Millimetre wave wideband low‐loss waveguide‐to‐substrate integrated waveguide transition

ABSTRACT A wideband Ka‐band waveguide‐to‐substrate integrated waveguide transition is presented based on a multi‐section transformer approach. We designed our transition by successfully adapting multi‐section inhomogeneous waveguide transformer theory to match a substrate integrated waveguide feedli...

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Veröffentlicht in:	Microwave and optical technology letters 2017-01, Vol.59 (1), p.10-12
Hauptverfasser:	Ross Aitken, J., Hong, Jiasheng
Format:	Artikel
Sprache:	eng
Schlagworte:	Degrees of freedom Design analysis Design standards Microwaves millimetre wave rectangular waveguide Simulation substrate integrated waveguide tolerance study Transformers Waveguides Wideband
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creator	Ross Aitken, J. Hong, Jiasheng
description	ABSTRACT A wideband Ka‐band waveguide‐to‐substrate integrated waveguide transition is presented based on a multi‐section transformer approach. We designed our transition by successfully adapting multi‐section inhomogeneous waveguide transformer theory to match a substrate integrated waveguide feedline to a standard waveguide flange, which offers more degrees of freedom than current design methods in the state of the art. We subjected our transition to a simulated tolerance analysis and have found the transition to be robust when fabrication errors are considered. We validated these simulations by measuring a back‐to‐back waveguide‐to‐substrate integrated waveguide transition, where there is very good agreement between measured and simulated results. Moreover, an insertion loss of −0.48 dB was measured at the center frequency of the required operating range. © 2016 Wiley Periodicals, Inc. Microwave Opt Technol Lett 59:10–12, 2017
doi_str_mv	10.1002/mop.30214
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subjects	Degrees of freedom Design analysis Design standards Microwaves millimetre wave rectangular waveguide Simulation substrate integrated waveguide tolerance study Transformers Waveguides Wideband
title	Millimetre wave wideband low‐loss waveguide‐to‐substrate integrated waveguide transition
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