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A lightweight framework for secure life-logging in smart environments
As the world becomes an interconnected network where objects and humans interact with each other, new challenges and threats appear in the ecosystem. In this interconnected world, smart objects have an important role in giving users the chance for life-logging in smart environments. However, smart devices have several limitations with regards to memory, resources and computation power, hindering the opportunity to apply well-established security algorithms and techniques for secure life-logging on the Internet of Things (IoT) domain. The need for secure and trustworthy life-logging in smart environments is vital, thus, a lightweight approach has to be considered to overcome the constraints of smart objects. The purpose of this paper is to present in details the current topics of life-logging in smart environments, while describing interconnection issues, security threats and suggesting a lightweight framework for ensuring security, privacy and trustworthy life-logging. In order to investigate the efficiency of the lightweight framework and the impact of the security attacks on energy consumption, an experimental test-bed was developed including two interconnected users and one smart attacker, who attempts to intercept transmitted messages or interfere with the communication link. Several mitigation factors, such as power control, channel assignment and AES-128 encryption were pplied for secure life-logging. Finally, research into the degradation of the consumed energy regarding the described intrusions is presented
SoK: A Systematic Review of TEE Usage for Developing Trusted Applications
Trusted Execution Environments (TEEs) are a feature of modern central
processing units (CPUs) that aim to provide a high assurance, isolated
environment in which to run workloads that demand both confidentiality and
integrity. Hardware and software components in the CPU isolate workloads,
commonly referred to as Trusted Applications (TAs), from the main operating
system (OS). This article aims to analyse the TEE ecosystem, determine its
usability, and suggest improvements where necessary to make adoption easier. To
better understand TEE usage, we gathered academic and practical examples from a
total of 223 references. We summarise the literature and provide a publication
timeline, along with insights into the evolution of TEE research and
deployment. We categorise TAs into major groups and analyse the tools available
to developers. Lastly, we evaluate trusted container projects, test
performance, and identify the requirements for migrating applications inside
them.Comment: In The 18th International Conference on Availability, Reliability and
Security (ARES 2023), August 29 -- September 01, 2023, Benevento, Italy. 15
page
PluralisMAC: a generic multi-MAC framework for heterogeneous, multiservice wireless networks, applied to smart containers
Developing energy-efficient MAC protocols for lightweight wireless systems has been a challenging task for decades because of the specific requirements of various applications and the varying environments in which wireless systems are deployed. Many MAC protocols for wireless networks have been proposed, often custom-made for a specific application. It is clear that one MAC does not fit all the requirements. So, how should a MAC layer deal with an application that has several modes (each with different requirements) or with the deployment of another application during the lifetime of the system? Especially in a mobile wireless system, like Smart Monitoring of Containers, we cannot know in advance the application state (empty container versus stuffed container). Dynamic switching between different energy-efficient MAC strategies is needed. Our architecture, called PluralisMAC, contains a generic multi-MAC framework and a generic neighbour monitoring and filtering framework. To validate the real-world feasibility of our architecture, we have implemented it in TinyOS and have done experiments on the TMote Sky nodes in the w-iLab.t testbed. Experimental results show that dynamic switching between MAC strategies is possible with minimal receive chain overhead, while meeting the various application requirements (reliability and low-energy consumption)
Towards a Secure Smart Grid Storage Communications Gateway
This research in progress paper describes the role of cyber security measures
undertaken in an ICT system for integrating electric storage technologies into
the grid. To do so, it defines security requirements for a communications
gateway and gives detailed information and hands-on configuration advice on
node and communication line security, data storage, coping with backend M2M
communications protocols and examines privacy issues. The presented research
paves the road for developing secure smart energy communications devices that
allow enhancing energy efficiency. The described measures are implemented in an
actual gateway device within the HORIZON 2020 project STORY, which aims at
developing new ways to use storage and demonstrating these on six different
demonstration sites.Comment: 6 pages, 2 figure
Securing the Internet of Things: Leveraging Blockchain for Enhanced Trust and Data Integrity
The rapid proliferation of the Internet of Things (IoT) has transformed various sectors, enabling unprecedented connectivity and automation. However, this connectivity also introduces significant security challenges, as IoT devices often operate in decentralized and heterogeneous environments, making them vulnerable to various cyber threats. Traditional security measures fall short in addressing these challenges, necessitating innovative solutions to ensure the integrity, confidentiality, and authenticity of data within IoT networks. Blockchain technology, with its decentralized and immutable nature, offers a promising solution to enhance the security of IoT systems. By leveraging blockchain, IoT networks can achieve a higher level of trust and data integrity. The inherent features of blockchain, such as cryptographic security, consensus mechanisms, and decentralized ledger technology, provide robust protection against data tampering, unauthorized access, and other malicious activities. This paper explores the integration of blockchain