李雄兵 - 中南大学 - 交通运输工程学院

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李雄兵博士教授收藏完善纠错
中南大学交通运输工程学院
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个人简介

【教育背景】 1996年－2000年，中南大学机电工程学院，学士； 2000年－2003年，中南大学交通运输工程学院，硕士； 2004年－2008年，浙江大学机械与能源工程学院，博士【工作经历】 2003年－2004年，深圳现代计算机有限公司，软件工程师； 2008年－2011年，中南大学，讲师； 2011年－2016年中南大学，副教授； 2012年－2013年，美国爱荷华州立大学，访问学者； 2016年－至今，中南大学，教授。【科研项目】 [1] 高温钛合金轮盘的微小缺陷超声检测，国家自然科学基金，主持，在研，项目编号：92060111 [2] 3D打印钛合金构件孔隙率的超声多次散射无损评价方法，国家自然科学基金，主持，已结题，项目编号：51575541 [3] 基于超声相控阵的3D打印件孔隙率无损评价方法，国家自然科学基金国际合作交流项目，主持，已结题，项目编号：51711530231 [4] 基于相速度的粉末合金构件晶粒度超声评价方法，国家自然科学基金，主持，已结题，项目编号：61271356 [5] 基于2D-SAFT的复杂型面构件超声检测方法研究，国家自然科学基金，主持，已结题，项目编号：51005252 [6] ****复杂型面镁合金构件无损检测与缺陷评价技术，国防基础科研计划项目，主持，已结题 [7] 增材制造钛合金材料中孔隙超声无损评价，国家高端外国专家项目，主持，在研，项目编号：GDW20184300289 [8] 复杂环境下轨道车辆全生命周期能力保持与优化，国家重点研发计划，参研，在研，项目编号：2017YFB1201201 [9] 镍基粉末合金晶粒尺寸的超声无损评价，湖南省自然科学基金，主持，在研，项目编号：2018JJ2512 [10] 航空高温合金密实度的超声无损评价基础研究，湖南省自然科学基金，主持，已结题，项目编号：14JJ2002 [11] 复杂型面构件的超声自动评估方法研究，湖南省自然科学基金，主持，已结题，项目编号：10JJ5061 [12] 寄生式超声自动检测系统的设计与实现，湖南省科技计划，主持，已结题，项目编号：2011GK3209 [13] 基于缺陷信号聚焦重构的机车车轴超声检测方法研究，教育部博士点基金，主持，已结题，项目编号：20100162120042 [14] 粉末高温合金致密度的超声无损评价方法，中国博士后科学基金，主持，已结题，项目编号：2014M562126 【审稿期刊】 NDT & E international；Ultrasonics；Journal of the Acoustical Society of America；IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control；Measurement；Applied Acoustics；Nondestructive Testing and Evaluation；Sensors & Actuators: A. Physical. 【授权/申请国家发明专利】 1. 授权国家发明专利： 1.1 一种基于二维邻域合成孔径聚焦的超声C扫描成像方法，中国发明专利，授权专利号：ZL201110458080.1，授权日期：2013-6-26 1.2 一种基于超声相速度的高温合金晶粒度评价方法，中国发明专利，授权专利号：ZL201310697572.5，授权日期：2015-9-30 1.3 一种基于哈尔小波的晶粒尺寸无损评价方法，中国发明专利，授权专利号：ZL201410373084.3，授权日期：2016-08-17 1.4 一种无需测厚的晶粒尺寸超声无损评价方法，中国发明专利，授权专利号：ZL201410478957.7，授权日期：2017-5-10 1.5 一种剔除水声距影响的晶粒尺寸超声评价方法，中国发明专利，授权专利号：ZL201510165438.X，授权日期：2017-9-5 1.6 一种基于起旋辅助线的型腔高速螺旋铣削方法，中国发明专利，授权专利号：ZL 201610817053.1，授权日期：2018-5-4 1.7一种考虑工件偏心装夹误差的超声C扫描路径校正方法，中国发明专利，申请专利号：ZL201610631155.4，申请日期：2018-8-24 1.8一种剔除曲面扩散影响的金属晶粒尺寸超声衰减评价方法，中国发明专利，授权专利号：ZL201510680907.1，授权日期：2019-3-19 1.9一种基于极值分布理论的微小缺陷超声检测方法，中国发明专利，授权专利号：ZL201710306311.4，授权日期：2019-9-6 1.10 校验超声压电探头的方法和装置，中国发明专利，授权专利号：ZL201811068765.3, 授权日期：2020-04-28 1.11一种考虑工件装夹误差校正的超声波自动检测方法.，中国发明专利，授权专利号：ZL201710358742.5, 授权日期：2019-12-19 1.12 一种基于横波背散射的六方晶材料近表面微小缺陷检测方法，中国发明专利，授权专利号：ZL201810747244.4, 授权日期：2020-9-29 2. 申请国家发明专利： 2.2 一种超声检测中机械手防碰撞方法, 中国发明专利, 申请专利号: CN201711176411.6, 申请日期：2017-11-22 2.3一种测量材料中纵波衰减系数与频率关系的水浸超声方法. 申请号：CN201911077021.2，申请日期：2019-11-6 2.4一种测量空气耦合超声探头灵敏度的装置及方法. 申请号：CN201911253211.5，申请日期：2019-12-9 计算机软件著作权 [1] 软件著作权. 复杂型面构件缺陷的超声检测及分析系统[简称:MyUltraScan]V1.0，证书号: 软著登字第0347361号，登记号：2011SR083687. [2] 软件著作权. 六轴超声自动检测与成像系统[简称:UltraInspect]V1.0，证书号: 软著登字第0426608号, 登记号: 2012SR058572. [3] 软件著作权. 复杂型面构件超声自动检测与成像软件系统V1.0，证书号：软著登字第1780516号，登记号：2017SR195232. 学术奖励 “复杂型面构件超声无损检测技术与应用”，2015年湖南省科技进步奖二等奖（完成人排名第一）； “复杂结构内部缺陷的声学检测技术及应用”，2018年湖南省科技进步奖二等奖（完成人排名第四）【教学奖励】中南大学高等教育校级教学成果奖；比亚迪奖学金优秀教师奖励；湖南省普通高校青年骨干教师、学科带头人培养对象验收结果“优秀”

