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汤云东
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副教授
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汤云东,博士,副教授,博士生导师, 福建省级高层次人才。2006年7月获哈尔滨工业大学硕士学位,2006-2007年清华大学进修,2018年12月获福州大学博士学位,撰写的博士毕业论文分别荣获福州大学优秀博士学位论文奖和福建省优秀博士学位论文奖。历任助理研究员、副研究员、副研究员博导(破格)、副教授博导等,现为福州大学物理与信息工程学院通信工程系专任教师(曾任职微电子科学与工程系),长期从事生物医学信息处理、智能信号检测与处理、电路与系统、以及嵌入式系统及应用等相关交叉学科领域的教学和科研工作。任现职以来,主持2项国家自然科学基金面上项目,1项目福建省自然科学基金面上项目,2项福建省教育厅科研项目,1项校人才基金项目,多项校企合作横向项目;参与国家/省部级/厅级等项目近10项,以及一项福建省科学技术奖一等奖;近年来作为第一作者在领域内权威SCI检索期刊Int. Commun. Heat Mass Transfer.、IEEE Trans Instrum. Meas.、IEEE Trans Magn.、Appl. Math. Modell.、Int. J. Heat Mass Transfer、J. Magn. Magn. Mater.、J. Therm. Biol.,J. Appl. Phys.等发表论文近40篇,其中JCR 1区及顶级期刊论文约10篇,SCI论文被引用约1000余次,授权及实审国家发明专利约30件。长期与巴西圣卡塔琳纳州联邦大学,罗马尼亚亚历山德鲁大学,埃及米尼亚大学,以及美国密歇根大学等国际知名高校有紧密合作,可推荐优秀硕士生进行访学或读博等。
研究兴趣(但不限于):
医学信息检测技术与信号处理、磁纳米热疗建模及导航系统、医学图像重建与肿瘤成像方法、电力电子技术与测控系统、医疗电子系统与嵌入式机器人、电-磁-热-流-固等多物理场建模方法,以及多学科和跨学科的医工交叉技术研究等。
研究生招生:
学术型博士研究生:081000信息与通信工程,及140100集成电路科学与工程
学术型硕士研究生:08100x信息与通信工程(信号与信息处理、通信与信息系统),及140100集成电路科学与工程
专业型硕士研究生:0854xx电子信息(新一代电子信息技术、集成电路工程)
>>欢迎动手能力强或热爱科学研究的本科生、研究生同学加入研究团队,绩点排名靠前者零基础可加入。课题组项目经费充足,可提供组内补助、研究生成果奖,及助研岗位等,同时组内同学研一绩点达标者基本均可获国奖。
>>>>欢迎准备报考2025级硕士生和博士生同学来信咨询。博士申请者需提供CET6和绩点成绩(wx.fzu.edu.cn/info/1059/5962.htm)<<<<
电子邮箱:121313724@qq.com,或 tangyundong@fzu.edu.cn
办公地址:福建省福州市福州大学城乌龙江北大道2号,福州大学旗山校区,物理与信息工程学院
Individual Profile:
Yundong Tang received his Ph.D degree in Electrical Engineering from Fuzhou University in 2018 with his provincial excellent doctoral dissertation, and M. A. degree in Automatic Testing and Control from Harbin institute of technology in 2006. He works currently at the School of Physics and Information Engineering, Fuzhou University as a associate professor. He published about 40 representative SCI papers as the first author in several prestigious journals, presided over several provincial and national level projects, and received about 20 authorizations for national invention patent in recent years. His research interest mainly focuses on Biomedical information processing, Intelligent signal detection and processing, Circuits and Systems, and Interdisciplinary and multidisciplinary research. In addition, he has a very close cooperation with Brazil’s Federal University of Santa Catalina, University of Michigan and other internationally renowned universities. Excellent students in our group can be recommended for academic purpose and futher education to these schools. In addition, he is alway allowed to enroll the master and doctoral students in the following major:
PhD student: Optoelectronic intelligent perception and processing, medical imaging and information detection system.
Master student: Information and Communication Engineering, and electronic information.The application of deep learning in medical image processing is limited to undergraduate and graduate students but not doctoral students.
