教师名录
田佳峻
通讯地址:广东省深圳市南山区西丽深圳大学城哈工大C423
电子邮件:tianjiajun@hit.edu.cn; jiajuntian@gmail.com
联系电话:0755-86913745

个人简介

副教授,工学博士,博士研究生指导教师,指导专业:物理电子学;光学工程。研究涉及光纤激光器和光纤传感技术和器件的实现。硕士招生专业(物理电子学,光学工程)。
招生计划:
1)博士生1名(招生专业为 电子科学与技术),提供国外交流和企业实践机会;
2)硕士研究生3-4名 (招生专业为 物理电子学 和 光学工程), 推免生优先;
3)博士后1名,待遇从优(年薪20万以上).

研究方向

1 光纤传感;2 光纤通信;3 光纤激光器;4 先进光电子器件

教育经历

2017-2010  哈尔滨工业大学,物理电子学,工学博士学位
2005-2007  哈尔滨工业大学,物理电子学,工学硕士学位
2001-2005  燕山大学,电子科学与技术,工学学士学位
  

研究与工作经历

2011.5-2013.7  哈尔滨工业大学深圳研究生院,博士后
2012.2-2013.6  美国内布拉斯加大学林肯分校,博士后
2013.7-2015.7  哈尔滨工业大学深圳研究生院,助理教授
2015.8-现在  哈尔滨工业大学(深圳),副教授
2018.4-现在  哈尔滨工业大学(深圳),博士生导师
  
  
  

专业资质与学术兼职

2012  国家自然科学基金委函评专家
2012  深圳市科创委科技创新函评专家
2007-至今  期刊审稿人:Optics Letters、Optics Express、Sensor and Acuator B、OSA/IEEE Journal of Lightwave Technology、IEEE Access、IEEE Photonics Technology Letters、IEEE Sensor Journal、Photonics Sensor、IEEE Transactions on Nano Technology、Superlattices and Microstructures、Applied Optics、Optics Coummunication等

科研项目

2017-2020  国家自然科学基金面上项目:面向环境扰动的多点复用光纤FBG超声探测机理与系统实现(61675055),主持。
2011-2014  国家自然科学基金青年基金项目:基于强度相关增益反馈控制的多功能掺铒光纤激光器的研究,主持。
2018-2020  深圳市科技计划学科布局项目(JCYJ20170815140136635),主持。
2014-2016  深圳市科技计划项目,主持。
2014-2016  深圳市科技计划项目,主持。
2012-2013  中国博士后科学基金特别资助项目,主持。
2011-2013  中国博士后基金面上项目。
2011-2013  深圳市科技计划项目,主持。
2013-2014  哈尔滨工业大学创新基金,主持。

科研成果及奖励

2011-2013  哈尔滨工业大学优秀博士后出站报告
2013  深圳市高层次人次,后备级

发明专利

1、田佳峻,李苑,全明冉,姚勇,一种分布式光纤激光超声换能器,国家发明专利,授权号:ZL201510099880.7,授权时间:20170524。
2、田佳峻,全明冉,李苑,姚勇,一种基于微孔光学反射隔膜的光纤F-P多功能传感器,国家发明专利,授权号:ZL2015100307029,授权时间:20170801。
3、田佳峻,李苑,全明冉,姚勇,一种基于多波长掺铒光纤激光器的分布式超声传感器,国家发明专利,授权号:ZL201510035800.1,授权时间:20170922。
4、田佳峻,胡玲,卢泽锦,姚勇,一种基于全琼脂F-P腔的超高灵敏度的光纤湿度传感器,国家发明专利,申请号:2016106018544,申请时间:20160727。
5、田佳峻,高士民,张新,姚勇,基于光纤错位熔接的分布式光纤激光超声换能器,国家发明专利,申请号:2016106045950,申请时间:20160727。
6、田佳峻、付琦、姚勇,一种基于波长相关偏振分离的可调谐多波长光纤激光器,国家发明专利,申请号:2017107996089,申请时间:20170907。
7、田佳峻、嵇绍波、李志岗、王博、姚勇,一种基于无芯光纤的分布式光纤激光超声换能装置,国家发明专利,申请号:201810824788.6,申请时间:20180725。

