Design and Analysis of a High-Selectivity Frequency-Selective Surface at 60 GHz

• Published in: IEEE transactions on microwave theory and techniques Vol. 64; no. 6; pp. 1694 - 1703
• Main Authors: Wang, De Song, Zhao, Peng, Chan, Chi Hou
• Format: Journal Article
• Language: English
• Published: New York IEEE 01.06.2016; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Aperture-coupled resonators (ACRs); Apertures; Arrays; Capacitance; Circuit design; Construction; Coupling; Couplings; Design analysis; Frequency selective surfaces; frequency-selective surface (FSS); high selectivity; Inductance; Integrated circuit modeling; narrow passband; Resonant frequency; Resonators; Stability; transmission zero (TZ); V-band (60 GHz); frequency-selective surface (FSS); Aperture-coupled resonators (ACRs); narrow passband; transmission zero (TZ); high selectivity; V -band (60 GHz)
• ISSN: 0018-9480; 1557-9670
• DOI: 10.1109/TMTT.2016.2557325

This work applies aperture-coupled resonators (ACRs) to realize a high-selectivity frequency-selective surface (FSS) at 60 GHz. In a generic ACR FSS, one or both of electrical and magnetic coupling paths can, theoretically, be constructed by appropriately designing coupling apertures. To investigate the operating principle of the ACR FSS, an equivalent-circuit model is first given and analyzed using the odd- and even-mode method. A novel ACR FSS structure with dominant electrical coupling is then proposed. This FSS consists of two crossed-dipole resonator arrays and one rectangular coupling aperture array in between. The constructed out-of-phase signal paths cause two transmission zeros (TZs) near the skirts of the narrow passband, thereby considerably enhancing the selectivity. Parametric study of the proposed ACR FSS was performed. Benefiting from the symmetric structure and low profile, the proposed FSS exhibits good angular stability and polarization stability. A prototype of the proposed ACR FSS at 60 GHz was fabricated and characterized experimentally. The measured results agree well with the full-wave and circuit simulated results, thus verifying the FSS design.