张洪明 - 清华大学 - 电子工程系

个人简介

副研究员，博士生导师，硕士生导师。于清华大学电子工程系获学士和工学博士学位。主要研究领域包括可见光通信、紫外光通信等。曾主持国家863项目、自然科学基金项目等，并参与国家重点研发计划、973、自然科学基金重点等项目。曾获国防科技进步三等奖，中国光学工程学会科技创新二等奖，国家电网信息通信产业集团有限公司科学技术进步一等奖，中国发明协会发明创业金奖，北京发明创新大赛金奖，第47届日内瓦发明展览会金奖，中国电子学会自然科学进步二等奖，中国轻工业联合会科学技术进步二等奖等。获授权发明专利16项，发表学术论文80余篇。教育经历 1998.9-2003.8 清华大学电子工程系博士学位 1993.9-1998.7 清华大学电子工程系学士学位工作经历 2008.4至今清华大学电子工程系副教授 2003.4-2008.4 清华大学电子工程系讲师曾获荣誉中国轻工业联合会科学技术进步奖二等奖(2022) 中国电子学会科学技术奖二等奖(2022) 北京市科学技术进步奖二等奖(2021) 第47届日内瓦发明展览会金奖(2019) 北京发明创新大赛金奖(2021) 中国发明协会发明创业金奖(2019) 国家电网信息通信产业集团有限公司科学技术进步一等奖(2018) 中国光学工程学会科技创新二等奖(2015) 国防科技进步三等奖(2012-04-16) 清华大学电子工程系优秀共产党员(2011-04-16) 清华大学优秀班主任二等奖(2008-04-16) 清华大学教学成果一等奖(2006-04-16) 清华大学优秀教学软件评选一等奖(2005-04-16)

