物品万维网资源管理框架研究与应用

李养群; 张登银

doi:10.11959/j.issn.2096-3750.2022.00271

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物品万维网资源管理框架研究与应用

理论与技术 | 更新时间：2024-06-05

- 物品万维网资源管理框架研究与应用
- Research and application of Web of things resource management framework
- 物联网学报 2022年6卷第2期页码：50-64
- 作者机构：
  
  1. 南京邮电大学物联网学院，江苏南京 210003
  2. 南京邮电大学江苏省宽带无线通信与物联网重点实验室，江苏南京 210003
- 作者简介：
  
  [ "李养群（1977−），男，博士，南京邮电大学物联网学院讲师，主要研究方向为物品万维网、区块链技术等" ]
  [ "张登银（1964− ），博士，南京邮电大学物联网学院教授，主要研究方向为智能信号处理、信息网络、信息安全等" ]
- 基金信息：
  
  国家自然科学基金资助项目;The National Natural Science Foundation of China(61972211)
- DOI：10.11959/j.issn.2096-3750.2022.00271
  中图分类号： TP391
- 纸质出版日期：2022-06-30，
  
  网络出版日期：2022-06，
- 稿件说明：
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李养群, 张登银. 物品万维网资源管理框架研究与应用[J]. 物联网学报, 2022,6(2):50-64.

YANGQUN LI, DENGYIN ZHANG. Research and application of Web of things resource management framework. [J]. Chinese journal on internet of things, 2022, 6(2): 50-64.
李养群, 张登银. 物品万维网资源管理框架研究与应用[J]. 物联网学报, 2022,6(2):50-64. DOI： 10.11959/j.issn.2096-3750.2022.00271.

YANGQUN LI, DENGYIN ZHANG. Research and application of Web of things resource management framework. [J]. Chinese journal on internet of things, 2022, 6(2): 50-64. DOI： 10.11959/j.issn.2096-3750.2022.00271.

摘要

物品万维网（WoT

Web of things）将万物通过Web相连在一起，实现物品（things）所提供的数据或服务等资源的共享，以充分实现它们的潜在价值。但这些资源分布于各地并且分属于不同组织，基于中央基础设施的 WoT 资源管理机制已无法满足当前应用规模不断扩展、需求快速变化、数据种类不断增加的新形势。针对这些新问题与新需求，提出了一种WoT资源管理框架（WoTRMF

Web of things resource management framework）。首先，在该框架的基础上对资源的分布式管理、资源高效发布与发现、资源的安全高效共享、资源统一管理平台等机制进行综述。接着，针对分布式管理需求，提出了一种基于地理位置的P2P技术以实现WoT应用的高可用性和高效资源管理；针对高效发布/发现需求，提出了基于概率主题的智能化WoT资源发布方法以实现资源的自动化分类及有序发布与存储；针对资源安全访问需求，提出了基于区块链的安全可信WoT资源共享机制。然后，针对资源统一管理需求，给出了该WoT资源管理框架的功能实现模型。最后，通过WoTRMF在智慧城市安全管理中的应用分析了其开放性、灵活性、可扩展性及智能化等特点。

Abstract

Web of things (WoT) connects all things together through the Web and realizes the sharing of resources

such as data or services provided by things

to fully implement their potential value.However

these resources are distributed in various places and belong to different organizations.The WoT resource management based on central infrastructure can no longer meet the new situation of continuous expansion of application scale

rapid changes in demand

and continuous increase of data types.In response to these new problems and new requirements

WoTRMF (Web of things resource management framework) was proposed.Firstly

based on this framework

the WoT resource management mechanism from the following aspects was reviewed

including distributed management of resources

efficient publish and discovery of resources

cost-effective

secure and efficient sharing of resources

and a unified resource management platform.Then

according to the requirement of distributed management

a P2P technology based on geographic location was proposed to realize distributed automatic management of WoT resources

so as to meet the high availability requirements of WoT applications and improve the efficiency of resource management.Aiming at the requirement of efficient resource publishing/discovery

an intelligent WoT resource publishing mechanism based on probabilistic topics was proposed to realize automatic classification and orderly publishing and storage of resources.Aiming at the security access requirements of resources

a secure and trusted WoT resource sharing mechanism based on blockchain was proposed.According to the requirement of unified resource management

the functional implementation model of WoTRMF was given.Finally

through the application case of WoTRMF framework in smart city security management

its characteristics of openness

flexibility

scalability and intelligence were analyzed.

