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杨强 副研究员

杨强,博士,北京石油化工学院人工智能研究院 副研究员。

北京邮电大学光学工程专业博士,近几年主要研究工作集中在生物组织深层成像技术和显微成像技术,包括光学相干断层成像、波前整形、结构光显微、光声成像技术等。作为课题主要成员参与了多项市级和部级科研项目,包括北京市教育委员会科技计划重点项目1项,美国国立卫生院National Institutes of Health的项目2项。在国内一级/国际期刊上发表了近20篇学术论文,其中SCI/EI收录15篇,在光学成像领域申请专利1项。

E-mail:yangqiang@bipt.edu.cn

个人简历

  • 2010.09-2014.07 北京邮电大学,信息光子学与光通信研究院(光学工程专业),工学博士

  • 2011.09-2013.08 圣路易斯华盛顿大学(美),生物医学工程系,国家公派访问博士生

  • 2014.10-2015.10 清华大学,精密仪器系,博士后

  • 2015.10-2018.10 加州大学欧文分校,贝克曼激光研究所,博士后

  • 2019.01-2020.07 北京信息科技大学,仪器科学与光电工程学院,讲师

主讲课程

人工智能与医疗影像 研究生课程

研究方向

生物医学光学成像,计算光学成像,光学全息术。

 

主要科研项目

1. 2021/03-今,人工智能青年科学家攀登计划-创新项目,眼底成像智能诊断系统,AAI-2021-004,项目负责人。

2. 2020/01-2022/12,北京市教育委员会科技计划重点项目,面向年龄相关性黄斑变性早期诊断的光学弹性成像方法研究,KZ202011232050,参加。

3. 2015/04-2019/03,National Institutes of Health, 5R01HL127271-02, Combined OCT/US/PAT system for intravascular imaging,参加。

4. 2014/08-2019/04,National Institutes of Health, 5R01HL125084-06, Phase resolved ARF optical coherence elastography for intravascular imaging,参加。

5. 2014/01-2018/12,国家重大仪器专项, 61327902, 多维多尺度高分辨率计算摄像仪器(项目总负责人为清华大学戴琼海老师),参加。

6. 2011/05-2013/05,National Academies Keck Futures Initiative, IS 13, Time-reversed ultrasonically encoded (TRUE) optical focusing for biomedical imaging,参加。

7. 2008/09-2013/08,National Cancer Institute,U54 CA136398, Photoacoustic / Optical / Ultrasonic Imaging of Sentinel Lymph Nodes and Metastas,参加。

 

发表论文

[1] Jing Cao, Qiang Yang, Yusi Miao, et al. Enhance the delivery of light energy ultra-deep into turbid medium by controlling multiple scattering photons to travel in open channelsLight: Science & Applications 11, 2022108. nature子刊,IF=20.02,中科院分区光学小类排第二)

[2] Qiang Yang, Jing Cao, Yusi Miao, Jiang Zhu, and Zhongping Chen*, Extended Imaging Depth of En-face Optical Coherence Tomography Based on Fast Measurement of Reflection Matrix by Widefield Heterodyne Detection, Optics Letters, 2020, 45(4): 828-831.

[3] 杨强,祝连庆,樊凡,端木正,朱疆*,正向切片光学相干断层成像系统的信号提取方法,光学学报, 2020, 40(07): 53-69.

[4] Qiang Yang, Yusi Miao, Tiancheng Huo, Yan Li, Emon Heidari, Jiang Zhu, and Zhongping Chen*, Deep imaging in highly scattering media by combining reflection matrix measurement with Bessel-like beam based optical coherence tomography, Applied Physics Letters, 2018, 113: 011106.

[5] Qiang Yang, Liangcai Cao*, Hua Zhang, Hao Zhang, Guofan Jin, Method of lateral image reconstruction in structured illumination microscopy with super resolution, Journal of Innovative Optical Health Sciences, 2016, 9(3): 1630002.

[6] 杨强, 曹良才*, 金国藩, 可抑制生物组织散射效应的光学聚焦技术研究进展, 中国激光, 2015, 42(9): 0901001.

[7] Qiang Yang, Xinzhu Sang*, Daxiong Xu, Time-reversed optical focusing through scattering media by digital full phase and amplitude recovery using a single phase-only SLM, Journal of Innovative Optical Health Sciences2015, 8(2): 1550007.

[8] Qiang Yang, Xiao Xu, Puxiang Lai, Daxiong Xu, and Lihong V. Wang*, Time-reversed ultrasonically encoded optical focusing using two ultrasonic transducers for improved ultrasonic axial resolution, Journal of Biomedical Optics, 2013, 18(11): 110502.

