外文论文: Note: [C]- Conference Paper
[J]-Journal Paper
[1] Xiaoqing Sun, Bintang Yang. A new methodology for
developing flexure-hinged displacement amplifiers with micro-vibration
suppression for a giant magnetostrictive micro drive system[J]. Sensors and
Actuators A: Physical, 2017.
[2] Sun, X., Yang, Y., Hu, W., & Yang, B.. Optimal design
and experimental performances of an integrated linear actuator with large
displacement and high resolution[J]. Microsystem Technologies, 2017: 1-11.
[3] Xiaoqing Sun, Bintang Yang, Shufeng Guo. Design and
analysis of a novel tensioning stage driven by a giant magnetostrictive
actuator[C]. The 5th International Conference on Mechanical, Automotive and
Materials Engineering, Guangzhou, August 1-3, 2017.
[4] Niu M, Yang B, Yang Y, et al. Dynamic modelling of
magnetostrictive actuator with fully coupled magneto-mechanical effects and
various eddy-current losses[J]. Sensors & Actuators A Physical, 2017,
258:163-173.
[5] Niu M, Yang B, Yang Y, et al. Modelling and Optimization
of Magnetostrictive Actuator Amplified by Compliant Mechanism[J]. Smart
Materials & Structures, 2017.
[6] Niu M, Yang B, Yang Y, et al. Two Generalized Models for
Planar Compliant Mechanisms based on Tree Structure Method[J]. Precision
Engineering, 2017.
[7] Sicheng Yi, Bintang Yang , and Muqing Niu, etc. Micropositioning
Control for an Amplified Magnetostrictive-Actuated Device[C]. The 5th
International Conference on Mechanical[C]. Automotive and Materials
Engineering, Guangzhou, August 1-3, 2017.
[8] Wei Hu, Quan He, Bintang Yang*,Shufeng Guo, Wenqiang Zhao, Jietan Zhang. Design of a Novel Active
Joint Mechanism for Solar Panels[C]. Automotive and Materials Engineering,
Guangzhou, August 1-3, 2017.
[9] Hu Yu, Bintang Yang, Xiaoqing Sun, Xi Wang, Hangjie Mo.
Effects of Tunable Angle for Vortex Generators on Aerodynamic Performances of
Airfoils[C]. The Second International Coference on Applied Engineering,
Materials and Mechanics, Tianjin, April 14-16, 2017.
[10] Fengyu Cao, Muqing Niu, Yikun Yang, Baoying Xie and
Bintang Yang. Modeling of the electromagnetic torque on the permanent magnet in
a novel drive mechanism[C]. The Second International Coference on Applied
Engineering, Materials and Mechanics, Tianjin, April 14-16, 2017.
[11] Fengyu Cao, Bintang Yang, Muqing Niu, Baoying Xie and
Wei Hu. Electrical-magnetic-mechanical modeling of a novel vibration shaker
based on a rotary permanent magnet[C]. The 5th International Conference on
Mechanical, Automotive and Materials Engineering, Guangzhou, August 1-3, 2017.
[12] Yikun Yang, Bintang Yang and Muqing Niu, Hybrid Frequency-dependent
Hysteresis Model of Magnetostrictive Actuator[C]. The 5th International
Conference on Mechanical, Automotive and Materials Engineering, Guangzhou,
August 1-3, 2017.
[13] Yang Y, Yang B, Niu M. Parameter identification of Jiles–Atherton model for magnetostrictive actuator using hybrid niching
coral reefs optimization algorithm[J]. Sensors and Actuators A: Physical, 2017,
261: 184-195.
[14] Yang Y, Yang B, Niu M. Spline adaptive filter with
fractional-order adaptive strategy for nonlinear model identification of
magnetostrictive actuator[J]. Nonlinear Dynamics, 2017: 1-13.
[15] Yang Y, Yang B, Niu M. Adaptive infinite impulse
response system identification using opposition based hybrid coral reefs
optimization algorithm[J]. Applied Intelligence, 2017: 1-18.
[16] Xi Wang, Bintang Yang, Hu Yu, Yulong Gao. Transient
vibration analytical modeling and suppressing for vibration absorber system
under impulse excitation[J]. Journal of Sound and Vibration, 2017, 394: 90-108.
[17] Xi Wang, Bintang Yang, Yu Zhu. Adaptive model-based
feedforward to compensate Lorentz force variation of voice coil motor for the
fine stage of lithographic equipment[J]. Optik-International Journal for Light
and Electron Optics, 2017, 135: 27-35.
[18] Xi Wang, Bintang Yang, Jiaxin You, Zhe Gao. Coarse-fine
adaptive tuned vibration absorber with high frequency resolution[J]. Journal of
Sound and Vibration, 2016, 383: 46-63.
