HUANG Tianye
HUANG Tianye
Professor, doctoral supervisor, candidate of Hubei Talent Program Head of Hubei Provincial Science and Technology Team Contact information: Email: tianye_huang@163.com Office: Room 229, No. 2 Teaching Building |
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Main experiences:
Professor at China University of Geosciences
Postdoctoral fellow at the Department of Electronic and Electrical Engineering, Nanyang Technological University
Joint training at McGill University, Canada
PhD at the National Laboratory for Optoelectronics of Huazhong University of Science and Technology
Research fields:
His current research interests are the applications of distributed fiber optic sensing, fiber optic communications and fiber optic lasers in high-speed information processing and sensing, mainly including:
1. New distributed fiber optic sensing/energy transmission/communication technology and integration: new sensing mechanisms, high-speed signal acquisition technology, development of embedded systems and upper computers, intelligent data and signal processing, and integrated instrument development.
2. Mechanism and application of optical frequency comb control: nonlinear dynamics, ultrafast fiber laser technology, laser precision control, laser intelligence, laser measurement.
3. System development and integration for applications such as geophysical observation, geological hazard monitoring and industrial testing.
Admission information:
1. The research group aims to cultivate students’ comprehensive ability, and the research content covers basic research and technology research, which involves in hardware system construction, development of underlying and upper computer systems, and principle prototype development.
2. Welcome undergraduate and graduate students with entrepreneurial spirit, firm willpower, and self motivation.
3. We will create the required conditions for excellent students to carry out scientific research and academic exchanges
4. Welcome foreign students with strong self-motivation as well.
Research conditions:
1. Distributed fiber optic sensing research platform
2. Time cavity soliton research platform
3. Ultrafast fiber laser research platform
4. Big data and artificial intelligence research platform
Main instruments: spectrometer, high-speed oscilloscope, code generator, high-speed clock source, tunable laser, ultra-narrow linewidth laser, RF instrument, autocorrelator, arbitrary waveform generator, PI controller, PDH controller, erbium-doped fiber amplifier, bandwidth/wavelength tunable filter, Waveshaper, etc.
Student training:
1. Since 2016, graduate students of the research group published more than 60 SCI papers, and have been awarded 9 excellent master’s theses at the university level; and more than 10 students have been awarded national scholarships.
2. Students’ employment destinations: Tsinghua University, Southern University of Science and Technology, and other universities; famous companies such as Xiaomi, FiberHome, BYD, etc; government institutions.
3. Outstanding Paste Report Award at Academic Conference IEEE ICOCN2023.
4. Outstanding Paste Report Award at Academic Conference AFL2022.
5. Best Student Paper Award at Academic Conference IEEE OGC2021.
6. Outstanding Report Award at Academic Conference IEEE ICICN2020.
7. Supervised several undergraduate students in conducting academic research and publishing SCI papers.
8. Guided students to win more than 20 national and provincial awards such as Challenge Cup, Internet+ and Engineering Robotics Competition.