论文及著作

*代表通信作者,IF影响因子
[33] Y. Li, J. J. Tian*, Q. Fu, Y. X. Sun, and Y. Yao. A multi-point switchable and seif-adaptive ultrasoinc sensor using fiber Bragg gratings in a fiber ring laser. IEEE/OSA Journal of Lightwave Technology (forthcoming DOI:10.1109/JLT.2018.288756) (2018) SCI, IF=3.652

[32] Z. G. Li, J. J. Tian*, Y. Z. Jiao, Y. X. Sun, and Y. Yao. Simultaneous Measurement of Air Pressure and Temperature Using Fiber-Optic Cascaded Fabry-Perot Interferometer. IEEE Photonics Journal (forthcoming DOI:10.1109/JPHOT.2018.2884776) (2018) SCI, IF=2.627

[31] S. B. Ji, J. J. Tian*, X. L. Dong, S. M. Gao, Y. X. Sun, and Y. Yao. Multipoint fiber optic ultrasonic actuator based on bent fiber structures along a single fiber. IEEE Sensors Journal 18(22): 9271-9276 (2018) SCI, IF=2.617

[30] S. B. Ji, J. J. Tian*, X. L. Dong, Y. X. Sun, and Y. Yao. Multi-point all-fiber laser-ultrasound transducer using cascaded fiber waist-enlarged fusion tapers. IEEE/OSA Journal of Lightwave Technology 36(16): 3284-3292 (2018) SCI, IF=3.652

[29] B. Wang, J. J. Tian*, L. Hu, and Y. Yao. High sensitivity humidity fiber-optic sensor based on all-agar Fabry–Perot interferometer. IEEE Sensors Journal 18(12): 4879-4885 (2018) SCI, IF=2.617

[28] J. J. Tian*, Y. Z. Jiao, Q. Fu, S. B. Ji, Z. G. Li, M. R. Quan, and Y. Yao. A Fabry–Perot interferometer strain sensor based on concave-core photonic crystal fiber. IEEE/OSA Journal of Lightwave Technology 36(10): 1952-1958 (2018) SCI, IF=3.652

[27] J. J. Tian*, Y. Z. Jiao, S. B. Ji, X. L. Dong, and Y. Yao. Cascaded-cavity Fabry–Perot interferometer for simultaneous measurement of temperature and strain with cross-sensitivity compensation. Optics Communications 412: 121-126 (2018) SCI, IF=1.887

[26] J. J. Tian*, X. L. Dong, S. M. Gao, and Y. Yao.Multipoint fiber-optic laser-ultrasonic actuator based on fiber core-opened tapers. Optics Express 25(24): 29737-29745 (2017) SCI, IF=3.356

[25] X. L. Dong, S. M. Gao, J. J. Tian*, and Y. Yao. Multipoint fiber-optic laser–ultrasound generation along a fiber based on the core-offset splicing of fibers. Photonics Research 5(4): 287-292 (2017) SCI, IF=5.242

[24] Y. Li, J. J. Tian*, M. R. Quan, and Y. Yao. Tunable Multiwavelength Er-Doped Fiber Laser With a Two-Stage Lyot Filter. IEEE Photonics Technology Letters 29(3): 287-290 (2017) SCI, IF= 2.446

[23] J. J. Tian*, Z. J. Lu, M. R. Quan, Y. Z. Jiao, and Y. Yao. Fast response Fabry–Perot interferometer microfluidic refractive index fiber sensor based on concave-core photonic crystal fiber. Optics Express 24(18): 20132-20142 (2016) SCI, IF=3.356

