TY - GEN
T1 - SAFER-D: A Self-adaptive Security Framework for Distributed Computing Architectures
AU - Stadler, Marco
AU - Vierhauser, Michael
AU - Riegler, Michael
AU - Waghubinger, Daniel
AU - Sametinger, Johannes
PY - 2026
Y1 - 2026
N2 - The rise of the Internet of Things and Cyber-Physical Systems has introduced new challenges on ensuring secure and robust communication. The growing number of connected devices increases network complexity, leading to higher latency and traffic. Distributed computing architectures (DCAs) have gained prominence to address these issues. This shift has significantly expanded the attack surface, requiring additional security measures to protect all components – from sensors and actuators to edge nodes and central servers. Recent incidents highlight the difficulty of this task: Cyberattacks, like distributed denial of service attacks, continue to pose severe threats and cause substantial damage. Implementing a holistic defense mechanism remains an open challenge, particularly against attacks that demand both enhanced resilience and rapid response. Addressing this gap requires innovative solutions to enhance the security of DCAs. In this work, we present our holistic self-adaptive security framework which combines different adaptation strategies to create comprehensive and efficient defense mechanisms. We describe how to incorporate the framework into a real-world use case scenario and further evaluate its applicability and efficiency. Our evaluation yields promising results, indicating great potential to further extend the research on our framework.
AB - The rise of the Internet of Things and Cyber-Physical Systems has introduced new challenges on ensuring secure and robust communication. The growing number of connected devices increases network complexity, leading to higher latency and traffic. Distributed computing architectures (DCAs) have gained prominence to address these issues. This shift has significantly expanded the attack surface, requiring additional security measures to protect all components – from sensors and actuators to edge nodes and central servers. Recent incidents highlight the difficulty of this task: Cyberattacks, like distributed denial of service attacks, continue to pose severe threats and cause substantial damage. Implementing a holistic defense mechanism remains an open challenge, particularly against attacks that demand both enhanced resilience and rapid response. Addressing this gap requires innovative solutions to enhance the security of DCAs. In this work, we present our holistic self-adaptive security framework which combines different adaptation strategies to create comprehensive and efficient defense mechanisms. We describe how to incorporate the framework into a real-world use case scenario and further evaluate its applicability and efficiency. Our evaluation yields promising results, indicating great potential to further extend the research on our framework.
UR - https://www.scopus.com/pages/publications/105015761615
U2 - 10.1007/978-3-032-02138-0_13
DO - 10.1007/978-3-032-02138-0_13
M3 - Conference proceedings
SN - 9783032021373
T3 - Lecture Notes in Computer Science
SP - 197
EP - 213
BT - Software Architecture - 19th European Conference, ECSA 2025, Proceedings
A2 - Andrikopoulos, Vasilios
A2 - Pautasso, Cesare
A2 - Ali, Nour
A2 - Soldani, Jacopo
A2 - Xu, Xiwei
ER -