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魏永峰

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发布时间:2016-01-04
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一、基本信息

姓名:魏永峰

性别:男

出生年月:1979.05

民族:汉族

政治面貌:中共党员

籍贯:内蒙古包头市

职称:教授

邮箱:weiyongfeng@imu.edu.cn;wyfily@bupt.cn

地址:北校区卓越楼906

招收信息与通信工程(081000)、通信工程(含宽带网络、移动通信等)(085402)专业研究生,欢迎报考!

二、教育背景

2011.09至2014.07,北京邮电大学,信号与信息处理,博士

三、工作经历

2022.10至2024.01,清华大学,电子工程系,访问学者

2022.12至今,内蒙古大学,电子信息工程学院,教授

2006.07至2022.11,内蒙古大学,电子信息工程学院,助教、讲师、副教授

四、授课情况

本科生:《电磁场与电磁波》、《新生研讨课》、《探秘光通信》、《通信原理》、《数字电路》、《信号与系统》、《现代交换原理》等

研究生:《现代通信理论与系统》、《数字通信》、《面向对象程序设计》

五、研究方向

基于微波光子技术的新体制雷达及其关键技术、无线通信理论等研究工作,包括微波光子信号处理、基于微波光子移相的模拟信号处理、光子雷达信道化接收和光载无线通信系统等。

六、教学科研成果

主持国家自然科学基金项目2项,内蒙古自然科学基金项目1项,内蒙古自治区科技计划项目2项,内蒙古大学高层次人才科研启动项目1项;主持产学合作协同育人项目1项,校级虚拟仿真实验教学一流课程1项,线上线下混合式一流课程《电磁场与电磁波》主干核心课程建设项目1项,主持建设通识教育选修课《探秘光通信》并获批自治区教育科学研究“十三五”规划课题,国家专利授权2项,参与国家973项目、国家自然科学基金项目、内蒙古自然科学基金多项。发表论文30余篇,其中SCI检索10余篇,EI检索20余篇。

1.科研项目

[1]国家自然科学基金委员会, 62161034, 基于镜像抑制混频的微波光子信道化接收方法, 2022-01至2025-12, 34万元, 主持

[2]国家自然科学基金委员会, 61561037, 光子雷达系统中光真延时及光子移相技术的研究, 2016-01至2019-12, 45.2万元, 已结题, 主持

[3]内蒙古自然科学基金委员会, 2017MS0609, 微波光子信号处理中光子射频移相技术的研究, 2017-01至2019-12, 6万元, 已结题, 主持

[4]国家自然科学基金委员会, 61861034, 混合供能异构网络的协作资源分配研究, 2019-01至2022-12, 36万元, 已结题, 参加

[5]国家自然科学基金委员会, 61461035, 基于认知技术的分层异构网络能效分析与资源分配研究, 2015-01至2018-12, 46万元, 已结题, 参加

[6]国家自然科学基金委员会, 61362027, α稳定分布噪声环境中循环平稳信号线性滤波与参数估计方法研究, 2014-01至2017-12, 43万元, 已结题, 参加

[7]国家自然科学基金委员会, 61001124, 基于效用的网络MIMO资源分配和调度优化研究, 2011-01至2013-12, 22万元, 已结题, 参加

[8]内蒙古大学高层次人才引进计划,光控相控阵雷达中光真延时及光子射频移相技术的研究, 2014.12至2017-12, 已结题,主持

[9]内蒙古自治区科技计划项目,子宫内膜癌影像多模态人工智能诊断系统的研发与临床转化,2022-2025,40万元,子课题,主持

[10]内蒙古自治区科技计划项目,基于人工智能神经网络技术在内蒙古地区宫颈癌早期筛查多组学数据中的应用及软件平台研发,2023-2026,40万元,子课题,主持

2.代表性论文

[1] Measurement and analysis of instantaneous microwave frequency based on an optical frequency comb,2022.08,Applied Optic,2022,61(23).

[2] Image classification of forage grasses on Etuoke Banner using edge auto encoder network,2022.10,PLOS ONE,2022,17(6).

[3] Efficient Microwave Filter Design by a Surrogate-Model-Assisted Decomposition-Based Multi-Objective Evolutionary Algorithm,2022.11,Electronics,2022,11(20).

[4] Measurement of Instantaneous Frequency in Channelized Receiver Based on OFC, 2021.11,IEEE ACP2021,EI;

[5] 雷达线性调频信号产生与去啁啾方法研究,2021.02,激光与光电子学进展,2021,58(3).CSCD;

[6] Flat Optical Frequency Comb Generation Based on Intensity Modulator with RF Frequency Multiplication Circuit and Dual-parallel Mach-Zehnder Modulator. Asia Communications and Photonics/International Conference on Information Photonics and Optical Communications Conferences (ACP/IOPC 2020)

[7] Multi-band Frequency Conversion Scheme Employing Single Optical Frequency Comb.

[8] All-optical, Broadband Microwave Photonic Image-Reject Mixer with Local Oscillator Frequency Doubling.

[9] Frequency-doubling microwave signal generation with tunable phase shift based on DP-QPSK modulator, 2019, Tenth International Conference on Signal Processing Systems,2019-11-16.

[10] A Novel Photonic Phase Shifter Based on Polarization Controller and Dual-parallel Mach-Zehender Modulator, Asia Communications and Photonics Conference, ACP, 2018-10-26.

[11] Photonic generation of millimeter-wave signals with frequency-multiplying and tunable phase shift, 2018 4th International Conference on Frontiers of Signal, Processing, ICFSP 2018, 2018-9-24.