technology into IoT security frameworks. We discuss the potential benefits of using blockchain for securing IoT devices, including improved transparency, traceability, and accountability. Furthermore, we analyze various blockchain-based IoT security models and architectures proposed in recent research, highlighting their strengths and limitations. In addition, this paper addresses the challenges associated with the implementation of blockchain in IoT environments, such as scalability, energy consumption, and latency. We propose potential solutions to these challenges and outline future research directions to enhance the synergy between blockchain and IoT. By leveraging blockchain technology, IoT systems can achieve enhanced security, fostering greater trust and reliability in interconnected devices. This paper aims to provide a comprehensive understanding of the intersection between blockchain and IoT, offering insights into how this integration can address current security concerns and pave the way for more secure and resilient IoT ecosystems
A Framework for Facilitating Secure Design and Development of IoT Systems
The term Internet of Things (IoT) describes an ever-growing ecosystem of physical objects
or things interconnected with each other and connected to the Internet. IoT devices
consist of a wide range of highly heterogeneous inanimate and animate objects. Thus, a
thing in the context of the IoT can even mean a person with blood pressure or heart rate
monitor implant or a pet with a biochip transponder. IoT devices range from ordinary
household appliances, such as smart light bulbs or smart coffee makers, to sophisticated
tools for industrial automation. IoT is currently leading a revolutionary change in many
industries and, as a result, a lot of industries and organizations are adopting the paradigm
to gain a competitive edge. This allows them to boost operational efficiency and optimize
system performance through real-time data management, which results in an optimized
balance between energy usage and throughput. Another important application area is
the Industrial Internet of Things (IIoT), which is the application of the IoT in industrial
settings. This is also referred to as the Industrial Internet or Industry 4.0, where Cyber-
Physical Systems (CPS) are interconnected using various technologies to achieve wireless
control as well as advanced manufacturing and factory automation. IoT applications
are becoming increasingly prevalent across many application domains, including smart
healthcare, smart cities, smart grids, smart farming, and smart supply chain management.
Similarly, IoT is currently transforming the way people live and work, and hence
the demand for smart consumer products among people is also increasing steadily. Thus,
many big industry giants, as well as startup companies, are competing to dominate the
market with their new IoT products and services, and hence unlocking the business value
of IoT.
Despite its increasing popularity, potential benefits, and proven capabilities, IoT is still in
its infancy and fraught with challenges. The technology is faced with many challenges, including
connectivity issues, compatibility/interoperability between devices and systems,
lack of standardization, management of the huge amounts of data, and lack of tools for
forensic investigations. However, the state of insecurity and privacy concerns in the IoT
are arguably among the key factors restraining the universal adoption of the technology.
Consequently, many recent research studies reveal that there are security and privacy issues
associated with the design and implementation of several IoT devices and Smart Applications
(smart apps). This can be attributed, partly, to the fact that as some IoT device
makers and smart apps development companies (especially the start-ups) reap business
value from the huge IoT market, they tend to neglect the importance of security. As a
result, many IoT devices and smart apps are created with security vulnerabilities, which
have resulted in many IoT related security breaches in recent years.
This thesis is focused on addressing the security and privacy challenges that were briefly
highlighted in the previous paragraph. Given that the Internet is not a secure environ ment even for the traditional computer systems makes IoT systems even less secure due
to the inherent constraints associated with many IoT devices. These constraints, which are
mainly imposed by cost since many IoT edge devices are expected to be inexpensive and
disposable, include limited energy resources, limited computational and storage capabilities,
as well as lossy networks due to the much lower hardware performance compared
to conventional computers. While there are many security and privacy issues in the IoT
today, arguably a root cause of such issues is that many start-up IoT device manufacturers
and smart apps development companies do not adhere to the concept of security by
design. Consequently, some of these companies produce IoT devices and smart apps with
security vulnerabilities.
In recent years, attackers have exploited different security vulnerabilities in IoT infrastructures
which have caused several data breaches and other security and privacy incidents
involving IoT devices and smart apps. These have attracted significant attention
from the research community in both academia and industry, resulting in a surge of proposals
put forward by many researchers. Although research approaches and findings may
vary across different research studies, the consensus is that a fundamental prerequisite for
addressing IoT security and privacy challenges is to build security and privacy protection
into IoT devices and smart apps from the very beginning. To this end, this thesis investigates
how to bake security and privacy into IoT systems from the onset, and as its main
objective, this thesis particularly focuses on providing a solution that can foster the design
and development of secure IoT devices and smart apps, namely the IoT Hardware Platform
Security Advisor (IoT-HarPSecA) framework. The security framework is expected to
provide support to designers and developers in IoT start-up companies during the design
and implementation of IoT systems. IoT-HarPSecA framework is also expected to facilitate
the implementation of security in existing IoT systems.