教授课程:
(1) 本科生教学:《微处理器原理及应用》、《单片机原理及其应用》、《嵌入式系统原理与应用》、《电磁场理论》、《微处理器系统工程设计》、《印制电路板设计》、《C程序设计实践》,以及《学科导论》等课程。
(2) 研究生教学:《嵌入式系统》、《生物医学多物理场建模》
学生指导(部分展示):
(1) 吴婷婷获得福州大学2016届优秀本科生毕业论文,2016/06
(2) 苏航发表EI卓越期刊论文一篇,2021/12
(3) 邹建在首届福州大学“高意杯”研究生学术论坛中获硕士组二等奖,2021
(4) 邹建发表EI卓越期刊论文一篇,2022/01
(5) 刘信涌获得福州大学2022届优秀本科生毕业论文,2022/06
(6) 邹建发表SCI一区论文一篇,2022/08
(7) 邹建授权国家发明专利两项,2022/2022
(8) 丁宇彬发表了卓越期刊(电气工程领域顶刊)论文一篇,2022
(9) 苏航发表SCI二区论文一篇,2023/02
(10) 王跃升发表SCI论文一篇,2023/03
(11) 丁宇彬发表EI卓越期刊论文一篇,2023/03
(12) 陈泓霖授权国家发明专利一项,2023/05
(13) 陈泓霖发表EI卓越期刊论文一篇,2023/08
(14) 陈鸣发表EI卓越期刊论文一篇,2023/10
(15) 王跃升发表SCI二区论文一篇,2023/11
(16) 丁宇彬发表SCI二区论文一篇,2023/11
(17) 陈鸣在物信学院第二届研究生学术论坛中获硕士组三等奖,2023/12
(18) 陈鸣发表SCI期刊论文一篇,2024/03
(19) 刘术在顶级期刊上发表学术论文一篇,2024/06
(20) 王跃升硕士学位论文送审成绩全优,答辩成绩优秀,2024/06
(21) 丁宇彬、陈鸣,及陈泓霖,同时各授权国家发明专利一项,2024/06
(22) 王跃升和陈鸣,同时获得“福州大学2024届优秀毕业生”荣誉称号,2024/06
(23) 陈鸿霖获得“综合优秀学业奖学金”特等奖(最高等级),2024/06
(24) 王跃升获得“综合优秀学业奖学金”特等奖(最高等级),2024/06
(25) 丁宇彬获得“中期学业奖学金”一等奖(最高等级),2024/06
(26) 苏航硕士学位论文被评为“校级优秀学位论文”,2024/07
(27) 邹建硕士学位论文被评为“校级优秀学位论文”,并推荐为“福建省优秀硕士学位论文”,2024/07
(28) 截至2024/07,课题组已毕业研究生中,学位论文答辩成绩“优秀”者占比80%(遥遥领先专业优秀率)。
(29) 邹建和王跃升,同时各授权国家发明专利一项,2024/08
(30) 丁宇彬获得“研究生国家奖学金”,2024/10
(31) 朱佳佳发表SCI论文一篇,2024/10
(32) 周德培发表SCI一区论文一篇,2024/11
(33) 篇幅所限,2025/1后不再更新。
学术及社会兼职:
(1) 全国研究生教育评估监测专家库专家
(2) 国家自然科学基金通讯评审专家
(3) 教育部人才计划通信评审专家
(4) 中国知网(CNKI)评审专家库系统专家
(5) 福建省科协专家库专家
(6) IEEE Member
(7) 中国生物医学工程学会会员
(8) 中国仪器仪表学会会员
(9) 受邀为20多本国际知名SCI期刊审稿专家(Including but not limited to:Applied Mathematical Modelling,Computers and Mathematics with Applications,Computers in Biology and Medicine,Computer Methods and Programs in Biomedicine,Computer Methods in Biomechanics and Biomedical Engineering,HEAT AND MASS TRANSFER,IEEE Transactions on Electron Devices,IEEE Transactions on Magnetics,Materials Research Express,Materials Science and Engineering: C Materials for Biological Applications,Mathematical and Computer Modelling of Dynamical Systems,Mathematics and Computers in Simulation, Measurement, Measurement Science and Technology, Medical & Biological Engineering & Computing,Medical Engineering and Physics,Numerical Methods for Partial Differential Equations, IET Nanobiotechnology,International Journal for Numerical Methods in Biomedical Engineering,Internationla Journal of Thermal Sciences, Journal of Magnetism and Magnetic Materials,Journal of Mechanical Science and Technology,Journal of Physics communication,Journal of Thermal Biology,Scientific Reports,The European Physical Journal Plus,Thermal Science and Engineering Progress,......)
