We present a new model order reduction technique for electrically large systems with delay elements, which can be modeled by means of neutral delayed differential equations. An adaptive multipoint expansion and model order reduction of equivalent first order systems are combined in the new proposed method that preserves the neutral delayed differential formulation. An adaptive algorithm to select the expansion points is presented. The proposed model order reduction technique is validated by pertinent numerical results. A comparison with a previous model order reduction algorithm based on a single point expansion is performed to show the considerably improved modeling capability of the new proposed technique
The demands for miniature sized circuits with higher operating speeds have increased the complexity ...
In this paper, a structure-preserving model reduction approach for a class of delay differential equ...
In this paper, we discuss the present and future needs of the electronics industry with regard to mo...
We present a new model order reduction technique for electrically large systems with delay elements,...
We propose a novel model order reduction technique that is able to accurately reduce electrically la...
Abstract—We present a new model order reduction technique for electrically large systems with delay ...
Abstract—We propose a novel model order reduction technique that is able to accurately reduce electr...
The increase of operating frequencies requires 3-D electromagnetic (EM) methods, such as the partial...
Three-dimensional electromagnetic methods are fundamental tools for the analysis and design of high-...
When the geometric dimensions become electrically large or signal waveform rise times decrease, time...
Advanced in the fabrication technology of integrated circuits (ICs) over the last couple of years ha...
AbstractAdaptive algorithms for computing the reduced‐order model of time‐delay systems (TDSs) are p...
This paper presents a model reduction technique for linear delay differential equations that, first,...
In this paper, we propose an algorithm for model order reduction of large scale systems that can be ...
The demands for miniature sized circuits with higher operating speeds have increased the complexity ...
In this paper, a structure-preserving model reduction approach for a class of delay differential equ...
In this paper, we discuss the present and future needs of the electronics industry with regard to mo...
We present a new model order reduction technique for electrically large systems with delay elements,...
We propose a novel model order reduction technique that is able to accurately reduce electrically la...
Abstract—We present a new model order reduction technique for electrically large systems with delay ...
Abstract—We propose a novel model order reduction technique that is able to accurately reduce electr...
The increase of operating frequencies requires 3-D electromagnetic (EM) methods, such as the partial...
Three-dimensional electromagnetic methods are fundamental tools for the analysis and design of high-...
When the geometric dimensions become electrically large or signal waveform rise times decrease, time...
Advanced in the fabrication technology of integrated circuits (ICs) over the last couple of years ha...
AbstractAdaptive algorithms for computing the reduced‐order model of time‐delay systems (TDSs) are p...
This paper presents a model reduction technique for linear delay differential equations that, first,...
In this paper, we propose an algorithm for model order reduction of large scale systems that can be ...
The demands for miniature sized circuits with higher operating speeds have increased the complexity ...
In this paper, a structure-preserving model reduction approach for a class of delay differential equ...
In this paper, we discuss the present and future needs of the electronics industry with regard to mo...