复合导引小车行进轨迹规划研究
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摘要
可移动自主攻击微系统是一种融合信息采集、分析、传递以及攻击执行的无线传感器网络系统。在这个系统中,布置不少于5个的具有行走、感知、攻击功能的智能小车,系统职守期间,小车出动次数频繁,能否顺利导引小车返回成为关键。本文正是对复合导引小车行进轨迹规划的研究。
本文概述了课题的国内外研究现状与发展趋势,提出了课题的系统总体设计方案,结合课题背景较高的导引精度要求(小于50mm),提出了声导引与电磁导引的复合导引方法。在声导引系统中,提出了一种全新的定位方法,不同于主动定位,也不同于被动定位,即采用标准声源发射信号、基站传感器阵列接收处理信号、网络节点通讯定位来完成。电磁导引系统采用埋地导线导引方法,其中对通电导线布局、小车跨越导线前后的行进方向判别作了详细研究。最终在电路设计的基础上,完成了对小车行进路线的复合导引。
文章中通过实验说明了导引的可行性,在声导引电路设计、电磁导引电路设计方面进行了大量工作研究,测试结果表明复合导引方式的实用性、可靠性与优越性。
Mobile autonomous attack micro-system is an integration of micro-attack information gathering, analysis, transfer and attack wireless sensor network system. In the system, dispenser with less than 5 walking, perception, attacks enabled smart car. during duties, as the number of frequent car out, the key is whether successfully guided the car to return. This article is for research on the car travel path plans based on compound guiding.
The actual research status and developing current of the study at home and abroad are summarized in the paper. The system design program is put forward, and issue guidance with high precision background (less than 50mm), raises the compound guiding the car approach, that the sound guidance and the electromagnetic guidance. In the sound Guidance system, a new positioning method is proposed, it is different from the active location and the passive position, the method is completed according to the sound source emission signal, the base station sensor array receiving and processing signals, the communication network nodes targeting.The electromagnetic guidance system uses buried wire guidance method, in which the layout for the power wires and the direction discrimination of the car travel across the wire were studied in detail. Finally, the car travel path plans based on compound guiding is completed according to the design of guidance circuit.
The feasibility of guidance is outlined in the paper by experiments, and a lot of research work is completed in circuit design of the sound guidance and the electromagnetic guidance. The practicality, reliability, superiority of the compound guiding method is confirmed by the results of experiment.
本文概述了课题的国内外研究现状与发展趋势,提出了课题的系统总体设计方案,结合课题背景较高的导引精度要求(小于50mm),提出了声导引与电磁导引的复合导引方法。在声导引系统中,提出了一种全新的定位方法,不同于主动定位,也不同于被动定位,即采用标准声源发射信号、基站传感器阵列接收处理信号、网络节点通讯定位来完成。电磁导引系统采用埋地导线导引方法,其中对通电导线布局、小车跨越导线前后的行进方向判别作了详细研究。最终在电路设计的基础上,完成了对小车行进路线的复合导引。
文章中通过实验说明了导引的可行性,在声导引电路设计、电磁导引电路设计方面进行了大量工作研究,测试结果表明复合导引方式的实用性、可靠性与优越性。
Mobile autonomous attack micro-system is an integration of micro-attack information gathering, analysis, transfer and attack wireless sensor network system. In the system, dispenser with less than 5 walking, perception, attacks enabled smart car. during duties, as the number of frequent car out, the key is whether successfully guided the car to return. This article is for research on the car travel path plans based on compound guiding.
The actual research status and developing current of the study at home and abroad are summarized in the paper. The system design program is put forward, and issue guidance with high precision background (less than 50mm), raises the compound guiding the car approach, that the sound guidance and the electromagnetic guidance. In the sound Guidance system, a new positioning method is proposed, it is different from the active location and the passive position, the method is completed according to the sound source emission signal, the base station sensor array receiving and processing signals, the communication network nodes targeting.The electromagnetic guidance system uses buried wire guidance method, in which the layout for the power wires and the direction discrimination of the car travel across the wire were studied in detail. Finally, the car travel path plans based on compound guiding is completed according to the design of guidance circuit.
The feasibility of guidance is outlined in the paper by experiments, and a lot of research work is completed in circuit design of the sound guidance and the electromagnetic guidance. The practicality, reliability, superiority of the compound guiding method is confirmed by the results of experiment.
