This paper presents a methodology for statistical simulation of non-linear integrated circuits affected by device mismatch. This simulation technique is aimed at helping designers maximize yield, since it can be orders of magnitude faster than other readily available methods, e.g. Monte Carlo. Statistical analysis is performed by modeling the electrical effects of tolerances by means of stochastic current or voltage sources, which depend on both device geometry and position across the die. They alter the behavior of both linear and non-linear components according to stochastic device models, which reflect the statistical properties of circuit devices up to the second order (i.e. covariance functions). DC, AC, and transient analyses are perf...
This paper addresses the statistical modeling and simulation of high-speed interconnects with uncert...
In today's semiconductor technology, the size of a transistor is made smaller and smaller. One of th...
Abstract — The intrinsic atomistic variability of nano-scale integrated circuit (IC) technology must...
This paper presents a methodology for statistical simulation of non-linear integrated circuits affec...
This paper presents a methodology for statistical simulation of non-linear integrated circuits affec...
A time-domain methodology for statistical simulation of nonlinear dynamic integrated circuits with a...
In this paper a simulator for the statistical analysis of analog CMOS integrated circuits affected b...
The various devices (transistors, resistors, etc.) in an integrated semiconductor circuit have very ...
This paper presents a simulator for the statistical analysis of MOS integrated circuits affected by ...
In the past few decades, the semiconductor industry kept shrinking the feature size of CMOS transist...
The scaling of MOSFETs has improved performance and lowered the cost per function of CMOS integrated...
This paper presents a simulator for the statistical analysis of MOS integrated circuits affected by ...
This paper extends recent literature results concerning the statistical simulation of circuits affec...
This paper presents a systematic approach for the statistical simulation of nonlinear networks with ...
Statistical analysis of VLSI interconnects is important in manufacturability-driven design of printe...
This paper addresses the statistical modeling and simulation of high-speed interconnects with uncert...
In today's semiconductor technology, the size of a transistor is made smaller and smaller. One of th...
Abstract — The intrinsic atomistic variability of nano-scale integrated circuit (IC) technology must...
This paper presents a methodology for statistical simulation of non-linear integrated circuits affec...
This paper presents a methodology for statistical simulation of non-linear integrated circuits affec...
A time-domain methodology for statistical simulation of nonlinear dynamic integrated circuits with a...
In this paper a simulator for the statistical analysis of analog CMOS integrated circuits affected b...
The various devices (transistors, resistors, etc.) in an integrated semiconductor circuit have very ...
This paper presents a simulator for the statistical analysis of MOS integrated circuits affected by ...
In the past few decades, the semiconductor industry kept shrinking the feature size of CMOS transist...
The scaling of MOSFETs has improved performance and lowered the cost per function of CMOS integrated...
This paper presents a simulator for the statistical analysis of MOS integrated circuits affected by ...
This paper extends recent literature results concerning the statistical simulation of circuits affec...
This paper presents a systematic approach for the statistical simulation of nonlinear networks with ...
Statistical analysis of VLSI interconnects is important in manufacturability-driven design of printe...
This paper addresses the statistical modeling and simulation of high-speed interconnects with uncert...
In today's semiconductor technology, the size of a transistor is made smaller and smaller. One of th...
Abstract — The intrinsic atomistic variability of nano-scale integrated circuit (IC) technology must...