无码中文字幕| 婷婷丁香成人五月天| 亚洲女婷婷五月基地综合久久久| 国产亚洲99久久精品| 91久久国产综合久久| 婷婷五月免费观看| 久99久视频| 久久香蕉婷婷| 丁香五月六月激情| 少妇做爰免费视看片| WWW.久久久久久久| 色婷婷狠狠18| 婷婷99视频在线| 五月色情婷婷| 欧美久久网| 久久99免费视屏| 五月天色婷婷图片| 六月婷婷中文字幕| 第四色激情网| 日本猛少妇色XXXXX猛叫| 色操综合| 深爱五月天 开心网| 五月丁香婷婷色| 色情婷| 婷婷欧美激情| av操逼网| 欧美丁香六月在线观看视频| 99久久性爱| 婷婷久久五月天丁香| 99国产这里只有精品| 国产偷人爽久久久久久老妇APP| www超碰| 熟妇人妻中文字幕无码老熟妇| 操草草草| 五月丁香六月欧美| 激情综合五月天| 丁香婷婷综合激情五月色,开心五月丁香花综合网,激情综合五月亚洲婷婷,五月天 | 大战熟女丰满人妻AV| 国产激情AV| 色综合天天| 九九热99在线视频| 思思久日精品视频| 三级毛片视频| 五月人人丁香婷婷五月人人丁香| 思思热在线| 激情婷婷五月久久| 91欧美日韩综合| 91久久综合| 狠狠摸狠狠摸| 中文字幕亚洲-区久久99婷婷| 五月丁香六月婷婷综合网缴情| 99爱视频| 天天操天天操| 国产毛多水多女人A片| 激情丁香久久| 99综合视频| 婷婷她六月天| site:pnnrt.com| 66精品国产成人| 免费亚洲婷婷中文字幕| 91尤物九色在线| 色婷六月| 99九九精品视频| 色九九九九| 婷婷午夜综合| 国产欧美日韩综合精品一区二区 | 小视频在线亚洲| 亚洲情欲| 日本女天天爽| 激情五月综合| 六月婷婷五月丁香首页| 少妇人妻丰满做爰XXX| 丁香五月婷婷久久久| 人人操AV| 99久久这里只有精品免费官网| 裸睡玩奶头(高H)| 亚洲精品操一操、噜一噜、摸一摸、爽 | 婷婷爱婷婷| 黄色视频网站在线播放| 婷婷色色播五月天| 碰碰人人人| 性生活久久朋友人妻| 香蕉99网| 天天插综合网| 五夜丁香| 久久婷婷网| 激情视频网址| AA丁香综合激情| 99热香港| 九九日伊人| 婷婷五月中文字幕国产| 国产99久9在线+|+传媒| 亚洲综合五月天| 激情久久久久久久久久| 丁香六月婷婷综合激情欧美| 九九热色视频| 性av| 婷婷香五月| 亚洲人成网站999久久久综合| 99精品免费视频| 成人五月天丁香婷| 五月婷丁香| 六月激情婷婷综合| 9热在线| 天天插天天插天天插天天插| 无码A片一区二区免费| 99九九视频| 欧美久热| 婷婷久草| 久久婷婷综合五月趴| 五月天婷婷激情在线色图| 日本色色网站| 欧美噜噜久久久XXX| 色一情一乱一乱一区91Av| 色色综合视频| 五月天婷婷AV| 色综合久久久久| 五月丁香婷婷国产精品综合| 婷婷情色五月| 操逼巨乳91| 这里只有精品偷拍| 天天干人人奸97| 五月天精品| 99在线观看| 欧美成人一区二区三区在线视频 | 九月丁香八月婷婷加勒比| 丁香五月亚综合图片| 久久九九@| 人人爱人人草| 五月婷婷丁香综合| 久久久久网站| 人人操av| 亚洲激情97五月天| 97人人操人人| 99热这里有精品| 激情内射p| 伊人超碰| 激情五月天综合网| 六月天婷婷| 丁香六月开心| 丁香五月瑟瑟| 91在线日| 婷婷六月天亚州| 天天操天天曰天天射| 99热精品无码| 5月婷婷五月天| 超碰91人人操| av九九| 五月天婷婷久久| 激情五月天综合网站网站网站| 婷婷五月天综合亚洲| 最近中文字幕2018| 五月六月激情婷婷| 色婷婷AⅤ| 色情婷婷五月天| 日本熟女内射| 五月婷婷欧美| 色逼综合网| 五月天丁香婷| 五月丁香花免费视频| 婷婷射图| 