研究领域

数控加工的刀具轨迹规划方法材料微结构的超声无损评价方法内部缺陷的超声无损检测方法

近期论文

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【SCI期刊论文】 [65] Shuzeng Zhang, Yuantian Huang, Xiongbing Li, Hyunjo Jeong. Modelling of wave fields generated by ultrasonic transducers using a quasi-Monte Carlo method[J]. Journal of the Acoustical Society of America, 2020, 149(1):7-15. [64] Yuantian Huang, Joseph A. Turner, Yongfeng Song, Xiongbing Li*. Transverse-to-transverse diffuse ultrasonic double scattering[J]. Ultrasonics ,2020 ,106301 [63] Yangguang Bu, Xiling Liu, Joseph A. Turner, Yongfeng Song, Xiongbing Li*. Grain size evaluation with time-frequency ultrasonic backscatter[J]. NDT & E International, 2020,117,102369. [62] Xiongbing Li,Yingdong Fu, Feng Zhang,Yanni Rao*. Detecting small flaws in two-phase Ti-6Al-4V with rough surfaces[J]. Ultrasonics, 2020, 106:106128. [61]Yongfeng Song, Christopher M. Kube, Jie Zhang, Xiongbing Li*Higher-order spatial correlation coefficients of ultrasonic backscattering signals using partial cross-correlation analysis[J]. Journal of the Acoustical Society of America, 2020, 147:757-768. [60]Shuzeng Zhang, Liang Qin, Xiongbing Li*, Christopher M. Kube*.Propagation of Rayleigh waves on curved surfaces[J]. Wave Motion,2020,94,102517. [59]Jie Zhang, Yongfeng Song, Xiongbing Li, ChengHuan Zhong. Comparison of Experimental Measurements of Material Grain Size Using Ultrasound[J]. Journal of Nondestructive Evaluation, 2020, 39(2):30. [58] Hyunjo Jeong, Sungjong Cho, Hyojeong Shin, Shuzeng Zhang, Xiongbing Li. Optimization and validation of dual element ultrasound transducers for improved pulse-echo measurements of material nonlinearity[J]. IEEE Sensors, 2020, available online. DOI 10.1109/JSEN.2020.3006376 [57]Xiongbing Li, Nan Sun, Yongfeng Song, Shuzeng Zhang*. Sizing small crack-like flaws through non-ideal part surface using ultrasonic measurement model[J]. Research in Nondestructive Evaluation, 2019, 31(3):147-163. [56]Shuzeng Zhang, Xiongbing Li*, Chao Chen, HyunjoJeong, Gang Xu. Characterization of aging treated 6061 aluminum alloy using nonlinear Rayleigh wave[J]. Journal of Nondestructive Evaluation,2019, 38(4):88. [55]Xiongbing Li, Duo Lyu, Yongfeng Song, Shuzeng Zhang*, Ping Hu, and Hyunjo Jeong. Simultaneously Determining Sensitivity and Effective Geometrical Parameters