[12] Frequency-quadrupled microwave signal generation with tunable phase shift employing no optical filter, 2018 the 3rd Optoelectronics Global Conference, OGC 2018, 2018-9-4.

[13] A Broadband Microwave Photonic Mixer with the Capability of Phase Shifting, 2018 the 3rd Optoelectronics Global Conference, OGC 2018, 2018-9-4.

[14] A filter-less frequency-sextupled microwave signal processor with tunable phase shift, International Symposium on Photonics and Optoelectronics, 2018-8-18.

[15] A Novel Microwave Photonic Mixer with Tunable Phase Shift Based on External Modulators, 2018 3rd International Conference on Communication and Information Systems, 2018-12-28.

[16] A frequency-doubling microwave photonic phase shifter based on dual-polarization MZM, Applied Optics and Photonics China: Fiber Optic Sensing and Optical Communications, AOPC 2017, 2017-6-4.

[17] A Frequency-quadrupling Microwave Photonic Phase Shifter based on Dual-polarization MZM, Asia Communications and Photonics Conference, ACP, 2017-11-10

[18] All-optical, Broadband Microwave Photonic Sub-harmonic Image-reject Frequency Downconverter, Asia Communications and Photonics Conference(ACP2019), Chengdu, 2019

[19] Microwave Photonic Sub-harmonic Downconverter with Image Rejection Capability, 2019 4th Optoelectronics Global Conference, Shenzhen. 2019-09-03.

[20] Performance Analysis of Diversity and Multiplexing Based on OPNET, 2017 3rd IEEE International Conference on Computer and Communications, Chengdu, 2017-12-13.

[21] An Interference-Aware Uplink Power Control in LTE Heterogeneous Networks, Proceedings of TENCON 2018 - 2018 IEEE Region 10 Conference, Jeju, Korea, 2018-10-28.

[22] User Association for On-grid Energy Minimizing in HetNets with Hybrid Energy Supplies, 2018 18th IEEE International Conference on Communication Technology, Chongqing, 2018-10-08.

[23] “Broadband and tunable RF photonic phase shifter based on optical SSB modulation and FBG filtering,” OPTIK, 2015.10

[24] “Programmable RF Photonic Phase Shifters Based on FD-OP for Optically Controlled Beamforming,” Optical Fiber Technology, 2014.11

[25] “Optical true time-delay for two-dimensional phased array antennas using compact fiber grating prism,” Chinese Optics Letters, 11(10), 100606-100609, 2013

[26] “Two-dimensional optical architecture for true time-delay beam forming in phased array antennas,” Asia Communications and Photonics Conference, ATh3F-5, Beijing, 2013, oral presentation

[27] “Tunable and integrated RF photonic phase shifter based on phase modulation and FBG filtering,”Applied Optics and Photonics China,2015

[28] “Tunable RF photonic phase shifter based on optical DSB modulation and FBG filtering,” 2015 International Conference on Optoelectronics and Microelectronics, 2015

[29] “Generating, multiplexing/demultiplexing and receiving the orbital angular momentum of radio frequency signals using an optical true time delay unit,” Journal of Optics, 15(10), 105401,2013

[30] “Control of Optical Power in Optical Beamforming Networks Based on Broadband Optical Source and Chirped Fiber Grating,” Asia Communications and Photonics Conference, AF2F-62, Beijing, 2013, poster presentation

[31] “Generating the orbital angular momentum of radio frequency signals using optical-true-time-delay unit based on optical spectrum processor,” Optical Letter, 39, 2652-265, 2014

[32] “A high-resolution compact optical true-time delay beamformer using fiber Bragg grating and highly dispersive fiber,” Optical Fiber Technology, 2014

[33] “Compensation of chromatic-dispersion for full-duplex ROF links with vector signal transmission using frequency tripling”, Journal of Optics, 2014

[34] “Full-Duplex ROF Link with Seamless Convergence and High-Speed Broadband Wireless Access”, 2014

[35] An orbital angular momentum radio communication system optimized by intensity controlled masks effectively: Theoretical design and experimental verification[J]. Applied Physics Letters, 2014, 105(24):241109 - 241109-5.

3.授权专利

[1]魏永峰; 李想; 盛萌萌; 刘晓丽; 一种基于光谱处理的微波光子射频移相器, 2019-11-01, 中国, ZL201920697992.6.

[2]巩彩丽; 魏永峰; 一种基于GPU并行处理的可视火灾检测系统, 2020-02-14, 中国, ZL201920630925.2.

七、获奖情况

1.第九届全国电工电子基础课程实验教学案例设计竞赛,中国电子学会,国家级三等奖;

2.第九届全国电工电子基础课程实验教学案例设计竞赛,中国电子学会,省部级一等奖;

3.指导“兆易创新杯”第十五届、十六届中国研究生电子设计竞赛,荣获商业计划书专项赛一等奖2项;指导“华为杯”第十二届中国研究生电子设计竞赛,荣获商业计划书专项赛二等奖2项;指导第十二届“认证杯”中国数学建模网络挑战赛,并获全国比赛第二阶段优秀奖;指导第九届“大唐杯”全国大学生移动通信5G技术比赛,获省部级二等奖、省部级三等奖各一项;

4.内蒙古大学2016-2018年度优秀工会干部;

5.2016国家级大学生创新创业训练计划项目优秀指导教师;

6.2015年荣获内蒙古大学2014-2015学年学生就业工作先进个人;

7.互联网+大学生创新创业大赛最佳创意作品奖指导教师;

8.互联网+大学生创新创业大赛创意组一等奖指导教师;

9.2007年获内蒙古大学第九届青年教师课堂教学技能大赛理工科三等奖