We discuss the general form of the transfer functions of linear lumped circuits. We show that an arbitrary transfer function defined on such circuits has a functional dependence on individual circuit parameters that is rational, with multi-linear numerator and denominator. This result demonstrates that rational polynomial chaos expansions provide more suitable models than standard polynomial chaos for the uncertainty quantification of this class of circuits
We present a novel technique to perform variability analysis of multiport systems. The versatility o...
This paper addresses for the first time the issue of passivity of the circuit models produced by mea...
This paper investigates the fundamental nature of the polynomial chaos (PC) response of dynamic syst...
This paper discusses the general form of the transfer functions of linear lumped circuits. It is sh...
This paper introduces the use of a rational polynomial chaos expansions (PCE) for the stochastic mac...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
In this chapter, we provide a collection of diverse applications of the polynomial chaos expansion ...
In this paper, we adopt the so-called sparse polynomial chaos metamodel for the uncertainty quantifi...
We present a novel technique to efficiently perform the variability analysis of electromagnetic syst...
This paper introduces a fast stochastic surrogate modeling technique for the frequency-domain respon...
This paper presents a metamodel based on the sparse polynomial chaos approach, well adapted to high ...
We present an analysis of the propagation of measurement uncertainty in microwave transistor nonline...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
One of the major tasks in electronic circuit design is the ability to predict the performance of gen...
We present a novel technique to perform variability analysis of multiport systems. The versatility o...
This paper addresses for the first time the issue of passivity of the circuit models produced by mea...
This paper investigates the fundamental nature of the polynomial chaos (PC) response of dynamic syst...
This paper discusses the general form of the transfer functions of linear lumped circuits. It is sh...
This paper introduces the use of a rational polynomial chaos expansions (PCE) for the stochastic mac...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
Advances in manufacturing process technology are key ensembles for the production of integrated circ...
In this chapter, we provide a collection of diverse applications of the polynomial chaos expansion ...
In this paper, we adopt the so-called sparse polynomial chaos metamodel for the uncertainty quantifi...
We present a novel technique to efficiently perform the variability analysis of electromagnetic syst...
This paper introduces a fast stochastic surrogate modeling technique for the frequency-domain respon...
This paper presents a metamodel based on the sparse polynomial chaos approach, well adapted to high ...
We present an analysis of the propagation of measurement uncertainty in microwave transistor nonline...
This letter proposes a general and effective decoupled technique for the stochastic simulation of no...
One of the major tasks in electronic circuit design is the ability to predict the performance of gen...
We present a novel technique to perform variability analysis of multiport systems. The versatility o...
This paper addresses for the first time the issue of passivity of the circuit models produced by mea...
This paper investigates the fundamental nature of the polynomial chaos (PC) response of dynamic syst...