Grid Cryptographic Simulation: A Simulator to Evaluate the Scalability of the X.509 Standard in the Smart Grid

PKI may be pushed beyond known limits when scaled to some visions of the smart grid; our research developed a simulation, Grid Cryptographic Simulation (GCS), to evaluate these potential issues, identify cryptographic bottlenecks, and evaluate tradeoffs between performance and security. Ultimately, GCS can be used to identify scalability challenges and suggest improvements to make PKI more efficient, effective, and scalable before it is deployed in the envisioned smart grid

Security assessment of the smart grid : a review focusing on the NAN architecture

Abstract: This paper presents a comprehensive review on the security aspect of the smart grid communication network. The paper focus on the Neighborhood Area Network (NAN) cybersecurity and it laid emphasis on how the NAN architecture is such an attractive target to intruders and attackers. The paper aims at summarizing recent research efforts on some of the attacks and the various techniques employed in tackling them as they were discussed in recent literatures and research works. Furthermore, the paper presents a detailed review on the smart grid communication layers, wireless technology standards, networks and the security challenges the grid is currently facing. The work concludes by explaining current and future directions NAN communication security could consider in terms of data privacy measures. The data privacy measures are discussed in terms of prevention and detection techniques

Efficient Key Management Schemes for Smart Grid

With the increasing digitization of different components of Smart Grid by incorporating smart(er) devices, there is an ongoing effort to deploy them for various applications. However, if these devices are compromised, they can reveal sensitive information from such systems. Therefore, securing them against cyber-attacks may represent the first step towards the protection of the critical infrastructure. Nevertheless, realization of the desirable security features such as confidentiality, integrity and authentication relies entirely on cryptographic keys that can be either symmetric or asymmetric. A major need, along with this, is to deal with managing these keys for a large number of devices in Smart Grid. While such key management can be easily addressed by transferring the existing protocols to Smart Grid domain, this is not an easy task, as one needs to deal with the limitations of the current communication infrastructures and resource-constrained devices in Smart Grid. In general, effective mechanisms for Smart Grid security must guarantee the security of the applications by managing (1) key revocation; and (2) key exchange. Moreover, such management should be provided without compromising the general performance of the Smart Grid applications and thus needs to incur minimal overhead to Smart Grid systems. This dissertation aims to fill this gap by proposing specialized key management techniques for resource and communication constrained Smart Grid environments. Specifically, motivated by the need of reducing the revocation management overhead, we first present a distributed public key revocation management scheme for Advanced Metering Infrastructure (AMI) by utilizing distributed hash trees (DHTs). The basic idea is to enable sharing of the burden among smart meters to reduce the overall overhead. Second, we propose another revocation management scheme by utilizing cryptographic accumulators, which reduces the space requirements for revocation information significantly. Finally, we turn our attention to symmetric key exchange problem and propose a 0-Round Trip Time (RTT) message exchange scheme to minimize the message exchanges. This scheme enables a lightweight yet secure symmetric key-exchange between field devices and the control center in Smart Gird by utilizing a dynamic hash chain mechanism. The evaluation of the proposed approaches show that they significantly out-perform existing conventional approaches

Advanced Metering Infrastructure Based on Smart Meters in Smart Grid

Due to lack of situational awareness, automated analysis, poor visibility, and mechanical switches, today\u27s electric power grid has been aging and ill‐suited to the demand for electricity, which has gradually increased, in the twenty‐first century. Besides, the global climate change and the greenhouse gas emissions on the Earth caused by the electricity industries, the growing population, one‐way communication, equipment failures, energy storage problems, the capacity limitations of electricity generation, decrease in fossil fuels, and resilience problems put more stress on the existing power grid. Consequently, the smart grid (SG) has emerged to address these challenges. To realize the SG, an advanced metering infrastructure (AMI) based on smart meters is the most important key

Internet of Things Applications as Energy Internet in Smart Grids and Smart Environments

Energy Internet (EI) has been recently introduced as a new concept, which aims to evolve smart grids by integrating several energy forms into an extremely flexible and effective grid. In this paper, we have comprehensively analyzed Internet of Things (IoT) applications enabled for smart grids and smart environments, such as smart cities, smart homes, smart metering, and energy management infrastructures to investigate the development of the EI based IoT applications. These applications are promising key areas of the EI concept, since the IoT is considered one of the most important driving factors of the EI. Moreover, we discussed the challenges, open issues, and future research opportunities for the EI concept based on IoT applications and addressed some important research areas

The role of communication systems in smart grids: Architectures, technical solutions and research challenges

The purpose of this survey is to present a critical overview of smart grid concepts, with a special focus on the role that communication, networking and middleware technologies will have in the transformation of existing electric power systems into smart grids. First of all we elaborate on the key technological, economical and societal drivers for the development of smart grids. By adopting a data-centric perspective we present a conceptual model of communication systems for smart grids, and we identify functional components, technologies, network topologies and communication services that are needed to support smart grid communications. Then, we introduce the fundamental research challenges in this field including communication reliability and timeliness, QoS support, data management services, and autonomic behaviors. Finally, we discuss the main solutions proposed in the literature for each of them, and we identify possible future research directions

