On privacy in home automation systems

Home Automation Systems (HASs) are becoming increasingly popular in newly built as well as existing properties. While offering increased living comfort, resource saving features and other commodities, most current commercial systems do not protect sufficiently against passive attacks. In this thesis we investigate privacy aspects of Home Automation Systems. We analyse the threats of eavesdropping and traffic analysis attacks, demonstrating the risks of virtually undetectable privacy violations. By taking aspects of criminal and data protection law into account, we give an interdisciplinary overview of privacy risks and challenges in the context of HASs. We present the first framework to formally model privacy guarantees of Home Automation Systems and apply it to two different dummy traffic generation schemes. In a qualitative and quantitative study of these two algorithms, we show how provable privacy protection can be achieved and how privacy and energy efficiency are interdependent. This allows manufacturers to design and build secure Home Automation Systems which protect the users' privacy and which can be arbitrarily tuned to strike a compromise between privacy protection and energy efficiency.Hausautomationssysteme (HAS) gewinnen sowohl im Bereich der Neubauten als auch bei Bestandsimmobilien stetig an Beliebtheit. Während sie den Wohnkomfort erhöhen, Einsparpotential für Strom und Wasser sowie weitere Vorzüge bieten, schützen aktuelle Systeme nicht ausreichend vor passiven Angriffen. In dieser Arbeit untersuchen wir Aspekte des Datenschutzes von Hausautomationssystemen. Wir betrachten die Gefahr des Abfangens von Daten sowie der Verkehrsanalyse und zeigen die Risiken auf, welche sich durch praktisch unsichtbare Angriffe für Nutzende ergeben. Die Betrachtung straf- und datenschutzrechtlicher Aspekte ermöglicht einen interdisziplinären Überblick über Datenschutzrisiken im Kontext von HAS. Wir stellen das erste Rahmenwerk zur formellen Modellierung von Datenschutzgarantien in Hausautomationssystemen vor und demonstrieren die Anwendung an zwei konkreten Verfahren zur Generierung von Dummy-Verkehr. In einer qualitativen und quantitativen Studie der zwei Algorithmen zeigen wir, wie Datenschutzgarantien erreicht werden können und wie sie mit der Energieeffizienz von HAS zusammenhängen. Dies erlaubt Herstellern die Konzeption und Umsetzung von Hausautomationssystemen, welche die Privatsphäre der Nutzenden schützen und die eine freie Parametrisierung ermöglichen, um einen Kompromiss zwischen Datenschutz und Energieeffizienz zu erreichen

Cybersecurity: Past, Present and Future

The digital transformation has created a new digital space known as cyberspace. This new cyberspace has improved the workings of businesses, organizations, governments, society as a whole, and day to day life of an individual. With these improvements come new challenges, and one of the main challenges is security. The security of the new cyberspace is called cybersecurity. Cyberspace has created new technologies and environments such as cloud computing, smart devices, IoTs, and several others. To keep pace with these advancements in cyber technologies there is a need to expand research and develop new cybersecurity methods and tools to secure these domains and environments. This book is an effort to introduce the reader to the field of cybersecurity, highlight current issues and challenges, and provide future directions to mitigate or resolve them. The main specializations of cybersecurity covered in this book are software security, hardware security, the evolution of malware, biometrics, cyber intelligence, and cyber forensics. We must learn from the past, evolve our present and improve the future. Based on this objective, the book covers the past, present, and future of these main specializations of cybersecurity. The book also examines the upcoming areas of research in cyber intelligence, such as hybrid augmented and explainable artificial intelligence (AI). Human and AI collaboration can significantly increase the performance of a cybersecurity system. Interpreting and explaining machine learning models, i.e., explainable AI is an emerging field of study and has a lot of potentials to improve the role of AI in cybersecurity.Comment: Author's copy of the book published under ISBN: 978-620-4-74421-

Private and censorship-resistant communication over public networks

Society’s increasing reliance on digital communication networks is creating unprecedented opportunities for wholesale surveillance and censorship. This thesis investigates the use of public networks such as the Internet to build robust, private communication systems that can resist monitoring and attacks by powerful adversaries such as national governments. We sketch the design of a censorship-resistant communication system based on peer-to-peer Internet overlays in which the participants only communicate directly with people they know and trust. This ‘friend-to-friend’ approach protects the participants’ privacy, but it also presents two significant challenges. The first is that, as with any peer-to-peer overlay, the users of the system must collectively provide the resources necessary for its operation; some users might prefer to use the system without contributing resources equal to those they consume, and if many users do so, the system may not be able to survive. To address this challenge we present a new game theoretic model of the problem of encouraging cooperation between selfish actors under conditions of scarcity, and develop a strategy for the game that provides rational incentives for cooperation under a wide range of conditions. The second challenge is that the structure of a friend-to-friend overlay may reveal the users’ social relationships to an adversary monitoring the underlying network. To conceal their sensitive relationships from the adversary, the users must be able to communicate indirectly across the overlay in a way that resists monitoring and attacks by other participants. We address this second challenge by developing two new routing protocols that robustly deliver messages across networks with unknown topologies, without revealing the identities of the communication endpoints to intermediate nodes or vice versa. The protocols make use of a novel unforgeable acknowledgement mechanism that proves that a message has been delivered without identifying the source or destination of the message or the path by which it was delivered. One of the routing protocols is shown to be robust to attacks by malicious participants, while the other provides rational incentives for selfish participants to cooperate in forwarding messages