VLSI systems in the nanometer regime suffer from high defect rates and large parametric variations that lead to yield loss as well as reduced reliability of operation. In this paper, we propose a novel memory-based computation framework that exploits on-chip memory for reliable operation by transferring activity from a defective or unreliable functional unit to the embedded memory. This allows the die to run at a reduced performance level instead of being completely discarded or being throttled (in case of variations). We show that the proposed method improves yield and reliability in a superscalar out-of-order processor by tolerating defective functional units and allowing dynamic thermal management. The simulation results show that it ent...
Abstract — An increasing number of hardware failures can be attributed to device reliability problem...
Abstract—With increasing parameter variations in nanometer technologies, on-chip cache in processor ...
As the CMOS technology continues to scale down for higher performance, power dissipation and robustn...
Abstract—VLSI systems in the nanometer regime suffer from high defect rates and large parametric var...
Ever decreasing device size causes more frequent hard faults, which becomes a serious burden to proc...
In this thesis, we have investigated the impact of parametric variations on the behaviour of one per...
The continued increase in microprocessor clock frequency that has come from advancements in fabricat...
As device density grows, each transistor gets smaller and more fragile leading to an overall higher ...
Process parameter variations are expected to be significantly high in a sub-50-nm technology regime,...
Reliability is a fundamental challenge for current and future microprocessors with advanced nanoscal...
Yield improvement through exploiting fault-free sections of defective chips is a well-known techniqu...
Abstract—This paper proposes a new fault tolerant cache organ-ization capable of dynamically mapping...
Recent advances in microelectronics industry allow us to create a System-On-Chip. The embedded memor...
Negative bias temperature instability (NBTI) is a major cause of concern for chip designers because ...
Modern day microprocessors effectively utilise supply voltage scaling for tremendous power reduction...
Abstract — An increasing number of hardware failures can be attributed to device reliability problem...
Abstract—With increasing parameter variations in nanometer technologies, on-chip cache in processor ...
As the CMOS technology continues to scale down for higher performance, power dissipation and robustn...
Abstract—VLSI systems in the nanometer regime suffer from high defect rates and large parametric var...
Ever decreasing device size causes more frequent hard faults, which becomes a serious burden to proc...
In this thesis, we have investigated the impact of parametric variations on the behaviour of one per...
The continued increase in microprocessor clock frequency that has come from advancements in fabricat...
As device density grows, each transistor gets smaller and more fragile leading to an overall higher ...
Process parameter variations are expected to be significantly high in a sub-50-nm technology regime,...
Reliability is a fundamental challenge for current and future microprocessors with advanced nanoscal...
Yield improvement through exploiting fault-free sections of defective chips is a well-known techniqu...
Abstract—This paper proposes a new fault tolerant cache organ-ization capable of dynamically mapping...
Recent advances in microelectronics industry allow us to create a System-On-Chip. The embedded memor...
Negative bias temperature instability (NBTI) is a major cause of concern for chip designers because ...
Modern day microprocessors effectively utilise supply voltage scaling for tremendous power reduction...
Abstract — An increasing number of hardware failures can be attributed to device reliability problem...
Abstract—With increasing parameter variations in nanometer technologies, on-chip cache in processor ...
As the CMOS technology continues to scale down for higher performance, power dissipation and robustn...