Security and Privacy for Green IoT-based Agriculture: Review, Blockchain solutions, and Challenges

open access articleThis paper presents research challenges on security and privacy issues in the field of green IoT-based agriculture. We start by describing a four-tier green IoT-based agriculture architecture and summarizing the existing surveys that deal with smart agriculture. Then, we provide a classification of threat models against green IoT-based agriculture into five categories, including, attacks against privacy, authentication, confidentiality, availability, and integrity properties. Moreover, we provide a taxonomy and a side-by-side comparison of the state-of-the-art methods toward secure and privacy-preserving technologies for IoT applications and how they will be adapted for green IoT-based agriculture. In addition, we analyze the privacy-oriented blockchain-based solutions as well as consensus algorithms for IoT applications and how they will be adapted for green IoT-based agriculture. Based on the current survey, we highlight open research challenges and discuss possible future research directions in the security and privacy of green IoT-based agriculture

Confidentiality, integrity and non-repudiation in smartgrids

Tese de mestrado em Segurança Informática, apresentada à Universidade de Lisboa, através da Faculdade de Ciências, 2011No actual contexto macroeconómico mundial é essencial a adopção de novas formas de geração de energia, alternativas à utilização de recursos fósseis, combinada com os objectivos de fiabilidade e qualidade dos fornecimentos e de indução de competitividade nos mercados. Torna-se necessário produzir, transportar e distribuir energia de forma sustentável sem prejudicar o ecossistema. A visão de uma infraestrutura com maior controlo, onde redes, produtores e consumidores têm papeis significativamente mais activos, está a provocar uma mudança de paradigma nas redes eléctricas e na sua gestão que se materializa no conceito das Smart Grids. Para obter um elevado nível de controlo de operação da rede, necessário para a concretização das funcionalidades prometidas pelas Smart Grids, a arquitectura terá que evoluir de modo a comportar um maior número de unidades remotas inteligentes, o desenvolvimento de novos sistemas técnicos e comerciais, o aumento de trocas de mensagens entre aplicações e a interligações entre diversas redes. Esta complexidade é bastante maior daquela que poderemos encontrar nas actuais infra-estruturas de sistemas de informação para a transmissão e distribuição de energia eléctrica e apresenta novos desafios no que diz respeito à disponibilidade da rede e, em particular, à sua segurança. Os novos equipamentos, aplicações, hardware, protocolos de comunicação, operação e administração da rede vão introduzir novas potenciais vulnerabilidades que podem ser exploradas por indivíduos mal intencionados ou simplesmente por erros de operação. Esta preocupação acerca da disponibilidade e segurança da rede de energia eléctrica do futuro evidenciam a importância que assumem a segurança e disponibilidade da infra-estrutura dos sistemas de informação e comunicações que a suportam. Este trabalho propõem-se analisar a confiabilidade das Smart Grids no que diz respeito aos seus aspectos de segurança de tecnologias de informação, incidindo em particular no projecto Português de Smart Grid denominado InovGrid. Este projecto de investigação irá descrever as funcionalidades da arquitectura InovGrid fazendo uma análise detalhada dos vectores de ataque e os riscos eminentes associados à sua implementação. Este estudo irá avaliar e propor soluções no domínio da autenticidade, confidencialidade e não-repudiação de informação numa arquitectura peculiar e heterogenia com a das Smart Grids.In the current global macroeconomic context is essential to adopt new ways of generating energy alternatives to fossil fuels, combined with the objectives of reliability and quality of delivery and induction of competitiveness in markets. It is necessary to produce, transport and distribute energy in a sustainable way without harming the ecosystem. The vision of an infrastructure with more control, where networks, producers and consumers have significantly more active roles, is causing a paradigm shift in electricity networks and their operations that is embodied in the concept of Smart Grids. To obtain a high level of control required to achieve the new features promised by Smart Grids, the architecture will need to comprise more intelligent remote terminal units, the development of new technical and commercial systems, the increase of the number of messages exchange between applications and also interconnections between enterprise networks. This complexity, far higher than found in present transmission and distribution infrastructures, will bring several challenges considering network reliability and security in particular. All the new devices, applications, hardware, communication protocols, network operations and administration will introduce potential vulnerabilities that might be explored by malicious users or simple by erroneous actions from a variety of external and internal sources. This concern about security and reliability of the future power grids increase the importance of the information technology and communications infrastructures and their security. This work proposes to analyze Smart Grid’s reliability regarding its information technology security but focusing the study in the Portuguese Smart Grid project implementation, named as InovGrid. It will describe the functionalities of the InovGrid architecture providing a detailed analysis of its attack vectors and the eminent risks associated with the implementation. It will propose and analysis solutions for confidentiality, authenticity and non-repudiation aspects in such peculiar and heterogeneous networks