[22] M. R. Quan, J. J. Tian*, and Y. Yao. Ultra-high sensitivity Fabry–Perot interferometer gas refractive index fiber sensor based on photonic crystal fiber and Vernier effect.Optics Letters 40(21): 4891-4894 (2015) SCI, IF=3.589

[21] Y. Li, M. R. Quan, and J. J. Tian*, and Y. Yao. Tunable multiwavelength erbium-doped fiber laser based on nonlinear optical loop mirror and birefringence fiber filter. Optics Communications, 119(2): 363-370 (2015) SCI, IF=1.887

[20] M. R. Quan, Y. Li, J. J. Tian*, and Yong Yao. Multifunctional tunable multiwavelength erbium-doped fiber laser based on tunable comb filter and intensity-dependent loss modulation. Optics Communications 340: 63-68 (2015) SCI, IF=1.887

[19] B. Guo, Y. Yao, J. J. Tian, Y. F. Zhao, S. Liu, M. Li, Q. M. Ran, “Observation of Bright-Dark Soliton Pair in a Mode-Locked Fiber Laser With Topological Insulator,” IEEE Photonics Technology Letters, 27(7): 701-704 (2015) SCI, IF=2.446

[18] Y. J. Lu, M. Han, J. J. Tian. Fiber-Optic Temperature Sensor Using a Fabry–Pérot Cavity Filled With Gas of Variable Pressure. IEEE Photonics Technology Letters 26(8): 757-760 (2014) SCI, IF=2.446

[17] Y. J. Yuan, Y. Yao, J. J. Xiao, Y. F. Yang, J. J. Tian, and C. Liu, “Experimental and numerical study of high order Stokes lines in Brillouin-erbium fiber laser,” Journal of Applied Physics 115, 043102 (2014) SCI, IF=2.176

[16] C. Liu,Y. Yao, J. J. Tian, Y. J. Yuan, Y. F. Zhao, B. S. Yu,“Packet Error Rate Analysis of DPIM for Free-Space Optical Links with Turbulence and Pointing Errors”, Chinese Optics Letters, 12(1), S10101-310105 (2014) SCI, IF=1.948

[15] Y. Yuan, Y. Yao, M. Yi, B. Guo, J. J. Tian, “Multiwavelength fiber laser employing a nonlinear Brillouin optical loop mirror: experimental and numerical studies” Optics Express, 22(13), 15352-15363 (2014) SCI, IF=3.356

[14] J. J. Tian, Y. J. Lu, Q. Zhang, and M. Han, "Microfluidic refractive index sensor based on an all-silica in-line Fabry–Perot interferometer fabricated with microstructured fibers," Optics Express 21(5), 6633-6639 (2013) SCI, IF=3.356 (Selected for Virtual Journal for Biomedical Optics, volume 8, issue 4, May 2013 )

[13] J. J. Tian, Q. Zhang, and M. Han. Distributed fiber-optic laser-ultrasound generation based on ghost-mode of tilted fiber Bragg gratings. Optics Express 21(5), 6109-6114 (2013) SCI, IF=3.356

[12] X. L. Yu, Y. Yao, J. J. Xiao, and J. J. Tian, “A hybrid method for designing fiber Bragg gratings with right-angled triangular spectrum in sensor applications, ” Optik 124, 1354-1357 (2013) SCI, IF=1.191

[11] J. J. Tian, Q. Zhang, T. Fink, H. Li, W. Peng, and M. Han. Tuning operating point of extrinsic Fabry–Perot interferometric fiber-optic sensors using microstructured fiber and gas pressure. Optics Letters 37, 4672-4674 (2012) SCI, IF=3.589

[10] J. J. Tian, Y. Yao, J. J. Xiao, X. L. Yu, and D. Y. Chen. Tunable multiwavelength erbium-doped fiber laser based on intensity-dependent loss and intra-cavity loss modulation. Optics Communications 258(9): 2426-2429 (2012) SCI, IF=1.887

