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العنوان
Applications of Ridge Gap Waveguide (RGW) in
Microwave Technology /
المؤلف
Salah El-Din,Mohamed Sherif Hassan
هيئة الاعداد
باحث / محمد شريف حسن صالح الدين ابراهيم
مشرف / هادية محمد سعيد الحناوى
مناقش / محمد عماد الدين ابو الدهب
مناقش / احمد هشام مرشد
تاريخ النشر
2023
عدد الصفحات
113P.:
اللغة
الإنجليزية
الدرجة
الدكتوراه
التخصص
الهندسة الكهربائية والالكترونية
تاريخ الإجازة
1/1/2023
مكان الإجازة
جامعة عين شمس - كلية الهندسة - كهربة اتصالات
الفهرس
Only 14 pages are availabe for public view

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from 146

Abstract

In short range wireless communication systems, the great need of high capacity and data
rate with the lack of available frequency resources leads to shift towards higher frequencies. This rises the interest of researchers and industry to develop in mm-wave wireless
communication systems. The tendency to work in such high frequencies leads to the use
of smaller sized system components including waveguides and antennas, thus realizing
compact size modules, at which passive, active components, antennas and waveguides
are all integrated and implemented on the same chip. On the other hand, the implementation of such modules for high frequency applications is difficult especially in the
presence of passive components and interconnected transmission lines with traditional
technologies. The main problem is that they suffer from high losses, difficulty to integrate with other components in addition to the high accuracy required for assembly and
fabrication processes to ensure good electrical contacts. To face the preceding challenges,
new technology is needed. Latterly, the gap waveguide (GW) technology is introduced
as a favorable candidate to address the difficulties and problems facing communication
systems at higher frequencies with traditional transmission lines technologies.
The main idea of GW technology is to allow the quasi-transverse electromagnetic wave
(Q-TEM) to propagate through guiding part while preventing the leakage in the other
directions. Regarding the structure, the area surrounding the guiding ridge consists
of two parallel layers; one is a perfect magnetic conductor (PMC) and the other is a
perfect electric conductor (PEC). The gap distance between two layers should be less
than quarter wavelength. There are different types of GWs that are realized based on
propagation characteristics and the type of guiding path required, such as groove gap
waveguide (GGW), ridge gap waveguide (RGW) and microstrip gap waveguide with different configurations; printed RGW (PRGW) and substrate integrated gap waveguide
(SIGW). Mainly, the design of these gap waveguides depends on the analysis of unit
cell to realize its band gap which is considered the operating bandwidth of whole structure. Firstly, we propose an approach turning the RGW design process into a simple,
systematic and straightforward procedure to achieve required bandwidth and center frequency. This work is presented in order to minimize the effort and time required for the
design. Nevertheless, it is important to point out that this study is mainly proposed to
standardize the design procedures for this technology. Afterward, different antennas fed
by RGW are designed and implemented to serve a variety of practical applications in
several frequency bands. For high gain 5G applications, four-element E-plane sectoral
horn array antenna fed by PRGW was designed and fabricated in millimeter wave band.
Moreover, a novel four-port multiple input multiple output (MIMO) antenna based on
SIGW with superior diversity performance was proposed and fabricated for satellite
xi
down link applications. A PRGW based bow-tie slot antenna loaded with three dielectric superstrate layers is proposed to enhance both the antenna gain and bandwidth for
5G and 6G applications.