超碰国产在线播放| 中文字幕成人影视| 激情五月天啪啪| 97操碰在线视频| 无码激情AAAAA片-区区 | 亚洲99手机免费看视频| 色娸娸综合网| 色色无码| av在线中文| 久久成人精品视频| 97在线碰| www...com黄在线观看| 久久伊人婷婷| 婷婷色爱| 成人视频九九| 超碰97免费在线| 激情五月天网站| 在线观看免费狠狠色丁香香综合| 这里只有精品在线播放| www.99久| 精品视频网| 深爱激情五月网| 日狠狠| 很很操很很操| 色情丁香五月婷婷精品| 影音先锋男人站,影音先锋男人色资源网,影音先锋AV最新资源站,影音先锋AV资源 | 性做爰A片免费视频A片直播| 五月天综合在线观看视频| 日韩a热| 五月婷婷综合影院| 国产,欧美,学生妹,视频| 婷婷综合亚洲| 天天爽免费视频| 青青草a在线| 婷婷情色五月天| 极骚大香蕉伊人| 欧美激情综合| 五月丁香六月激情视频| 狠狠操天天日| 丁香六月婷婷久久综合| 日韩免费99| 亚洲AV在线免费看| 亚洲操b| 丁香五月天资源网| www.五月激情红色| 婷婷丁香五月天婷婷| se.久久视频在线观看| 久久xx| 99热国产精品| 99性爱视频| 丁香五月第四色88| 99这里只有精品国产| 91九色精品| 婷婷色色色| 最近韩国日本免费高清观看| 97久久人人| 5月婷婷6月六月丁香| 森林影视大全,最好看的2019年视频 | 婷婷激情人妻| 国产午夜一区二区三区| 丁香5月啪啪| 五月丁香日本片| 婷婷射综合| 免费啪啪啪网站| 婷婷五月激情四射手| www.色五月| 久久久WWW| 日日做A爰片久久毛片A片英语| 久99热| 色视五月天婷婷| 五月丁香综合啪啪| www.99热视频| 99热线观看9| av五月丁香| 99欧美精品99日本精品| 免费看欧美成人A片无码| 五月丁香亚洲综合| 婷婷永久在线| 久久婷婷五月综合伊人| A片试看50分钟做受视频| 婷婷性爱五月天| 五月花婷婷丁香| 亚洲色小说在线综合| 夜夜骑操AV| 99精品视频在线观看免费| 色综合中文色综合网| 色婷婷影音| 亚洲国产黄色电影| 五月 婷 久| 亚洲九九99精品视频在线播放| 99色婷婷| 国产午夜精品一区二区三区四区 | 亚洲视频99| 99热国产精品| 久超超碰| AA久久| 大香蕉久久婷婷精品综合| 色五月激情五月| 日本VA视频| 激情五月狠狠| 狠狠干五月丁香综合网| 情婷婷五月天| 久久A区B区| 操逼棍操逼| 五月天婷婷视频30| 婷婷五月天天aV| 婷婷五月天第四色| 五月丁香激情婷婷综合| 日日激情网| 五月天激情综合10p| 青青草六月丁香| 亚洲性爱99在线| 六月婷婷影院| 色综合久久久久久久久五月| 综合六月激情婷婷| 婷婷五月深深爱| 五月天激情视频五月天| www,26uuu,c0m,色情| 久久综合丁香激情五月| 婷婷丁香色无五月| 五月婷婷丁香俺日污视频| 九九婷婷网五月天| 激情网婷婷五月天| 成人在线视频一区| 99九九在线精品热动漫| 99热国产精品| 国产性爱亚洲是图| 99精品偷自拍| 91日韩在线| 国产婷伊人| 91av视频| 97香蕉人人在线观看| 99内射视频| 婷婷情色五月天| 欧美久久婷婷| 久热只有这里有精品| 婷婷五六月丁香| 深爱激情网婷婷| 这里只有精品久| 深爱五月网| 十一月婷婷激情四射| 99久久精品国产色欲| 色色色婷婷五月天| 日日.c| 最新高清无码专区| 熟女色色一区二区| 青青久久91| 九九色院| 99热这里是精品| 九九这里有精品视频| 久热这里精品免费| 99爱在线视频观看| 五月婷婷丁香五月 | 97色欧美| 天天操婷婷| 99精品在线| Av中文在线| www.99热这里精品| 久久婷五月婷| 另类图片激情五月天| 99惹精品视频| 日本色视| 激情综合网五月丁香| 思思热这里只有精品| 色欧美一级| 亚洲国产成人AV在线| 五月天婷婷色色网| 26uuu视频欧美| 丁香激情六月天婷婷| 天天操夜夜橾| 人人综合久| 国产亚洲精品AAAAAAA片| 大香蕉伊人丁香五月| 99少妇精品| 第四色激情网| 五月天婷婷丁香蜜桃91| 五月成人天| 日韩在线视频网站| 天天色情站| 丁香五月婷婷高清| 影音先锋色婷婷| 情欲综合网| www.