[9] X. L. Yu, Y. Yao, J. Xiao, and J. J. Tian. Optimal design of short fiber Bragg gratings with triangular spectrum. Optics Communications, 285(5), 631-637 (2012) SCI, IF=1.887

[8] X. L. Yu, Y. Yao, J. J. Xiao, and J. J. Tian, “A practical approach to synthesize multi-channel fiber Bragg grating with right-angled triangular spectrum”, Chinese Physics Letters 29, 114211 (2012) SCI, SCI=0.847

[7] J. J. Tian, Y. Yao, J. J. Xiao, X. C Xu, and D. Y. Chen. A triple function linear fiber laser with passive mode-locking, continuous wave single- and multi-wavelength lasing. Optics Letters 36(8): 1509-1511 (2011) SCI, IF=3.589

[6] J. J. Tian, Y. Yao, J. J. Xiao, X. C Xu, and D. Y. Chen. Multiwavelength Erbium-doped fiber laser based on intensity-dependent transmission in a linear cavity. Journal of Applied Physics 109(11): 113102 (2011) SCI, IF=2.176

[5] J. J. Tian, Y. Yao, J. J. Xiao, X. C. Xu, and D. Y. Chen. A pump power controlled multiwavelength fiber laser with adjustable output channels at fixed wavelength. Applied Physics. B: 102(3): 545-549 (2011) SCI, IF=1.881

[4] J. J. Tian and Y. Yao. A linear cavity multiwavelength fiber laser with adjustable lasing line number for fixed spectral regions. Laser Physics. 21(3): 505-508 (2011) SCI, IF=1.158

[3] J. J. Tian, Y. Yao, Y. X. Sun, X. C. Xu, X. H. Zhao, and D. Y. Chen. Flat broadband Erbium-doped fiber ASE source based on symmetric nonlinear optical loop mirror. Laser Physics. 20 (8): 1760-1766 (2010) SCI, IF=1.158

[2] X. H. Zhao, Y. Yao, Y. X. Sun, X. C. Xu, J. J. Tian, and C. Liu. Condition of keeping polarization property unchanged in the circle polarization shift keying system. J. Opt. Commun. Netw. 2, 570-575 (2010) SCI, IF=2.742

[1] J. J. Tian, Y. Yao, Y. X. Sun, X. L. Yu, and D. Y. Chen. Multiwavelength Erbium-doped fiber laser employing nonlinear polarization rotation in a symmetric nonlinear optical loop mirror. Optics Express. 17(17): 15160–15166 (2009) SCI, IF=3.356

会议论文及发表演说

[13] S. B. Ji, J. J. Tian*, and Y. Yao. Fiber-optic ultrasonic transducer achieved at the sidewall of optic fiber using coreless fiber. Advanced Photonics Congress, Switzerland, July, 2018.

[12] S. B. Ji, J. J. Tian*, and Y. Fiber-optic laser-ultrasound generation on a fiber side wall based on peanut-shape structure. International Symposium on Optoelectronic Technology and Application 2018, Beijing, China, 2018.

[11] Z. G. Li, J. J. Tian*, Y. X. Sun, and Y. Yao. High sensitivity Fabry-Perot interferometer based on offset splicing fibers and Vernier effect for strain measurement. International Symposium on Optoelectronic Technology and Application 2018, Beijing, China, 2018.

[10] Q. Fu, Y. Li, J. J. Tian*, and Y. Yao. Dual-channel fiber ultrasonic sensor system based on fiber Bragg grating in an erbium-doped fiber ring laser. IEEE 2017 Conference on Lasers and Electro-Optics - Pacific Rim (CLEO-PR), Singapore, August, 2017.

[9] X. L. Dong; S. M. Gao, J. J. Tian*, and Y. Yao. Efficient laser-ultrasound generation at optical fiber sidewall based on core-offset splicing fiber. IEEE 2017 Conference on Lasers and Electro-Optics - Pacific Rim (CLEO-PR), Singapore, August, 2017.

