物联网运维系统标准化技术的研究
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摘要
从物联网概念的提出到现在,物联网技术飞速发展。世界各国都在开展物联网的研究。物联网被称为继计算机、互联网之后,世界信息产业的第三次浪潮。随着物联网产业链的飞速发展,物联网技术的标准化已成为目前亟待解决的问题。
目前世界标准化组织已经提出了物联网四层标准体系结构。从下到上分为感知层、传输层、处理层和应用层。在感知层中,对WSN和RIFD的标准已经进行了制定,这包括EPCGlobal提出的EPC标准和IEEE组织提出的IEEE802.15.4标准等等。在传输层标准化方面,主要对移动通信网络协议进行了协议加强。在处理层,提出了数据处理标准,如ETSI M2M TC制定了M2M的功能架构。在应用层,目前的标准化工作侧重于大的规模化的行业应用,如智能电网标准和IEC TC65制定的工业监控类的标准。
物联网运维系统跨越处理层和应用层。通过分析国内外物联网运维系统的研究动态,本文提出了物联网运维系统的标准化,给出物联网运维系统的标准化体系模型。
物联网运维系统依据其跨越的两个层次,分别进行标准化设计。在数据处理层,遵循数据处理流程;在应用层,纵向方面采用基于ITIL的业务流程(用户可以自定义流程),横向方面由于物联网运维涉及到各行各业,因此功能模块各异,遵循不同的行业标准(比如智能电网、智能交通和智能物流等等)。在应用层横向方面本文以智能电网为例,来论述智能电网运维系统中的最小功能集合。另外论述了贯穿两层的安全管理,各层具有各自的安全处理策略。
最后,针对不同行业的应用,提出物联网运维系统的二次功能扩展,对二次开发接口的原理进行了论述,并以某一物联网运维系统WSN功能模块添加为例进行了阐述。此二次功能扩展方法简化了物联网运维系统功能的扩展。
From the Internet of Things concept proposing to now, the technologies of the Internet of Things rapidly develop. All countries in the world start the research of the Internet of Things. The Internet of Things is called as the third wave of information industry after computer and internet. Along with the rapid development of the Internet of Things industry chain, the standardization of the Internet of Things technologies has become a problem to be solved at present.
The current world standardization organization has put forward four layers standard system structure of the Internet of Things.It is divided into sensor layer, the transport layer, processing layer and the application layer from bottom to top. In the sensor layer,the standardization of the WSN and RIFD has formulated, including the EPC standards proposed by EPCGlobal and IEEE802.15.4standard proposed by IEEE organization and so on. In the transport layer standardization, mainly strengthen for the mobile communication network protocols. In the processing layer, put forward the data processing standards, such as ETSI M2M TC formulated the M2M function architecture. In the application layer, the standardization work focused on large scale industry applications, such as intelligent power grids standards and industrial control standard set by IEC TC65.
Operation and maintenance system of the Internet of Things cross the processing layer and the application layer. Through the dynamic research analysis of operation and maintenance system of the Internet of Things in home and abroad, this paper puts forward that the standardization of operation and maintenance system of the Internet of Things, and give the standardization system model of operation and maintenance system of the Internet of Things.
The operation and maintenance system of the Internet of Things carry on the standard design respectively according to crossing the two layers. In data processing layer, follow the data processing flow; In the application layer, adopt the business flow based on ITIL (the user can define flows) in longitudinal aspects; the operation and maintenance system of the Internet of Things involves network all walks of life in horizon, so function modules are different and follow different dustry standard (such as intelligent power grids, intelligent traffic and intelligent logistics, etc.). This paper takes the intelligent power grids as an example in horizon fact of the application layer, discusses the minimum function set of the intelligent power grids operation and maintenance system. Also discuss security management throughout the two layers, each layer has its own safety treatment strategies.
At last, according to the application of different industries,the paper puts forward the second fuction expansion of the operation and maintenance system of the Internet of Things, and discuss the theory of the second development interface. And take WSN module function adding of certain operation and maintenance system of the Internet of Things for example to expound it. The second function expansion method simplifies the function expansion of operation and maintenance of the Internet of Things.
