Miniaturised multilayer RF and microwave circuits

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dc.contributor.author Nassar, Shamim O.
dc.date.accessioned 2022-06-02T12:42:57Z
dc.date.available 2022-06-02T12:42:57Z
dc.date.issued 2022-06-02
dc.identifier.uri http://scholar.sun.ac.za/handle/10019.1/98484
dc.identifier.uri http://repository.seku.ac.ke/handle/123456789/6801
dc.description Doctor of Philosophy in Engineering, 2016 en_US
dc.description.abstract Ceramic and laminate multilayered technologies are explored in the design of novel circuit topologies and in novel implementations of classical circuit topologies. A cross-slot coupled filter topology implemented in folded substrate integrated waveguide (FSIW) is proposed and is shown to exhibit properties that make it favourable for diplexer design. A C-Band diplexer design is presented. The diplexer is fabricated in both Liquid crystalline Polymer (LCP) and Printed Circuit Board (PCB) multilayed technology. The viability of both processes for this type of circuit is analysed and performance is verified by simulation and measurement. A ’ridge-like’ folded substrate integrated waveguide resonator is proposed. A comparative analysis of this resonator and a traditional ridge waveguide resonator structure in substrate integrated technology is presented. For rectangular waveguide resonators with identical outer dimensions, the former is shown to achieve lower operational frequencies relative to the latter. Two X-band filters are designed using the ’ridge-like’ FSIW resonator. Both filters are fabricated in PCB multilayered technology and performance is verified by both simulation and measurement. The measurement results of the first, a second order filter, show a maximum insertion loss of 2.23 dB for the primary band and a wide frequency range of 7.5 GHz between the first passband and the second. The second filter is a fourth order filter which achieves a maximum measured insertion loss of 4.7 dB for the primary passband with the second passband occuring over 8.5 GHz away. A classical sequence asymmetric RC polyphase filter (PPF) is implemented in low temperature co-fired ceramics (LTCC) technology. The novel implementation realises a miniaturised structure comprising embedded components interconnected using planar transmission lines. Verification of the structure’s performance is by simulation of a three segment PPF. The LTCC PPF is shown to achieve an image suppression of 35 dB over a frequency range of 100 MHz to 300 MHz and a gain error of 0.14dB between its quadrature outputs. The final design is a novel implementation of a miniaturised two-stage PIN Diode limiter-switch in LTCC. The structure comprises both embedded components and surface mount components interconnected using planar transmission lines and vias. Circuit viability is assessed through simulation of a multilayered L-Band limiter-switch design. An insertion loss of 0.25 dB and a return loss of 25.34 dB at a center frequency of 1.3 GHz are obtained when the switch is in its off-state. When a large 1 ms input pulse signal of 45 dBm is applied at the input of the limiter-switch, the resulting output pulse has a flat leakage of approximately 16.4 dBm. en_US
dc.description.sponsorship University of Stellenbosch en_US
dc.language.iso en en_US
dc.subject Multilayered technology en_US
dc.subject Miniaturised circuits en_US
dc.subject Substrate Integrated Waveguides en_US
dc.subject Printed Circuit Boards en_US
dc.subject Low Temperature Co-fired Ceramics en_US
dc.subject Liquid Crystalline Polymer en_US
dc.subject Folded Waveguides en_US
dc.subject Ridge Waveguides en_US
dc.subject Analog Polyphase Filters en_US
dc.subject PIN Diodes en_US
dc.subject LTCC limiter-switch en_US
dc.title Miniaturised multilayer RF and microwave circuits en_US
dc.type Thesis en_US


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