Journal of Mechanical Engineering >

2016 , Vol. 52 >Issue 9: 105 - 115

DOI: https://doi.org/10.3901/JME.2016.09.105

Influence of Dynamic Load on the Mechanical and Electrical Performance of Structurally Integrated Antenna

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  • 1. Key Laboratory of Electronic Equipment Structure Design of Ministry of Education, Xidian University, Xi’an 710071;
    2. State Key Laboratory of Structural Analysis for Industrial Equipment, Dalian University of Technology, Dalian 116023

Online published: 2016-05-05

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Abstract

Structurally integrated antenna is a kind of novel antenna which can embed RF circuit and microstrip antenna array into the structure of weapon platforms. The antenna is not only a load-bearing skin structure, but also a microwave antenna which can receive or send electromagnetic waves, and it can be applied to all kinds of new weapon platforms in the future. As for the evolving problems of the mechanical and electrical performance of structurally integrated antenna, the influence relationship between the structural deformation and the electrical performance is analyzed, and an electromechanical coupling model is developed by using the phase errors. Moreover, the deformed structure is fitted by using least square support vector regression to obtain the electrical performance. At the end, an experimental apparatus with 2.5 GHz structurally integrated antenna is developed, and some experiments from the apparatus are carried out, and the experimental results confirm the effectiveness of the electromechanical coupling model. The validated model is applied to investigate the influence mechanism of dynamic load on the mechanical and electrical performance by analyzing the obtained results. The results show that the structural deformation will affect the direction of main beam, side lobe and gain of the structurally integrated antenna.

Key words: structurally integrated antenna; electromechanical coupling; structural deformation; support vector regression

Cite this article

ZHOU Jinzhu1, 2, SONG Liwei1, DU Leigang1, GUO Donglai1 . Influence of Dynamic Load on the Mechanical and Electrical Performance of Structurally Integrated Antenna[J]. Journal of Mechanical Engineering, 2016 , 52(9) : 105 -115 . DOI: 10.3901/JME.2016.09.105

