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杨淑娜 教授

通信工程学院

信息与通信共程

职务:

毕业院校: 挪威科技大学
邮件: shunayang@hdu.edu.cn
办公地点:

10 访问

  • 个人资料
  • 社会职务
  • 研究领域
  • 教学与课程
  • 科研项目
  • 论文
  • 科研成果
  • 著作
  • 专利成果
  • 荣誉及奖励
  • 软件成果
个人简介

教授,硕士生导师,信息与通信工程系主任,长期从事微波光子学、光电子器件与系统、无线与光子融合通信等领域的研究工作,先后主持包括国家自然科学基金面上、青年项目,浙江省自然科学基金青年、探索项目,JKW重点研发、基础加强计划课题等在内的十余项国家级和省部级项目,已在国际一流期刊发表SCI论文60余篇,授权国家发明专利20余项。相关研究成果获浙江省自然科学奖三等奖,中国光学协会技术发明奖二等奖等。


联系方式:15968845761/shunayang@hdu.edu.cn


教育经历

  • 2010.08-2015.09, 挪威科技大学, 信息与信号处理, 博士

  • 2007.09-2010.03,浙江大学,物理电子学,硕士


工作经历

2015.12-至今,杭州电子科技大学,副教授,教授

2010.09-2015.09,挪威科技大学,研究助理

2010.03-2010.08,华为科技有限公司杭研所


社会职务

2022.01-至今  中国移动泛联研究院   技术顾问

中国通信学会高级会员,中国光学工程学会高级会员

国家自然科学基金网络评审专家

研究领域

微波光子信号产生、传输、接收、处理、测量及相关应用

下一代光网络结构设计、算法优化及调度


教学与课程

主讲本科生课程

电磁场与电磁波,信号与系统


主讲研究生课程

微波光子学,通信理论与优化


纵向科研

近五年主要主持和参与的纵向项目包括:

  • 自适应宽带任意波形光子学产生关键技术研究,2025.01-2028.12,国家自然科学基金面上项目,55万,主持

  • 融合噪声整形的宽带微波光子D/A转换方法研究,2026.01-2027.12,浙江省自然科学基金面上项目,10万,主持

  • 宽带可重构射频任意波形光子学产生理论与实验研究,2022.01-2024.12,浙江省自然科学基金一般项目,10万,主持

  • 基于脉冲处理的光子模数/数模转换技术研究,2020.01-2022.12,国家自然科学基金青年项目,27万,主持

  • 基于混合交换技术的绿色光网络节能算法研究,2017.01-2019.12,浙江省自然科学基金青年项目,8万,主持

  • 下一代集成式混合光交换网络的结构优化与性能分析,2017.01-2017.12,浙江省教育厅一般项目,1.5万,主持

  • 微波光子宽带信号收发一体化架构及关键技术研究,2019.01-2022.12,国家自然科学基金面上项目,62万,参与

  • 光子学高速数模转换关键技术研究,2019.01-2022.12,浙江省自然科学基金重点项目,30万,参与

  • 基于掺钕介质的热致频差可调谐同步双频脉冲激光器研究,2018.01-2020.12,国家自然科学基金青年项目, 25万,参与

  •  JG重点项目课题:高精细******,时间:20221-202512月,590万,主参

  • 重点研发计划课题:微波光子*****,2021-2024,350万,主参


横向科研

近五年主要主持横向课题

  • 中国移动:超宽带雷达信号产生与传输技术研究,2023.01-2024.12,XX万,主持

  • 浙江省电网:面向多元融合高弹性电网业务的OTN组网及关键技术研究,2019.01-2024.12,XX万,主持

  • 中国石油:热管温-压耦和模型建立及求解,2024.01-2024.12,XX万,主持

  • 中国石油:重力热管传热热性模拟研究,2024.01-2024.12, XX万,主持

论文

  • 2025

    1.     Haonan Zheng, Shuna Yang*, Zhaoyang Qiu, Yiran Gao, Bo Yang, and Hao Chi*, Photonic Nyquist folding receiver using optical pulses with discrete pulse position modulation, Optics Express, vol. 33, no. 6, pp. 12699-12708, Mar. 2025. 

    2.     R. Liu, S. Yang, Z. Qiu, B. Yang, J. Ou, and H. Chi*, Optical pulse position modulation based on the temporal Talbot effect for the Nyquist folding receiver, Optics Letters, vol. 50, no. 9, pp. 3030-3033, May 2025.