引文
[1]被动声探测若干关键技术研究,南京理工大学学位论文,2005.
[2]陈佳奎.微弱信号探测[M].北京,中央广播电视大学出版社,1987.
[3]赵玉洁.声测定位技术的现状和发展趋势[J].声学与电子工程,1993年第4期.
[4]向瑾.基于四元十字阵的被动声定位技术研究.中北大学学位论文,2008.
[5]李晋.脉冲声源无源声定位探测技术研究.哈尔滨工业大学学位论文,2007.
[6]王皖君等.自动导引车导引技术研究现状与发展趋势[J].传感器与微系统,2009.
[7]张营.智能车辆定位技术研究[D].上海:上海交通大学机械与动力工程学院,2008.
[8]吕国云,许学忠.战场目标被动噪声识别技术[J].探测与控制学报。2001.
[9]刘贯领.声目标识别方法研究[D].南京,南京理工大学,2003.
[10]Savvides A, Han C C, Srivastava M. Dynamic Fine-grained Localization in Ad-hoc Networks of Sensors[C]//Proc. of ACM MOBICOM. Rome, Italy:[s. n.],2001.
[11]Bahl P, Padmanabhan V N. RADAR:An In-building RF-based User Location and Tracking System[C]//Proc. of IEEE INFOCOM'00. Tel Aviv, Israel:[s. n.],2000.
[12]唐鸿宾.微弱信号探测技术[M].南京大学出版社,1995,235-242.
[13]栗苹,施聚生,崔占忠.被动声定位系统的设计与应用[J].北京理工大学学报,1994(3):33-36.
[14]蔡宗义,赵俊渭,陈华伟.两种声学基阵被动定向性能的研究[J].声学与电子工程,2003(2):10—14.
[15]程翔,张河.高低四元阵定位算法及其精度分析[J].探测与控制学报、2006,28(4).
[16]林志斌,徐柏龄.基于传声器阵列的声源定位[J].电声技术,2004(5):19-22.
[17]吴喜录,陈庆生.直升机声目标定位系统分析.南京理工大学学报,1996(2):22-27.
[18]张元,陈庆生,吴喜录.被动声定位系统的计算机仿真.现代引信,1996(1):19-24.
[19]谢毅.战场目标识别技术研究:[博士后出站报告].北京:北京理工大学机电工程系,1998.
[20]刘闯,王洪洋,廖桂生.被动直升机声信号波大方向估计[J].工程应用,2005.
[21]严素青,黄冰.传感器阵列的声源定位研究[J].电声技术,2004-12.
[22]周胜海,郭淑红.基于低噪声运放的传感器前置放大器设计[J].仪表技术与传感器,2006.9.
[23]潘峰,秦丽,孟令军.具有声定位功能的无线传感器网络节点设计[J].计算机工程,2008.12.
[24]刘永春,陈琳.基于广义互相关时延估计算法声源定位的研究[J].中国科技论文在线,2008.
[25]崔玮玮,曹志刚,魏建强.声源定位中的延时估计技术[J].数据采集及处理2007年3月,第22卷第1期.
[26]Priyantha N, Chakraborty A, Balakrishnan H. The Cricket Location-support System[C]//Proc. of ACM MOBICOM. Boston, Massachusetts, USA:[s. n.],2000.
[27]Niculescu D, Nath B. Ad Hoc Positioning System Using AOA[C]//Proc. of IEEE INFOCOM'03. San Francisco, California, USA:[s. n.],2003.
[28]刘小刚.基于四元十字阵的声被动定位研究[D].南京:南京理工大学,2005.
[29]王昭,赵俊渭.空气声被动定位的误差分析[J].应用声学,2000,19(2):39-43.
[30]Zhang JB, Yan T, Stankovic J A, et al. Thunder:Towards Practical, Zero Cost Acoustic Localization for Outdoor Wireless Sensor Networks[J]. Mobile Computing and Communications Review,2007,11(1):15-28.
[31]张莉.基于传声器阵列的声源定位方法研究.电子科技大学学位论文,2007.
[32]曹学斌,郭相科,刘进忙.基于到达时差法的目标定位系统[J].指挥控制与仿真,2006.9.