[19] Xi Wang, Bintang Yang, Yu Zhu. Modeling and analysis of
a novel rectangular voice coil motor for the 6-DOF fine stage of lithographic
equipment[J]. Optik - International Journal for Light and Electron Optics,
2016, 127(4): 2246-2250.
[20] Xi Wang, Bintang Yang, Yu Zhu. Optimization of current
distribution coefficients to decouple the 6-DOF fine stage of lithographic
equipment[J]. Optik - International Journal for Light and Electron Optics,
2016, 127(20): 9896-9904.
[21] Xi Wang, Bintang Yang. Adaptive dynamic absorber for
wideband micro-vibration control based on precision self-positioning linear
actuator[C]. 15th International Conference on New Actuators, Bremen, Germany,
2016.
[22] Xi Wang, Bintang Yang, Hu Yu. Optimal design and
experimental study of a multi-dynamic vibration absorber for multi-frequency
excitation[J], Journal of Vibration and Acoustics, 2017, 139(3): 031011.
[23] Xiaoqing Sun, Bintang Yang, Long Zhao, Xiaofen Sun.
Optimal design and experimental analyses of a new micro-vibration control
payload-platform[J]. Journal of Sound and Vibration, 2016, 374: 43-60.
[24] Bintang Yang, Yikun Yang. A new angular velocity sensor
with ultrahigh resolution using magnetoelectric effect under the principle of
Coriolis force[J]. Sensors and Actuators A: Physical, 2016, 238: 234-239.
[25] Muqing Niu, Bintang Yang, Guang Meng. Design and
modelling of a sensor-integrated actuator using combined effects of
magnetostriction and piezoelectricity[C]. 15th International Conference on New
Actuators, Bremen, Germany, 2016.
[26] Quan He, Bin-tang Yang. Design and optimization of a new
type of active hinge[C]. 2nd International Conference on Mechanical, Electronic
and Information Technology Engineering, Chongqing, May 21-22, 2016.
[27] Xiaoqing Sun, Qiwei Guo, Bintang Yang. Study and
simulation of a vibration-isolation system for the large precision optical load
on the Chinese space station[C]. The 7th International Conference On Vibration
Engineering, Shanghai, September, 2015.
[28] Muqing Niu, Bintang Yang, Guang Meng. Design and
modelling of a 3-DOF hybrid micro-vibration isolator[C]. The 7th International
Conference On Vibration Engineering, Shanghai, September, 2015.
[29] B.T. Yang, T. Zhang, J.Q. Li, F.C. Li, H.G. Li and G.
Meng, Research on Giant Magnetostrictive Actuator for Low Frequency Adaptive
Vibration Control[J]. Advances in Vibration Engineering, 2013, 12(6):611-622.
[30] Kai Deng, Bintang Yang. The adaptive feedback control
with dynamic feed-forward compensation of the giant magnetostrictive
actuator[J]. Applied Mechanics and Materials, 2014, 654:208-211.
[31] Pei Cai, Bintang Yang. Design and research of smart
blades based on load optimization and power control[J]. Applied Mechanics and
Materials, 2014, 654:229-232.
[32] Zhang Ting , Yang Bin Tang* , Li Hong Guang , Meng
Guang. Dynamic Modeling and Adaptive Control of a Giant Magnetostrictive
Actuator for Vibration Control[J]. Sensors and Actuators A: Physical, 2013,
190: 96-105.
[33] Z.K. PENG, W.M. Zhang, B.T. YANG, G. MENG, Fulei Chu.
The parametric characteristic of bispectrum for nonlinear systems subjected to
Gaussian input[J]. Mechanical Systems and Signal Processing, 2013, 36(2):
456-470.
[34] Bintang Yang, Tianxiang Che, Guang Meng, Zhiqiang Feng,
Jie Jiang, Shuo Zhang and Qi Zhou. Design of a safety escape device based on
magnetorheological fluid and permanent magnet[J]. Journal of intelligent material
systems and structures, 2013, 24(1): 49-60.
[35] Bintang Yang, Qingwei Liu, Ting Zhang, Yudong Cao.
Zhiqiang Feng, Guang Meng, Non-contact translation-rotation sensor using
combined effects of magnetostriction and piezoelectricity[J]. Sensors, 2012, 12(10),
13829-13841.
[36] Bin-tang Yang, De-hua Yang, Peng-you Xu, Yu-dong Cao,
Zhi-Qiang Feng, Guang Meng. Large stroke and nanometer-resolution giant
magnetostrictive assembled actuator for driving segmented mirrors in very large
astronomical telescopes[J]. Sensors and Actuators A: Physical, 2012, 179:
193-203.
[37] Y.D. Cao, B.T. Yang*. Non-linear modelling of multilayer
piezoelectric actuators in non-trivial configurations based on actuator design
parameters and piezoelectric material properties[J]. Journal of Intelligent
Material Systems and Structures, 2012, 23(8): 875-884.