of Ultrasonic Piezoelectric Transducers using a Self-reciprocity Method[J].IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control,2019,66(10):1649-1657. [54] Yuantian Huang, Joseph A.Turner, Yongfeng Song, Peijun Ni, Xiongbing Li*. Enhanced ultrasonic detection of near-surface flaws using transverse-wave backscatter[J]. Ultrasonics, 2019,98:20-27. [53] Shan Li, Joseph A.Turner, Lester W.Schmerr, Xiongbing Li* Non-paraxial multi-Gaussian beam model of Leaky Rayleigh waves generated by a focused immersion transducer[J]. Ultrasonics, 2019,97:57-62. [52] Yu Liu, Xiongbing Li*,Chao Chen*,Yongfeng Song，Peijun Ni. High Throughput Rapid Detection for SLM Manufactured Elements Using Ultrasonic Measurement[J]. Measurement, 2019,144:234-242. [51] Yingdong Fu, Ping Hu, Joseph Turner, Yongfeng Song, Xiongbing Li*. Ultrasonic flaw detection for two-phase Ti-6Al-4V based on secondary scattering[J]. NDT & E International, 2019, 102: 199-206. [50] Weixin Wang, Xiling Liu, Xiongbing Li, Gang Xu, Shuzeng Zhang*.Modeling Flaw Pulse-Echo Signals in Cylindrical Components Using an Ultrasonic Line-Focused Transducer with Consideration of Wave Mode Conversion[J]. Sensors, 2019,19:12-2744. [49] Guangdong Zhang, Xiling Liu, Xiongbing Li, Yongfeng Song, Shuzeng Zhang.Measurement of shear wave attenuation coefficient using a contact pulse-echo method with consideration of partial reflection effects[J]. Measurement Science and Technology, 2019, 30(11):115601. [48] Yongfeng Song, Christopher M. Kube, Zuoxiang Peng, Joseph A. Turner, Xiongbing Li*. Flaw detection with ultrasonic backscatter signal envelopes[J]. Journal of the Acoustical Society of America, 2019, 145(2): 142-148. [47]Shufeng Zhang, Chao Ma, Haifeng Hu, Yu Jiang, Xun Chen*, Xiongbing Li. Far-sided defect recognition of FRP sandwich structures based on local defect resonance[J]. Journal of Sandwich Structures & Materials, 2019,available online.DOI：https://doi.org/10.1177/1099636219840250 [46]Hyunjo Jeong, Hyojeong Shin, Shuzeng Zhang, Xiongbing Li, Sungjong Cho. Application of Fresnel Zone Plate Focused Beam to Optimized Sensor Design for Pulse-Echo Harmonic Generation Measurements[J]. Sensors, 2019, 19(6): 1373. [45] Zhiping Liu, Xiongbing Li, Bing Yi. Generating spiral tool path to machine free-form surface with complex topology based on fusing constraint mapping and enriched voronoi diagram[J]. International Journal of Advanced Manufacturing Technology, 2019,102(1-4) : 647-658. [44] Xiongbing Li, Zhiping Liu, Fulin Wang, Bing Yi*, Yongfeng Song. Combining physical shell mapping and reverse-compensation optimization for spiral machining of free-form surfaces. International Journal of Production Research. 