    3.    Yi Wang, S. Yang, B. Yang, Y. Gao, and H. Chi*, Photonic real-time Fourier transform via optical phase conjugation, Optics Letters, vol. 50, no. 11, pp. 3632-3635, June 2025. 

    4.        Xiao Zhang, Shuna Yang, Bo Yang*, and Hao Chi*, Photonic Approach for Multiparameter Measurement of CW and Pulsed Microwave Signals, IEEE Transactions of Microwave Theory and Techniques, Vol. 73, No. 8, pp. 5028-5037, August 2025. 

    5.        Ao Zeng, Shuna Yang, Yiran Gao, and Hao Chi*, Photonic Arbitrary Waveform Generation Based on Delta-Sigma Modulation and Spectrum Stitching, IEEE Photonics Technology Letters, Vol. 37, No. 21, pp. 1221-1224, Nov. 2025. 

    6.     周震,杨淑娜*,杨波,池灏,基于多音输入实现实时可重构射频任意波形产生方法,光子学报,VOL.54, NO.3, 0306005, 20253

    7.   Yizai Cai, Shuna Yang*, Hao Chi, All-optical digital-to-analog conversion based on pulse walk-off effect, Optical Fiber Technology, Vol.90, art. 104084, March 2025. 

    8.    Runyu Wang, Shuna Yang*, Bo Yang, Hao Chi, Photonic-assisted Nyquist folding receiver using binary phase-shift keying local oscillator, Optical Engineering, vol. 64, No. 11, Art no. 115102, Nov. 2025. 

    9.   Yuanyuan Yao, Shuna Yang*, Fei Xu, Yang Wang, Bo Yang, Hao Chi, Real-time photonic detection of direction and chirp rate for blind microwave LFM signals, Optics Communications, Vol. 591, Oct. 2025, Art no. 132134. 

    10.    Xinghua Yang, Shuna Yang*, Bo Yang, Fei Xu, Yunxin Lv, Yang Wang, and Hao Chi, Photonic generation of dual-band dual-chirp waveforms with a programmable duty cycle and immunity to power fading, Applied Optics, Vol 64, No. 29, pp. 8569-8574, Oct. 2025. 

  • 2025年-

  • 1.         X. Qin, S. Yang*, H. He, B. Yang, H. Chi, Photonic generation and anti-dispersion transmission of the quaternary phase-coded microwave waveforms, Optical engineering, vol. 63, no. 3, pp. 038104, 2024.

    2.         S. Yang, W. Zhu, H. Chi, B. Yang, J. Ou, Y. Zhai, Photonic generation of dual-band dual-chirp waveforms with anti-dispersion transmission, Applied Optics, vol. 62, no. 13, pp. 3512-3518, 2023.

    3.         S. Yang, L. Yin, H. Chi, B. Yang, J. Ou, Y. Zhai, Symmetry-Tunable Full-Duty Triangular-Shaped Waveform Generation Using a Simple Single-Drive Mach-Zehnder Modulator, IEEE Photonics Journal, vol. 15, no. 3, pp. 1-6, 2023.

    4.         S. Yang, Y. Huai, B. Yang, H. Chi,High-stable and reconfigurable photonic generation of radio-frequency arbitrary waveforms with multi-tone inputs, Optical Engineering, vol. 62, no.1, pp. 015101, 2023.

    5.         C. Yi, B. Yang, T. Jin, S. Yang*, Photonic generation and switching of multi-format chirp waveforms with anti-dispersion transmission, IEEE Photonics Technology Letters, vol. 34, no. 2, pp. 137-140, 2022.

    6.         S. Yang, J. Wang, H. Chi, B. Yang, Distortion compensation in continuous-time photonic time-stretched ADC based on redundancy detection, Applied Optics, vol. 60, pp. 1646-1652, 2021.

    7.         S. Yang, H. He, H. Chi, R. Zeng, Photonic quantization and encoding scheme with improved bit resolution based on waveform folding, Optics Express, vol. 27, pp. 35565-35573, 2019.

    8.         S. Yang, H. Chi, B. Yang, R. Zeng, J. Ou, Y. Zhai, Q. Li, Photonic digitization with differential encoding based on orthogonal vector superposition, IEEE Photonics Journal, vol. 11, pp. 1-9, 2019.