Programs:
1. Major Research Instrument Development Program of the National Natural Science Foundation of China, Development of a distributed synchronous observation instrument system for multiple geophysical fields based on special optical fibers, project leader
2. Hubei Provincial Science and Technology Innovation Team Program, Smart Fiber Optic Deep Earth Sensing and Communications, PI
3. Hubei Key Research and Development Program, Research on key technologies for the development of high speed all fiber true random number generator, PI
4. Sinopec Key Laboratory of Geophysics Fund, Research on key technologies of “sensing energy integration” fiber DAS system, PI
5. National Natural Science Foundation of China, Active mode-locked thulium doped high-frequency parametric thulium fiber laser based on all-optical injection, PI
6. General Program of the Natural Science Foundation of Guangdong Province, Research on the generation mechanism and regulation method of high flatness soliton optical frequency comb, PI
7. Major Science and Technology Project of Guangxi Province, Research on key technologies and vehicle applications of full view, highly trustworthy, reconfigurable, deep decoupled hybrid electrical architecture, participant
8. General Program of the Natural Science Foundation of Guangdong Province, Research on the evolution mechanism and control method of single cavity time soliton dual optical frequency comb, PI
9. General Program of the Natural Science Foundation of Hubei Province, Research on key technologies of 2-micron high-repetition-rate laser, PI
10. Application Foundation leading-edge program of Wuhan Science and Technology Bureau, Research on new on-chip gas sensing technology based on parametric effects, PI
11. Major Science and Technology “Bottleneck” Special Project of Wuhan City, Research on key technologies for high temperature resistant special fiber optic materials and fiber optic monitoring applications, participant
12. Announcement Project of High-tech Development Zone, Ultra-high-repetition-rate narrow pulse width fiber laser for cold processing, participant
13. Cooperation program with XXX Institute of China Aerospace Science and Technology Corporation, Development of servo optical interconnect technology, PI
14. Program supported by China Space Foundation, Mid-infrared XXXX key technology, PI
15. Open project of Wuhan National Laboratory for Optoelectronics, Research on the Control Mechanism of Heterogeneous Nonlinear Coexistence States in Multi dimensional Reuse Resonant Resonators, PI
16. Open Fund of Hubei Inland Shipping Technology Key Laboratory, PI
17. CUG-HZGC university-enterprise collaboration program, Development of distributed fiber optic cable detection technology, PI
18. CUG-Optics Valley Technology university-enterprise collaboration program, Development of distributed microseismic sensing signal noise reduction technology based on deep learning, PI
19. CUG and Sky-blue university-enterprise collaboration program, Development of automatic on-board data acquisition equipment and software, PI
20. National Key Research and Development Program, Design and Testing Method of Ultra High Precision Inertial Sensor, participant
Awards and Honors:
1. Hubei “Chutian Talent Program”, 2023
2. IEEE Senior Member, 2024
3. IEEE Photonics Society, OGC Young Scientist Award, 2024
4. Elsevier Top 2% Scientists (Career-long Impact), 2022-2023
5. Elsevier Top 2% Scientists (Single-year Impact), 2021-2023
6. “3551 Talent Program - Industry Professor of Optics Valley” of Wuhan East Lake High-tech Development Zone, 2023
7. Research and application of key technologies for multi band and tunable pulsed fiber lasers, Third Prize of the Award for Science and Technology Progress of Hubei Province, Ranked First, 2023
8. Research and development of key technologies for IoT video perception and its application in safe city, Second Prize of the Award for Science and Technology Progress of Hubei Province, Ranked Third, 2020
9. Research and development of key technologies for advanced fiber lasers and their application in additive manufacturing, Second Prize of the Award for Science and Technology Progress of China National Light Industry Council, Ranked Third, 2023
10. National Silver Award of “Challenge Cup” College Students’ Entrepreneurship Competition, Instructor, 2024
11. National Silver Award of China International College Students’ Innovation Competition, Instructor, 2023
12. National Bronze Award of China College Students’ ‘Internet+’ 'Innovation and Entrepreneurship Competition, Instructor, 2023
Academic Positions:
1. IEEE China Council Sensors Council and Systems Council Joint Chapter, Secretary, 2023-2025
2. IEEE Photonics Technology Letters ACP Special Issue, Guest Editor, 2022-2023
3. “Vice President of Science and Technology” in Hubei Province”, 2021-2022
4. Hubei Laser Society, Director, 2019-2024
5. Wuhan Laser Society, Director, 2019-2024
Academic papers:
[1] D. Li, X. Li, T. Huang*, J. Zhang, Z. Wu, L. Xiong, C. Peng, Y. Chen, Q. Qi, P. P. Shum, “Interference Fading Suppression with Multi-Subcarrier Pulse in Distributed Acoustic Sensor,” Optics Express, vol. 32, no.11, 2024
[2] T. Huang*, A. Li, D. Li, J. Zhang, X. Li, L. M. Xiong, J. Tu, W. F. Sun, X. Y. Hu, “Multiple noise reduction for distributed acoustic sensing data processing through densely connected residual convolutional networks,” Journal of Applied Geophysics, vol. 228, 2024.