狠狠艹| 色五月婷婷综合| 另类少妇人与禽zOZZ0性伦| 日韩AV在线电影| 九九AV在线| 激情网第四色| 五月婷婷啪啪| 99色色网| 九一九九黄色| 色婷久久| 五月婷婷色色| 亚洲色欲AAAAAA| 日日夜夜狠狠| 国产人妻777人伦精品HD| 婷婷丁香精品视频在线观看| 天天射天天干天插色综合| 青草性爱视频| 狠狠做深爱婷婷久久综合一区| 涩综合网| 久草婷婷网| 丁香五月欧美色综合| 婷婷六月综合在线| 亚洲天堂aaaa| 开心五月天激情网| 久久久久五月丁香| 色噜噜狠狠色综合无码久久欧美| 婷婷五月天激情综合网| 日本久久精品18| 97干在线| 中文字幕97超级碰| 五月丁香网中文字幕| 色99色| 99久久国产宗和精品1上映| 91久久九九| 色视频2025| 99这里只有精品|v| www.久热| 五月婷婷亚洲色图| 熟女婷婷网站一婷婷五月一丁香婷婷一婷婷激情网 | 蜜臀AV在线观看| 成年视频免费观看| 青青操avbb| 久久综合五月天| 久久小说| 色哟哟www| www.com操| 色婷久九| 五月天啪啪网| 26UUU一区二区| 欧美五月丁香| 欧美S码亚洲码精品M码| 九九九九九九毛片| 狠狠999| 婷婷97碰碰| 国产av第一专区| 天天噜天天插| 99视频只有精品| 狠狠色丁香| 色一情一乱一乱一区91| 丁香五月激情综合啪啪| 精品久久人妻| 丁香五月777| 人人干Av| 久久草大香蕉| 冬月かえでAV无码播放| 中文不卡一二三区| 九九亚洲综合| 五月婷婷丁香五月| 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 | 婷婷五月色| 久久婷婷网站| 成人综合伍月天| www.色五月| 97干在线观看视频| 99热这里只有精品18| 99热国品| 五月色色网| 人人草人| 超碰日韩成人| 亚洲性受XXXX五月丁香| 能看的av| 97婷婷五月| 激情5月婷婷狠狠干| 日韩成人AV在线播放| 无码一区二区三区四区五区91c| 婷婷九月激情| 97AV在线视频| 碰碰人人漕| 婷婷六月花| 国产精产国品一二三在观看| 久久99久久99精品免视看婷| 久久这里都是精品| 婷婷色五月综合| 日韩欧美一区二区三区四区| 碰97久久| 综合色视频| 丁香五月六月激情| 久久国产一区二区三区| 婷婷精品免费久久| 色色热| 色色热日| 亚洲六月婷| 天天干天天做| 91久久久久久| 99精品国产在热久久婷婷| 九九九九中文字幕| 国产色五月婷婷| 在线不卡视频| 夜夜爽天天| 综合色99| 五月天婷婷网站888| 丁香成人五月天| 色爱爱综合网| 五月丁香色婷婷熟女| 欧美性生交XXXXX无码小说| 亚洲成人网无码| 色一情一乱一乱一区91| 久久3p| 五月婷婷啪啪| 色色丁香色五月| 少妇人妻综合色6699| 综合色色五月| 久久五月天黄色五月天色网址| 51国精产品自偷自偷综合| 91精品久久久久| 五月婷婷丁香大陆免费| 婷婷五月天网址| 五月天婷婷社区| 超爽内射| 婷婷五月天激情网站| 亚洲在线网站| 严洲天天插| 丁香五月天操B| 亚洲女婷婷五月基地综合久久久| 国产精品久久久久久久久久| 