[8] X. L. Dong, Q. Fu, Y. Z. Jiao, J. J. Tian*, and Y. Yao. Side-excitation fiber-optic laser-ultrasonic transducer based on fused taper fiber. 16th International Conference on Optical Communications and Networks ( ICOCN 2017), Wuzhen, China, August, 2017.

[7] Q. Fu, Y. Z. Jiao, X. L. Dong, Y. Li, S. B. Ji, J. J. Tian*, and Y. Yao. Multi-wavelength lasing oscillation based on polarization hole burning effect in an Erbium-doped fiber laser. 16th International Conference on Optical Communications and Networks ( ICOCN 2017), Wuzhen, China, August, 2017.

[6] Y. Z. Jiao, X. L. Dong, Q. Fu, Z. G. Li, J. J. Tian*, and Y. Yao. Open-cavity Fabry-Perot interferometer pressure and temperature fiber sensor based on photonic crystal fiber. 16th International Conference on Optical Communications and Networks (ICOCN 2017), Wuzhen, China, August, 2017.

[5] Y. Z. Jiao, J. J. Tian*, and Y. Yao. Simultaneous measurement of temperature and strain based on all-fiber Fabry-Perot sensor. Applied Optics and Photonics China: Fiber Optic Sensing and Optical Communications (AOPC 2017), Beijing, China, June, 2017.

[4] Z. J. Lu, Y. Z. Jiao, M. R. Quan, J. J. Tian*, and Y. Yao. Study on the response speed of Fabry-Perot interferometer gas pressure fiber sensor based on photonic crystal fiber and Vernier effect. 2016 Optoelectronics Global Conference (OGC 2016), Shenzhen, China, September, 2016.

[3] M. R. Quan, Z. J. Lu, J. J. Tian*, and Y. Yao. Refractive index Fabry-Perot interferometric fiber sensor based on a microporous silver diaphragm and silica tube. Asia Communications and Photonics Conference (ACP 2015), Hong Kong, China, November, 2015.

[2] M. R. Quan, Y. Li, J. J. Tian*, and Y. Yao. Study on the influence of Mach–Zehnder interferometers to the output characteristics of multiwavelength erbium-doped fiber laser. SPIE/COS Photonics Asia, Beijing, China, October, 2014.

[1] Y. Li, M. R. Quan, J. J. Tian*, and Y. Yao. Performance study on a tunable multiwavelength erbium-doped fiber laser based on nonlinear optical loop mirror and Lyot birefringence fiber filter. SPIE/COS Photonics Asia, Beijing, China, October, 2014.

任教和任导师经历

研究生课程  《光学测量与传感》

指导学生  2013级
李苑 本科哈尔滨工业大学 毕业去向:哈尔滨工业大学 读博
全明冉 本科北华航天工业学院 毕业去向:华为技术有限公司 优秀毕业论文
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2014级
胡玲 本科哈尔滨工业大学 毕业去向:华为技术有限公司
高士民 本科哈尔滨理工大学 毕业去向:华为技术有限公司
卢泽锦 本科东北林业大学 毕业去向:华为技术有限公司 优秀毕业论文
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2015级
付琦 本科黑龙江大学(推免生)毕业去向:华为技术有限公司 优秀毕业论文
焦玉竹 本科大连海事大学(推免生)毕业去向:华为技术有限公司
董小龙 本科燕山大学 毕业去向:华为技术有限公司
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2016级
嵇绍波 本科江苏大学(推免生)毕业去向:华为技术有限公司 优秀毕业论文
李志岗 本科江苏大学(推免生)毕业去向:中兴通讯股份有限公司
王博 本科哈尔滨工业大学 毕业去向:华为技术有限公司
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2017级
肖梦哲 本科潍坊学院 在读
谢诗逸 本科燕山大学 在读
周程 本科中国石油大学 在读
最后更新:2019-02-16 10:10:49