关键词

物品万维网资源管理区块链概率主题管理平台智慧城市安全数字孪生

Keywords

Web of thingsresource managementblockchainprobabilistic topicmanagement platformsmart city securitydigital twin

references

Y. 2060:Overview of the internet of things[R]. 2012.

AL-FUQAHA A, GUIZANI M, MOHAMMADI M ,et al. Internet of Things:a survey on enabling technologies,protocols,and applications[J]. IEEE Communications Surveys ＆ Tutorials, 2015,17(4): 2347-2376.

吴振宇 . 基于 Web 的物联网应用体系架构和关键技术研究[D]. 北京:北京邮电大学, 2013.

WU Z Y . Research on web of things service environment architecture and key technologies[D]. Beijing:Beijing University of Posts and Telecommunications, 2013.

RAZZAQUE M A, MILOJEVIC-JEVRIC M, PALADE A ,et al. Middleware for internet of things:a survey[J]. IEEE internet of things Journal, 2016,3(1): 70-95.

STIRBU V, . Towards a RESTful plug and play experience in the web of things[C]// Proceedings of 2008 IEEE International Conference on Semantic Computing. Piscataway:IEEE Press, 2008: 512-517.

ZHAO S, YU L, CHENG B . A real-time web of things framework with customizable openness considering legacy devices[J]. Sensors (Basel,Switzerland), 2016,16(10): 1596.

NADIM I, ELGHAYAM Y, SADIQ A . Semantic discovery architecture for dynamic environments of web of things[C]// Proceedings of 2018 International Conference on Advanced Communication Technologies and Networking (CommNet). Piscataway:IEEE Press, 2018: 1-6.

RUTA M, SCIOSCIA F, PINTO A ,et al. CoAP-based collaborative sensor networks in the semantic web of things[J]. Journal of Ambient Intelligence and Humanized Computing, 2019,10(7): 2545-2562.

TOUSEAU L, SOMMER N . Contribution of the web of things and of the opportunistic computing to the smart agriculture:a practical experiment[J]. Future Internet, 2019,11(2): 33.

LE SOMMER N, TOUSEAU L, MAHÉO Y ,et al. A disruption-tolerant RESTful support for the web of things[C]// Proceedings of 2016 IEEE 4th International Conference on Future Internet of Things and Cloud (FiCloud). Piscataway:IEEE Press, 2016: 17-24.

OSTERMAIER B, KOVATSCH M, SANTINI S . Connecting things to the web using programmable low-power Wi-Fi modules[C]// WoT '11:Proceedings of the Second International Workshop on Web of Things. 2011: 1-6.

DUQUENNOY S, GRIMAUD G, VANDEWALLE J J . The web of things:interconnecting devices with high usability and performance[C]// Proceedings of 2009 International Conference on Embedded Software and Systems. Piscataway:IEEE Press, 2009: 323-330.

MAYER S, GUINARD D, TRIFA V . Facilitating the integration and interaction of real-world services for the web of things[C]// Proceedings of Urban Internet of Things-Towards Programmable Real-time Cities (UrbanIOT). 2010.

COLLINS J T, KNAPPER J, MCDERMOTT S J ,et al. Simplifying the OpenFlexure microscope software with the web of things[J]. Royal Society Open Science, 2021,8(11): 211158.

OLIVER S . WISSPR-a web-based infrastructure for sensor data streams sharing,processing and storage[D]. Eidgenössische Technische Hochschule Zürich, 2010.

MAYER S, GUINARD D, TRIFA V ,et al. Real-world service interaction with enterprise systems in dynamic manufacturing environments[EB]. 2020.

OSTERMAIER B, SCHLUP F, RÖMER K, . WebPlug:a framework for the web of things[C]// Proceedings of 2010 8th IEEE International Conference on Pervasive Computing and Communications Workshops. Piscataway:IEEE Press, 2010: 690-695.

GUINARD D, MUELLER M, PASQUIER-ROCHA J, . Giving RFID a REST:building a web-enabled EPCIS[C]// Proceedings of 2010 Internet of Things (IoT). Piscataway:IEEE Press, 2010: 1-8.