References

[1] SMALLWOOD B P,CANFIELD R A,TERZUOLI J A J. Structurally integrated antennas on a joined-wing aircraft[C] //44th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics,and Materials Conference,April 7-10,2003,Norfolk,VA,United States. Reston: AIAA,2003:549-556.
[2] URCIA M,BANKS D. Structurally integrated phased arrays[C]//2010 IEEE Aerospace Conference,March 5-12,2011,Big Sky,MT,USA. Piscataway:IEEE,2011:1-8.
[3] LOCKYER A J,ALT K H,COUGHLIN D P,et al. Design and development of a conformal load-bearing smart-skin antenna:Overview of the AFRL smart skin structures technology demonstration (S3TD)[C]// Proceedings of the 1999 Smart Structures and Materials - Industrial and Commercial Applications of Smart Structures Technologies,March 2-4,1999,Newport Beach,CA,USA. Bellingham:SPIE,1999:410-424.
[4] LOCKYER A J,ALT K H,KINSLOW R W,et al. Development of a structurally integrated conformal load-bearing multifunction antenna:Overview of the air force smart skin structures technology demonstration program[C]// Smart Structures and Materials 1996:Smart Electronics and MEMS,February 28-29,1996,San Diego,CA,USA. Bellingham:SPIE,1996:55-64.
[5] RONALD F G. A review of recent research on mechanics of multifunctional composite materials and structures[J]. Composite Structures,2010,92(12):2793-2810.
[6] MURPHEY T W,CLIFF E M,LANE S A. Matching space antenna deformation electronic compensation strategies to support structure architectures[J]. IEEE Transactions on Aerospace and Electronic Systems,2010,46(3):1422-1436.
[7] ALGERMISSEN S,MONNER H P,KNOTT P,et al. Closed-loop subspace identification for vibration control of structure integrated antenna arrays[C]// 2011 IEEE Aerospace Conference,March 5-12,2011,Montana,USA. Piscataway:IEEE,2011:1-8 .
[8] KNOTT P,LOCKER C,ALGERMISSEN S,et al. Research on vibration control and structure integration of antennas in nato/rto/set-131[C]//2010 IEEE International Symposium Antennas and Propagation and CNC-USNC/ URSI Radio Science Meeting,July 11-17,2010,T. Piscataway:IEEE,2010:1-4.
[9] SON S H,EOM S Y,HWANG W. Development of a smart-skin phased array system with a honeycomb sandwich microstrip antenna[J]. Smart Materials and Structures,2008,17:1-9.
[10] CHISANG Y,TENTZERIS M M,WOONBONG H. Multilayer effects on microstrip antennas for their integration with mechanical structures[J]. IEEE Transactions on Antennas and Propagation,2007,55(4):1051-1058.
[11] CHISANG Y,WOONBONG H. Design of load-bearing antenna structures by embedding technology of microstrip antenna in composite sandwich structure[J]. Composite Structures,2005,71(3-4):378-382.
[12] CHISANG Y,DANIELA S,LARA M,et al. A novel hybrid electrical/mechanical optimization technique using time-domain modeling,finite element method and statistical tools for co-design and optimization of RF-integrated mechanical structures[J]. International Journal of Numerical Modeling:Electronic Network,Devices and Fields,2007,21(1-2):91-101.
[13] 蔡良元,白树成,曲建直,等. 某新型航天器返回舱舱门共形天线研制[J]. 宇航材料工艺,2000,5:66-69.
CAI Liangyuan,BAI Shucheng,QU Jianzhi. A study of return module hatchdoor conformal antenna[J]. Aerospace Materials & Technology,2000,5:66-69.
[14] YAO L,QIU Y. Design and fabrication of microstrip antennas integrated in three dimensional orthogonal woven composites[J]. Composites Science and Technology,2009,69(7-8):1004-1008.
[15] XU F,YAO L,ZHAO D,et al. Performance and impact damage of a three dimensionally integrated microstrip feeding antenna structure[J]. Composite Structures,2010,93(1):193-197.
[16] 戴福洪,王广宁. 埋微带天线蜂窝夹层结构的力电性能分析[J]. 复合材料学报,2011,28(2):231-234.
DAI Fuhong,WANG Guangning. Analysis of mechanical and electric performance of honeycomb sandwich structures embedded with the microstrip antenna[J]. Acta Materiae Compositae Sinica,2011,28(2):231-234.
[17] 谢宗蕻,李磊,赵剑,等. 空间智能天线夹芯结构热变形力学分析[J]. 南京航空航天大学学报,2008,40(5):617-621.
XIE Zonghong,LI Lei,ZHAO Jian,et al. Thermal deformation analysis for space smart antenna composite sandwich structures[J]. Journal of Nanjing University of Aeronautics & Astronautics,2008,40(5):617-621.
[18] ZHOU J,HUANG J,SONG L,et al. Electromechanical co-design and experiment of structurally integrated antenna[J]. Smart Materials and Structures,2015,24(3):1-11.
[19] 胡乃岗,保宏,连培园,等. 大型相控阵天线结构与调整机构一体化设计[J]. 机械工程学报,2015,51(1):196-202.
HU Naigang,BAO Hong,LIAN Peiyuan,et al. Synthetic design of structure and adjustment mechanism of large phased array antennas[J]. Journal of Mechanical Engineering,2015,51(1):196-202.
[20] 周金柱,黄进,宋立伟,等. 结构功能一体化天线的机电耦合机理和实验[J]. 电子机械工程,2014,30(1):1-6.
ZHOU Jinzhu,HUANG Jin,SONG Liwei,et al. Electromechanical coupling mechanism and experiment for structurally integrated antenna[J]. Electro-Mechanical Engineering,2014,30(1):1-6.
[21] 段宝岩. 电子装备机电耦合研究的现状与发展[J]. 中国科学:信息科学,2015,45(3):299-312.
DUAN Baoyan. Review of electromechanical coupling of electronic equipment[J]. Scientia Sinica:Informationis,2015,45(3):299-312.
[22] 段宝岩. 电子装备机电耦合理论、方法及应用[M]. 北京:科学出版社,2011.
DUAN Baoyan. Electromechanical coupling theory,method and application of electronic equipment[M]. Beijing:Science Press,2011.
[23] 张伟伟,叶正寅. 基于当地流活塞理论的气动弹性计算方法研究[J]. 力学学报,2005,37(5):632-638.
ZHANG Weiwei,YE Zhengyin. Numerical method of aeroelasticity based on local piston theory[J]. Acta Mechanica Sinica,2013,45(5):632-638.
[24] 姜辉,杨建国,姚晓栋,等. 数控机床主轴热漂移误差基于贝叶斯推断的最小二乘支持向量机建模[J]. 机械工程学报,2013,49(15):115-121.
JIANG Hui,YANG Jianguo,YAO Xiaodong,et al. Modeling of CNC machine tool spindle thermal distortion with LS-SVM based on bayesian inference[J]. Journal of Mechanical Engineering,2013,49(15):115-121.
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