Unified Architecture for Security, Reliability, and Trust in Internet of Things

物联网安全性、可靠性和信任的统一架构

• 批准号: RGPIN-2020-06573
• 负责人: SAMPALLI, SRINIVAS
• 金额: $ 2.55万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=717828
• 关键词: Unified; Architecture; Security; Reliability; Trust

Internet of Things (IoT) technology is poised to revolutionize a multitude of application sectors in the next few years. IoT refers to networks of autonomous and uniquely identifiable “smart” objects with embedded processors that have sensing, computing, communicating, and service discovery capabilities. IoT promises enormous application benefits in the areas of smart critical infrastructure such as power grids, water supply, nuclear plants, connected health, telecommunications, environment, agriculture and defence. Security, reliability, and trust stand out as three critical research areas in the design of IoT before the technology can be successfully deployed. While there is a broad corpus of independent solutions for addressing security, reliability and trust in IoT networks, an integrated approach has met with limited success due to many inherent challenges. Firstly, IoT devices mainly consist of small sensors with limited computational power, storage and bandwidth which makes the deployment of traditional security algorithms infeasible. Secondly, threat exposure of IoT systems increases due to their integration with different wireless technologies, each with its own vulnerability. Thirdly, nonuniform traffic, unpredictable topology changes, differing node densities, high degree of mobility, and high bit error rates dictate communication among IoT devices. Finally, there is little consensus among trust mechanisms for IoT. The overarching goal of this research proposal is to build a unified architecture that integrates security, reliability and trust mechanisms in IoT networks. Towards the realization of this objective, this proposal will a) Investigate vulnerabilities, security threats, reliability and trust requirements specific to IoT; b) Perform analytics on IoT traffic data for modelling of attack and reliability vectors; c) Develop a context-aware framework for the design of a unified architecture for secure, reliable and trustworthy delivery of information over IoT networks; d) Experimentally validate the proposed architecture by developing and testing candidate applications on an IoT test bench. The novelty of the proposal is the design of an unified architecture that uses a context-aware framework consisting of three modules, namely, a cognitive module, an adaptive module, and an authentication module. There is a major demand for the design of mechanisms for secure, reliable and trustworthy information transfer in IoT networks, especially since such networks are being increasingly deployed for business, healthcare, government and defence applications. This would be one of the first research proposals to integrate a set of lightweight mechanisms for security, reliability and trust in IoT. Thus, this research will not only train valuable HQP by giving them the unique combination of knowledge and expertise in this area but also has the potential to pave the way for the design of next generation wireless networks.

物联网(IoT)技术将在未来几年给众多应用领域带来革命性的变化。物联网是指具有感知、计算、通信和服务发现能力的嵌入式处理器的自主和可唯一识别的“智能”对象的网络。物联网有望在电网、供水、核电站、联网医疗、电信、环境、农业和国防等智能关键基础设施领域带来巨大的应用效益。安全、可靠性和信任是物联网设计中的三个关键研究领域，然后才能成功部署该技术。虽然有广泛的独立解决方案来解决物联网网络的安全性、可靠性和信任度问题，但由于许多固有的挑战，集成方法的成功有限。首先，物联网设备主要由计算能力、存储和带宽有限的小型传感器组成，这使得传统安全算法的部署不可行。其次，物联网系统的威胁暴露增加，因为它们与不同的无线技术集成，每种技术都有自己的漏洞。第三，不均匀的流量、不可预测的拓扑变化、不同的节点密度、高移动性和高误码率决定了物联网设备之间的通信。最后，物联网信任机制之间几乎没有达成共识。 该研究方案的总体目标是构建一个集成了物联网网络中的安全、可靠性和信任机制的统一架构。为了实现这一目标，该建议将a)调查物联网特有的漏洞、安全威胁、可靠性和信任要求；b)对物联网流量数据进行分析，以建立攻击和可靠性向量的模型；c)开发一个情景感知框架，以设计用于在物联网网络上安全、可靠和可信地交付信息的统一架构；d)通过在物联网测试平台上开发和测试候选应用程序，对所提出的架构进行实验验证。该方案的新奇之处在于设计了一个统一的架构，该架构使用由三个模块组成的情景感知框架，即认知模块、自适应模块和身份验证模块。 对物联网网络中安全、可靠和值得信赖的信息传输机制的设计有很大的需求，特别是在这样的网络越来越多地被部署用于商业、医疗、政府和国防应用的情况下。这将是首批整合一套轻量级物联网安全、可靠性和信任机制的研究提案之一。因此，这项研究不仅将为HQP提供该领域的独特知识和专业知识组合，从而培养有价值的HQP，而且还有可能为下一代无线网络的设计铺平道路。