An improved design of microstrip patch antennas using photonic bandgap structure

In this letter, a patch antenna on a photonic bandgap substrate is presented. A reduction in the le¨el of surface-wa¨e mode excitation has been obtained. This leads to impro¨ed efficiency, gain, and far-field radiation pattern. Furthermore, impro¨ements in the input return loss ha¨e been reported.

## Abstract Harmonic suppression is an important factor for active microstrip patch antennas radiating harmonic frequencies. Here, a novel compact low pass filter (LPF) having high filter selectivity and wide stop band is used on the microstrip feed line of the patch antenna. The 15 dB LPF stopband

## Abstract This paper describes an efficient design method for an aperture‐coupled microstrip patch antenna, based on an improved transmission line model. The governing equations have been derived and applied to the design of the antenna with a center operating frequency of 11 GHz. The theoretical

We propose a simple and fast fiber grating model for the analysis and synthesis of 1-D photonic bandgap structures consisting of circles etched in the ground plane of microstrip lines. The relationship between the parameters of the photonic bandgap structure and those for an equi¨alent fiber Bragg g