[33]李哲,陈文聪,李杰.基于时延的被动声探测阵列综合仿真比较[J].探测与控制,2004(1).
[34]孙建伟,谭惠民.被动声目标定位与跟踪的实验研究[J].北京理工大学学报,1999(6).
[35]张元,陈庆生,吴喜录.被动声定位系统的计算机仿真[J].现代引信,1996(1).
[36]万建伟,石践,周良柱等.超声速运动目标的被动声定位算法研究[J].国防科技参 考,1998,19(4):36-40.
[37]靳莹,杨润泽.声测定位技术的研究现状[J].电声基础,2007.
[38]祝龙石.利用圆阵实现声目标的全空域被动定位[J].声学学报,1999,24(2):204-209.
[39]顾晓辉,王晓鸣.用双直角三角形阵对声目标定位的研究[J].声学技术,2003,22(1):44-47.
[40]行鸿彦,赵守国,邸继征.广义相关时延估计算法的自适应实现形式[J].西安石油学院学报:自然科学版,2001,16(6):47-51.
[41]马雯,黄建国.广义相关时延估计在被动定位系统中的应用研究[J].探测与控制学报,2000,22(3):51-54.
[42]周喜章.热释电传感器原理与应用.传感器世界。1996,002:38-42.
[43]贺凤成,王本.热释电探测器及其应用,红外技术,199.4,016:8-13.
[44]张昊飏,马旭,卓晴.基于电磁场检测的寻线智能车设计[J].2009.
[45]倪明,陈哲,胡永明.战场背景下的声信号的目标识别技术[J].压电与声光,1999.
[46]555时基集成电路应用[DB/OL].http://www.autoo.net/icdata/data_47248.html, 2009-04-22/2009-10-06.
[47]董平.电磁导引器电路设计及数据采集分析软件[J].物流技术,1999.
[48]郭峰,袁星军,余达太,原魁.自动导引车系统关键技术的研究[J].北京科技大学学报,1999.
[49]张向晖.声测定位原理及误差分析[J].电声技术,1997(3):6-7.
[50]陈华伟,赵俊渭等.两种声学阵列的定向精度分析及仿真[J].声学与电子工程,2001年第3期.
[2]陈佳奎.微弱信号探测[M].北京,中央广播电视大学出版社,1987.
[3]赵玉洁.声测定位技术的现状和发展趋势[J].声学与电子工程,1993年第4期.
[4]向瑾.基于四元十字阵的被动声定位技术研究.中北大学学位论文,2008.
[5]李晋.脉冲声源无源声定位探测技术研究.哈尔滨工业大学学位论文,2007.
[6]王皖君等.自动导引车导引技术研究现状与发展趋势[J].传感器与微系统,2009.
[7]张营.智能车辆定位技术研究[D].上海:上海交通大学机械与动力工程学院,2008.
[8]吕国云,许学忠.战场目标被动噪声识别技术[J].探测与控制学报。2001.
[9]刘贯领.声目标识别方法研究[D].南京,南京理工大学,2003.
[10]Savvides A, Han C C, Srivastava M. Dynamic Fine-grained Localization in Ad-hoc Networks of Sensors[C]//Proc. of ACM MOBICOM. Rome, Italy:[s. n.],2001.
[11]Bahl P, Padmanabhan V N. RADAR:An In-building RF-based User Location and Tracking System[C]//Proc. of IEEE INFOCOM'00. Tel Aviv, Israel:[s. n.],2000.
[12]唐鸿宾.微弱信号探测技术[M].南京大学出版社,1995,235-242.
[13]栗苹,施聚生,崔占忠.被动声定位系统的设计与应用[J].北京理工大学学报,1994(3):33-36.
[14]蔡宗义,赵俊渭,陈华伟.两种声学基阵被动定向性能的研究[J].声学与电子工程,2003(2):10—14.
[15]程翔,张河.高低四元阵定位算法及其精度分析[J].探测与控制学报、2006,28(4).
[16]林志斌,徐柏龄.基于传声器阵列的声源定位[J].电声技术,2004(5):19-22.
[17]吴喜录,陈庆生.直升机声目标定位系统分析.南京理工大学学报,1996(2):22-27.