近年获奖成果:
(1) 2024年,福建省研究生优秀学位论文(推荐)指导教师
(2) 2024年,福州大学研究生优秀学位论文(两篇)指导教师
(3) 2023年,福建省省级高层次人才
(4) 2022年,福建省科学技术奖一等奖(核心成员)
(5) 2022年,福州大学优秀本科生毕业论文指导教师
(6) 2020年,福州大学厦航奖教金
(7) 2020年,福建省优秀博士学位论文奖
(8) 2019年,福州大学优秀博士学位论文奖
(9) 2019年,福州大学博士生综合优秀学业奖(特等奖)
(10) 2016年,福州大学优秀本科生毕业论文指导教师
代表性科研项目:
(1) 国家自然科学基金面上项目(62471144):磁纳米粒子迁移行为建模及其在磁热疗理论中的应用;(项目负责,2025-2028)
(2) 国家自然科学基金面上项目(62071124):靶向注射下磁流体输运模型构建及其在磁纳米热疗中的应用研究 ;( 项目负责,2021-2024)
(3) 福建省自然科学基金面上项目(2020J01464):磁流体浓度预测模型构建及其在磁热疗理论中的应用研究 ;( 项目负责,2020-2023)
(4) 福建省教育厅项目(JAT190013):基于智能优化算法的磁纳米热疗装置交变磁场均匀度分析及优化方法研究 ;( 项目负责,2019-2022)
(5) 福州大学校人才基金项目(GXRC-19044):人体环境温度在不规则形状肿瘤磁热疗中的影响研究 ;( 项目负责,2019-2021)
(6) 企业横向项目(0110-00101810): 福州输电线路在线监测诊断中心智能综合监控平台改造技术开发服务采购 ;( 测试负责,201801-201812)
(7) 福建省教育厅项目(JB06061):基于1553B通讯总线的数据处理系统的研究;( 项目负责,2006-2008)
(8) 福建省自然科学基金重点项目(DQ2007-62007J0003):基于MB-OFDM的UWB射频前端电路设计研究;( 项目参与,2007-2009)
(9) 信息产业厅公共服务平台(WL2007-23):福建省集成电路设计公共服务平台;( 项目参与,2007-2009)
Representative articles published in the international authoritative journals of interdisciplinary fields as the first author and corresponding author:
(1) Y. Tang*, etc. Effect of injection strategy for nanofluid transport on thermal damage behavior inside biological tissue during magnetic hyperthermia [J]. International Communications in Heat and Mass Transfer, 2022, 133: 105979., doi.org/10.1016/ j.icheatmasstransfer.2022.105979
(2) Y. Tang*, etc. Effect of nanoparticle shape on therapeutic temperature distribution during magnetic hyperthermia [J]. J. Phys. D: Appl. Phys., 2021, 54: 165401, DOI 10.1088/ 1361-6463/abdb0e (Highly cited paper)
(3) Y. Tang*, etc. Computational evaluation of malignant tissue apoptosis in magnetic hyperthermia considering intratumoral injection strategy [J]. International Journal of Heat and Mass Transfer, 2021, 178: 121609. ,doi.org/10.1016/j.ijheatmasstransfer.2021.121609
(4)Y. Tang*,etc. Effect of intratumoral nanofluid distribution on magnetic hyperthermia considering mass diffusion [J]. Chinese Journal of Scientific Instrument, 2021, 42(11), 146-156., DOI:10.19650/j.cnki.cjsi.J2108392
(5) Y. Tang*, etc. Effect of nanofluid distribution on therapeutic effect considering transient bio-tissue temperature during magnetic hyperthermia [J]. Journal of Magnetism and Magnetic Materials, 2021, 517: 167391., doi.org/10.1016/j.jmmm.2020.167391 (Highly cited paper)
(6) Y. Tang*, etc. Effect of bio-tissue deformation behavior due to intratumoral injection on magnetic hyperthermia[J]. Chinese Physics B, 2021, 32: 034304., DOI 10.1088/1674-1056/ac744c
(7) Y. Tang*, etc. Simultaneous Optimization of Injection Dose and Location for Magnetic Hyperthermia Using Metaheuristic Algorithms [J]. IEEE Transactions on Magnetics,2020, 56(1): 5200106., DOI: 10.1109/TMAG.2019.2949933
(8) Y. Tang*, etc. Improvement of solenoid magnetic field and its influence on therapeutic effect during magnetic hyperthermia [J]. Journal of Physics D: Applied Physics, 2020, 53: 305003., DOI 10.1088/1361-6463/ab87c5
(9) Y. Tang*, etc. Effect of mass transfer and diffusion of nanofluid on the thermal ablation of malignant cells during magnetic hyperthermia [J]. Applied Mathematical Modelling, 2020, 83: 122-135., doi.org/10.1016/j.apm.2020.02.010