PINTUS A, CARBONI D, PIRAS A ,et al. Connecting smart things through web services orchestrations[M]// Current Trends in Web Engineering. Berlin,Heidelberg: Springer Berlin Heidelberg, 2010: 431-441.

International conference on mobile ubiquitous computing,systems,services and technologies - TOC[C]// Proceedings of International Conference on Mobile Ubiquitous Computing,Systems,Services and Technologies (UBICOMM'07). Piscataway:IEEE Press, 2007:v-viii.

SPIESS P, KARNOUSKOS S, SOUZA L ,et al. Reliable execution of business processes on dynamic networks of service-enabled devices[C]// Proceedings of 2009 7th IEEE International Conference on Industrial Informatics. Piscataway:IEEE Press, 2009: 533-538.

DAVIDYUK O, MILARA I S, RIEKKI J . CADEAU:Supporting autonomic and user-controlled application composition in ubiquitous environments[M]. Pervasive Computing and Communications Design and Deployment: Technologies,Trends and Applications,IGI Global, 2011: 74-102.

MORARU A, MLADENIC D, VUCNIK M ,et al. Exposing real world information for the web of things[C]// IIWeb '11:Proceedings of the 8th International Workshop on Information Integration on the Web:in conjunction with WWW 2011. 2011: 1-6.

PFISTERER D, ROMER K, BIMSCHAS D ,et al. SPITFIRE:toward a semantic web of things[J]. IEEE Communications Magazine, 2011,49(11): 40-48.

NAMBI S N A U, SARKAR C, PRASAD R V ,et al. A unified semantic knowledge base for IoT[C]// Proceedings of 2014 IEEE World Forum on Internet of Things. Piscataway:IEEE Press, 2014: 575-580.

BOUSSARD M, CHRISTOPHE B, LE BERRE O ,et al. Providing user support in web-of-things enabled smart spaces[C]// WoT '11:Proceedings of the Second International Workshop on Web of Things. 2011: 1-6.

李养群, 沈苏彬, 许斌 . 物品万维网技术综述[J]. 南京邮电大学学报(自然科学版), 2014,34(2): 32-42,56.

LI Y Q, SHEN S B, XU B . Technology of web of things:a survey[J]. Journal of Nanjing University of Posts and Telecommunications (Natural Science), 2014,34(2): 32-42,56.

Web of Things (WoT) Architecture W3C Candidate Recommendation[R]. 2019.

ITU-T Y . 2063:Framework of the web of things[R]. 2012.

ITU-T Y . 4414/H.623:Web of things service architecture[R]. 2012.

WOLF S, COOLEY R, BOROWCZAK M . S-CHIRP:securing communications in lightweight peer-to-peer networks in the IoT[J]. IEEE Potentials, 2019,38(1): 14-19.

TANGANELLI G, VALLATI C, MINGOZZI E . Edge-centric distributed discovery and access in the Internet of Things[J]. IEEE Internet of Things Journal, 2018,5(1): 425-438.

CHEN J . Devify:decentralized Internet of Things software framework for a peer-to-peer and interoperable IoT device[J]. ACM SIGBED Review, 2018,15(2): 31-36.

BATTAGLIA F, LO BELLO L . A novel JXTA-based architecture for implementing heterogenous networks of things[J]. Computer Communications, 2018(116): 35-62.

BENOMAR Z, LONGO F, MERLINO G ,et al. A cloud-based and dynamic DNS approach to enable the web of things[J]. IEEE Transactions on Network Science and Engineering, 2021,PP(99): 1-1.

MURTURI I, DUSTDAR S . A decentralized approach for resource discovery using metadata replication in edge networks[J]. IEEE Transactions on Services Computing, 2305,PP(99): 1-1.

DANG H V, TATIPAMULA M, NGUYEN H X . Cloud-based digital twinning for structural health monitoring using deep learning[J]. IEEE Transactions on Industrial Informatics, 2022,18(6): 3820-3830.

FAHEEM M R, ANEES T, HUSSAIN M . The web of things:findability taxonomy and challenges[J]. IEEE Access, 2019(7): 185028-185041.

AUTIOSALO J, SIEGEL J, TAMMI K . Twinbase:open-source server software for the digital twin web[J]. IEEE Access, 2021(9): 140779-140798.

LEI Z C, ZHOU H, HU W S ,et al. Toward a web-based digital twin thermal power plant[J]. IEEE Transactions on Industrial Informatics, 2022,18(3): 1716-1725.

