Optically controlled microstrip load and stub on silicon substrate

## Abstract This paper deals with the 3D modeling of the photo‐induced load created by a laser that illuminates a semiconductor substrate. This independent optical command allows us to change the microwave behavior of the microstrip device. We present a 3D‐equivalent microwave model for the photo‐i

## Abstract High performance CPW and novel microstrip ring resonators at ∼30 GHz and 40 GHz have been fabricated on Si substrates, using an optimized proton‐implantation process. Very good insertion loss and resonator characteristics, close to those from ideal electro‐magnetic simulations, were mea

Figure 3 Measured return loss for dual-frequency operation; s r 4.4, h s 1.6 mm, w s 1 mm, d s 16 mm, l s 14 mm y Figure 4 Measured E-plane and H-plane radiation patterns for the dual-frequency operation with l s 12 mm. Other parameters are x given in Figure 3 ## 3. Conclusions A single-feed, redu

## Abstract A new closed‐form expression to calculate frequency‐dependent distributed inductance and the associated distributed series resistance of microstrip lines on a lossy silicon substrate (CMOS technology) are presented. The proposed analytic model for series impedance is based on a self‐con

Porous silicon (PSi) samples were prepared by electrochemical etching of silicon-on-insulator wafers, consisting of 45 m thick p-type (111) silicon epitaxial layer grown on a thin 100 nm SiO 2 layer on silicon substrates, by varying the concentration of 48% HF in ethanol solution. Within the epitaxi

## Abstract An improved equivalent circuit model is proposed to accurately characterize a metal via transition, between a finite ground coplanar waveguide (FGCPW) and a finite ground thin film microstrip line (FGTFML), which was fabricated using standard CMOS technology. This circuit model with onl