[3] T. Huang*, H. Zheng, G. Xu, J. Pan, F. Xiao, W. Sun, K. Yan, S. Chen, B. Huang, H. Yu, P. P. Shum, “Coexistence of nonlinear states with different polarizations in a Kerr resonator,” Physical Review A, vol. 109, no. 1, 2024
[4] T. Huang*, C. Tong, J. Pan, Z. Cheng, B. Yu, J. Yin, Z. Yin, S. Chen, H. Yu, K. Yan, et al., “Spatial-multiplexing of nonlinear states in a few-mode-fiber-based Kerr resonator,” Optics Communications., vol. 555, 2024.
[5] Y. Wu, Y. Zhou, J. Pan, T. Huang*, and S. Jin, “Design of highly sensitive refractive index sensor based on silicon photonic Mach-Zehnder interferometer,” Optics Communications., vol. 534, 2023.
[6] D. Li, H. Wang, X. Wang, X. Li, T. Huang*, M. Ge, J. Yin, S. Chen, B. Huang, K. Guan, et al., “Denoising algorithm of Φ-OTDR signal based on curvelet transform with adaptive threshold,” Optics Communications., vol. 545, 2023.
[7] Y. Cheng, H. Wang, D. Li, Y. Qiu, M. Luo, X. Zhang, J. Zhang, Z. Wu, T. Huang*, and X. Li, “Interference fading mitigation in coherent Φ-OTDR based on subband phase-shift transform,” IEEE Photonics Journal., vol. 15, no. 5, 2023.
[8] T. Yao, T. Huang, B. Yan, M. Ge, J. Yin, C. Peng, L. Li, W. Sun, and P. P. Shum, “Inverse design of dispersion for photonic devices based on LSTM and gradient-free optimization algorithms hybridization,” Journal of the Optical Society of America B, 40(6), 1525-1532, 2023.
[9] J. Pan, T. Huang*, C. Xu, G. Xu, Z. Wu, J. Zhang, X. Li, Z. Cheng, N. Zhang, H. Yu, et al., “Binding dynamics of cavity solitons in a Kerr resonator with high order dispersion,” Optics Express., vol. 31, no. 22, 35709-35719, 2023.
[10] T. Yao, T. Huang, X. Zeng, Z. Wu, J. Zhang, D. Luo, X. Zhang, Y. Wang, Z. Cheng, X. Li, L. Han, and P. P. Shum, “Multimode waveguide analyses and design based on the FC-LSTM hybrid network,” Journal of the Optical Society of America B, 39(10), 2564-2572, 2022.
[11] X. Tu, Y. Wu, T. Huang*, J. Zhang, and P. P. Shum, “Optimizing two-dimensional polarization-diversity metagrating couplers for silicon photonics,” Journal of the Optical Society of America B-Optical Physics., vol. 39, no. 4, 1256-1262, 2022.
[12] Q. Ji, R. Lei, S. Liu, and T. Huang*, “Highly sensitive based on a Mach-Zehnder interferometer with double-slot hybrid plasmonic waveguide,” Optik., vol. 270, 2022.
[13] J. Zhang, Y. Chen, Z. Wu, S. Feng, P. P. Shum, and T. Huang*, “Panda type separated-circles-formed elliptical ring core few-mode fiber,” Optical Fiber Technology., vol. 73, 2022.
[14] J. Pan, C. Xu, Z. Wu, J. Zhang, T. Huang*, and P. P. Shum, “Dynamics of cavity soliton driven by chirped optical pulses in Kerr resonators,” Frontiers of Optoelectronics., vol. 15, no. 1, 2022.
[15] X. Li, Y. Zhang, D. Li, P. P. Shum, and T. Huang*, “Nonlinear channel equation using gaussian processes regression in IMDD fiber link,” IEEE Photonics Journal., vol. 14, no. 6, 2022.
[16] T. Huang, S. Feng, X. Zeng, G. Xu, J. Pan, F. Xiao, Z. Wu, J. Zhang, L. Han, and P. P. Shum, “Polarization-decoupled cavity solitons generation in Kerr resonators with flattened near-zero dispersion,” Optics Express., vol. 30, no. 12, 20767-20782, 2022.
[17] Z. Wu, J. Zeng, J. Pan, C. Xu, D. Luo, J. Zhang and T. Huang*, “Vector soliton molecules manipulation using projected super-position technique,” IEEE Photonics Technology Letters., vol. 34, no. 2, 105-108, 2022.
