Mixed-criticality systems integrate components of different criticality. Different criticality levels require different levels of confidence in the correct behavior of a component. One aspect of correctness is timing. Confidence in worst-case execution time (WCET) estimates depends on the process by which they have been obtained. A somewhat naive view is that static WCET analyses determines safe bounds in which we can have absolute confidence, while measurement-based approaches are inherently unreliable. In this paper, we refine this view by exploring sources of doubt in the correctness of both static and measurement-based WCET analysis
Traditional approaches for worst case execution time (WCET) analysis produce values which are very p...
To reduce complexity while computing an upper bound on the worst-case execution time, static WCET an...
Epistemic uncertainty widely exists in real-time systems that the precise nature of the external env...
Mixed-criticality systems integrate components of different criticality. Different criticality level...
International audienceMixed-criticality systems integrate components of different criticality. Diffe...
Mixed-criticality systems integrate components of different criticality. Different criticality level...
In the last three decades a number of methods have been devised to find upper-bounds for the executi...
International audienceAll contemporary safety standards require to demonstrate the absence of functi...
Precise operation of real-time systems depends on functionally correct computations that are deliver...
A prerequisite for creating a safe and predictable real time computer system is to have knowledge ab...
In this paper we present a measurement-based approach that produces both a WCET (Worst Case Executio...
I point to some challenges for WCET analysis offered in the transition to integrated mixed-criticali...
Guaranteeing that the worst-case scenario has been covered for each basic block individually is a ma...
Timeliness is a critical aspect of real-time systems since both functional and temporal properties m...
The process requirements that govern the development of high-integrity real-time systems make timing...
Traditional approaches for worst case execution time (WCET) analysis produce values which are very p...
To reduce complexity while computing an upper bound on the worst-case execution time, static WCET an...
Epistemic uncertainty widely exists in real-time systems that the precise nature of the external env...
Mixed-criticality systems integrate components of different criticality. Different criticality level...
International audienceMixed-criticality systems integrate components of different criticality. Diffe...
Mixed-criticality systems integrate components of different criticality. Different criticality level...
In the last three decades a number of methods have been devised to find upper-bounds for the executi...
International audienceAll contemporary safety standards require to demonstrate the absence of functi...
Precise operation of real-time systems depends on functionally correct computations that are deliver...
A prerequisite for creating a safe and predictable real time computer system is to have knowledge ab...
In this paper we present a measurement-based approach that produces both a WCET (Worst Case Executio...
I point to some challenges for WCET analysis offered in the transition to integrated mixed-criticali...
Guaranteeing that the worst-case scenario has been covered for each basic block individually is a ma...
Timeliness is a critical aspect of real-time systems since both functional and temporal properties m...
The process requirements that govern the development of high-integrity real-time systems make timing...
Traditional approaches for worst case execution time (WCET) analysis produce values which are very p...
To reduce complexity while computing an upper bound on the worst-case execution time, static WCET an...
Epistemic uncertainty widely exists in real-time systems that the precise nature of the external env...