    9.         H. Chi, Q. Zhang, S. Yang*, B. Yang, Y. Zhai, J. Ou, Photonic analog-to-digital conversion based on time-to-frequency mapping, Optics Communications, vol. 502, pp. 127440, 2022.

    10.      S. Yang, X. Hu, B. Yang, H. Chi, Resolution-enhanced photonic quantization scheme based on weighted modulation transfer functions of lithium niobate Mach-Zehnder modulators, Applied Optics, vol. 59, pp. 9780-9785, 2020.

    11.      B. Yang, H. Zhao, S. Yang*, H. Chi, Wideband doppler frequency shift measurement and direction discrimination based on optical single sideband modulation with a fixed low-frequency reference signal, Optics Communications, vol. 499, pp. 127306, 2021.

    12.      S. Yang, J. Wang, B. Yang, J. Ou, Y. Zhai, Q. Li, A serial digital-to-analog conversion based on photonic time-stretch technology, Optics Communications, vol. 510, pp. 127949, 2022.

    13.      S. Yang, X. Hu, J. Ou, B. Yang, R. Zeng, High-performance digital-to-analog conversion based on dual-electrode Mach–Zehnder modulators, Optical Engineering, vol. 61, no. 4, pp. 045101, 2022.

    14.      S. Yu, S. Yang, B. Yang, H. Chi, Photonic generation of switchable dual-band dual-chirp microwave waveforms, IEEE Photonics Journal, vol. 14, no. 1, pp. 5504305, 2022.

    15.      G. Lyu, H. Chi, S. Yang*, B. Yang, All-optical digital-to-analog conversion based on time-domain pulse spectrum encoding, Optical Engineering, vol. 62, no. 6, pp. 06510, 2023.

    16.      H. Chi, S. Wang, S. Yang, B. Yang, et al., Photonic arbitrary waveform generation based on the temporal Talbot effect, Optics Express, vol. 29, no. 11, pp. 16927-16938, 2021.

    17.      C. Yi, S. Yang, B. Yang, T. Jin, H. Chi, Photonic approach for generating bandwidth-doubled and switchable multi-format chirp waveforms, Optics Letters, vol. 46, no. 7, pp. 1578-1581, 2021.

    18.      H. He, S. Yang, B. Yang, Y. Zhai, T. Jin, H. Chi, Photonic time-stretch based on phase modulation for sub-octave applications, Applied Optics, vol. 60, no. 22, pp. 6481-6488, 2021.

    19.      S. Yang, X. Hu, B. Yang, H. Chi, Resolution-enhanced photonic quantization scheme based on weighted modulation transfer functions of lithium niobate Mach-Zehnder modulators, Applied Optics, vol. 59, pp. 9780-9785, 2020.

    20.      H. He, S. Yang, H. Chi, T. Jin, Photonic serial implementation of a flash analog-to-digital converter, Optics Letters, vol. 45, no. 7, pp. 1643-1646, 2020.

    21.      S. Yang, M. Hu, H. Chi, Q. Li, Photonic digital-to-analog conversion based on wavelength multiplexing, Optics Communications, vol. 401, pp. 1-5, 2017.

    22.      S. Yang, N. Stol, H. Chi, Q. Li, Optimized design of delay-line buffers with an input-feedback mechanism for asynchronous optical packet switching networks, Applied Optics, vol. 55, no. 31, pp. 8705-8712, 2016.

    23.      H. He, S. Yang, T. Jin, H. Chi, Photonic quantization using dual-output Mach-Zehnder modulators and balanced photodetectors, Optics Communications, vol. 446, pp. 72-76, 2019.

    24.      S. Yang, Z. Shi, H. Chi, X. Zhang, S. Zheng, X. Jin, J. Yao, Photonic analog-to-digital conversion using multiple comparators and Mach-Zehnder modulators with identical half-wave voltages, Optics Communications, vol. 282, no. 4, pp. 504-507, 2009.

    25.      S. Yang, N. Stol, Performance modeling in multi-service communications systems with preemptive scheduling, Journal of Communications, vol. 9, no. 6, pp. 448-460, 2014.

    26.      S. Yang, C. Wang, H. Chi, X. Zhang, S. Zheng, X. Jin, J. Yao, Photonic analog-to-digital converter using Mach-Zehnder modulators having identical half-wave voltages with improved bit resolution, Applied Optics, vol. 48, no. 22, pp. 4458-4467, 2009.