[18] J. Pan, T. Huang, Y. Wang, Z. Wu*, J. Zhang and L. Zhao, “Numerical investigations of cavity-soliton distillation in Kerr resonators using the nonlinear Fourier transform,” Physical Review A., vol. 104, no. 4, 2021.
[19] T. Huang, X. Rang, L. Han, G. Zhang, J. Pan, Y. Wang and Z. Chen*. “Dual-channel sensor based on Tamm plasmon polariton and defect mode hybridization in topological insulator covered photonic crystals,” Journal of the Optical Society of America B-Optical Physics., vol. 38, no. 6, 1951-1957, 2021.
[20] T. Huang, G. Xu, X. Tu, G. Zhang, R. Lei, Y. Wu, J. Pan, L. Shao, and P. P. Shum, “Design of highly sensitive interferometric sensors based on subwavelength grating waveguides operating at the dispersion turning point,” Journal of the Optical Society of American B, vol. 38, no. 9, 2680-2686, 2021.
[21] J. Liao, Y. Xie, T. Huang, Z. Cheng, “Design and analysis of a compact subwavelength-grating-assisted 1.55/2 μm wavelength demultiplexer,” Applied Optics, vol. 60, no. 16, 4972-4975, 2021.
[22] X. Tu, W. Xie, Z. Chen, M. Ge, T. Huang, C. Song, H. Fu, “Analysis of Deep Neural Network Models for Inverse Design of Silicon Photonic Grating Coupler,” IEEE Journal of Lighw. Technol., vol. 39, no. 9, 2790-2799, 2021.
[23] Z. Wu, Q. Wei, B. Zhan, T. Huang*, M. Zhu, L. Li, P. P. Shum, “Manipulation of soliton bunches generated from a polarization-route-assisted vector fiber laser,” IEEE Photonics Journal, vol. 13, no. 1, 1501108, 2021.
[24] J. Pan, Z. Cheng, T. Huang*, M. Zhu, Z. Wu, P. P. Shum, “Numerical Investigation of All-Optical Manipulation for Polarization-Multiplexed Cavity Solitons,” IEEE Journal of Lightw. Technol., vol. 39, no.2, 2021.
[25] T. Huang*, J. Pan, Z. Cheng, G. Xu, Z. Wu, T. Du, S. Zeng, and P. P. Shum, “Nonlinear-mode-coupling-induced soliton crystal dynamics in optical microresonators,” Physical Review A, vol.103, no. 2, 023502, 2021.
[26] X. Zhao, T. Huang*, S. Zeng, C. Son, Z. Cheng*, X. Wu, P. Huang, J. Pan, Y. Wu and P. P. Shum, “Highly Sensitive Polarimetric Sensor Based on Fano Resonance for DNA Hybridization Detection,” Plasmonics., vol. 15, no. 3, 769-781, 2020.
[27] J. Liao, Z. Ding, Y. Xie, X. Wang, Z. Zeng and T. Huang*, “Ultra-broadband and highly sensitive surface plasmon resonance sensor based on four-core photonic crystal fibers,” Optical Fiber Technology., vol. 60, 2020.
[28] Z. Wu, Q. Wei, P. Huang, D. Luo, X. Zhang, S. Fu, L. Zhao, D. Liu, P. Shum. T. Huang, “Single-axis soliton molecule and multiple solitons generation from a vector fiber laser,” Optics Express, vol. 28, no. 4, 5212, 2020.
[29] G. Xu, J. Yan, Z. Chen, T. Huang*, Z. Cheng, P. P. Shum and G. Brambilla, “Design of germanium-silicon carbide hybrid waveguides for mid-infrared third-order parametric conversion,” Opt. Commun., vol. 456, 2020.
[30] J. Pan, Z. Cheng, T. Huang*, C. Song, P. P. Shum, and G. Brambilla, “Fundamental and third harmonic mode coupling induced single soliton generation in Kerr microresonators,” IEEE Journal of Lightw. Technol., vol. 37, no.21, 2019.
