Quantifying notions of extensibility in FlexRay schedule synthesis

FlexRay has now become a well-established in-vehicle communication bus at most original equipment manufacturers (OEMs) such as BMW, Audi, and GM. Given the increasing cost of verification and the high degree of crosslinking between components in automotive architectures, an incremental design process is commonly followed. In order to incorporate FlexRay-based designs in such a process, the resulting schedules must be extensible, that is: (i) when messages are added in later iterations, they must preserve deadline guarantees of already scheduled messages, and (ii) they must accommodate as many new messages as possible without changes to existing schedules. Apart from extensible scheduling having not received much attention so far, traditional metrics used for quantifying them cannot be trivially adapted to FlexRay schedules. This is because they do not exploit specific properties of the FlexRay protocol. In this article we, for the first time, introduce new notions of extensibility for FlexRay that capture all the protocol-specific properties. In particular, we focus on the dynamic segment of FlexRay and we present a number of metrics to quantify extensible schedules. Based on the introduced metrics, we propose strategies to synthesize extensible schedules and compare the results of different scheduling algorithms. We demonstrate the applicability of the results with industrial-size case studies and also show that the proposed metrics may also be visually represented, thereby allowing for easy interpretation

Model-Based Engineering of Collaborative Embedded Systems

This Open Access book presents the results of the "Collaborative Embedded Systems" (CrESt) project, aimed at adapting and complementing the methodology underlying modeling techniques developed to cope with the challenges of the dynamic structures of collaborative embedded systems (CESs) based on the SPES development methodology. In order to manage the high complexity of the individual systems and the dynamically formed interaction structures at runtime, advanced and powerful development methods are required that extend the current state of the art in the development of embedded systems and cyber-physical systems. The methodological contributions of the project support the effective and efficient development of CESs in dynamic and uncertain contexts, with special emphasis on the reliability and variability of individual systems and the creation of networks of such systems at runtime. The project was funded by the German Federal Ministry of Education and Research (BMBF), and the case studies are therefore selected from areas that are highly relevant for Germany’s economy (automotive, industrial production, power generation, and robotics). It also supports the digitalization of complex and transformable industrial plants in the context of the German government's "Industry 4.0" initiative, and the project results provide a solid foundation for implementing the German government's high-tech strategy "Innovations for Germany" in the coming years

Safety and Reliability - Safe Societies in a Changing World

The contributions cover a wide range of methodologies and application areas for safety and reliability that contribute to safe societies in a changing world. These methodologies and applications include: - foundations of risk and reliability assessment and management - mathematical methods in reliability and safety - risk assessment - risk management - system reliability - uncertainty analysis - digitalization and big data - prognostics and system health management - occupational safety - accident and incident modeling - maintenance modeling and applications - simulation for safety and reliability analysis - dynamic risk and barrier management - organizational factors and safety culture - human factors and human reliability - resilience engineering - structural reliability - natural hazards - security - economic analysis in risk managemen