LIU C, JIANG P Y, JIANG W L . Web-based digital twin modeling and remote control of cyber-physical production systems[J]. Robotics and Computer-Integrated Manufacturing, 2020(64): 101956.

BEZERRA J D H, DE SOUZA C T . smAR2t:a models at runtime architecture to interact with the web of things using augmented reality[C]// SBES 2019:Proceedings of the XXXIII Brazilian Symposium on Software Engineering. 2019: 124-129.

AGUZZI C, GIGLI L, SCIULLO L ,et al. From cloud to edge:seamless software migration at the era of the web of things[J]. IEEE Access, 2020,8: 228118-228135.

YU H, CAI H M, LIU Z Y ,et al. An automated metadata generation method for data lake of industrial WoT applications[J]. IEEE Transactions on Systems,Man,and Cybernetics:Systems, 9871,PP(99): 1-14.

PERERA C, VASILAKOS A V . A knowledge-based resource discovery for Internet of Things[J]. Knowledge-Based Systems, 2016,109: 122-136.

BARNAGHI P, SHETH A . On searching the Internet of Things:requirements and challenges[J]. IEEE Intelligent Systems, 2016,31(6): 71-75.

ZHOU Y C, DE S, WANG W ,et al. Search techniques for the web of things:a taxonomy and survey[J]. Sensors, 2016,16(5): 600.

QI L Y, HE Q, CHEN F F ,et al. Finding all You need:web APIs rec ommendation in web of things through keywords search[J]. IEEE Transactions on Computational Social Systems, 2019,6(5): 1063-1072.

KALLAB L, CHBEIR R, MRISSA M . Location-aware resource discovery and QoR-driven resource selection for hybrid web environments[J]. Sensors, 2021,21(20): 6835.

MAAMAR Z, FACI N, ELNAFFAR S ,et al. Semantic thingsourcing for the Internet of Things[J]. Concurrency and Computation:Practice and Experience, 2021:e6684.

BOTONAKIS S, TZAVARAS A, PETRAKIS E G M . iSWoT:service oriented architecture in the cloud for the semantic web of things[C]// Advanced Information Networking and Applications, 2020: 1201-1214.

CIMMINO A, POVEDA-VILLALÓN M, GARCÍA-CASTRO R . eWoT:a semantic interoperability approach for heterogeneous IoT ecosystems based on the web of things[J]. Sensors (Basel,Switzerland), 2020,20(3): 822.

RUTA M, SCIOSCIA F, IEVA S ,et al. A blockchain infrastructure for the semantic web of things[EB]. 2018.

VICTOR C, SEBASTIAN K, HARALD K . A framework for semantic discovery on the web of things[J]. Studies on the Semantic Web, 2018,36: 147-162.

RUTA M, SCIOSCIA F, PINTO A ,et al. CoAP-based collaborative sensor networks in the Semantic web of things[J]. Journal of Ambient Intelligence and Humanized Computing, 2019,10(7): 2545-2562.

KHADIR K, GUERMOUCHE N, MONTEIL T ,et al. Towards avatar-based discovery for IoT services using social networking and clustering mechanisms[C]// Proceedings of 2020 16th International Conference on Network and Service Management (CNSM). Piscataway:IEEE Press, 2020: 1-7.

ROBLES M I, SILVERAJAN B, NARENDRA N C . Web of things semantic functionality distance[C]// Proceedings of 2019 26th International Conference on Telecommunications (ICT). Piscataway:IEEE Press, 2019: 260-264.

EL HAJJI S, NITAJ A, CARLET C ,et al. Securing the web of things with role-based access control[C]// Proceedings of 1st International Conference on Codes,Cryptology,and Information Security (C2SI), 2015: 14-26.

ZHANG Y, LI B, LIU B ,et al. An attribute-based collaborative access control scheme using blockchain for IoT devices[J]. Electronics, 2020,9(2): 285.

The OAuth 2.0 Authorization Framework[R]. 2012.

SCIANCALEPORE S, PIRO G, CALDAROLA D ,et al. OAuth-IoT:an access control framework for the Internet of Things based on open standards[C]// Proceedings of 2017 IEEE Symposium on Computers and Communications. Piscataway:IEEE Press, 2017: 676-681.

