As technology scales, the impact of process variation on the maximum supported frequency (FMAX) of individual cores in a multiprocessor system-on-chip (MPSoC) becomes more pronounced. Task allocation without variation-aware performance analysis can greatly compromise performance and lead to a significant loss in yield, defined as the percentage of manufactured chips satisfying the application timing requirement. We propose variation-aware task allocation for best-effort and real-time streaming applications modeled as task graphs. Our solutions are primarily based on the throughput requirement, which is the most important timing requirement in many real-time streaming applications. The four main contributions of this work are (1) distinguish...
none6siMultimedia streaming applications running on next-generation parallel multiprocessor arrays i...
Modern embedded systems are based on Multiprocessor-Systems-on-Chip (MPSoCs) to meet the strict timi...
This work addresses the new problem of timing variation-aware (TV) task scheduling and binding (TSB)...
As technology scales, the impact of process variation on the maximum supported frequency (FMAX) of i...
Abstract—As technology scales, the impact of process variation on the maximum supported frequency (F...
A bs tr act —As t echnology s cales, t he impact of proces s variat ion on the maximum supported fre...
As technology scales, the impact of process variation on the maximum supported frequency (FMAX) of i...
Abstract — As technology scales, the delay uncertainty caused by process variations has become incre...
In nanometer technology regime, process variation (PV) causes uncertainties in the processor frequen...
none5noAbstract Sub-50nm CMOS technologies are affected by significant variability which causes pow...
Embedded streaming applications specified using parallel Models of Computation (MoC) often contain a...
Variability in the manufacturing process results in variation in the maximum supported frequency of ...
This article studies the scheduling of real-time streaming applications on multiprocessor systems-on...
none6siMultimedia streaming applications running on next-generation parallel multiprocessor arrays i...
Modern embedded systems are based on Multiprocessor-Systems-on-Chip (MPSoCs) to meet the strict timi...
This work addresses the new problem of timing variation-aware (TV) task scheduling and binding (TSB)...
As technology scales, the impact of process variation on the maximum supported frequency (FMAX) of i...
Abstract—As technology scales, the impact of process variation on the maximum supported frequency (F...
A bs tr act —As t echnology s cales, t he impact of proces s variat ion on the maximum supported fre...
As technology scales, the impact of process variation on the maximum supported frequency (FMAX) of i...
Abstract — As technology scales, the delay uncertainty caused by process variations has become incre...
In nanometer technology regime, process variation (PV) causes uncertainties in the processor frequen...
none5noAbstract Sub-50nm CMOS technologies are affected by significant variability which causes pow...
Embedded streaming applications specified using parallel Models of Computation (MoC) often contain a...
Variability in the manufacturing process results in variation in the maximum supported frequency of ...
This article studies the scheduling of real-time streaming applications on multiprocessor systems-on...
none6siMultimedia streaming applications running on next-generation parallel multiprocessor arrays i...
Modern embedded systems are based on Multiprocessor-Systems-on-Chip (MPSoCs) to meet the strict timi...
This work addresses the new problem of timing variation-aware (TV) task scheduling and binding (TSB)...