(10) Y. Tang, etc. Numerical method to evaluate the survival rate of malignant cells considering the distribution of treatment temperature field for magnetic hyperthermia [J]. Journal of Magnetism and Magnetic Materials, 2019, 490: 165458. ,doi.org/10.1016/j.jmmm.2019.165458
(11) Y. Tang, etc. Impact of different infusion rates on mass diffusion and treatment temperature field during magnetic hyperthermia [J]. International Journal of Heat and Mass Transfer, 2018, 124: 639-645. ,DOI: 10.1016/j.ijheatmasstransfer.2018.03.096
(12) Y. Tang*, etc. Injection strategy for the optimization of therapeutic temperature profile considering irregular tumors in magnetic hyperthermia [J]. IEEE Transactions on Magnetics, 2018, 54(6): 5200206. ,DOI: 10.1109/TMAG.2018.2808206
(13) Y. Tang, etc. Numerical analysis of the effect of non-uniformity of the magnetic field produced by a solenoid on temperature distribution during magnetic hyperthermia [J]. Journal of Magnetism and Magnetic Materials, 2018, 449: 455-460. ,doi.org/10.1016/j.jmmm.2017.10.076
(14) Y. Tang, etc. Numerical investigation of temperature field in magnetic hyperthermia considering mass transfer and diffusion in interstitial tissue [J]. Journal of Physics D: Applied Physics, 2018, 51(3): 035401., DOI 10.1088/1361-6463/aa9b9a
(15) Y. Tang, etc. A method for increasing the homogeneity of the temperature distribution during magnetic fluid hyperthermia with a fe-cr-nb-b alloy in the presence of blood vessels [J]. Journal of Magnetism and Magnetic Materials, 2017, 432: 330-335. ,DOI: 10.1016/j.jmmm.2017.02.015
(16) Y. Tang, etc. Numerical analysis of temperature field improvement with nanoparticles designed to achieve critical power dissipation in magnetic hyperthermia [J]. Journal of Applied Physics, 2017, 122(3): 034702. ,DOI: 10.1063/1.4994309(Highly cited paper)
(17) Y. Tang, etc. Numerical temperature analysis of magnetic hyperthermia considering nanoparticle clustering and blood vessels [J]. IEEE Transactions on Magnetics, 2017, 53(10): 5400106. ,DOI: 10.1109/TMAG.2017.2722425(Highly cited paper)
(18) Y. Tang, etc. Thermal apoptosis analysis considering injection behavior optimization and mass diffusion during magnetic hyperthermia [J]. Chinese Physics B, 2022, 31: 014401.,DOI 10.1088/1674-1056/ac0819
(19) Y. Tang*, etc. An optimization method for magnetic hyperthermia considering Nelder-Mead algorithm [J]. Journal of Magnetism and Magnetic Materials, 2022,545: 168730, doi.org/10.1016/j.jmmm.2021.168730
(20) Y. Tang*,etc. Backflow modeling in nanofluid infusion and analysis of its effects on heat induced damage during magnetic hyperthermia [J]. Applied Mathematical Modelling, 2023, 114: 583-600., doi.org/10.1016/j.apm.2022.10.020
(21) Y. Tang*,etc. Optimization for magnetic field distribution in ferrite core and its effect on magnetic hyperthermia [J]. Journal of Central South University, 2022, 54(8): 583-600.,DOI: 10.11817/j.issn.1672-7207.2023.08.012