[31] T. Huang*, G. Xu, J. Pan, Z. Cheng, P. P. Shum, and G. Brambilla, “Theoretical study of bicharacteristic waveguide for fundamental-mode phase-matched SHG from MIR to NIR,” Opt. Express, vol. 27, no. 11, 15236-25250, 2019
[32] T. Huang*, Q. Wei, Z. Wu, X. Wu, P. Huang, Z. Cheng, and P. P. Shum, “Ultra-flattened normal dispersion fiber for supercontinuum and dissipative soliton resonance generation at 2 μm,” IEEE Photonics Journal, vol. 11, no. 3, 7101511, 2019.
[33] T. Huang*, Y. Xie, Y. Wu, Z. Cheng, S. Zeng, and P. P. Shum, “Compact polarization beam splitter assisted by subwavelength grating in triple-waveguide directional coupler,” Applied Optics, vol. 58, no. 9, 2264-2268, 2019.
[34] X. Zhang, Y. Wang, X. Zhao, T. Huang*, S. Zeng, and P. P. Shum, “Fano resonance based on long range surface phonon resonance in the mid-infrared region,” IEEE Photonics Journal, vol.11, no.2, 4800808, 2019.
[35] L. Han, X. Zhao, T. Huang*, F. Ding, and C. Wu, “Comprehensive Study of Phase-Sensitive SPR Sensor Based on Metal-ITO Hybrid Multilayer,” Plasmonics, vol. 14, no. 6, 1743-1750, 2019.
[36] W. Zou, T. Huang, J. Yuan, D. Wang, X. Li, Z. Cheng, “Modified constellation reshaping method for PAPR reduction of PDM CO-OFDM based on a SLM algorithm,” Applied Optics, vol. 58, no. 7, 1800-1807, 2019
[37] Y. Xie, Z. Chen, Y. Wang, Y. Zhao, T. Huang*, Z. Cheng, “Bloch supermode interaction for high-performance polarization beam splitting,” Optical Engineering, vol. 59, no. 9, 095102, 2019.
[38] P. Huang, T. Huang*, S. Zeng, J. Pan, X. Wu, X. Zhao, Y. Wu, P. P. Shum and G. Brambilla, “Nonlinear gas sensing based on third harmonic generation in cascaded chalcogenide microfibers,” Journal of Optical Society of American B, vol. 36, no. 2, 300-305, 2019.
[39] X. Tu, S. Chen, C. Song, T. Huang* and L. J. Guo, “Ultrahigh Q polymer microring resonators for biosensing applications,” IEEE Photonics Journal, vol. 11, no. 2, 4200110, 2019.
[40] T. Huang, Y. Wu, Y. Xie, and Z. Cheng, “A slot-waveguide-based polarization beam splitter assisted by epsilon-near-zero material,” Photonics and Nanostructures-Fundamentals and Applications, vol. 33, 42-47, 2019.
[41] T. Huang, S. Zeng, X. Zhao, Z. Cheng, and P. P. Shum, “Fano resonance enhanced surface plasmon resonance sensors operating in near-infrared,” Photonics, vol. 5, no. 3. 23, 2018.
[42] T. Huang*, J. Pan, Z. Cheng, C. Song, J. Wang, X. Shao, P. P. Shum, and G. Brambilla, “Photon-plasmon coupling for fundamental-mode phase-matched third harmonic and triplet photon generation,” IEEE Journal of Lightw. Technol., vol. 36, no. 18, 3892-3897, 2018.
[43] L. Han, H. Ding, T. Huang*, X. Wu, B. Chen, K. Ren, S. Fu, “Broadband optical reflection modulator in indium-tin-oxide-filled hybrid plasmonic waveguide with high modulation depth,” Plasmonics, vol. 13, no. 4, 1309-1314, 2018.
[44] L. Li. T. Huang*, X. Zhao, X. Wu, and Z. Cheng, “Highly sensitive SPR sensor based on hybrid coupling between plasmon and photonic mode,” IEEE Photon. Technol. Lett., vol. 30, no. 15, 1364-1367, 2018.
