Electronic International Standard Serial Number (EISSN)
The gap waveguide technology for millimeter waves applications has been recently presented. The new structure is made by generating a parallel plate cut-off region between an artificial magnetic conductor (AMC) and a metallic plate. Propagating waves will be only allowed to follow a metal ridge or groove surrounded by the AMC. The gap waveguide can be made of only metal and does not need any contact between the metal joints compared to standard waveguides. In this study, a study of Q-factors of resonators made in ridge and groove gap waveguides are presented. The resonators are made of copper and the AMC used is a textured surface of metallic pins. Simulated and measured unloaded Qs are presented and compared with Q of a standard rectangular waveguide. High Q-factors are measured for the prototypes presented, approaching 90-96% of the simulated values. Furthermore, it is shown how the lid of pins can easily stop the leakage loss at the joints of the circuit, which is the typical cause of reduced Q-factor of standard waveguides at high frequency.
q-factor measurement; conductors (electric); magnetic circuits; magnetic devices; magnetic leakage; millimetre wave circuits; millimetre wave resonators; ridge waveguides; amc; q-factor; artificial magnetic conductor; groove gap waveguide resonator; leakage loss; metallic pin; surface texture; metallic plate; millimeter wave application; parallel plate cut-off generation; rectangular waveguide; ridge gap waveguide resonator; wave propagation