2018,57(13):4118-4131. [43] Xiongbing Li, Xuanrun Wang, Peijun Ni, Feng Chen*, Yongfeng Song(2018). Automatic Ultrasonic Testing Method for AZ80 Magnesium Alloy Cartridge[J]. Materials Evaluation, 2018,10: 1414-1420. [42] Shuzeng Zhang, Xiongbing Li*, Hyunjo Jeong, Hongwei Hu. Experimental investigation of material nonlinearity using the Rayleigh surface waves excited and detected by angle beam wedge transducers[J]. Ultrasonics, 2018, 89: 118-125. [41] Shuzeng Zhang, Xiongbing Li*, Hyunjo Jeong, Sungjong Cho. Investigation of material nonlinearity measurements using the harmonic generation[J]. IEEE Transactions on Instrumentation & Measurement, 2019,68(10):3635-3646. [40] Yongfeng Song, Joseph Turner, Zuoxiang Peng, Chao Chen, Xiongbing Li*(2018). Enhanced Ultrasonic Flaw Detection using an Ultra-high Gain and Time-dependent Threshold[J]. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 2018, 65(7): 1214-1225. [39] Yongfeng Song, Xuhui Zi, Yingdong Fu, Xiongbing Li*, Chao Chen*, Kechao Zhou(2018). Nondestructive testing of additively manufactured material based on ultrasonic scattering measurement[J]. Measurement, 2018, 118: 105–112. [38] Xiongbing Li*, Shuzeng Zhang, Hyunjo Jeong, Hongwei Hu. Modelling nonlinear focused beams of a linear phased array using Multi-Gaussian beam model[J]. International Journal of Acoustics and Vibration, 2018, 23(4): 529-533. [37].Xiujuan Miao, Xiongbing Li*, Hongwei Hu, Guangjun Gao, Shuzeng Zhang(2018). Effects of the Oxide Coating Thickness on the Small Flaw Sizing Using an Ultrasonic Test Technique[J]. Coatings, 2018,8(2): 69. [36]. Shuzeng Zhang, Ping Hu, Xiongbing Li*, Hyunjo Jeong(2018). Calibration of focused circular transducers using a multi-Gaussian beam model[J]. Applied Acoustics, 2018, 133: 182-185. [35].Hyunjo Jeong*, Sungjong Cho, Shuzeng Zhang, Xiongbing Li(2018). Acoustic nonlinearity parameter measurements in a pulse-echo setup with the stress-free reflection boundary. Journal of the Acoustical Society of America, 2018, 143 (4): 237-242. [34]. Hyunjo Jeong*, Shuzeng Zhang, Xiongbing Li(2018). Improvement of pulse-echo harmonic generation from a traction-free boundary through phase shift of a dual element transducer[J]. Ultrasonics, 2018, 87: 145-151. [33] Shan Li, Xiongbing Li, Yongfeng Song, Chao Chen. Ultrasonic scattering unified theory for polycrystal material with grain sizes distribution[J]. Acta Physica Sinica, 2018, 67(23): 234301. [32] Bing Yi, Yue Yang, Ran Zheng, Xiongbing Li, Minhan Yi*. Triangulated surface flattening based on the physical shell model[J]. Journal of Mechanical Science and Technology, 2018, 32(5): 2163-2171. [31] 王炫润, 倪培君, 易兵, 李雄兵. 