CIRANI S, PICONE M, GONIZZI P ,et al. IoT-OAS:an OAuth-based authorization service architecture for secure services in IoT scenarios[J]. IEEE Sensors Journal, 2015,15(2): 1224-1234.

OH S R, KIM Y G, CHO S . An interoperable access control framework for diverse IoT platforms based on OAuth and role[J]. Sensors (Basel,Switzerland), 2019,19(8): 1884.

NOVO O . Blockchain meets IoT:an architecture for scalable access management in IoT[J]. IEEE Internet of Things Journal, 2018,5(2): 1184-1195.

ZHANG Y Y, KASAHARA S, SHEN Y L ,et al. Smart contract-based access control for the Internet of Things[J]. IEEE Internet of Things Journal, 2019,6(2): 1594-1605.

PAN J L, WANG J Y, HESTER A ,et al. EdgeChain:an edge-IoT framework and prototype based on blockchain and smart contracts[J]. IEEE Internet of Things Journal, 2019,6(3): 4719-4732.

OUADDAH A, ABOU ELKALAM A, AIT OUAHMAN A . FairAccess:a new blockchain-based access control framework for the Internet of Things[J]. Security and Communication Networks, 2016,9(18): 5943-5964.

刘敖迪, 杜学绘, 王娜 ,等. 基于区块链的大数据访问控制机制[J]. 软件学报, 2019,30(9): 2636-2654.

LIU A D, DU X H, WANG N ,et al. Blockchain-based access control mechanism for big data[J]. Journal of Software, 2019,30(9): 2636-2654.

HAMDAOUI B, ALKALBANI M, RAYES A ,et al. IoTShare:a blockchain-enabled IoT resource sharing on-demand protocol for smart city situation-awareness applications[J]. IEEE Internet of Things Journal, 2020,7(10): 10548-10561.

CHIU W Y, MENG W Z, JENSEN C D . My data,my control:a secure data sharing and access scheme over blockchain[J]. Journal of Information Security and Applications, 2021,63:103020.

CRUZ J P, KAJI Y, YANAI N . RBAC-SC:role-based access control using smart contract[J]. IEEE Access, 2018,6: 12240-12251.

BELLI L, CIRANI S, DAVOLI L ,et al. Design and deployment of an IoT application-oriented testbed[J]. Computer, 2015,48(9): 32-40.

Fit IOT-LAB[EB]. 2012.

SOTRES P, SANTANA J R, SÁNCHEZ L, ,et al. Practical lessons from the deployment and management of a smart city Internet-of-things infrastructure:the SmartSantander testbed case[J]. IEEE Access, 2017(5): 14309-14322.

SÁNCHEZ L, GUTIÉRREZ V, GALACH J A ,et al. SmartSantander:experimentation and service provision in the smart city[C]// 16th International Symposium on Wireless Personal Multimedia Communications, 2013: 4-9.

DA CRUZ M A A, RODRIGUES J J P C, AL-MUHTADI J ,et al. A reference model for internet of things middleware[J]. IEEE Internet of Things Journal, 2018,5(2): 871-883.

沈苏彬, 杨震 . 物联网体系结构及其标准化[J]. 南京邮电大学学报(自然科学版), 2015,35(1): 1-18.

SHEN S B, YANG Z . Architecture of internet of things and its standardization[J]. Journal of Nanjing University of Posts and Telecommunications (Natural Science Edition), 2015,35(1): 1-18.

SCIULLO L, GIGLI L, TROTTA A ,et al. WoT Store:managing resources and applications on the web of things[J]. Internet of Things, 2020,9:100164.

D’ONOFRIO S, FRANZELLI S, PORTMANN E ,et al. Advancing Cognitive Cities with the web of things new advances in the internet of things[EB]. 2018.

HE Q, YAN J, YANG Y ,et al. A decentralized service discovery approach on peer-to-peer networks[J]. IEEE Transactions on Services Computing, 2013,6(1): 64-75.

魏强, 金芝, 许焱 . 基于概率主题模型的物联网服务发现[J]. 软件学报, 2014,25(8): 1640-1658.

WEI Q, JIN Z, XU Y . Service discovery for internet of things based on probabilistic topic model[J]. Journal of Software, 2014,25(8): 1640-1658.

PEREIRA J, BATISTA T, CAVALCANTE E ,et al. A platform for integrating heterogeneous data and developing smart city applications[J]. Future Generation Computer Systems, 2022,128: 552-566.

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