(22) Y. Tang*,etc. Adaptive PID control approach considering simulated annealing algorithm for thermal damage of brain tumor during magnetic hyperthermia [J]. IEEE Transactions on Instrumentation and Measurement, 2023, 72: 4002108., DOI: 10.1109/TIM.2023.3242011
(23) Y. Tang*,etc. Effect of porous heat transfer model on different equivalent thermal dose methods considering an experiment-based nanoparticle distribution during magnetic hyperthermia [J]. Journal of Physics D: Applied Physics, 56 (2023) 145402., DOI: 10.1088/1361-6463/acc07d
(24) Y. Tang*,etc.,Extraction method of nanoparticles concentration distribution from magnetic particle image and its application in the thermal damage of magnetic hyperthermia [J]. Chinese Physics B, 2023, 32: 094401., DOI: 10.1088/1674-1056/acde50
(25) Y. Tang*,etc. Research on optimization method of magnetic hyperthermia based on Helmholtz coil device [J]. TRANSACTIONS OF CHINA ELECTROTECHNICAL SOCIETY, 2023, 38(5), 1248-1260., DOI: 10.19595/j.cnki.1000-6753.tces.220866
(26) Y. Tang*,etc. Influence of different heat transfer models on therapeutic temperature prediction and heat-induced damage during magnetic hyperthermia [J]. Journal of Thermal Biology, 2023, 118: 103747.,https://doi.org/10.1016/j.jtherbio.2023.103747
(27) Y. Tang*,etc. Improvement for Magnetic Field Uniformity of Helmholtz Coils and Its Influence on Magnetic Hyperthermia [J]. IEEE Transactions on Instrumentation and Measurement, 2023,72: 4012008., https://doi.org/10.1109/TIM.2023.3325860
(28) Y. Tang*,etc. Evaluation and optimization for temperature distribution in magnetic hyperthermia considering particle dispersion [J]. J. Huazhong Univ. of Sci. & Tech. (Natural Science Edition), 2024,52(3):65-71., https://10.13245/j.hust.240472.
(29) Y. Tang*,etc. Research on the improved method of open detection device for magnetic particle imaging considering magnetic field uniformity optimization [J]. TRANSACTIONS OF CHINA ELECTROTECHNICAL SOCIETY, 2024, Accepted for publication.
(30) No further updates after 2024.6 due to space limitations
已授权的国家专利(包括但不限于):
(1) 汤云东,陈泓霖等.用于加热磁纳米粒子的高频时谐磁场产生电路. 专利号:ZL 202111324379.8, 福州大学
(2) 汤云东,邹建等.基于有限元方法的磁纳米颗粒浓度分布预测方法. 专利号:ZL 202110331274.9, 福州大学
(3) 汤云东,邹建等.基于注射策略的磁流体浓度分布预测方法.专利号:ZL 202110629343.4, 福州大学
(4) 汤云东,邹建等.基于不规则磁流体浓度分布的琼脂糖凝胶温度预测方法.专利号:ZL 202110590087.2,福州大学
(5) 汤云东,苏航等.基于 PID 控制的生物组织内磁纳米粒子产热优化方法.专利号:ZL 202110323757.4, 福州大学
(6) 汤云东,金涛.一种基于单孔隙率流体输运模型的间质内磁流体浓度分布预测方法.专利号:ZL 202010532488.8, 福州大学
(7) 汤云东,金涛.一种基于双孔隙率模型的生物模型组织内的磁流体浓度分布预测方法.专利号:ZL 202010527142.9, 福州大学
(8) 汤云东,金涛. 基于粒子群算法的磁纳米热疗交变磁场均匀度优化方法.专利号:ZL 202010516759.0, 福州大学
(9) 汤云东,金涛. 基于单纯形算法的磁纳米粒子临界产热值自动定位方法.专利号:ZL 202010534084.2,福州大学
(10) 汤云东,何明华等.公交位置监测报告系统.专利号:ZL 201120504634.2,福州大学
(11) 汤云东,何明华等.一种基于复杂可编程逻辑器件的仿真器.专利号:ZL 201120470462.1,福州大学
(12) 汤云东,何明华等.基于MCU的教学实验平台.专利号:ZL 201120504632.3,福州大学
(13) 汤云东,何明华等.基于Nios II系统的SOPC开发平台.专利号:ZL 201120522483.3,福州大学
(14) 汤云东,丁宇彬. 基于粒子群算法的磁纳米粒子体积分数优化方法.专利号:ZL 202210448936.5,福州大学
(15) 汤云东,陈鸣等. 基于组织形变的磁流体回流浓度分布预测方法.专利号:ZL 202210571592.7,福州大学
(16) 汤云东,陈泓霖等. 基于遗传算法的铁氧体磁场优化装置及方法.专利号:ZL 202210666164.2,福州大学
(17) 汤云东,邹建等. 基于组织形变的琼脂糖凝胶内磁流体空间分布预测方法.专利号:ZL 202111289728.7,福州大学
(18) 汤云东,王跃升等. 基于相位滞后传热行为的生物组织温度预测方法.专利号:ZL 202210825096.X,福州大学
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