Critical real-time embedded systems feature complex safety-related, performance-demanding functionality. High-performance hardware and software can provide such functionality, but the use of aggressive technologies and architectures challenges time predictability and reliability. The authors propose a new approach to obtain trustworthy worst-case execution time estimates for safety-critical applications running on high-performance faulty hardware by using both timing-analysis techniques and minor hardware modifications.Peer Reviewe
Ubiquitous deployment of embedded systems is having a substantial impact on our society, since they ...
Car manufacturers relentlessly replace or augment the functionality of mechanical subsystems with el...
International audienceEmbedded systems in critical domains, such as automotive, aviation, space doma...
Critical real-time embedded systems feature complex safety-related, performance-demanding functional...
Abstract: The growing complexity of safety-critical embedded systems is leading to an increased comp...
Abstract—Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates as...
International audienceMany tasks in safety-critical embedded systems have hard real-time characteris...
The demand for guaranteed, hence predictable, performance in the real-time systems domain is project...
Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates assume that...
As software continues to control more system-critical functions in cars, its timing is becoming an i...
Embedded processors play a key role in many safety-critical applications including medical, automoti...
Many industrial real-time embedded systems are very large, flexible and highly configurable software...
Cars, trains, trucks, telecom networks and industrial robots are examples of products relying on com...
Application requirements in High-Performance Computing (HPC) are becoming increasingly exacting, and...
A large part of safety-critical embedded systems has to satisfy hard real-time constraints. These ne...
Ubiquitous deployment of embedded systems is having a substantial impact on our society, since they ...
Car manufacturers relentlessly replace or augment the functionality of mechanical subsystems with el...
International audienceEmbedded systems in critical domains, such as automotive, aviation, space doma...
Critical real-time embedded systems feature complex safety-related, performance-demanding functional...
Abstract: The growing complexity of safety-critical embedded systems is leading to an increased comp...
Abstract—Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates as...
International audienceMany tasks in safety-critical embedded systems have hard real-time characteris...
The demand for guaranteed, hence predictable, performance in the real-time systems domain is project...
Existing timing analysis techniques to derive Worst-Case Execution Time (WCET) estimates assume that...
As software continues to control more system-critical functions in cars, its timing is becoming an i...
Embedded processors play a key role in many safety-critical applications including medical, automoti...
Many industrial real-time embedded systems are very large, flexible and highly configurable software...
Cars, trains, trucks, telecom networks and industrial robots are examples of products relying on com...
Application requirements in High-Performance Computing (HPC) are becoming increasingly exacting, and...
A large part of safety-critical embedded systems has to satisfy hard real-time constraints. These ne...
Ubiquitous deployment of embedded systems is having a substantial impact on our society, since they ...
Car manufacturers relentlessly replace or augment the functionality of mechanical subsystems with el...
International audienceEmbedded systems in critical domains, such as automotive, aviation, space doma...