Add to ORKGIn this work, we present a non linear non Gaussian and incremental Statistical Timing Analysis (SSTA) framework. Specifically, unlike current approaches for non linear non Gaussian SSTA which have numerical components, our approach is a completely analytical. We also investigate the incremental aspects of SSTA and present (1) a fast yet accurate incremental approach (2) a method to efficiently estimate the expected error injected by the incremental SSTA, which could be used to decide, when accurate SSTA should be executed and when incremental SSTA would suffice. Our approach (non incremental) is about 9588 times faster than Monte Carlo whereas an existing state of the art non linear non Gaussian SSTA engine is only 31.3 times faster. Both h...
We formulate statistical static timing analysis (SSTA) as a mixed-integer program and as a geometric...
As CMOS technology scales down, process variation introduces significant uncertainty in power and pe...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer S...
In the nanometer manufacturing region, process variation causes significant uncertainty for circuit ...
Variability of process parameters makes prediction of digital circuit timing characteristics an impo...
As CMOS technology continues to scale down, process variation introduces significant uncertainty in ...
Timing analysis plays a vital role in chip design, which analyze whether a chip design meets the tim...
The move to deep submicron processes has brought about new problems that designers must contend with...
The effect of process variation is getting worse with every technology generation. With variability ...
DoctorAggressive technology scaling in feature size has propelled designers to integrate millions of...
Abstract—As technology scales into the sub-90nm domain, manufacturing variations become an increasin...
Abstract—The most challenging problem in the current block-based statistical static timing analysis ...
textTechnology scaling in the nanometer era comes with a significant amount of process variation, le...
textWith aggressive technology scaling, within-die random variations are becoming the most dominant...
This paper proposed the impact of variations on delay in CMOS technology of 32 nm. The magnitude of ...
We formulate statistical static timing analysis (SSTA) as a mixed-integer program and as a geometric...
As CMOS technology scales down, process variation introduces significant uncertainty in power and pe...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer S...
In the nanometer manufacturing region, process variation causes significant uncertainty for circuit ...
Variability of process parameters makes prediction of digital circuit timing characteristics an impo...
As CMOS technology continues to scale down, process variation introduces significant uncertainty in ...
Timing analysis plays a vital role in chip design, which analyze whether a chip design meets the tim...
The move to deep submicron processes has brought about new problems that designers must contend with...
The effect of process variation is getting worse with every technology generation. With variability ...
DoctorAggressive technology scaling in feature size has propelled designers to integrate millions of...
Abstract—As technology scales into the sub-90nm domain, manufacturing variations become an increasin...
Abstract—The most challenging problem in the current block-based statistical static timing analysis ...
textTechnology scaling in the nanometer era comes with a significant amount of process variation, le...
textWith aggressive technology scaling, within-die random variations are becoming the most dominant...
This paper proposed the impact of variations on delay in CMOS technology of 32 nm. The magnitude of ...
We formulate statistical static timing analysis (SSTA) as a mixed-integer program and as a geometric...
As CMOS technology scales down, process variation introduces significant uncertainty in power and pe...
Thesis (S.M.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer S...