This paper presents a new approach aimed at limiting the growth of the computational cost of variability analysis, of nonlinear circuits, using the Hermite-based polynomial chaos (PC), with the increase in the number of random variables. The proposed technique is based on deriving a closed-form formula for the structure of the augmented Jacobian matrix generated by the PC approach, and then showing that this structure can be approximated with a different structure that can be decoupled into independent diagonal blocks
This paper provides an overview of the polynomial chaos (PC) technique applied to the statistical an...
This paper proposes an exact formalism for the inclusion of nonlinear elements with polynomial I-V c...
The generalized Polynomial Chaos Expansion Method (gPCEM), which is a random uncertainty analysis me...
This paper presents a new approach aimed at limiting the growth of the computational cost of variabi...
This paper presents a new approach aimed at limiting the growth of the computational cost of variabi...
This paper describes a new approach to extend the variability analysis based on the polynomial chaos...
One of the major tasks in electronic circuit design is the ability to predict the performance of gen...
This paper presents a new approach to statistically characterize the variability of the steady-state...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
Abstract—A novel approach is presented to perform stochastic variability analysis of nonlinear syste...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
This paper presents a new approach to statistically characterize the variability of intermodulation ...
This paper proposes a decoupled and iterative circuit implementation of the stochastic Galerkin meth...
A novel approach is presented to perform stochastic variability analysis of nonlinear systems. The v...
This paper deals with the analysis of the dynamic behavior of nonlinear systems subject to probabili...
This paper provides an overview of the polynomial chaos (PC) technique applied to the statistical an...
This paper proposes an exact formalism for the inclusion of nonlinear elements with polynomial I-V c...
The generalized Polynomial Chaos Expansion Method (gPCEM), which is a random uncertainty analysis me...
This paper presents a new approach aimed at limiting the growth of the computational cost of variabi...
This paper presents a new approach aimed at limiting the growth of the computational cost of variabi...
This paper describes a new approach to extend the variability analysis based on the polynomial chaos...
One of the major tasks in electronic circuit design is the ability to predict the performance of gen...
This paper presents a new approach to statistically characterize the variability of the steady-state...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
Abstract—A novel approach is presented to perform stochastic variability analysis of nonlinear syste...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
This paper presents a new approach to statistically characterize the variability of intermodulation ...
This paper proposes a decoupled and iterative circuit implementation of the stochastic Galerkin meth...
A novel approach is presented to perform stochastic variability analysis of nonlinear systems. The v...
This paper deals with the analysis of the dynamic behavior of nonlinear systems subject to probabili...
This paper provides an overview of the polynomial chaos (PC) technique applied to the statistical an...
This paper proposes an exact formalism for the inclusion of nonlinear elements with polynomial I-V c...
The generalized Polynomial Chaos Expansion Method (gPCEM), which is a random uncertainty analysis me...