99rewww| 九九热最新视频| 五月丁香久久精品在线观看| 99精品久久久久久久婷婷| 激情五月丁香社区| 国产avapp 网| 久操综合| 精品在线网站| 日韩无码成人电影| 日韩另类| 色噜噜狠狠色综合无码久久欧美| 大香蕉综合在线| 久久九九网| 九九五月天| 丁香五月影院| 色色色五月婷婷| 、激情六月天| 综合网五月| 五月天色播网| 性一交一乱一交A片久 | 99热这里只有精品4| 精品99这里有| 99在线免费观看| 99 频99热国里只有精品| 久久99国产综合精品免费| www色婷婷久久综合久色| 粉嫩AV久久一区二区三区| 五月婷高清视频| 99亚洲天堂| va婷婷在线免费观看| 五月天丁香婷婷视频网址 | 婷婷五月天另类网站| 狠狠色综合图片| 99热在线免费| 久久天堂婷婷五月| 色135综合网| 超碰免费人妻| 老司机伊人| 99人这里只有精品| 99色在线| 亚洲久热无码| 狠爱婷色| 丁香花在线电影小说观看| 成人av在线网站| 日本综合色图| 激情丁香淫荡婷婷| 99五月香婷婷丁香在线视频| 色丁香婷婷| 久久婷中文字幕| www99在线观看视频| 丁香六月婷婷综合| 亚洲人妻av伦理| 久久婷婷五月丁香| 97婷婷丁香五月综合| 开心激情婷婷| 91人人爽狠狠狠| 婷婷五月天AV| 国产精品国产VA片国产| 九九99偷拍视频| 免费人成视频19674不收费| aa久久| 丁香五月欧美| 色性日本| 99re青青草| 天天色丁香| 九九视频精品这里只有| 丁香五月婷婷激情97| 婷婷色五月色| 中文色婷婷| 婷婷五月激情中文字幕| 天天开心AV色综合婷婷五月天| 青青草99re| 久久香蕉丁香| 开心 五月 综合| 国产av天天插天天操天天爽| 久久久免费精彩视频| 婷婷九月激情| 免费视频在线观看的网站| 开心五月深爱激情| 91日韩美女被插视频| 婷婷99狠狠躁天天躁| 影音先锋 91工厂| 六月丁香婷婷综合影院| 久久久大香蕉| 深爱激情五月天色婷婷| 五月色激情综合网| 五月婷啪| 五月天激情网址| ...婷婷五月综合不卡,国产在线手机 | 天天插天天操| 97精品欧美91久久久久久久| 人妻熟女一区二区AV| 国产,欧美,日韩,性爱| 一本久道综合99| 三人荫蒂添的好舒服A片| 99热久草| 九九色综合网| www99热| 99精品热| 九九99在线观看视频| 成人久碰| 91干在线| 五月色婷婷综合丁香精品无遮挡| 操婷婷久久| 99久久久久| 国精产品一区二区三区| 九九色色色| 香蕉久久av一区二区三区| 五月丁香六月婷婷在线| 色噜噜婷婷| 久久九网| 爆乳熟妇一区二区三区爆乳照片| 激情五月婷婷在线区| 人人叉久| 五月花婷婷| 裸体美女丁香五月天。| 久热这里只有精品6官网亚洲| 操逼电影免费看| 日韩AV片| 丁香五月婷婷乱| 婷婷五月天激情电影| 韩国真做片在线观看| 涩婷婷五月天在线精品视频| 久久性爱视频免费| 久草丁香婷婷五月天婷| 五月色丁香| 夜夜干夜夜操| 影音先锋女人av鲁色资源网小说免费| ady狠狠入| 婷婷色婷婷| 综合图片色色| 日韩黄黄| 热久69| 欧美成人精品A片免费一区99| 婷婷激情视频欧美视频自拍视频欧美剧| WWW,激情五月天,COM| www网站在线观看| 婷婷五月激情小说| 天天搞天天爽| VA国产在线综合网站| 天天综合色丁香| 午夜精品人妻无码一区二区三区| 九九无码| 精品综合五月| 中文字幕黄色片| 九九成年视频| 亚洲日本韩国| 色婷婷基地| 九月婷婷丁香| 日本综合久久| 午夜激情久久| 一本大道伊人AV久久综合| 丁香五月天视频| 99热这里只有精品23| 亚洲av免费在线| 微拍92| 搡BBBB搡BBB搡五十| 