Abstract—Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates assume that hardware in the target platform (e.g., the CPU) is fault-free. Given the performance requirements increase in current Critical Real-Time Embedded Systems (CRTES), the use of high-performance features and smaller transistors in current and future hardware becomes a must. The use of smaller transistors helps provid-ing more performance while maintaining low energy budgets; however, hardware fault rates increase noticeably, affecting the temporal behaviour of the system in general, and WCET in particular. In this paper, we reconcile these two emergent needs of CRTES, namely, tight (and trustworthy) WCET estimates and the use of hardwar...
Industry developing Critical Real-Time Embedded Systems (CRTES), such as Aerospace, Space, Automotiv...
Despite the scientic advances in the worst-case execution-time (WCET) analysis, there is hardly any ...
Application requirements in High-Performance Computing (HPC) are becoming increasingly exacting, and...
Abstract—Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates as...
Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates assume that...
Critical Real-Time Embedded Systems (CRTES) industry needs increasingly complex hardware to attain t...
The pressing market demand for competitive performance/cost ratios compels Critical Real-Time Embedd...
Estimating the worst-case execution time (WCET) of tasks in a system is an important step in timing ...
Critical Real-Time Embedded Systems require functional and timing validation to prove that they will...
The difficulties in estimating the Worst-Case Execution Time (WCET) of applications make the use of ...
Critical real-time embedded systems feature complex safety-related, performance-demanding functional...
Timeliness is a critical aspect of real-time systems since both functional and temporal properties m...
International audienceStatic timing analysis is the state-of-the-art practice of ascertaining the ti...
As time-critical systems require timing guarantees, Worst-Case Execution Times (WCET) have to be emp...
Industry developing Critical Real-Time Embedded Systems (CRTES), such as Aerospace, Space, Automotiv...
Despite the scientic advances in the worst-case execution-time (WCET) analysis, there is hardly any ...
Application requirements in High-Performance Computing (HPC) are becoming increasingly exacting, and...
Abstract—Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates as...
Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates assume that...
Critical Real-Time Embedded Systems (CRTES) industry needs increasingly complex hardware to attain t...
The pressing market demand for competitive performance/cost ratios compels Critical Real-Time Embedd...
Estimating the worst-case execution time (WCET) of tasks in a system is an important step in timing ...
Critical Real-Time Embedded Systems require functional and timing validation to prove that they will...
The difficulties in estimating the Worst-Case Execution Time (WCET) of applications make the use of ...
Critical real-time embedded systems feature complex safety-related, performance-demanding functional...
Timeliness is a critical aspect of real-time systems since both functional and temporal properties m...
International audienceStatic timing analysis is the state-of-the-art practice of ascertaining the ti...
As time-critical systems require timing guarantees, Worst-Case Execution Times (WCET) have to be emp...
Industry developing Critical Real-Time Embedded Systems (CRTES), such as Aerospace, Space, Automotiv...
Despite the scientic advances in the worst-case execution-time (WCET) analysis, there is hardly any ...
Application requirements in High-Performance Computing (HPC) are becoming increasingly exacting, and...