Abstract
A high gain and high directive microstrip patch array antenna formed from dielectric layer stacked on bismuth titanate (BiT) ceramics have been investigated, fabricated, and measured. The antennas are designed and constructed with a combination of two-, four-, and six-BiT elements in an array form application on microwave substrate. For gain and directivity enhancement, a layer of dielectric was stacked on the BiT antenna array. We measured the gain and directivity of BiT array antennas with and without the dielectric layer and found that the gain of BiT array antenna with the dielectric layer was enhanced by about 1.4 dBi of directivity and 1.3 dB of gain over the one without the dielectric layer at 2.3 GHz. The impedance bandwidth of the BiT array antenna both with and without the dielectric layer is about 500 MHz and 350 MHz, respectively, which is suitable for the application of the WiMAX 2.3 GHz system. The utilization of BiT ceramics that covers about 90% of antenna led to high radiation efficiency, and small-size antennas were produced. In order to validate the proposed design, theoretical and measured results are provided and discussed.
Highlights
Microstrip antennas with attractive features, such as low profile, light weight, and easy fabrication, are being widely used
The simulation and measurement results show that the reflectivity is the lowest at −27 dB at the centre frequency of 2.40 GHz for bismuth titanate (BiT) array antenna without the dielectric layer
The application of rectangular bismuth titanate (BiT) material as a ceramic antenna (CA) in array form, which composed of two, four, and six-element BiT as well as a stacked dielectric layer, were investigated and successfully carried out
Summary
Microstrip antennas with attractive features, such as low profile, light weight, and easy fabrication, are being widely used. We propose a novel CA with a new branching structure that uses ceramic material. The antenna presented in this paper is based on the increasing number of patch elements that utilize BiT ceramic materials instead of copper plate as the conventional antenna uses. The raw materials used consist of bismuth pentahydrate and titanium (IV) isopropoxide. We investigated the new aspect of the development and utilization of the Agilent 85070B high-temperature dielectric probe kit in measuring the permittivity of the BiT ceramic material.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