[9] Qiang Yang, Yusi Miao, Jiang Zhu and Zhongping Chen*, Deep tissue imaging by combining reflection matrix measurement with parallel heterodyne-detection based low-coherence interferometer, International Workshop on Holography and Related Technologies (IWH2018), 2018, Suzhou, P. R. China, page# 128-129, 2018.11.30-12.02.

[0] Qiang Yang, Xinzhu Sang, Liangcai Cao*, Guofan Jin, Optical Focusing through Scattering Media by Time-reversing the Diffused Complex Field by Using a Single SLM, Digital Holography and 3D Imaging, 2015, Shanghai, P. R. China, Paper# DTh2A.7 2015.05.24-05.28.

[11] Qiang YangXiao Xu, Puxiang Lai, Xinzhu Sang, Lihong V. Wang*, Improving the axial resolution in time-reversed ultrasonically encoded (TRUE) optical focusing with dual ultrasonic waves, Proc. SPIE 8943, Photons Plus Ultrasound: Imaging and Sensing 2014, 894338, San Francisco, U.S.A., 2014.02.01-02.06.

[12] Jiang Zhu, Jianting Liu, Lianqing Zhu, Chongyang Wang, Fan Fan, Qiang Yang, Fan Zhang, Optical coherence tomography angiography for mapping cerebral microvasculature based on normalized differentiation analysis, Journal of Biophotonics, 2020, 13(10): e202000245.

[14] Jianting Liu, Jiang Zhu, Lianqing Zhu, Chongyang Wang, Qiang Yang, Fan Fan, Fan Zhang, Quantitative Assessment of Optical Coherence Tomography Angiography Algorithms for Neuroimaging. Journal of Biophotonics, 2020, 13(9): e202000181.

[14] Jiang Zhu, Junxiao Yu, Yueqiao Qu, Youmin He, Yan Li, Qiang Yang, Tiancheng Huo, Xingdao He, and Zhongping Chen*, Coaxial excitation longitudinal shear wave measurement for quantitative elasticity assessment using phase-resolved optical coherence elastography, Optics Letters, 2018, 43(10): 2388-2391.

[15] Yan Li, Joseph Jing, Junxiao Yu, Buyun Zhang, Tiancheng Huo, Qiang Yang and Zhongping Chen*, Multimodality endoscopic optical coherence tomography and fluorescence imaging technology for visualization of layered architecture and subsurface microvasculature, Optics Letters, 2018, 43(9): 2074-2077.

[16] Jiang Zhu, Buyun Zhang, Li Qi, Ling Wang, Qiang Yang, Zhuqing Zhu, Tiancheng Huo, Zhongping Chen*, Quantitative angle-insensitive flow measurement using relative standard deviation OCT. Applied Physics Letters, 2017, 111: 181101.

[17] Jiang Zhu, Yusi Miao, Li Qi, Yueqiao Qu, Youmin He, Qiang Yang, Zhongping Chen. Longitudinal shear wave imaging for elasticity mapping using optical coherence elastography. Applied Physics Letters, 2017, 110: 201101.

[18] Yan Zhao, Liangcai Cao*, Hao Zhang, Wei Tan, Shenghan Wu, Zheng Wang, Qiang Yang, Guofan Jin, Time-division multiplexing holographic display using angular-spectrum layer-oriented method, Chinese Optics Letters, 2016, 14(1), 010005.

[19] Yuta Suzuki, Jian Wei Tay, Qiang Yang, Lihong V. Wang*, Continuous scanning of a time-reversed ultrasonically encoded optical focus by reflection-mode digital phase conjugation, Optics Letters, 2014, 39(12): 3441-3444.

[20] Yuta Suzuki, Jian Wei Tay, Qiang Yang, Lihong V. Wang*, Digital reflection-mode time-reversed ultrasonically encoded (TRUE) optical focusing, Proc. SPIE. 8943, Photons Plus Ultrasound: Imaging and Sensing 2014, 89431B, San Francisco, United States, 2014.02.01-02.06.

[21] Di Zhang , Binbin Yan , Kuizhi Huang, Qiang Yang, Xiao Chen, Genxiang Chen, Xinzhu Sang*, Opto-DMD -based tunable triple-channel-wavelength fiber laser, Proc. SPIE 8943, Optoelectronic Devices & Integration IV. 2012, 8555, Beijing, China, 2012.11 05-11.07.

 

专利

1.杨强、祝连庆、朱疆、樊凡、端木正,一种光学相干断层成像方法 。国家知识产权局发明专利。专利申请号:201911238001.9,2019年12月6日。