回转组合体超声自动检测中防碰撞研究[J].兵工学报, 2018, 39(04): 780-786. [30] Xiongbing Li, Yongfeng Song, Andrea P. Arguelles, Joseph A Turner*(2017). Diffuse ultrasonic backscatter using a multi-Gaussian beam model. Journal of The Acoustical Society of America. 2017, 141(6): 195-205. [29] Xiongbing Li, Shuzeng Zhang, Hyunjo Jeong*, Sungjong Cho(2017). Calibration of focused ultrasonic transducers and absolute measurements of fluid nonlinearity with diffraction and attenuation corrections[J]. Journal of the Acoustical Society of America, 2017, 142(2): 984-990. [28] Xiongbing Li, Xiaoqin Han, Andrea P. Arguelles, Yongfeng Song, Hongwei Hu*(2017). Evaluating grain size in polycrystals with rough surfaces by corrected ultrasonic attenuation[J]. Ultrasonics, 2017, 78: 23-29. [27] Xiongbing Li, Yilin Wang, Peijun Ni, Hongwei Hu, Songyong Feng(2017). Flaw sizing using Ultrasonic C-scan imaging with Dynamic Thresholds. INSIGHT, 2017, 59(11): 603-608. [26]. Yu Liu, Yongfeng Song, Xiongbing Li*, Chao Chen*, Kechao Zhou(2017). Evaluating the Reinforcement Content and Elastic Properties of Mg-based Composites Using Dual-Mode Ultrasonic Velocities[J]. Ultrasonics, 2017, 81:167-173. [25]. Yongfeng Song, Christopher M. Kube, Joseph A. Turner, Xiongbing Li*(2017). Statistics associated with the scattering of ultrasound from microstructure, Ultrasonics, 2017. 80: 58-61. [24].Shuzeng Zhang, Xiongbing Li*, Hyunjo Jeong, Sungjong Cho, Hoingwei Hu(2017). Theoretical and experimental investigation of the pulse-echo nonlinearity acoustic sound fields of focused transducers[J]. Applied Acoustics, 2017, 117: 145-149. [23]. Shuzeng Zhang, Xiongbing Li*, Hyunjo Jeong(2017). Analytical diffraction corrections for circular focused transducers expressed using the multi-Gaussian beam model[J]. Acta Acustica united with Acustica, 2017, 103(5):717-720. [22]. Zhiping Liu, Xiongbing Li*, Yongfeng Song, Bing Yi(2017). Generating spiral tool paths based on spiral enter assistant line[J]. The International Journal of Advanced Manufacturing Technology, 2017, 92(1): 869-879. [21].ShuZeng Zhang, XiongBing Li*, Hyunjo Jeong, Hongwei Hu(2017). Modeling linear Rayleigh wave sound fields generated by angle beam wedge transducers[J]. AIP Advances, 2017, 7(1): 015005. [20].Shuzeng Zhang, Xiongbing Li* ,Hyunjo Jeong(2017) .Measurement of Rayleigh Wave Beams Using Angle Beam Wedge Transducers as the Transmitter and Receiver with Consideration of Beam Spreading[J]. Sensors, 2017, 17(6):1449. [19]. Hyunjo Jeong*, Dan Barnard, Sungjong Cho, Shuzeng Zhang, Xiongbing