\u3cp\u3eIn this chapter we define what a mixed-time-criticality system is and what its requirements are. After defining the concepts that such systems should follow, we described CompSOC, which is one example of a mixed-time-criticality platform. We describe, in detail, how multiple resources, such as processors, memories, and interconnect, are combined into a larger hardware platform, and especially how they are shared between applications using different arbitration schemes. Following this, the software architecture that transforms the single hardware platform into multiple virtual execution platforms, one per application, is described.\u3c/p\u3
Designing a SoC for applications with mixed time-criticality is a complex and time-consuming task. E...
Abstract—Contiguous processor allocation improves both the network and the application performance, ...
Multiprocessor Systems-on-Chip (MPSoC) integrating hard processing cores with programmable logic (PL...
In this chapter we define what a mixed-time-criticality system is and what its requirements are. Aft...
Systems-on-Chip (SoC) complexity increases as a grow-ing number of applications are integrated and e...
Systems-on-Chip (SoC) complexity increases as a grow-ing number of applications are integrated and e...
Recent trends show a steady increase towards concurrently executing more and more applications on a ...
Recent trends show a steady increase towards concurrently executing more and more applications on a ...
The System-on-Chip revolution has not impacted the field of safety-critical systems as widely as the...
The common availability of multiple processors in modern CPU devices and the need to reduce cost of ...
Systems on chip (SOC) contain multiple concurrent appli-cations with different time criticality (fir...
Systems on chip (SOC) contain multiple concurrent applicationswith different time criticality (firm,...
Designing a SoC for applications with mixed time-criticality is a complex and time-consuming task. E...
The relevance and popularity of mixed-criticality real-time systems precipitously increase in many i...
Designing a SoC for applications with mixed time-criticality is a complex and time-consuming task. E...
Abstract—Contiguous processor allocation improves both the network and the application performance, ...
Multiprocessor Systems-on-Chip (MPSoC) integrating hard processing cores with programmable logic (PL...
In this chapter we define what a mixed-time-criticality system is and what its requirements are. Aft...
Systems-on-Chip (SoC) complexity increases as a grow-ing number of applications are integrated and e...
Systems-on-Chip (SoC) complexity increases as a grow-ing number of applications are integrated and e...
Recent trends show a steady increase towards concurrently executing more and more applications on a ...
Recent trends show a steady increase towards concurrently executing more and more applications on a ...
The System-on-Chip revolution has not impacted the field of safety-critical systems as widely as the...
The common availability of multiple processors in modern CPU devices and the need to reduce cost of ...
Systems on chip (SOC) contain multiple concurrent appli-cations with different time criticality (fir...
Systems on chip (SOC) contain multiple concurrent applicationswith different time criticality (firm,...
Designing a SoC for applications with mixed time-criticality is a complex and time-consuming task. E...
The relevance and popularity of mixed-criticality real-time systems precipitously increase in many i...
Designing a SoC for applications with mixed time-criticality is a complex and time-consuming task. E...
Abstract—Contiguous processor allocation improves both the network and the application performance, ...
Multiprocessor Systems-on-Chip (MPSoC) integrating hard processing cores with programmable logic (PL...