[18]张元,陈庆生,吴喜录.被动声定位系统的计算机仿真.现代引信,1996(1):19-24.
[19]谢毅.战场目标识别技术研究:[博士后出站报告].北京:北京理工大学机电工程系,1998.
[20]刘闯,王洪洋,廖桂生.被动直升机声信号波大方向估计[J].工程应用,2005.
[21]严素青,黄冰.传感器阵列的声源定位研究[J].电声技术,2004-12.
[22]周胜海,郭淑红.基于低噪声运放的传感器前置放大器设计[J].仪表技术与传感器,2006.9.
[23]潘峰,秦丽,孟令军.具有声定位功能的无线传感器网络节点设计[J].计算机工程,2008.12.
[24]刘永春,陈琳.基于广义互相关时延估计算法声源定位的研究[J].中国科技论文在线,2008.
[25]崔玮玮,曹志刚,魏建强.声源定位中的延时估计技术[J].数据采集及处理2007年3月,第22卷第1期.
[26]Priyantha N, Chakraborty A, Balakrishnan H. The Cricket Location-support System[C]//Proc. of ACM MOBICOM. Boston, Massachusetts, USA:[s. n.],2000.
[27]Niculescu D, Nath B. Ad Hoc Positioning System Using AOA[C]//Proc. of IEEE INFOCOM'03. San Francisco, California, USA:[s. n.],2003.
[28]刘小刚.基于四元十字阵的声被动定位研究[D].南京:南京理工大学,2005.
[29]王昭,赵俊渭.空气声被动定位的误差分析[J].应用声学,2000,19(2):39-43.
[30]Zhang JB, Yan T, Stankovic J A, et al. Thunder:Towards Practical, Zero Cost Acoustic Localization for Outdoor Wireless Sensor Networks[J]. Mobile Computing and Communications Review,2007,11(1):15-28.
[31]张莉.基于传声器阵列的声源定位方法研究.电子科技大学学位论文,2007.
[32]曹学斌,郭相科,刘进忙.基于到达时差法的目标定位系统[J].指挥控制与仿真,2006.9.
[33]李哲,陈文聪,李杰.基于时延的被动声探测阵列综合仿真比较[J].探测与控制,2004(1).
[34]孙建伟,谭惠民.被动声目标定位与跟踪的实验研究[J].北京理工大学学报,1999(6).
[35]张元,陈庆生,吴喜录.被动声定位系统的计算机仿真[J].现代引信,1996(1).
[36]万建伟,石践,周良柱等.超声速运动目标的被动声定位算法研究[J].国防科技参 考,1998,19(4):36-40.
[37]靳莹,杨润泽.声测定位技术的研究现状[J].电声基础,2007.
[38]祝龙石.利用圆阵实现声目标的全空域被动定位[J].声学学报,1999,24(2):204-209.
[39]顾晓辉,王晓鸣.用双直角三角形阵对声目标定位的研究[J].声学技术,2003,22(1):44-47.
[40]行鸿彦,赵守国,邸继征.广义相关时延估计算法的自适应实现形式[J].西安石油学院学报:自然科学版,2001,16(6):47-51.
[41]马雯,黄建国.广义相关时延估计在被动定位系统中的应用研究[J].探测与控制学报,2000,22(3):51-54.
[42]周喜章.热释电传感器原理与应用.传感器世界。1996,002:38-42.
[43]贺凤成,王本.热释电探测器及其应用,红外技术,199.4,016:8-13.
[44]张昊飏,马旭,卓晴.基于电磁场检测的寻线智能车设计[J].2009.
[45]倪明,陈哲,胡永明.战场背景下的声信号的目标识别技术[J].压电与声光,1999.
[46]555时基集成电路应用[DB/OL].http://www.autoo.net/icdata/data_47248.html, 2009-04-22/2009-10-06.
[47]董平.电磁导引器电路设计及数据采集分析软件[J].物流技术,1999.
[48]郭峰,袁星军,余达太,原魁.自动导引车系统关键技术的研究[J].北京科技大学学报,1999.
[49]张向晖.声测定位原理及误差分析[J].电声技术,1997(3):6-7.
[50]陈华伟,赵俊渭等.两种声学阵列的定向精度分析及仿真[J].声学与电子工程,2001年第3期.