Add to ORKGClosed-form expressions to describe artificial dielectric layers (ADLs) are presented. The propagation of a generic plane wave within the artificial material is described by means of transmission line models, where each layer is represented as an equivalent shunt impedance. The given analytical formulas for the shunt impedance account for the reactive coupling between the layers due to higher order Floquet modes, thus remain valid even for extremely small electrical distance between layers. The expressions are derived assuming finite conductivity of the metal, thus also an accurate estimation of the losses within the artificial dielectric is obtained from the equivalent circuit.Tera-Hertz Sensin
This paper presents a new version of an artificial dielectric substrate. The substrate is fabricated...
The equivalent circuit model for artificial magnetic materials based on various arrangements of spli...
A new artificial material single layer (AMSL) model is presented to solve shielding problem. The fie...
Closed-form expressions to describe artificial dielectric layers (ADLs) with finite conductivity are...
In this work, the analytical models to describe artificial dielectric layers (ADLs), when a lateral ...
We present a general analysis to describe non-periodic artificial dielectric layers (ADLs). Closed-f...
In this paper, we present analytical models to describe artificial dielectric layers (ADLs), when a ...
We present an analysis of artificial dielectric layers (ADLs), when a lateral shift between layers i...
We present a general analysis to describe nonsquare artificial dielectric layers (ADLs). Closed-form...
We present an analytical method to model artificial dielectric layers (ADLs) of finite height. Start...
In journal: FERMAT(ISSN 2470-4202), Volume 31, Communication 5, Jan.-Feb., 2019Tera-Hertz Sensin
An improved second order artificial material single layer (AMSL) method is proposed to predict the e...
This paper deals with the extension of the artificial material single-layer (AMSL) method, recently ...
An improved second-order artificial material single-layer (AMSL) method is proposed to predict the e...
International audienceWe present a method of homogenization of thin metallo-dielectric structures as...
This paper presents a new version of an artificial dielectric substrate. The substrate is fabricated...
The equivalent circuit model for artificial magnetic materials based on various arrangements of spli...
A new artificial material single layer (AMSL) model is presented to solve shielding problem. The fie...
Closed-form expressions to describe artificial dielectric layers (ADLs) with finite conductivity are...
In this work, the analytical models to describe artificial dielectric layers (ADLs), when a lateral ...
We present a general analysis to describe non-periodic artificial dielectric layers (ADLs). Closed-f...
In this paper, we present analytical models to describe artificial dielectric layers (ADLs), when a ...
We present an analysis of artificial dielectric layers (ADLs), when a lateral shift between layers i...
We present a general analysis to describe nonsquare artificial dielectric layers (ADLs). Closed-form...
We present an analytical method to model artificial dielectric layers (ADLs) of finite height. Start...
In journal: FERMAT(ISSN 2470-4202), Volume 31, Communication 5, Jan.-Feb., 2019Tera-Hertz Sensin
An improved second order artificial material single layer (AMSL) method is proposed to predict the e...
This paper deals with the extension of the artificial material single-layer (AMSL) method, recently ...
An improved second-order artificial material single-layer (AMSL) method is proposed to predict the e...
International audienceWe present a method of homogenization of thin metallo-dielectric structures as...
This paper presents a new version of an artificial dielectric substrate. The substrate is fabricated...
The equivalent circuit model for artificial magnetic materials based on various arrangements of spli...
A new artificial material single layer (AMSL) model is presented to solve shielding problem. The fie...