Li(2017). Receiver calibration and the nonlinearity parameter measurement of thick solid samples with diffraction and attenuation corrections[J]. Ultrasonics, 2017, 81: 147-157. [18].Bing Yi, Xiongbing Li, Yue Yang. Heterogeneous model integration of complex mechanical parts based on semantic feature fusion[J]. Engineering with Computers, 2017, 33(4): 797-805. [17]. Chenxin Zhang, Xiongbing Li*, Yongfeng Song, Xiaoqin Han(2016). Evaluating the grain size in curved components using the ultrasonic attenuation method with diffraction correction[J]. NDT&E international.2016, 84: 20-26. [16]. Xiaoqin Han, Xiongbing Li*, Yongfeng Song, Peijun Ni，Yiwei Shi(2016). Correcting the Ultrasonic Scattering Attenuation coefficient of a Metal Using an Equivalent Medium Layer[J]. Materials Transactions. 2016, 57(10):1729-1734. [15]. Shuzeng Zhang, Xiongbing Li*, Hyunjo Jeong, Hongwei Hu(2016). Modeling nonlinear Rayleigh wave fields generated by angle beam wedge transducers-A theoretical study[J]. Wave Motion, 2016, 67: 141-159. [14]. Zhiping Liu, Xiongbing Li*, Yongfeng Song, et al(2016). Lofting-based spiral tool path generation algorithm for milling a pocket with an island[J]. The International Journal of Advanced Manufacturing Technology, 2016，88(5): 2169-2178. [13]. Shuzeng Zhang, Christopher M. Kube, Yongfeng Song, Xiongbing Li*(2016). A self-reciprocity calibration method for broadband focused transducers[J]. Journal of the Acoustical Society of America, 2016,140(3):236-241. [12]. Shuzeng Zhang, Xiongbing Li*, Hyunjo Jeong(2016). A more general model equation of nonlinear Rayleigh waves and their quasilinear solutions[J]. Modern Physics Letters B, 2016,30(8):1650096. [11]. 宋永锋, 李雄兵*, 史亦韦, 倪培君(2016).表面粗糙度对固体内部超声背散射的影响(J). 物理学报, 2016, 65 (16): 214301. [10]. 宋永锋, 李雄兵*, 吴海平, 司家勇, 韩晓芹(2016). In718晶粒尺寸对超声背散射信号的影响及其无损评价方法[J].金属学报.2016,52(3):378-384. [9].Shu-Zeng Zhang, XiongBing Li, Hyunjo Jeong*(2016). Phased Array Beam Fields of Nonlinear Rayleigh Surface Waves[J]. Chinese Physics Letters, 2016, 33(7): 074302. [8]. Hyunjo Jeong*, Shuzeng Zhang, Sungiong Cho, Xiongbing Li(2016). Development of explicit diffraction corrections for absolute measurements of acoustic nonlinearity parameters in the quasilinear regime[J].Ultrasonics, 2016, 70: 199-293. [7].Hyunjo Jeong*, Shuzeng Zhang, Xiongbing Li(2016). A novel method for extracting acoustic nonlinearity parameters with diffraction corrections[J]. Journal of Mechanical Science and Technology, 2016, 30(2):643-652. [6]. Jeong H*, Zhang SZ, Cho S, Li XB(2016). Development of attenuation and diffraction corrections for linear and nonlinear Rayleigh surface waves