EN
师资队伍
教授
王 磊     教授     

所在单位:飞行器结构强度系

研究方向:计算固体力学、飞行器结构动力学、结构可靠性、结构拓扑优化、飞行器结构动态载荷识别、复合材料结构设计、结构损坏识别与健康监测、振动主动控制。

邮箱:leiwang_beijing@buaa.edu.cn

详细介绍


,男,博士,1987年出生于北京,教授,博士生导师,玛丽居里学者,北京航空航天大学固体力学研究所党支部书记。于2009年7月在北京航空航天大学航空科学与工程学院工程力学专业获得学士学位;于2015年7月在北京航空航天大学获固体力学博士学位;2015年7月~2016年5月,在北京航空航天大学航空科学与工程学院人机与环境工程专业博士后;2016年5月~20197月,在北京航空航天大学固体力学研究所讲师;20197月~2024年6月,在北京航空航天大学固体力学研究所副教授;20247月~今,在北京航空航天大学固体力学研究所教授;2017年10月~2018年10月,在新加坡南洋理工大学土木与环境专业访问学者。


研究方向:

计算固体力学、飞行器结构动力学、结构可靠性、结构拓扑优化飞行器结构动态载荷识别复合材料结构设计、结构损坏识别与健康监测、振动主动控制。


立德树人:

本科生课程:《结构分析中的有限元法》、《弹性力学》、《材料力学/工程力学试验》、《航空工程大型通用软件应用》、《专业课程设计-固体力学》;

研究生课程:《飞机结构强度基础》、《先进飞行器设计工程》;

教改项目:2021年度教育部产学研合作协同育人项目:“自主化仿真算法及软件在结构有限元分析课堂教学中的应用探索”负责人,2021年度北京航空航天大学教改重点项目:“航空工程大型通用软件应用”课程线上线下混合教学模式探索与实践主研教师,2023年度北京航空航天大学教改重点项目:“新工科视角下弹性力学的教学探索与实践”主研教师,一般项目:面向航空航天工程应用的《结构分析中的有限元法》课程教学改革探索与实践”负责人。2023年北京航空航天大学新一代全数字化飞行器科教协同创新平台参建教师。

课程建设:北京市虚拟教研室团队核心成员(排名第三),2021年度北京航空航天大学校级一流本科课程《弹性力学》教学团队骨干教师,2021年度北京航空航天大学校级研究生精品课《计算固体力学》教学团队骨干教师,2023年度北京航空航天大学院级一流本科课程《结构分析中的有限元法》负责人,2023年度北京航空航天大学校级一流本科课程《航空工程大型通用软件应用》教学团队骨干教师,2023年度北京高等学校优秀本科教学实验室(北航材料力学实验室)骨干教师

培养人才:指导博士研究生(刘亚儒,2023)、硕士研究生(刘英歌,2024)连续两年荣获北航青年最高荣誉“五四奖章”;指导研究生(熊闯)获得2019年度北航硕士十佳研究生称号(总分排名第一),指导研究生(刘亚儒)获得2020年度北航硕士十佳研究生称号(航空学院唯一获奖者),指导研究生(刘亚儒、刘英歌)获得2023年度北航博士生十佳提名;博士研究生刘亚儒在2024年度北航毕业典礼上作为学生代表发言;近几年指导研究生10人次(熊闯2次、梁金雄2次、刘亚儒2次(总分排名第一)、刘嘉祥1次、赵兴宇1次、李泽商1次、赵源源1次)获得国家奖学金;10余人次获得北航校级三好学生、新生奖学金、学业奖学金、企业奖学金、研究生发表优秀论文奖励等;指导硕士研究生(熊闯、梁金雄)、博士研究生(刘亚儒)荣获北京市优秀毕业生称号,指导本科生(黄思怡、张昊宇)荣获北京航空航天大学航空学院优秀毕业论文称号;2022年评为院级优秀本科班主任

党建育人:2024年北京航空航天大学第三批“不忘初心、对标争先”教师样板党支部、“双带头人”教师党支部书记工作室负责人。


科研项目和学术成果:

主持国家自然科学基金2项(青年和面上各1项),中国博士后科学基金项目1项,*基础科研计划重大/重点项目子课题4项,*基础研究重大课题2项,*领域基金1项,军委科技委*基金1项,宁波市自然科学基金重点1项,航空科学基金1项,航天科学技术基金2项,高校合作基金项目1项,首都科技条件平台与科技创新券项目2项。主要参与国家自然科学基金4项,其中重点项目1项,面上项目2项,青年项目1项;*基础科研计划项目3项,其中重点项目2项,一般项目1项;航空、航天、船舶等型号单位横纵向课题20余项。

目前已出版专著4部,其中中文专著2部,英文专著节选2部;在国内外著名期刊如Computer Methods in Applied Mechanics and EngineeringMechanical Systems and Signal ProcessingInternational Journal of Mechanical SciencesStructural Control and Health Monitoring》,《Structural and Multidisciplinary Optimization》,《Journal of Sound and Vibration等发表和录用论文100篇,其中一作/通讯SCI论文收录99,SCI他引2400余次,18篇先后入选ESI高被引(包括6篇ESI热点论文),英文综述论文2篇,社论1篇,受权发明专利39项,获得软件著作权9。研究成果得到了同行的普遍认可,2020-2023连续四年入选全球前2%顶尖科学家年度影响力榜单,2021年荣获*技术发明三等奖1项,2022年荣获北京市科协首都前沿学术成果奖,2024年入选国家自然科学基金委员会数理科学部优秀青年科学基金项目上会答辩名单。


主要学术兼职:

学术组织兼职:

[1]中国振动工程学会动力学载荷与设计专业委员会委员(2023

[2]中国振动工程学会随机振动专业委员会委员(2023

[3]中国机械工程学会机械设计专业委员会青年委员(2023

[4]中国航空学会会员(2023

[5]International Institute of Acoustics and Vibration (IIAV) 会员(2022)

[6]中国运筹学会会员(2022

[7]中国汽车工程学会会员(2022

[8]中国运筹学会智能工业数据解析与优化专业委员会理事(2022

[9]International Society for Structural and Multidisciplinary Optimization (ISSMO) 会员(2019

[10]中国力学学会会员(2016)


学术期刊任职:

[1]SCI Q1ENGINEERING, AEROSPACE领域期刊《Aerospace》专刊客座主编(2023

[2]SCI Q1MECHANICSENGINEERING, MULTIDISCIPLINARY领域著名期刊《Structural and Multidisciplinary Optimization》编委(2022)

[3]SCI Q2区ENGINEERING, CIVIL领域期刊《StructuresAssociate Editor(2022)

[4]SCI Q2PHYSICS, MULTIDISCIPLINARY领域期刊《Frontiers in Physics》编委(2022)

[5]SCI Q2ENGINEERING, MULTIDISCIPLINARYPHYSICS, APPLIED领域期刊Applied Sciences-Basel编委(2022)

[6]SCI MATHEMATICS, INTERDISCIPLINARY APPLICATIONSENGINEERING, MULTIDISCIPLINARY领域期刊《Mathematical Problems in Engineering》编委(2022)

[7]SCI MECHANICSACOUSTICS领域期刊《International Journal of Acoustics and Vibration》Associate Editor(2022)

[8]SCI Q2ENGINEERING, MULTIDISCIPLINARYPHYSICS, APPLIED领域期刊Applied Sciences-Basel专刊客座主编(2021

[9]SCI Q2MECHANICSENGINEERING, MECHANICAL领域期刊《Journal of Vibration Engineering & Technologies》Associate Editor(2021)

[10]ESCI ENGINEERING, MULTIDISCIPLINARY领域期刊《Engineering Reports》青年编委(2022

[11]EI 工程领域期刊《中南大学学报(自然科学版)》青年编委(2022

[12]国内航空领域著名期刊《航空科学技术》青年编委(2023

[13]国内机械工程领域著名期刊《机械设计》青年编委(2023

[14]国际环境工程领域期刊《Frontiers in Environmental Engineering》、应用数学领域期刊《Frontiers in Applied Mathematics and Statistics编委(2022)

[15]国际机械工程领域期刊《Journal of Modern Industry and Manufacturing》编委(2021)


机构评审专家:

[1]国家自然科学基金委员会项目涵评专家(2022

[2]科工局*基础科研计划项目先进设计技术组评审专家(2022

[3]浙江省科技专家库专家(2022

[4]教育部学位办博士研究生学位论文评审专家(2021

[5]江苏省教育评估中心学位论文评审专家(2021

[6]广东省基础与应用基础研究基金委员会高层次人才项目评审专家(2021


主要荣誉称号:

[1]欧盟地平线2020计划玛丽居里学者称号(2021)

[2]第四批北京航空航天大学青年拔尖人才称号(2017)

[3]首批北京航空航天大学卓百博士后称号(2015)


会议组织&大会报告等情况(2023以来):

[1]2024年全国固体力学学术会议MS07、MS19分会场邀请报告

[2]2024年航天五院501所“飞行器结构强度设计的不确定性技术”邀请报告

[3]The 6th International Conference on Modeling in Mechanics and Materials(CMMM2024)分会场负责人

[4]首届航空航天结构动力学国际研讨会(ICASD 2023)分会场主席

[5]中国计算力学大会2023(CCCM2023)分会场主持人

[6]第一届全国动力学载荷与设计学术会议学术委员会委员


代表性工作:

专著:

[1]王晓军, 王磊, 李云龙, 邱志平. 飞行器复合材料结构非概率可靠性优化设计. 北京: 科学出版社, 2020年10月.

[2]王晓军, 王磊, 邱志平. 结构可靠性分析与优化设计的非概率集合理论. 北京: 科学出版社, 2016年3月. (ISBN 978-7-03-047167-3)


综述论文

[1]Wang L, Liu Y R, Xu H Y. Review: Recent Developments in the Dynamic Load Identification for Aerospace Vehicles Considering Multi-source Uncertainties. Transactions of Nanjing University of Aeronautics & Astronautics, 2021, 38(2): 271-287.


20篇代表性一作+20篇代表性通讯SCI论文(2020-今)

[1]Wang L, Zhang H Y, Wang Y, Wu D. A Data-Driven Force-Thermal Coupling Load Identification Method Considering Multi-Source Uncertainties of Structural Characteristics and Measuring Noises. Computer Methods in Applied Mechanics and Engineering, 2024, 425: 116937.

[2]Wang L, Cheng L L, Xu H Y, Hu J X, Chen W M, Han B. Multi-source Uncertainty-oriented Dynamic Force Reconstruction Framework Based on Adaptive Fitting Precise Integration and Optimized Wavelet Denoising. Structural and Multidisciplinary Optimization, 2024, 67(3): 28.

[3]Wang L, Zhao Y Y, Liu J X. A Kriging-based Decoupled Non-probability Reliability-based Design Optimization Scheme for Piezoelectric PID Control Systems. Mechanical Systems and Signal Processing, 2023, 203: 110714.

[4]Wang L, Liu Y G, Li Z S, Hu J X, Han B. Non-probabilistic Reliability-based Topology Optimization (NRBTO) Scheme for Continuum Structures Based on the Strength Constraint Parameterized Level Set Method and Interval Mathematics. Thin-Walled Structures, 2023, 188: 110856.

[5]Wang L, Zhou Z, Liu J X. Double-time-scale Non-probabilistic Reliability-based Controller Optimization for Manipulator Considering Motion Error and Wear Growth. ISA Transactions, 2023, 142: 270-288.

[6]Wang L, Zhao Y Y, Liu J X, Zhou Z. Uncertainty-oriented Optimal PID Control Design Framework for Piezoelectric Structures Based on Subinterval Dimension-wise Method (SDWM) and Non-probabilistic Time-dependent Reliability (NTDR) Analysis. Journal of Sound and Vibration, 2023, 549: 117588.

[7]Wang L, Liu J X, Zhou Z, Li Y L. A Two-stage Dimension-reduced Dynamic Reliability Evaluation (TD-DRE) Method for Vibration Control Structures Based on Interval Collocation and Narrow Bounds Theories. ISA Transactions, 2023, 136: 622-639. (ESI热点)

[8]Wang L, Zhou Z, Liu J X. Interval-based Optimal Trajectory Tracking Control Method for Manipulators with Clearance Considering Time-dependent Reliability Constraints. Aerospace Science and Technology, 2022, 128: 107745.

[9]Wang L, Zhao X Y, Liu D L. Size-Controlled Cross-Scale Robust Topology Optimization Based on Adaptive Subinterval Dimension-Wise Method Considering Interval Uncertainties. Engineering with Computers, 2022, 38, 5321-5338.