目前世界标准化组织已经提出了物联网四层标准体系结构。从下到上分为感知层、传输层、处理层和应用层。在感知层中,对WSN和RIFD的标准已经进行了制定,这包括EPCGlobal提出的EPC标准和IEEE组织提出的IEEE802.15.4标准等等。在传输层标准化方面,主要对移动通信网络协议进行了协议加强。在处理层,提出了数据处理标准,如ETSI M2M TC制定了M2M的功能架构。在应用层,目前的标准化工作侧重于大的规模化的行业应用,如智能电网标准和IEC TC65制定的工业监控类的标准。
物联网运维系统跨越处理层和应用层。通过分析国内外物联网运维系统的研究动态,本文提出了物联网运维系统的标准化,给出物联网运维系统的标准化体系模型。
物联网运维系统依据其跨越的两个层次,分别进行标准化设计。在数据处理层,遵循数据处理流程;在应用层,纵向方面采用基于ITIL的业务流程(用户可以自定义流程),横向方面由于物联网运维涉及到各行各业,因此功能模块各异,遵循不同的行业标准(比如智能电网、智能交通和智能物流等等)。在应用层横向方面本文以智能电网为例,来论述智能电网运维系统中的最小功能集合。另外论述了贯穿两层的安全管理,各层具有各自的安全处理策略。
最后,针对不同行业的应用,提出物联网运维系统的二次功能扩展,对二次开发接口的原理进行了论述,并以某一物联网运维系统WSN功能模块添加为例进行了阐述。此二次功能扩展方法简化了物联网运维系统功能的扩展。
From the Internet of Things concept proposing to now, the technologies of the Internet of Things rapidly develop. All countries in the world start the research of the Internet of Things. The Internet of Things is called as the third wave of information industry after computer and internet. Along with the rapid development of the Internet of Things industry chain, the standardization of the Internet of Things technologies has become a problem to be solved at present.
The current world standardization organization has put forward four layers standard system structure of the Internet of Things.It is divided into sensor layer, the transport layer, processing layer and the application layer from bottom to top. In the sensor layer,the standardization of the WSN and RIFD has formulated, including the EPC standards proposed by EPCGlobal and IEEE802.15.4standard proposed by IEEE organization and so on. In the transport layer standardization, mainly strengthen for the mobile communication network protocols. In the processing layer, put forward the data processing standards, such as ETSI M2M TC formulated the M2M function architecture. In the application layer, the standardization work focused on large scale industry applications, such as intelligent power grids standards and industrial control standard set by IEC TC65.
Operation and maintenance system of the Internet of Things cross the processing layer and the application layer. Through the dynamic research analysis of operation and maintenance system of the Internet of Things in home and abroad, this paper puts forward that the standardization of operation and maintenance system of the Internet of Things, and give the standardization system model of operation and maintenance system of the Internet of Things.
The operation and maintenance system of the Internet of Things carry on the standard design respectively according to crossing the two layers. In data processing layer, follow the data processing flow; In the application layer, adopt the business flow based on ITIL (the user can define flows) in longitudinal aspects; the operation and maintenance system of the Internet of Things involves network all walks of life in horizon, so function modules are different and follow different dustry standard (such as intelligent power grids, intelligent traffic and intelligent logistics, etc.). This paper takes the intelligent power grids as an example in horizon fact of the application layer, discusses the minimum function set of the intelligent power grids operation and maintenance system. Also discuss security management throughout the two layers, each layer has its own safety treatment strategies.
At last, according to the application of different industries,the paper puts forward the second fuction expansion of the operation and maintenance system of the Internet of Things, and discuss the theory of the second development interface. And take WSN module function adding of certain operation and maintenance system of the Internet of Things for example to expound it. The second function expansion method simplifies the function expansion of operation and maintenance of the Internet of Things.
引文
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[2]王亚唯.物联网发展综述[J].科技信息,2010,(3):37,7.
[3]马忠梅,孙娟,李奇.物联工程专业课程体系与实践探讨[J].单片机与嵌入式系统应用,2011,(10):1-4.
[4]周霞,薛晓磊.基于物联网技术的消防安全系统的设计[J].数字技术与应用,2010,(10):11.
[5]谢招犇,刘万蓉,谢静如.依托物联网技术促进农业信息化[J].安徽农业科学,2011,(36):22821-22822,22832.
[6陈山枝.关于我国推进智慧城市的思考与建设——从我国社会紧急发展及转型的视角[J].电信科学,2011,(11).
[7]魏葆春.物联网技术及其应用分析与研究[J].物联网技术,2011,(9).
[8]卞钧霈,崔优凯,潘志炎.物联网在浙江交通应用的设想[J].公路,2010,(8).