[45] X. Zhao, T. Huang*, P. P. Shum, X. Wu, P. Huang, J. Pan, Y. Wu, and Z. Cheng, “Sensitivity enhancement in surface plasmon resonance biochemical sensor based on transition metal dichalcogenides/graphene heterostructure,” Sensors, vol. 18, no. 7, 2056, 2018.
[46] X. Wu, P. Huang, T. Huang*, Z. Wu, Z. Cheng, B. Chen, K. Ren, and S. Fu, “Tunable all-optical actively mode-locked fiber laser at 2 mu m based on tellurite photonic crystal fiber,” Laser Phys. Lett., vol. 15, no. 6, 065103, 2018.
[47] K. Ren, X. Li, T. Huang*, Z. Cheng, B. Chen, X. Wu, S. Fu, P .P. Shum, “A time and frequency synchronization method for CO-OFDM based on CMA equalizers,” Optics Commun., vol. 416, no. 1, 166-171, 2018.
[48] C. Wu, H. Ding, T. Huang*, X. Wu, B. Chen, K. Ren, S. Fu, “Plasmon-induced transparency and refractive index sensing in side-coupled stub-hexagon resonators,” Plasmonics, vol. 13, no. 1, 251-257, 2018.
[49] C. Song, T. Jin, R. Yanm W. Qi, T. Huang, H. Ding, S. Tan, N. Nguyen, L. Xi, “Opto-acousto-fluidic microscopy for three-dimensional label-free detection of droplets and cells in microchannels,” Lab on a Chip, vol. 18, no. 9, 1292-1297, 2018.
[50] T. Huang*, P. Huang, Z. Cheng, J. Liao, X. Wu, J. Pan, “Design and analysis of a hexagonal tellurite photonic crystal fiber with broadband ultra-flattened dispersion in mid-IR,” Optik, vol. 167, 144-149, 2018.
[51] K. Ren, X. Li, T. Huang*, Z. Cheng, B. Chen, X. Wu, S. Fu, P .P. Shum, “A time and frequency synchronization method for CO-OFDM based on CMA equalizers,” Optics Communications, vol. 416, no. 1, 166-171, 2018.
[52] J. Liao, Y. Xie, X. Wang, D. Li, and T. Huang*, “Ultra-flattened nearly-zero dispersion and ultrahigh nonlinear slot silicon photonic crystal fibers with ultrahigh birefringence,” Photonics and Nanostructures-Fundamentals and Applications, vol. 25, 19-24, 2017.
[53] C. Zhuo, and T. Huang*, “Tunable spectral splitting in nanoscale graphene waveguide with coupled resonators,” Journal of Nanophotonics, vol. 11, no. 3, 036013, 2017.
[54] X. Wu, Z. Wu, T. Huang*, B. Chen, K. Ren, and S. Fu, “All-optical actively mode-locked fiber laser at 2-μm based on interband modulation,” IEEE Photonics Journal, vol. 9, no. 5, 1505908, 2017.
[55] T. Huang. “Highly Sensitive SPR Sensor Based on D-shaped Photonic Crystal Fiber Coated with Indium Tin Oxide at Near-Infrared Wavelength,” Plasmonics, vol. 12, no. 3, 583-588, 2017.
[56] N. Zhang, D. Hu, P. Shum, Z. Wu, K. Li, T. Huang, and L. Wei, “Design and analysis of surface plasmon resonance sensor based on high-birefringent microstructured optical fiber,” Journal of Optics, vol. 18, no. 6, 065005, 2016.
[57] T. Wu, P. Shum, Y. Sun, T. Huang, and L. Wei, “Third Harmonic Generation with the Effect of Nonlinear Loss,” Journal of Lightwave Technology, vol. 34, no. 4, 1274-1280, 2016.
[58] T. Huang, Z. Pan, M. Zhang, and S. Fu, “Design of reconfigurable on-chip mode filters based on phase transition in vanadium dioxide,” Applied Phys. Express, vol. 9, no. 11, 112201, 2016.
[59] T. Huang, “TE-pass Polarizer Based on Epsilon-near-zero Material Embedded in a Slot Waveguide” IEEE Photon. Technol. Lett., vol. 28, no. 20, 2145-2148, 2016.