[38] Wang Q, Yang B T, Liu L T, et al. Design and Modeling of
a New Inchworm Linear Motor[J]. Advanced Materials Research. Trans Tech
Publications, 2012, 562: 603-606.
[39] Lan-tao Liu, Bin-tang Yang*, Qi Wang, Guang Meng.
Modeling and Simulation of A Novel Drive Joint Based on Permanent Magnet and
Electromagnet[C]. Materials Engineering and Automatic Control(ICMEAC2012),
Jinan, April 27-29, 2012.
[40] L.T. Liu, B.T. Yang *, Q. Wang, L. Li, G. Meng. Design
of A New Type of Drive Joint for Rehabilitation Robots[C]. 2012 6th
International Conference on Bioinformatics and Biomedical Engineering (iCBBE
2012), Shanghai, May 17-20, 2012.
[41] B.T. Yang*, Q. Wang, M.Bonis, Z.Y.Zhang, G.Meng, X.F.
Sun, Z.Q. Feng, D.H.Yang. Development of a novel electromagnetic-driven low
frequency and heavy load vibration table with a rotary permanent magnet[C].
Proceedings of ACTUATOR 2012, 13th International Conference on New Actuators,
BREMEN, Germany, June 16-19, 2012.
[42] Qi Wang, Bin-tang Yang*, Lan-tao Liu, Guang Meng. Design
and Modeling of a New Inchworm Linear Motor[C]. Materials Engineering and
Automatic Control(ICMEAC2012), Jinan, April 27-29, 2012.
[43] B.T. Yang*, T. Zhang, J. Q. LI, F.C.LI, H.G LI, G. Meng.
Research on Giant Magnetostrictive Actuator for Low Frequency Adaptive
Vibration Control[C]. The Seventh International Conference on VIBRATION
ENGINEERING AND TECHNOLOGY OF MACHINERY, Shanghai, November 21-24.
[44] B.T. Yang, Y.M Lu, G. Meng, Zh-Q Feng. Numerical and
experimental study of a vibration driver due to electromagnetic forces on a
rotary permanent magnet[J]. Sensors and Actuators A: Physical, 2011, 172(2):
491-496.
[45] Bintang Yang, Guang Meng, Zhi-Qiang Feng, Dehua Yang.
Giant magnetostrictive clamping mechanism for heavy-load and precise
positioning linear inchworm motors[J]. Mechatronics, 2011, 21(1): 92-99.
[46] Pan Pengsheng, Yang Bintang*, Meng Guang, Design and
Simulation of a mini precision positioning magnetostrictive inchworm linear
motor[J]. Applied Mechanics and Materials. 2011, 130-134: 2846-2850.
[47] Jianqiang Li, Bintang Yang*, Guang Meng, Dynamic
Modeling and Simulation of 3-d.o.f. Vibration Active Isolation Platform Based on
Giant Magnetostrictive Actuators[J]. Applied Mechanics and Materials. 2011,
130-134:2719-2723.
[48] W. B. Xu, B. T. Yang , G. Meng, Y. M. Lu.. Dynamic
Modeling and Simulation to Precision Positioning Magnetostrictive Inchworm
Linear Motor[C]. Proceedings of ACMFMS2010, Nanjing, China.
[49] B.T. Yang, G. Meng, Z.Q. Feng, D.H. Yang, W.B. Xu, Y.M.
Lu.. Heavy Load and Nano-Metric Positioning Magnetostrictive Inchworm Linear
Motor[C]. Proceedings of ACTUATOR 2010, 12th International Conference on New
Actuators, BREMEN, Germany, June 13-16, 2010.
[50] Feng Z.-Q., Yang B. T., Cros J.-M., and Renaud C..
Dynamics of shell structures with contact interfaces[C]. IV European Conference
on Computational Mechanics, Paris, France, May 16-21, 2010.
[51] C.Renaud, Z.Q.Feng, J. Cros, B.T.Yang. The Yeoh model
applied to the modeling of large deformation contact/impact problems[J].
International Journal of Impact Engineering, 2009, 36: 659-666.
[52] Yang B.T, Meng G, Yang D.H, Feng Z.Q, PY. Xu, Tan X.T..
Magnetostrictive blocked-force mechanism for secure and heavy-load inchworm
motion[C]. Proceedings of the ASME 2009 Conference on Smart Materials, Adaptive
Structures and Intelligent Systems SMASIS2009-1268, Oxnard, California, USA,
September 20-24, 2009.
[53] Liang Shao, Dehua Yang, Bintang Yang, Kunxin Chen.
Design and Test of a Micro-displacement Actuator Based on Giant
Magnetostrictive Material[C]. Second International Conference on Smart
Materials and Nanotechnology in Engineering, Proc. of SPIE, 2007.
