In this paper, a compact and easy to fabricate brach-line couplers, which can be used for tight and weak couplings with high directivity, is proposed. For these purpose, various artificial transmission lines (ATLs) are incorporated. Design of 3 dB and 10 dB couplers are designed and their characteristics are measured. Good electrical performance and circuit miniaturization indicate the validity of the present theory.
An analysis and design theory of an aperture-coupled cavity-fed back-to-back microstrip directional coupler is presented for efficient and optimized design. For this purpose, an equivalent network is developed, and a simple yet accurate circuit element value calculation is described. Design equations of the coupler are derived based on the equivalent circuit. To determine various structural design parameters, the evolutionary hybrid optimization method based on a genetic algorithm and the Nelder-Mead method is used. As a validation check of the proposed theory and optimized design method, a 10 dB directional coupler was designed and fabricated. The measured coupling was 10.3 dB at 3 GHz, and the return loss and isolation were 31.8 dB and 30.5 dB, respectively. The directional coupler also showed very good quadrature phase characteristics. Good agreements between the measured and the design specifications fully validate the proposed network analysis and design procedure.ABSTRACT: A novel uniplanar electromagnetic Band-Gap (EBG) scheme is presented for size reduction, the proposed structure can be considered as an ameliorated uniplanar compact EBG (UC-EBG) incorporated with interdigital structure which enlarges the fringe capacitance to compress the overall size of unit cell. Its design is detailed in this article and several simulation and experimental results are presented, the properties of the proposed ID-UC-EBG are examined when compared with that of the conventional UC-EBG.
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