radiating from a uniform line source[J]. AIP Advances, 2016, 6(4): 045313. [5]Xiongbing Li*, Yongfeng Song, Feng Liu, Hongwei Hu, Peijun Ni(2015). Evaluation of mean grain size using the multi-scale ultrasonic attenuation coefficient[J]. NDT&E International, 2015, 72: 25-32. [4]. Li Xiongbing*, Song Yongfeng, Liu Feng, Wang Zi, Hu Hongwei(2015). Grain size evaluation of structural materials in nuclear power plant using a thickness independent ultrasonic method [J]. Nuclear Inst. and Methods in Physics Research, B, 2015, 351:16-22. [3]. 李雄兵*, 宋永锋, 倪培君, 刘锋(2015). 面向晶粒尺寸的超声多尺度衰减评价方法[J].金属学报.2015,51(1): 121-128. [2]. Xiongbing Li*, Jiajia Liang, Peijun Ni, Yuguo Wang, Yongfeng Song, Linjun Tong(2014). Novel path generation algorithm for high-speed pocket milling. International Journal of Production Research, 2014,52(02):397- 404. [1]. XiongBing Li*, Hong-Wei Hu, Yue Yang, Pei-Jun Ni(2010). Cheng Yang. Automatic ultrasonic inspection of flaws in a propeller-blade[J]. Nondestructive Testing and Evaluation, 2010, 25(4): 341-351. 【EI期刊论文】 [18]倪培君, 王猛, 乔日东, 李雄兵, 张荣繁. 变形镁合金缺陷及其无损检测研究进展[J]. 兵器装备工程学报, 2020, 41(07):158-163. [17]. 张书增, 李雄兵*, 郑慧峰(2016). 反射法测量固体材料的非线性系数研究[J]. 机械工程学报, 52(16): 8-14, 2016. [16]. 李雄兵*, 张书增, 陈峰(2016). 多元高斯声束衍射修正下液体非线性系数检测方法[J].声学学报. 2016, 41(4):515-520. [15]. 张晨昕, 李雄兵*, 宋永锋, 刘锋, 刘希玲(2016). 考虑水声距的晶粒尺寸超声衰减评价模型[J]. 中南大学学报(自然科学版), 2016, 04:1151-1157. [14]. 王家斌, 王炫润, 李劭晨, 宋永锋, 李雄兵*(2016). 含孤岛型腔铣削加工的螺旋刀轨生成算法[J].航空学报, 2016, 36(5): 1689-1695. [13]. 李雄兵*, 宋永锋, 胡宏伟, 倪培君(2015). 基于衰减速率的晶粒尺寸超声评价方法[J].机械工程学报. 2015, 51(14):1-7. [12]. 刘希玲, 吕铎, 李雄兵*, 倪培君(2015). 基于超声测量模型的镁合金弹壳自动检测方法[J]. 湖南大学学报(自然科学版),2015, 10(42):54-58. [11]. 杨岳, 戴万林, 李雄兵*, 倪培君, 乔日东(2015). 镁合金壳体内部缺陷的精确超声定量方法[J]. 中国有色金属学报，2015, 25(10): 2666-2671. [10]. 张书增, 李雄兵*, 杨岳, 胡宏伟, 宋永锋(2014).钢轨轨头内多元高斯声场模拟及其缺陷响应.铁道学报, 2014, 36(1):76-80. [9]. 张杨, 周晓军, 杨辰龙, 李雄兵, 郑慧峰(2013). 变厚度曲面构件超声检测灵敏度补偿. 浙江大学学报(工学版), 2013, 47( 1) : 116-121. [8]. 胡宏伟, 李雄兵*, 杨岳, 倪培君, 童林军(2012). CFRP复杂型面构件的孔隙率超声检测方法. 中南大学学报(自然科学版),2012, 43(4): 1315-1319. [7]. 张杨, 周晓军, 郑慧峰, 李雄兵, 杨辰龙(2012). 基于模板的大型复杂曲面超声C扫方法. 仪器仪表学报, 2012, 33(7): 1626-1633. [6]. 张杨, 周晓军, 杨辰龙, 李雄兵, 陈汝蒋, 牛彦牧(2012). 基于声束追踪的变厚度曲面工件超声探头位姿规划. 农业机械学报, 2012, 43(9) : 230-234. [5]. 李雄兵, 杨岳, 胡宏伟, 倪培君, 阳程(2010). 面向超声检测的曲面自动测量, 中南大学学报, 2010, 41(1): 194-200. [4]. 刘希玲, 杨述明, 李雄兵(2010). Hoffmann液压机构压力波动的动态特性仿真. 湖南大学学报(自然科学版),2011,38(2): 41-44. [3]. 杨先勇, 周晓军, 胡宏伟, 李雄兵, 庞茂(2009). 螺旋锥齿轮非线性振动特性及参数影响. 浙江大学学报(工学版), 2009,43(3):505-510. [2]. 李雄兵, 周晓军, 郑慧峰(2008). 面向超声检测的数据压缩方法. 浙江大学学报, 2008, 42(7): 1251-1254. [1]. 郑慧峰, 周晓军, 李雄兵(2008). 基于本体多关节的超声检测机器人误差补偿. 农业机械学报, 2008, 39(4) :164-167.

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