One of the major tasks in electronic circuit design is the ability to predict the performance of general circuits in the presence of uncertainty in key design parameters. In the mathematical literature, such a task is referred to as uncertainty quantification. Uncertainty about the key design parameters arises mainly from the difficulty of controlling the physical or geometrical features of the underlying design, especially at the nanometer level. With the constant trend to scale down the process feature size, uncertainty quantification becomes crucial in shortening the design time. To achieve the uncertainty quantification, this thesis presents a new approach based on the concept of generalized Polynomial Chaos (gPC) to perform variability...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
This paper describes a new approach to extend the variability analysis based on the polynomial chaos...
Inherent physical uncertainties can have a significant influence on computational predictions. It is...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
This paper presents a new approach to statistically characterize the variability of the steady-state...
This paper presents a new approach aimed at limiting the growth of the computational cost of variabi...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
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...
This communication deals with the uncertainty quantification in high dimensional problems. It introd...
This paper presents an iterative and decoupled perturbative stochastic Galerkin (SG) method for the ...
Uncertainty exists widely in engineering design. As one of the key components of engineering design,...
Unavoidable statistical variations in fabrication processes have a strong effect on the functionalit...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
This paper describes a new approach to extend the variability analysis based on the polynomial chaos...
Inherent physical uncertainties can have a significant influence on computational predictions. It is...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
This paper presents a new approach to statistically characterize the variability of the steady-state...
This paper presents a new approach aimed at limiting the growth of the computational cost of variabi...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
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...
This communication deals with the uncertainty quantification in high dimensional problems. It introd...
This paper presents an iterative and decoupled perturbative stochastic Galerkin (SG) method for the ...
Uncertainty exists widely in engineering design. As one of the key components of engineering design,...
Unavoidable statistical variations in fabrication processes have a strong effect on the functionalit...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
This paper describes a new approach to extend the variability analysis based on the polynomial chaos...
Inherent physical uncertainties can have a significant influence on computational predictions. It is...