[54] Bintang Yang, Dehua Yang, Guang Meng, Kunxin Chen,
Yongjun Qi, Haiting Zhou, Peiyong Hou. Application study on
giant-magneostrictive actuator for drivingsegmented mirrors of very large
astronomical telescope[C]. Int. Conf. on Smart Materials and Nanotechnology in
Engineering, Proc. of SPIE, 2007.
[55] B.T. Yang, M. Bonis, H. Tao, C. Prelle and F. Lamarque.
Magnetostrictive mini actuator for long-stroke positioning with nanometer
resolution[J]. J. Micromech. Microeng., 2006, 16: 1227-1232.
[56] Hongjun Qiu, Hua Tao, Bintang Yang, Xiaobin Gao. Study
on formalizable aircraft assembly process planning knowledge[J]. Materials
Science Forum, 2006, 532-533: 640-643.
[57] B.T. YANG, M.BONIS. An aproach of optimum design of an
inchworm magnetostrictive mini-actuator[C]. 1st International Conference of
Micromanufacturing, University of Illinois, Urbana-Champaign, September 13-15,
2006.
[58] B.T. YANG, M.BONIS. Experimental study on giant
magnetostrictive material for mini-actuator design[C]. Proceedings of the 2nd
International Conference on Smart Materials & Structures in Aerospace
Engineering, Nanjing, China, September 24-26, 2006.
[59] Yang B.T., Bonis M., Tao H., Prelle C. Lamarque F..
Modeling and simulation study for a mini actuator using a giant
magnetostrictive material[C]. Proc. of 5th euspen international conference,
Montpellier, France, May 8-11, 2005.
[60] Yang B.T., Bonis M., Tao H., Prelle C.. Design approach
of a magnetostrictive actuator[C]. Proc. of 4th euspen international
conference, Glasgow, Scotland (UK), May 31st-June 2nd, 2004.
[61] Yang B.T., Prelle C., Lamarque F., Bonis M., Tao H..
Development of a Mini-actuator Based on Giant Magnetostrictive Materials[C].
Proc. of 4th International Workshop on Microfactories, Shanghai, China, October
15-17, 2004.
中文论文:
[1] 莫杭杰,杨斌堂,喻虎,曹逢雨. 超磁致伸缩微振动电驱系统设计与实现[J]. 噪声与振动控制,2017,37(2)(期刊号尚未确定).
[2] 何泉,刘澜涛,杨斌堂. 基于主动关节机构的航天扰性结构的振动控制[J]. 上海交通大学学报,2016,50(12):36-42.
[3] 孙晓芬,杨斌堂,赵龙. 巨磁致伸缩自适应精密驱动和振动控制[J]. 噪声与振动控制,2014,34(5):16-21.
[4] 赵龙,杨斌堂,孙晓芬. 微振动主动隔振平台的超磁致伸缩驱动器设计[J]. 噪声与振动控制,2014,34(5):203-209.
[5] 杨斌堂,赵寅,彭志科,孟光. 基于Prandtl-Ishlinskii模型的超磁致伸缩驱动器实时磁滞补偿控制[J]. 光学精密工程, 2013, 21(1):124-130.
[6] 赵寅,杨斌堂,彭志科,孟光. 超磁致伸缩驱动器自适应精密驱动控制研究[J]. 噪声与振动控制, 2013, 33(6):1-4.
[7] 杨斌堂,徐彭有,孟光,杨德华,许文秉,谭先涛. 大行程精密定位超磁致伸缩驱动器的设计与控制[J]. 机械工程学报,2012, 48(1):25-31.
[8] 许文秉,杨斌堂,孟光,吕扬名. 大负载精密驱动超磁致伸缩直线电机动力学建模与仿真. 上海交通大学学报,2012, 46(3): 480-486.
[9] 吕扬名,杨斌堂,孟光,许文秉,夏明璐,钱文韬. 振动驱动的电磁-永磁复合驱动建模. 噪声与振动控制,2011,
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[10] 徐彭有,杨斌堂,孟光. 天文望远镜子镜超磁致伸缩驱动器驱动模型及参数识别[J]. 天文研究与技术,2010, 7(2):150-157.
[11] 谭先涛,杨斌堂,孟光. 超磁致伸缩驱动器二维轴对称非线性驱动位移模型及有限元分析[J]. 天文研究与技术,2010, 07(4):362-368.
[12] 张梦良,戚永军,杨斌堂. 磁致伸缩微位移驱动器性能测试分析[J]. 天文研究与技术,2009, 6(4):000342-346.
[13] 邵亮,杨德华,陈昆新,杨斌堂 光学天文望远镜用微位移驱动器机构研究综述[J]. 天文学进展,2009, 27(1):70-79.
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