[9]卫菊红.基于RIFD技术的物联网在现代物流中的应用[J].电子世界,2011,(15).
[10]舒文琼.感知中国未来——解密无锡国家传感信息中心[J].通信世界,2010,(23).
[11]陈宝国.新一轮信息技术革命浪潮对我国的影响[J].科技决策,2011,(11).
[12]孙秀英,于正永,郭城.浅谈物联网的组网技术与应用[J].科技信息,2010,(26).
[13]王昊哲.基于节点智能交互的物联网数据处理研究[D].大连:大连理工大学,2011.
[14]宋俊德.浅谈物联网的现状和未来[J].移动通信,2010,(15):8-10.
[15]龙燕,韦运玲.制约物联网发展的因素[J].通信管理与技术,2011(1),42.
[16]温家宝.十一届人大三次会议上的政府工作报告[R].北京,2010年
[17]欧盟第七框架RFID和互联网项目组报告[R],2009年9月.
[18]王汝传,孙力娟.物联网技术导论[M].北京:清华大学出版社,2011年9月第一版.
[19]伍新华,陆丽萍.物联网工程技术[M].北京:清华大学出版社,2011年8月第一版.
[20]李磊,陈静.物联网感知层中RFID系统安全解决方案[J].网络安全技术与应 用,2011,(6):34-36.
[21]Jeremy Landt.The history of RFID.IEEE. Volume:24 Issue:4.8.11.2005.
[22]刘利民,肖德宝,李琳等.物联网感知层中RFID的信息安全对策研究[J].武汉理工大学学报,2010年10月:79-81.
[23]刘云浩.物联网导论[M].北京:科学出版社,2010年12月,第一版.
[24]韩腾.物联网体系结构[J],201].
[25]Peipei Fu, Limin Liu, Debao Xiao. A Three tier Architecture of The Internet of Things Management, ICCNT2011.
[26]汇文.超高频电子标签与EPC标准,2011.
[27]张鹏明,李洪烈,刘水RFID(Radio Frequency Identification)在航空装备保障中的应用探析[J].科技信息,2008,(17):353.
[28]肖巍.基于Alien阅读器的RFID技术研究[J].长春师范学院学报,2010,(12):34-37.
[29]白承森,马志新,詹建.如何提高RFID系统数据读取率[J].微计算机信息,2009,(8):246-247,300.
[30]http://www.233.com/ec/fudao/20070919/10464847.html.
[31]党子磊.后勤物资仓储可视化与实时监控系统研究与实现[J].科学信息,2010年30期.
[32]百度百科http://baike.baidu.com/view/3609604.htm.
[33]陈晓凤.物联网技术在水产品冷链物流中的应用[J].物流工程和管理,2010,33(12):59-61.
[34]http://www.rfidinfo.com.cn/Tech/n13021.html.
[35]http://www.rfidchina.org/tech/readinfos.27493.306.html.
[36]谢希仁.计算机网络(第五版)[M].北京:电子工业出版社,2009.
[37]周斌,唐劲松,张学波.基于IEEE 1451.4的智能水听器设计[J].舰船电子工程2011,(11):15-159.
[38]章韵,宋汝芸,陈志等基于簇头选择的移动传感网拓扑控制算法研究[J].传感技术学报2011,(11):1602-1606
[39]张敏.面向海量数据的物联网空间数据交换平台建设,第七届数字中国发展高层论坛暨信息主管峰会,2010.
[40]甘勇,郑富娥,吉星等RFID中间件关键技术研究[J].电子技术应用,2007,(9):130-132.
[41]董丽峰RFID中间件技术在物联网中的应用及研究[J].黑龙江科技信息,2010,(10):74,73.
[42]何云峰.关联规则算法研究及在股市中的应用[D].重庆:西南交通大学,2006.
[43]李莉,孙华,张振宇.蜜罐技术在校园网络安全中的应用研究[M].新疆大学学报(自然科学版),2011,28(4):478-481.
[44]刘宴兵,胡文平.物联网安全模型及关键技术[J].数字通信,2010.
[45]秦学.被动监听检测技术的研究与实现[D].贵州:贵州大学,2007.
[46]杨庚,许建,陈伟等.物联网安全特征与关键技术[J].南京邮电大学学报,2010,(4).
[47]苏伟平.基于IP的智能电网网络安全体系[J].科技资信,2010,No.26.
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