To accomplish the previously mentioned objective as well as to affirm the aforementioned
assertion, the following step-by-step problem-solving approach is followed. The first step
is an exhaustive survey of different aspects of IoT security and privacy, including security requirements in IoT architecture, security threats in IoT architecture, IoT application domains
and their associated cyber assets, the complexity of IoT vulnerabilities, and some
possible IoT security and privacy countermeasures; and the survey wraps up with a brief
overview of IoT hardware development platforms. The next steps are the identification of
many challenges and issues associated with the IoT, which narrowed down to the abovementioned
fundamental security/privacy issue; followed by a study of different aspects of
security implementation in the IoT. The remaining steps are the framework design thinking
process, framework design and implementation, and finally, framework performance
evaluation.
IoT-HarPSecA offers three functionality features, namely security requirement elicitation security best practice guidelines for secure development, and above all, a feature that recommends
specific Lightweight Cryptographic Algorithms (LWCAs) for both software and
hardware implementations. Accordingly, IoT-HarPSecA is composed of three main components,
namely Security Requirements Elicitation (SRE) component, Security Best Practice
Guidelines (SBPG) component, and Lightweight Cryptographic Algorithms Recommendation
(LWCAR) component, each of them servicing one of the aforementioned features.
The author has implemented a command-line tool in C++ to serve as an interface
between users and the security framework. This thesis presents a detailed description,
design, and implementation of the SRE, SBPG, and LWCAR components of the security
framework. It also presents real-world practical scenarios that show how IoT-HarPSecA
can be used to elicit security requirements, generate security best practices, and recommend
appropriate LWCAs based on user inputs. Furthermore, the thesis presents performance
evaluation of the SRE, SBPG, and LWCAR components framework tools, which
shows that IoT-HarPSecA can serve as a roadmap for secure IoT development.O termo Internet das coisas (IoT) é utilizado para descrever um ecossistema, em expansão,
de objetos físicos ou elementos interconetados entre si e à Internet. Os dispositivos
IoT consistem numa gama vasta e heterogénea de objetos animados ou inanimados e,
neste contexto, podem pertencer à IoT um indivíduo com um implante que monitoriza a
frequência cardíaca ou até mesmo um animal de estimação que tenha um biochip. Estes
dispositivos variam entre eletrodomésticos, tais como máquinas de café ou lâmpadas inteligentes,
a ferramentas sofisticadas de uso na automatização industrial. A IoT está a
revolucionar e a provocar mudanças em várias indústrias e muitas adotam esta tecnologia
para incrementar as suas vantagens competitivas. Este paradigma melhora a eficiência
operacional e otimiza o desempenho de sistemas através da gestão de dados em tempo
real, resultando num balanço otimizado entre o uso energético e a taxa de transferência.
Outra área de aplicação é a IoT Industrial (IIoT) ou internet industrial ou Indústria 4.0,
ou seja, uma aplicação de IoT no âmbito industrial, onde os sistemas ciberfísicos estão interconectados
a diversas tecnologias de forma a obter um controlo de rede sem fios, bem
como fabricações avançadas e automatização fabril. As aplicações da IoT estão a crescer
e a tornarem-se predominantes em muitos domínios de aplicação inteligentes como sistemas
de saúde, cidades, redes, agricultura e sistemas de fornecimento. Da mesma forma,
a IoT está a transformar estilos de vida e de trabalho e assim, a procura por produtos inteligentes
está constantemente a aumentar. As grandes indústrias e startups competem
entre si de forma a dominar o mercado com os seus novos serviços e produtos IoT, desbloqueando
o valor de negócio da IoT.
Apesar da sua crescente popularidade, benefícios e capacidades comprovadas, a IoT está
ainda a dar os seus primeiros passos e é confrontada com muitos desafios. Entre eles,
problemas de conectividade, compatibilidade/interoperabilidade entre dispositivos e sistemas,
falta de padronização, gestão das enormes quantidades de dados e ainda falta de
ferramentas para investigações forenses. No entanto, preocupações quanto ao estado de
segurança e privacidade ainda estão entre os fatores adversos à adesão universal desta
tecnologia. Estudos recentes revelaram que existem questões de segurança e privacidade
associadas ao design e implementação de vários dispositivos IoT e aplicações inteligentes
(smart apps.), isto pode ser devido ao facto, em parte, de que alguns fabricantes e empresas
de desenvolvimento de dispositivos (especialmente startups) IoT e smart apps., recolham
o valor de negócio dos grandes mercados IoT, negligenciando assim a importância
da segurança, resultando em dispositivos IoT e smart apps. com carências e violações de
segurança da IoT nos últimos anos.