[10]Wang L, Liu Y R, Wang X J, Qiu Z P. Convexity-oriented Reliability-based Topology Optimization (CRBTO) in the Time Domain Using the Equivalent Static Loads Method. Aerospace Science and Technology, 2022, 123: 107490.

[11]Wang L, Liu Y R, Li M. Time-dependent Reliability-based Optimization for Structural-topological Configuration Design under Convex-bounded Uncertain Modeling. Reliability Engineering and System Safety, 2022, 221: 108361. (ESI热点)

[12]Wang L, Zhao X Y, Wu Z M, Chen W P. Evidence Theory-based Reliability Optimization for Cross-scale Topological Structures with Global Stress, Local Displacement and Micro Manufacturing Constraints. Structural and Multidisciplinary Optimization, 2022, 65(1): 23. (ESI高被引)

[13]Wang L, Xu H Y, Wang X J, Ding X Y. Multi-source Uncertain Dynamic Load Identification Fitted by Legendre Polynomial Based on Precise Integration and the Savitzky-Golay (S-G) Filters. International Journal for Numerical Methods in Engineering, 2022, 123(20): 4974-5006.

[14]Wang L, Liu Y R, Liu D L, Wu Z M. A Novel Dynamic Reliability-based Topology Optimization (DRBTO) Framework for Continuum Structures via Interval-process Collocation and the First-passage Theories. Computer Methods in Applied Mechanics and Engineering, 2021, 386: 114107.

[15]Wang L, Li Z S, Ni B W, Gu K X. Non-probabilistic Reliability-based Topology Optimization (NRBTO) Scheme for Continuum Structures Based on the Parameterized Level-Set method and Interval Mathematics. Computer Methods in Applied Mechanics and Engineering, 2021, 373: 113477.

[16]Wang L, Liu J X, Yang C, Wu D. A Novel Interval Dynamic Reliability Computation Approach for the Risk Evaluation of Vibration Active Control Systems based on PID Controllers. Applied Mathematical Modelling, 2021, 92: 422-446. (ESI热点)

[17]Wang L, Ni B W, Wang X J, Li Z S. Reliability-based Topology Optimization for Heterogeneous Composite Structures under Interval and Convex Mixed Uncertainties. Applied Mathematical Modelling, 2021, 99: 628-652.

[18]Wang L, Zhao X Y, Liu D L, Chen X. Uncertainty-oriented Double-scale Topology Optimization with Macroreliability Limitation and Microfanufacturing Control. International Journal for Numerical Methods in Engineering, 2021, 122(9): 2254-2286.

[19]Wang L, Liu Y R, Gu K X, Wu T. A Radial Basis Function Artificial Neural Network (RBF ANN) Based Method for Uncertain Distributed Force Reconstruction Considering Signal Noises and Material Dispersion. Computer Methods in Applied Mechanics and Engineering, 2020, 364: 112954.

[20]Wang L, Liu Y R. A Novel Method of Distributed Dynamic Load Identification for Aircraft Structure Considering Multi-source Uncertainties. Structural and Multidisciplinary Optimization, 2020, 61: 1929-1952. (ESI高被引)

[21]Li Z S, Wang L#, Gu K X. Efficient Reliability-based Concurrent Topology Optimization Method under PID-driven Sequential Decoupling Framework. Thin-Walled Structures, 2024, 203: 112117.

[22]Liu J X, Wang L#, Wu Z M. Novel Study on Active Reliable PID Controller Design Based on Probability Density Evolution Method and Interval-oriented Sequential Optimization Strategy. Computer Methods in Applied Mechanics and Engineering, 2024, 427: 117057.

[23]Liu Y R, Wang L#, Bing Feng Ng. A Hybrid Model-Data-Driven Framework for Inverse Load Identification of Interval Structures Based on Physics-Informed Neural Network and Improved Kalman Filter Algorithm. Applied Energy, 2024, 359: 122740.

[24]Zhao W, Wang L#. A Novel Interval Dynamic Topology Optimization Methodology of Piezoelectric Structures under Reliable Active Control. Computer Methods in Applied Mechanics and Engineering, 2024, 421: 116766.

[25]Li Z S, Wang L#, Geng X Y, Chen W M, Han B. Complex Uncertainty-Oriented Robust Topology Optimization for Multiple Mechanical Metamaterials Based on Double-layer Mesh. Computer Methods in Applied Mechanics and Engineering, 2024, 419: 116589.