近期论文

查看导师最新文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

Di Zheng, Hongming Zhang, Jian Song, “DCO-OTFS-based full-duplex relay-assisted visible light communications,” Optics Express, Vol. 29, No. 25, 41323, Dec. 2021. Tian Cao, Hongming Zhang, Jian Song, “BER Performance Analysis for Downlink Nonorthogonal Multiple Access With Error Propagation Mitigated Method in Visible Light Communications,” IEEE Transactions on Vehicular Technology, vol. 70, no. 9, pp.9190-9206, Sep. 2021. J. Song, T. Cao, and H. Zhang, “Performance analysis of a low-complexity nonorthogonal multiple access scheme in visible light communication downlinks using pulse modulations,” Intelligent and Converged Networks 2(1): 50-65, 2021. D. Zheng, H. Zhang and J. Song, "OFDM With Differential Index Modulation for Visible Light Communication," in IEEE Photonics Journal, vol. 12, no. 1, pp. 1-8, Feb. 2020, Art no. 7900708. D. Zheng, H. Zhang and J. Song,"Spatial Multiplexing MIMO Visible Light Communications With Densely Distributed LEDs and PDs," IEEE Photonics Journal, vol. 12, no. 5, Oct. 2020, Art no. 7905807. Tao Liu, Hongming Zhang, Jian Song, “Monte-Carlo simulation-based characteristics of underwater scattering channel,” Optical Engineering, 56 (7), 070501, 2017. Ling Wei, Hongming Zhang, Guanghua Gong and Jian Song, “Experimental Demonstration of a Cubic Receiver based MIMO Visible Light Communication System,” IEEE Photonics Journal, 9(1), pp.7900107, 2017. Ling Wei, Hongming Zhang, Bingyan Yu, “Optimal bit-and-power allocation algorithm for VLC-OFDM system,” Electronics Letters, 52(12), pp. 1036-1037, 2016. C. Xu, J. Cheng, and H. Zhang, “Performance of subcarrier PSK systems using PSAM maximum likelihood estimation in turbulence channels,” IEEE/OSA Journal of Lightwave Technology, 34(9), pp. 2267 – 2279, 2016. Ling Wei, Hongming Zhang, Bingyan Yu, Jian Song, Yang Guan, “Cubic-Receiver-based Indoor Optical Wireless Location System,” IEEE Photonics Journal, 8(1), pp.7901207, 2016. Ling Wei, Hongming Zhang, Bingyan Yu, Yang Guan, “High-accuracy indoor positioning system based on visible light communication,” Optical Engineering, 54(11), pp. 110501, 2015. Bingyan Yu, Hongming Zhang, Ling Wei, and Jian Song, “Subcarrier Grouping OFDM for Visible Light Communication Systems,” IEEE Photonics Journal, 7(5), pp, 7903812, 2015. Guanghua Gong, Hongming Zhang, and Minyu Yao, "Speckle noise reduction algorithm with total variation regularization in optical coherence tomography," Opt. Express 23(19), 24699-24712 (2015). Changming Xu, Hongming Zhang, and Julian Cheng, "Effects of haze particles and fog droplets on NLOS ultraviolet communication channels," Opt. Express 23(18), 23259-23269 (2015). Peng Wang, Hongming Zhang, and Zhengyuan Xu, "Simplified model and experimental validation for ultraviolet single-scattering channels," Chinese Optics Letters Vol. 13, Issue 8, pp. 080603(2015). Tao Liu, Hongming zhang, Peng wang “Performance analysis of non line of sight ultraviolet communication through turbulence channel”，Chin. Opt. Lett. 13(04), 040601(2015). Xu C.; Zhang H., “Channel analyses over wide optical spectra for long-range scattering communication,” IEEE Communications Letters, 19(2), pp 187-190, 2015. Bingyan Yu, Hongming Zhang, Hao Dong, “An Optimized 481-Mbit/s Visible Light Communication System using Phosphorescent White LED,” Chinese Optics Letters, 12(11), 110606, 2014. Yu B, Zhang H. Peak-to-Average Power Ratio Distribution of OFDM Visible Light Communication Systems. Applied Mechanics and Materials, 2014, 987-990. Guanghua Gong, Hongming Zhang, and Minyu Yao, “Construction model for total variation regularization parameter,” Optics Express, Vol. 22 No. 9, 10500-10508, 2014. Hao Dong, Hongming Zhang, Kai Lang, Bingyan Yu, Minyu Yao, “OFDM visible light communication transmitter based on LED array,” Chinese Optics Letters, 12(5), pp. 052301, 2014. Zhexin Ren, Hongming Zhang, Ling Wei,Yang Guan, “A High Precision Indoor Positioning System Based on VLC and Smart Handheld,” Applied Mechanics and Materials, 2014, 571-572, pp. 183-186 Yujie Dou, Hongming Zhang, Yang Wang, and Minyu Yao, “Flat-top optical frequency comb generation based on optical fiber-loop modulation with external injection,” Chinese Optics Letters, 11(7), pp. 070603, 2013. Yang Wang, Hongming Zhang, Yujie Dou, and Minyu Yao, “Experimental evaluation of resolution-enhancement phase-shifted all optical analog-to-digital converter using electrical ADC array,” Chinese Optics Letters, 11(8), pp. 082301, 2013. Yang Wang, Hongming Zhang, Yujie Dou, and Minyu Yao, “Error code correction for phase-shifted optical quantization based on maximum likelihood estimation algorithm,” Electronics Letters, 49(7), pp. 485-486, 2013. Yang Wang, Yujie Dou, and Hongming Zhang, “Experimental