Esta tese aborda os desafios de segurança e privacidade que foram supra mencionados.
Visto que a Internet e os sistemas informáticos tradicionais são por vezes considerados inseguros,
os sistemas IoT tornam-se ainda mais inseguros, devido a restrições inerentes a tais dispositivos. Estas restrições são impostas devido ao custo, uma vez que se espera que
muitos dispositivos de ponta sejam de baixo custo e descartáveis, com recursos energéticos
limitados, bem como limitações na capacidade de armazenamento e computacionais,
e redes com perdas devido a um desempenho de hardware de qualidade inferior, quando
comparados com computadores convencionais. Uma das raízes do problema é o facto
de que muitos fabricantes, startups e empresas de desenvolvimento destes dispositivos e
smart apps não adiram ao conceito de segurança por construção, ou seja, logo na conceção,
não preveem a proteção da privacidade e segurança. Assim, alguns dos produtos e
dispositivos produzidos apresentam vulnerabilidades na segurança.
Nos últimos anos, hackers maliciosos têm explorado diferentes vulnerabilidades de segurança
nas infraestruturas da IoT, causando violações de dados e outros incidentes de
privacidade envolvendo dispositivos IoT e smart apps. Estes têm atraído uma atenção significativa
por parte das comunidades académica e industrial, que culminaram num grande
número de propostas apresentadas por investigadores científicos. Ainda que as abordagens
de pesquisa e os resultados variem entre os diferentes estudos, há um consenso e
pré-requisito fundamental para enfrentar os desafios de privacidade e segurança da IoT,
que buscam construir proteção de segurança e privacidade em dispositivos IoT e smart
apps. desde o fabrico. Para esta finalidade, esta tese investiga como produzir segurança
e privacidade destes sistemas desde a produção, e como principal objetivo, concentra-se
em fornecer soluções que possam promover a conceção e o desenvolvimento de dispositivos
IoT e smart apps., nomeadamente um conjunto de ferramentas chamado Consultor
de Segurança da Plataforma de Hardware da IoT (IoT-HarPSecA). Espera-se que o conjunto
de ferramentas forneça apoio a designers e programadores em startups durante a
conceção e implementação destes sistemas ou que facilite a integração de mecanismos de
segurança nos sistemas préexistentes.
De modo a alcançar o objetivo proposto, recorre-se à seguinte abordagem. A primeira fase
consiste num levantamento exaustivo de diferentes aspetos da segurança e privacidade na
IoT, incluindo requisitos de segurança na arquitetura da IoT e ameaças à sua segurança,
os seus domínios de aplicação e os ativos cibernéticos associados, a complexidade das
vulnerabilidades da IoT e ainda possíveis contramedidas relacionadas com a segurança e
privacidade. Evolui-se para uma breve visão geral das plataformas de desenvolvimento
de hardware da IoT. As fases seguintes consistem na identificação dos desafios e questões
associadas à IoT, que foram restringidos às questões de segurança e privacidade. As demais
etapas abordam o processo de pensamento de conceção (design thinking), design e
implementação e, finalmente, a avaliação do desempenho.
O IoT-HarPSecA é composto por três componentes principais: a Obtenção de Requisitos
de Segurança (SRE), Orientações de Melhores Práticas de Segurança (SBPG) e a recomendação
de Componentes de Algoritmos Criptográficos Leves (LWCAR) na implementação de software e hardware. O autor implementou uma ferramenta em linha de comandos
usando linguagem C++ que serve como interface entre os utilizadores e a IoT-HarPSecA.
Esta tese apresenta ainda uma descrição detalhada, desenho e implementação das componentes
SRE, SBPG, e LWCAR. Apresenta ainda cenários práticos do mundo real que
demostram como o IoT-HarPSecA pode ser utilizado para elicitar requisitos de segurança,
gerar boas práticas de segurança (em termos de recomendações de implementação) e recomendar
algoritmos criptográficos leves apropriados com base no contributo dos utilizadores.
De igual forma, apresenta-se a avaliação do desempenho destes três componentes,
demonstrando que o IoT-HarPSecA pode servir como um roteiro para o desenvolvimento
seguro da IoT
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