    27.      S. Yang, N. Stol, Multiple input single output optical buffers for asynchronous optical packet switched networks, IEEE GLOBECOM, pp. 2054-2059, Austin, TX, USA, 2014.

    28.      B. Yang, H. Chi, S. Yang, Y. Zhai, J. Ou, Polarization multiplexed active mode-locking optoelectronic oscillator for frequency tunable dual-band microwave pulse signals generation, Optics Express, vol. 30, no.15, pp. 27132-27139, 2022.

    29.      杨淑娜,刘志伟,杨波,曾然,基于矢量叠加实现差分编码的光子模数转换方案,光子学报,Vol. 49, No. 3, pp. 57-63, 2020.

    30.      C. Huang, H. Chi, S. Yang, H. Chi, Photonic generation of dual-mode multi-format chirp microwave signals, Applied Optics, vol. 62, no. 31, pp. 8224-8228, 2023.



科研成果

近五年主要主持和参与的纵向项目包括:

  • 自适应宽带任意波形光子学产生关键技术研究,2025.01-2028.12,国家自然科学基金面上项目,55万,主持

  • 融合噪声整形的宽带微波光子D/A转换方法研究,2026.01-2027.12,浙江省自然科学基金面上项目,10万,主持

  • 宽带可重构射频任意波形光子学产生理论与实验研究,2022.01-2024.12,浙江省自然科学基金一般项目,10万,主持

  • 基于脉冲处理的光子模数/数模转换技术研究,2020.01-2022.12,国家自然科学基金青年项目,27万,主持

  • 基于混合交换技术的绿色光网络节能算法研究,2017.01-2019.12,浙江省自然科学基金青年项目,8万,主持

  • 下一代集成式混合光交换网络的结构优化与性能分析,2017.01-2017.12,浙江省教育厅一般项目,1.5万,主持

  • 微波光子宽带信号收发一体化架构及关键技术研究,2019.01-2022.12,国家自然科学基金面上项目,62万,参与

  • 光子学高速数模转换关键技术研究,2019.01-2022.12,浙江省自然科学基金重点项目,30万,参与

  • 基于掺钕介质的热致频差可调谐同步双频脉冲激光器研究,2018.01-2020.12,国家自然科学基金青年项目, 25万,参与

  •  JG重点项目课题:高精细******,时间:20221-202512月,590万,主参

  • 重点研发计划课题:微波光子*****,2021-2024,350万,主参


著作
专利成果

  • 基于集成式混合交换技术的光交换机,发明专利,专利授权,201811433178.X,CN 109451377 B,杨淑娜

  • 一种基于强度调节和差分编码的光子模数转换方法及系统,发明专利,专利,201910243149.5,CN109828421B,,杨淑娜

  • 一种基于非对称数字编码方案的光子模数转换系统及方法,发明专利,201910308729.8,杨淑娜

  • 一种基于分级量化原理的光子模数转换系统及方法,发明专利,202010008437.5,杨淑娜

  • 一种基于数字映射的高速光子数模转换方法及系统,发明专利,专利授权,202010679505.0,CN111884727B,杨淑娜

  • 一种基于射频信号延迟光子时间拉伸模数转换方法及系统,发明专利,202010553566.2,杨淑娜

  • 基于DP-MZM的双频段相位编码脉冲信号的产生方法及系统,发明专利,202110792715.5,杨淑娜

  • 一种基于加权调制曲线的光子模数转换方法及系统,发明专利,202011600799.X,杨淑娜

  • 基于DP-BPSK的双频段相位编码信号产生的方法及系统,发明专利,202110864675.0,杨淑娜

  • 一种基于双驱动电光调制器阵列的高速光子数模转换方法,发明专利,202110470026.2,杨淑娜

  • 一种基于光谱整形的数模转换方法与系统,发明专利,202110468241.9,杨淑娜

  • 电力业务可靠性约束RWA方法及系统,发明专利,202111362414.5,杨淑娜

  • 基于脉冲处理的光子数模转换系统,发明专利,202111474819.8,杨淑娜


荣誉及奖励

2024年度浙江省自然科学奖三等奖,微波光子宽带信号处理关键理论与方法

2025年度中国光学学会技术发明奖二等奖,工业物联状态预测微波光子物理通信控制融合方法及系统

软件成果