demonstration of 5-bit phase-shifted all-optical analog-to-digital converter,” Chinese Optics Letters, 11(4), pp. 042301, 2013. Yang Wang, Hongming Zhang, and Yujie Dou, “Proposal for an all optical analog-to-digital converter based on modal birefringence in a polarization maintaining fiber,” Optical Engineering, 52(2), p. 025005, 2013. Yang Wang, Hongming Zhang, Qingwei Wu, and Minyu Yao, “Improvement of Photonic ADC Based on Phase-Shifted Optical Quantization by Using Additional Modulators,” IEEE Photonics Technology Letters, 24(7), pp. 566-568, 2012. Yujie Dou, Hongming Zhang, and Minyu Yao, “Multi-wavelength pulse generation using flattop optical frequency comb and array wave grating,” Chinese Optics Letters, 10(12), 2012. Yujie Dou, Hongming Zhang, and Yao Minyu, “Generation of Flat Optical-Frequency Comb Using Cascaded Intensity and Phase Modulators,” IEEE Photonics Technology Letters, 24(9), pp. 727-729, 2012. Yuancheng Zhang, Hongming Zhang, and Yao Minyu, “All-optical queue buffer using optical threshold functions and wavelength converters,” Chinese Optics Letters, 10(3), 2012. Yujie Dou, Hongming Zhang, and Minyu Yao, “Improvement of flatness of optical frequency comb based on nonlinear effect of intensity modulator,” Optics Letters, vol. 36, pp. 2749-2751, July 2011. Hao Nan, Yuantao Gu, and Zhang Hongming, “Optical Analog-to-Digital Conversion System Based on Compressive Sampling,” IEEE Photonics Technology Letters, 23(2), pp. 67-69, January 2011. Yuancheng Zhang, Hongming Zhang, and Minyu Yao, “Modular and intelligently controlled optical buffer with last-in-first-out priority,” Electronics Letters, 47(22), pp. 1236-1238, 2011. Xin Fu, Hongming Zhang, and Minyu Yao, “Phase spectrum algorithm for correction of time distortion in wavelength de-multiplexing analog-to-digital converter,” Optical Engineering, 49(5), p. 055003, 2010. Yue Peng, Hongming Zhang, Qingwei Wu, Xin Fu, and Minyu Yao, “Adaptive thresholding scheme in photonic analog-to-digital conversion,” Optics Letters, 34(14), pp. 2201-2203, 2009. Qingwei Wu, Hongming Zhang, Yue Peng, and Minyu Yao, “40GS/s optical analog-to-digital conversion system and its improvement,” Optics Express, 17(11), pp. 9252-9257, 2009. Xin Fu, Hongming Zhang, Yue Peng, and Minyu Yao, “40-Gbps time- and wavelength-interleaved pulse-train generation in wavelength demultiplexing analog-to-digital conversion,” Optical Engineering, 48(10), p. 104302, 2009. Xin Fu, Hongming Zhang, Zhuangquan Zhang, and Minyu Yao, “Noninterferometric optical phase-shifter module in phase-shifted optical quantization,” Optical Engineering, 48(3), p. 034301, 2009. Xin Fu, Hongming Zhang, Meng Yan, and Minyu Yao, “Repetition rate tunable ultra-short optical pulse generation based on electrical pattern generator,” Chinese Optics Letters, 7(11), pp. 1010-1011, 2009. Yue Peng, Hongming Zhang, Qingwei Wu, Yuancheng Zhang, Xin Fu, Minyu Yao, “Experimental demonstration of all-optical analog-to-digital conversion with balanced detection threshold scheme,” IEEE Photonics Technology Letters, 21(23), pp. 1776-1778, 2009. Qingwei Wu, Hongming Zhang, Xin Fu, Yue Peng, and Minyu Yao, “Spectral encoded photonic analog-to- digital converter based on cascaded unbalanced MZMs,” IEEE Photonics Technology Letters, 21(4), pp. 224-226, 2009. Yue Peng, Hongming Zhang, Meng Yan, Minyu Yao, “Photonic arbitrary waveform generator based on dispersion of multiwavelength pulse sequence,” Optical Engineering, 47(4), 2008. Yue Peng, Hongming Zhang, Qingwei Wu, Xin Fu, and Minyu Yao, “Ultrawideband monocycle pulse generation using dual output intensity modulator,” Optical Engineering, 47(6), p.060501, 2008. Yue Peng, Hongming Zhang, Yuanchun Zhang, and Minyu Yao, “Photonic digital-to-analog converter based on summing of serial weighted multi-wavelength Pulses,” IEEE Photonics Technology Letters, 20(21), pp. 2135-2137, 2008. Qingwei Wu, Hongming Zhang, Minyu Yao, and Wei Zhou, “All-optical analog-to-digital conversion using inherent multiwavelength phase shift in LiNbO3 phase modulator,” IEEE Photonics Technology Letters, 20(9-12), pp. 1036-1038, May-June 2008. Meng Yan, Minyu Yao, Hongming Zhang, Li Xia, and Ye Zhang, “En/Decoder for spectral phase-coded OCDMA system based on amplitude sampled FBG,” IEEE Photonics Technology Letters, 20(10), pp. 788-790, May 2008. Wangzhe Li, Hongming Zhang, Qingwei Wu, Zhuangqian Zhang, and Minyu Yao, “All-optical analog-to-digital conversion based on polarization-differential interference and phase modulation,” IEEE Photonics Technology Letters, 19(8), pp. 625-627, 2007.[J49] Meng Yan, Hongming Zhang, and Minyu Yao, “Impact of encoder-decoder wavelength mismatch on the performance of direct-sequence optical code-division multiple-access system,” Optical Engineering, 46, p. 115007, 2007.