[26]Li Z S, Wang L#, Geng X Y. A Level Set Reliability-based Topology Optimization (LS-RBTO) Method Considering Sensitivity Mapping and Multi-Source Interval Uncertainties. Computer Methods in Applied Mechanics and Engineering, 2024, 419: 116587.

[27]Li Z S, Wang L#, Geng X Y. A double-layer mesh-driven robust topology optimization strategy for mechanical metamaterials under size uncertainty. Thin-Walled Structures, 2024, 196: 111439.

[28]Liu Y R, Wang L#, Bing Feng Ng. Load-Independent Multi-Objective Sensor Placement Method for Localization and Reconstruction of External Excitations under Interval Uncertainties. Computer Methods in Applied Mechanics and Engineering, 2023, 416: 116344.

[29]Liu Y R, Wang L#. A Robust-based Configuration Design method of Piezoelectric Materials for Mechanical Load Identification Considering Structural Vibration Suppression. Computer Methods in Applied Mechanics and Engineering, 2023, 410: 115998.

[30]Li Z S, Wang L#, Lv T Q. A Level Set Driven Concurrent Reliability-Based Topology Optimization (LS-CRBTO) Strategy Considering Hybrid Uncertainty Inputs and Damage Defects Updating. Computer Methods in Applied Mechanics and Engineering, 2023, 405: 115872. (ESI热点)

[31]Liu Y R, Wang L#. A Two-step Weighting Regularization Method for Stochastic Excitation Identification under Multi-source Uncertainties Based on Response Superposition-Decomposition Principle. Mechanical Systems and Signal Processing, 2023, 182: 109565. (ESI高被引)

[32]Li Z S, Wang L#, Lv T Q. Additive Manufacturing-Oriented Concurrent Robust Topology Optimization Considering Size Control. International Journal of Mechanical Sciences, 2023, 250: 108269. (ESI高被引)

[33]Liu Y R, Wang L#. Multiobjective-clustering-based Optimal Heterogeneous Sensor Placement Method for Thermo-mechanical Load Identification. International Journal of Mechanical Sciences, 2023, 253: 108369.

[34]Liu Y R, Wang L#. Quantification, Localization, and Reconstruction of Impact Force on Interval Composite Structures. International Journal of Mechanical Sciences, 2023, 239: 107873. (ESI高被引)

[35]Liu J X, Wang L#. Hybrid Reliability-Based Sequential Optimization for PID Vibratory Controller Design Considering Interval and Fuzzy Mixed Uncertainties. Applied Mathematical Modelling, 2023, 122: 796-823.

[36]Liu J X, Wang L#. Two-stage Vibration-suppression Framework for Optimal Robust Placements Design and Reliable PID Gains design via Set-crossing Theory and Artificial Neural Network. Reliability Engineering and System Safety, 2023, 230: 108956. (ESI高被引)

[37]Li Z S, Wang L#, Luo Z X. A Feature-Driven Robust Topology Optimization Strategy Considering Movable Non-Design Domain and Complex Uncertainty. Computer Methods in Applied Mechanics and Engineering, 2022, 401: 115658. (ESI高被引)

[38]Liu Y R, Wang L#, Li M, Wu Z M. A Distributed Dynamic Load Identification Method Based on the Hierarchical-Clustering-Oriented Radial Basis Function Framework Using Acceleration Signals under Convex-Fuzzy Hybrid Uncertainties. Mechanical Systems and Signal Processing, 2022, 172: 108935. (ESI高被引)

[39]Liu Y R, Wang L#, Gu K X, Li Min. Artificial Neural Network (ANN) - Bayesian Probability Framework (BPF) Based Method of Dynamic Force Reconstruction under Multi-source Uncertainties. Knowledge-Based Systems, 2022, 237: 107796. (ESI热点)

[40]Liu Y R, Wang L#, Qiu Z P, Chen X. A Dynamic Force Reconstruction Method based on Modified Kalman Filter Using Acceleration Responses under Multi-source Uncertain Samples. Mechanical Systems and Signal Processing, 2021, 159: 107761.


联系方式:

Tel: 13466660129(微信同号)

Email: leiwang_beijing@buaa.edu.cn; ntucee.wanglei@gmail.com

办公地址:北京航空航天大学(沙河校区)2号航空大楼505

通信地址:北京市昌平区高教园南三街9号 北京航空航天大学固体力学研究所

邮编:102206