Article

“Accurate Wide-Range Design Equations for Parallel Coupled Microstrip Lines,”

IEEE Transactions on Microwave Theory and Techniques (Impact Factor: 2.94). 02/1984; MTT-32(1):83 - 90. DOI: 10.1109/TMTT.1984.1132616
Source: IEEE Xplore

ABSTRACT In this paper, closed-form expressions are presented which model the frequency-dependent even- and odd-mode characteristics of parallel coupled microstrip lines with hitherto unattained accuracy and range of validity. They include the effective dielectric constants, the characteristic impedances using the power-current formulation, as well as the open-end equivalent lengths for the two fundamental modes on coupled microstrip. The formulas are accurate into the millimeter-wave region. They are based on an extensive set of accurate numerical data which were generated by a rigorous spectral-domain hybrid-mode approach and are believed to represent a substantial improvement compared to the state-of-the-art and with respect to the computer-aided design of coupled microstrip filters, directional couplers, and related components.

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    • "J j, j+1 is the characteristic admittance of J inverter and Yo is the characteristic admittance of the connecting transmission line. With the data of characteristic admittance of the inverter, the characteristic impedances of even-mode and odd-mode of the parallel-coupled microstrip transmission line can be calculated [5] -[6] as: "
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