丁香花在线视频完整版| 怡红院精品视频久久久久久久久| 亚洲午夜av| 99碰在线视频| 五月香婷婷| 91精品久久久久久| 丁香五月天激情免费在线观看AV777| www色婷婷久久综合久色| 97九色视频| 99re资源在线视频导航| 天天日综合| 国产丝袜美女| 婷婷五月丁综合| 丁香婷婷五月激情综合| 91人人澡人人爽人人看| 日韩三级高清无码| 亚洲精品久久久久久久久久吃药| 婷婷五月天AV在线| 亚洲成人黄色网| 五月婷无码| 丁香婷婷久久 | 综合久久久| 99久久婷婷五月| 国产做爰视频免费播放| www色五月| 六月丁香激情| 99热这里只有精品 搜| 欧美激情 日韩无码 婷婷 五月天 久久婷婷丁香五月一二三 | 亚洲黄网在线| 国产精品久久久久久亚洲毛片| 久久精品9| 五月天com| 五月香六月婷| 五月激情另类| 狠狠舔| 五月天婷婷免费| 综合 蜜月 婷婷| 成人五月丁香花| 中文字幕欧美日韩VA免费视频| 九九婷婷综合| 五月丁香啪啪| 久久精品亚洲一级牲爱综合| 丁香综合伊人AV| 久鲁鲁色网 | 丁香五月综合首页| 国产女18毛片多18精品| 乱岳熟女50岁| 99亚洲视频| 久久久久久久97| 芭乐视频在线播放| 婷婷狠狠干| wwwwww.色| 天天操夜夜玩!| 99re思思在线视频| 丁香五月婷婷深爱综合激情| 亚洲午夜视频| 涩涩婷婷五月| 月丁香久久久| 91九色超碰| 五月天婷婷影院| 精品一二三区久久AAA片| 国产激情久久久| 天天肏在线观看| 成人在线视频一区| 亭亭玉月丁香| 五月成人网站| 激情婷婷五月社区| 天天天天爽爽天干| 国精产品一区二区三区| 热99久久这里只有精品| 亚洲色婷婷激情| 月月AV| 色VA| 婷五月丁香俺| 色色综合无码| 丁香五月天啪啪| 99久久综合网| 香蕉综合在线| 99在线视频色版| 丁香五月中文字幕| 五月婷婷中文字幕| 综合网啪啪| 91网站黄| 大香蕉婷婷丁香| 日本人人草草| 成人免费在线电影| 人人干女人| 综合色影院| 99久精品视频| 欧美日韩国产一区| 超碰资源在线| 91狠狠色丁香| 久久香蕉福利| 久操综合| 91人人爽狠狠狠| 91Chinese在线| 五月婷婷色色| 激情婷婷五月久久| 在线观看熟女少妇| 六月色日韩| 另类综合激情| 夜夜爽日日躁| 久久草婷婷丁香网站| 五月开心激情网| 伊人五月丁香| 激情婷婷五月社区| 丁香五月婷婷香| 99九九视频高清在线| www.yw色| 在线视频另类| 亚洲成人在线播放| www.夜夜操| 欧美槡BBBB槡BBB少妇| 亚洲欧洲另类| 日B日潘金莲BB| 狠狠色综合久久久久| Aα在线免费观看| 十区AV| 久久九九玖玖| 中文字幕成人| 一区二区中文字幕| 五月婷婷色丁香| 久色网五月| 亚洲日日操| 婷婷八月丁香激情综合| 97色在线观看视频| 色999五月色| 色色色色网| 日韩成人免费电影| 蒲京久久无码视频| 狠狠色丁香婷婷| 99婷婷国产最新视频| 国产67194| 亚洲 25P| 日韩精品色| 色五月婷婷亚洲| 99视频网址| 91丨九色丨国产打屁股| 亚洲精品久久久久久久久久吃药| 男人操女人高潮91视频| 综合久久十| 99九九中文字幕视频| 4399亚洲视频| 丁香五月天激情婷婷丁香六月| 五月丁香六月婷婷综合网| 久久66成人网站| 天天弄| 九九碰九九爱97超碰| 欧美三级巜人妻互换| 久久99大| 视频1区2区| 久久综合激情| 五月婷无码| 99国产这里只有精品| 中文字幕资源网| 91九九| 91|疯狂丨高潮丨对白| 91久久九九| 亚洲欧洲国产精品| 九热在线这里有精品6| 五月丁香基地| 大地9中文在线观看免费高清| 婷婷五月天精品| 一区二区三区四日本|