[60] T. Huang, X. Shao, P. P. Shum, T. Lee, T. Wu, Z. Wu, Y. Sun, H. Q. Lam, J. Zhang, and G. Brambilla, “Internal asymmetric plasmonic slot waveguide for third harmonic generation with large fabrication tolerance,” Plasmonics, vol. 11, no. 6, 1451-1459, 2016.
[61] T. Huang, P. M. Tagne, and S. Fu, “Efficient second harmonic generation in internal asymmetric plasmonic slot waveguide,” Opt. Express, vol. 24, no. 9, 9706-9714, 2016.
Invention patents:
1. Huang Tianye, Huang Pan. A gas sensor based on third-harmonic generation in cascaded microfibers. Granted Chinese invention patent. Sept. 9, 2020. Patent No.: ZL201910345668.2.
2. Huang Tianye, Huang Pan and Wu Xu. A tellurite cluster velocity-matched photonic crystal fiber. Chinese invention patent grant. May 26, 2023. Patent No.: ZL201711013491.3
3. Huang Tianye, Pan Jianxing. Device and application of mid-infrared to near-infrared conversion based on phase matching between fundamental modes. Chinese invention patent grant. Aug. 7, 2023. Patent No.: ZL201810350853.6
4. Huang Tianye, Pan Jianxing. An optical waveguide structure capable of generating mid-infrared entangled-state photons and a method thereof. Granted Chinese invention patent. Nov. 24, 2020. Patent No.: ZL201810350188.0
5. Huang Tianye, Ren Kaixuan, Li Xiang. A method, apparatus and storage device for timing synchronization in coherent optical OFDM communication system. Granted Chinese invention patent. July 7, 2020. Patent No.: ZL201711174166.5
6. Huang Tianye, Wu Yiheng, Xie Yuan. A polarization beam splitter based on surface plasma subwavelength gratings. Granted Chinese invention patent. Feb. 24, 2023. Patent No.: ZL201811010642.4
7. Huang Tianye, Wu Zhichao, Wei Qian. A mode-locked fiber laser with adjustable number of solitons. Granted Chinese invention patent. May 13, 2022. Patent No.: ZL202010775837.9
8. Huang Tianye, Wu Xu, Huang Pan. A 1.55um to 2um wavelength converter. Granted Chinese invention patent. Oct. 25, 2017. Patent No.: ZL201711013472.0
9. Huang Tianye, Wu Xu. Active mode-locked fiber laser based on group velocity-matched photonic crystal fiber. State invention patent grant. Aug. 4, 2023. 2017110134928
10. Huang Tianye, Wu Xu. An optical soliton generation device in the 2um band. Granted Chinese invention patent. June 6, 2023. Patent No.: ZL201810030129.5
11. Huang Tianye, Xiao Fan, Wang Yong, Pan Jianxing, Wu Zhichao, Luo Dapeng, Zhang Xiangli. A dual frequency comb generation system and method based on fiber ring resonator. Granted Chinese invention patent. Dec. 23, 2020. Patent No.: ZL202011536371.3
12. Huang Tianye, Xie Yuan, Wu Yiheng. A polarization beam splitter. Granted Chinese invention patent. May 26, 2023. Patent No.: ZL201810094046.2
13. Huang Tianye, Zhao Xiang. A device and method for measuring the detection limit of Fano resonance sensor. Granted Chinese invention patent. May 26, 2023. Patent No.: ZL201811174816.0
14. Chen Bingwei, Huang Tianye. A fiber structure for adjustable wavelength conversion. Granted Chinese invention patent. Aug. 31, 2017. Patent No.: ZL201710773672.X.
15. Huang Tianye, Wei Qian. A 2-μm d dissipative soliton resonant mode-locked fiber laser. Granted Chinese invention patent. Sept. 1, 2023. Patent No.: ZL201811533865.9
16. Huang Tianye, Wu Zhichao, Wei Qian. A mode-locked fiber laser with adjustable number of solitons. Granted Chinese invention patent. May 13, 2022. Patent No.: ZL202010775837.9
17. Wu Zhichao, Hua Shuhao, Huang Tianye. A vector soliton laser. Granted Chinese invention patent. Oct. 17, 2023. Patent No.: ZL202111590354.2