Abstract:
With the emergence of novel wireless technologies, the demands for larger bandwidth, high
efficiency and high capacity RF and microwave devices have been growing tremendously. The
recent implementations in solid state and semiconductor materials give us hope for future
applications. It should be remarked that although many of the ideas could have been proposed
much earlier, it is only recently that they were identified or demonstrated due to various
technological advances. The electromagnetic bandgap (EBG) is introduced to improve the
performances of existing RF active and passive devices. Electromagnetic Band Gap (EBG)
structures produced a wide variety of design alternatives for researchers working in the area
of microwave and photonics. The focus is now towards on finding real applications combined
with detailed modeling. Due to the incredible potential of EBGs, there are huge applications in
which they can be used. New companies have also started to exploit the commercial potential of
this technology.
This thesis describes the planar EBG structures in the forms of conventional circular and
rectangular photonic bandgaps (PBGs) and dumbbell shaped defected ground structures (DGSs).
Novel PBGs in the form of non-uniform Binomial and Chebyshev distributions of unit PBG cells
have been proposed. This novel PBGSs contains fewer ripples with lesser height or ripple free
passband and wide stopband properties, which are very useful to suppress higher order harmonics
in the lowpass filters (LPF). The dumbbell shaped DGSs study has been described with the gap
width and length and the size of dumbbell slots. Some novel designs have been proposed such as;
non-uniform dumbbell shaped DGSs with Binomial and Chebyshev distribution, hybrid dumbbell
shaped DGS and PBGS and modified hybrid dumbbell shaped DGS and PBGS configurations.
The novel designs perform better than the conventional DGSs reported in the literature. The DGSs
yield perfect LPF responses with negligible passband ripples and extremely wide stopband.
In this thesis, we have investigated on uniform circular, rectangular and dumbbell shaped
DGS structures with different filling factor (FF). Therefore, FF is not a single valued parameter.
In our study, we have defined the FF as the ratio of central dumbbell shaped DGS element and
inter-element spacing. And then for the better performance, we have focused on different
Binomially and Chebyshev distributed dumbbell shaped DGSs. This research conveys the
performance of low pass filter using those distributions at about 4 GHz cutoff frequency. These
distributions remove the unwanted insertion loss in the band rejection region. Sufficient
explanations have been provided to validate the total research works in the thesis. Finally,
comparing the insertion loss (IL) and return loss (RL) performances of the LPFs with binomially
and Chebyshev distributed dumbbell shaped DGSs and hybrid DGSs. Binomially distributed DGSs
and hybrid DGSs provide improved performance than conventional PBGSs and Chebyshev
distributed dumbbell shaped DGSs in terms of suppression of the ripple in the passband and return
and insertion-loss bandwidths.
Description:
This thesis is submitted to the Department of Electrical and Electronic Engineering, Khulna University of Engineering & Technology in partial fulfillment of the requirements for the degree of Master of Science in Electrical and Electronic Engineering, July 2015.
Cataloged from PDF Version of Thesis.
Includes bibliographical references (pages 115-119).