Design of H-shaped microstrip patch antennas

## Abstract The genetic‐based approach to the modified resonant frequency calculation for E‐shaped and H‐shaped microstrip patch antennas is presented.Continuous parameter genetic algorithm (CPGA) has been used to modify the resonant frequency expressions of E‐shaped and H‐shaped microstrip antenna

## Abstract In this Letter, a new Koch island microstrip patch antenna is proposed. The Koch patch is fractal shaped and characterized by space‐filling and self‐similarity properties. Due to the space‐filling properties of fractal geometry, the proposed antennas are a smaller in size than conventio

## Abstract A parasitic‐coupled T‐shaped microstrip patch antenna is discussed in this article. The T‐shaped microstrip patch antenna gives dual band resonant frequency on a thin substrate. The two resonant frequencies are within the 3 dB bandwidth that shows wide bandwidth. The experimental result

## Abstract Characteristics of a single‐layer, multi‐frequency microstrip patch antenna, which uses a Sinc shaped microstrip patch configuration, are studied. This antenna is capable of providing good impedance matching at all frequencies without tuning the feed position and other design parameters

The proposed antenna is found to ha¨e a much broader impedance bandwidth as compared to the con¨entional U-slot antenna. An impedance bandwidth of about 33.8% is achie¨ed for the proposed E-plane antenna. Through the use of a washer on the proposed antenna, the probe inductor is compensated, and an

A new antenna structure comprising of multiple radiating microstrip patches, representing a figure of digit eight, proximity fed by a microstrip line is proposed. On a double-layered substrate of FR4, this antenna achieves multiband functionality in the range of 3.81-12.42 GHz, which covers IEEE 802