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HARDEN: A high assurance design environment

Summary

Systems resilient to cyber-attacks for mission assurance are difficult to develop, and the means of effectively evaluating them is even harder. We have developed a new architectural design and engineering environment, referred to as HARDEN (High AssuRance Design ENvironment), which supports an agile design methodology used to create secure and resilient systems. This new toolkit facilitates the quantitative analysis of a system's security posture by setting up a systematic approach of securing and analyzing embedded systems. HARDEN promotes the early co-design of functionality and security that now enables the development of mission assured systems.
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Summary

Systems resilient to cyber-attacks for mission assurance are difficult to develop, and the means of effectively evaluating them is even harder. We have developed a new architectural design and engineering environment, referred to as HARDEN (High AssuRance Design ENvironment), which supports an agile design methodology used to create secure and...

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Designing secure and resilient embedded avionics systems

Summary

With an increased reliance on Unmanned Aerial Systems (UAS) as mission assets and the dependency of UAS on cyber resources, cyber security of UAS must be improved by adopting sound security principles and relevant technologies from the computing community. On the other hand, the traditional avionics community, being aware of the importance of cyber security, is looking at new architecture and designs that can accommodate both the safety oriented principles as well as the cyber security principles and techniques. The Air Force Research Laboratories (AFRL) Information Directorate has created the Agile Resilient Embedded System (ARES) program to investigate mitigations that offer a method to "design-in" cyber protections while maintaining mission assurance. ARES specifically seeks to 'build security in' for unmanned aerial vehicles incorporating security and hardening best practices, while inserting resilience as a system attribute to maintain a level of system operation despite successful exploitation of residual vulnerabilities.
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Summary

With an increased reliance on Unmanned Aerial Systems (UAS) as mission assets and the dependency of UAS on cyber resources, cyber security of UAS must be improved by adopting sound security principles and relevant technologies from the computing community. On the other hand, the traditional avionics community, being aware of...

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Functionality and security co-design environment for embedded systems

Published in:
IEEE High Performance Extreme Computing Conf., HPEC, 25-27 September 2018.

Summary

For decades, embedded systems, ranging from intelligence, surveillance, and reconnaissance (ISR) sensors to electronic warfare and electronic signal intelligence systems, have been an integral part of U.S. Department of Defense (DoD) mission systems. These embedded systems are increasingly the targets of deliberate and sophisticated attacks. Developers thus need to focus equally on functionality and security in both hardware and software development. For critical missions, these systems must be entrusted to perform their intended functions, prevent attacks, and even operate with resilience under attacks. The processor in a critical system must thus provide not only a root of trust, but also a foundation to monitor mission functions, detect anomalies, and perform recovery. We have developed a Lincoln Asymmetric Multicore Processing (LAMP) architecture, which mitigates adversarial cyber effects with separation and cryptography and provides a foundation to build a resilient embedded system. We will describe a design environment that we have created to enable the co-design of functionality and security for mission assurance.
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Summary

For decades, embedded systems, ranging from intelligence, surveillance, and reconnaissance (ISR) sensors to electronic warfare and electronic signal intelligence systems, have been an integral part of U.S. Department of Defense (DoD) mission systems. These embedded systems are increasingly the targets of deliberate and sophisticated attacks. Developers thus need to focus...

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Mission assurance: beyond secure processing

Published in:
18th IEEE Int. Conf. on Software Quality, Reliability, and Security, QRS 2018, 16-20 July 2018, pp. 593-8.

Summary

The processor of a drone runs essential functions of sensing, communications, coordination, and control. This is the conventional view. But in today's cyber environment, the processor must also provide security to assure mission completion. We have been developing a secure processing architecture for mission assurance. A study on state-of-the-art secure processing technologies has revealed that no one-size-fits-all solution can fully meet our requirements. In fact, we have concluded that the provision of a secure processor as a mission assurance foundation must be holistic and should be approached from a systems perspective. We have thus applied a systems analysis approach to create a secure base for the system. This paper describes our journey of adapting and synergizing various secure processing technologies into a baseline asymmetric multicore processing architecture. We will also describe a functional and security co-design environment, created to customize and optimize the architecture in a design space consisting of hardware, software, performance, and assurance.
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Summary

The processor of a drone runs essential functions of sensing, communications, coordination, and control. This is the conventional view. But in today's cyber environment, the processor must also provide security to assure mission completion. We have been developing a secure processing architecture for mission assurance. A study on state-of-the-art secure...

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