IEEE (2016)Ĭohn, S.B.: Direct-coupled-resonator filters. In: IEEE 9th UK-Europe-China Workshop on Millimetre Waves and Terahertz Technologies (UCMMT), pp. Zou, T., Zhang, B., Fan, Y.: Design of a 73 GHz waveguide bandpass filter. Zhang, B., Zirath, H.: A metallic 3-D printed E-band radio front end. Zhang, B., Zirath, H.: 3D printed iris bandpass filters for millimetre-wave applications. Xu, X., Zhang, M., Hirokawa, J., Ando, M.: E-band plate-laminated waveguide filters and their integration into a corporate-feed slot array antenna with diffusion bonding technology. Vosoogh, A., et al.: Compact integrated full-duplex gap waveguide-based radio front end for multi-Gbit/s point-to-point backhaul links at E-band. IEEE (2018)ĭing, D.Z., Xu, J.P.: Low conversion loss full E-band seventh-harmonic mixer with compact filter. In: 48th European Microwave Conference (EuMC), pp. 24(8), 545–547 (2014)ĭilek, S.M., Henneberger, R., Kallfass, I.: Performance analysis of e-band duplex transceiver based on waveguide diplexer filters. ETSI ISG mWT White Paper (2015)Ĭhan, K.Y., Ramer, R., Mansour, R.R., Guo, Y.J.: 60 GHz to E-band switchable bandpass filter. 1–4 (2015)įrecassetti, M.G.L.: E-band and v-band - survey on status of worldwide regulation. In: IEEE MTT-S International Microwave Symposium, pp. 1–5 (2015)īoes, F., et al.: Multi-gigabit E-band wireless data transmission. Stander, T.: A review of key development areas in low-cost packaging and integration of future E-band mm-wave transceivers. Hong, J.S., Lancaster, M.J.: Microstrip Filters for RF/Microwave Applications. Thesis, Electronics Engineering Department, IUG, Gaza (2013) 35(12), 1143–1149 (1987)Ībuhussain, M.M.: An E-band Diplexer for Gigabit Wireless Communications Systems. 20(4), 258–265 (1972)īonetti, R.R., Williams, A.E.: Application of dual TM modesto triple-and quadruple-mode filters. 1–4 (2013)Ītia, A.E., Williams, A.E.: Narrow-bandpass waveguide filters. In: 2013 13th Mediterranean Microwave Symposium (MMS), Saida, pp. Skaik, T., AbuHussain, M.: Design of diplexers for e-band communication systems. In: Electrical Engineering, 4th edn., pp. The new waveguide bandpass filter shortened the physical length of WBPF by \(37.5\%\) and boosted the return loss up to \(6.7\%\). Subsequently, the proposed waveguide BPF and the traditional WBPF which coupled with inductive H-plane resonators have been compared at the same resonant frequency 73.5 GHz. By selecting proper physical dimensions of CSRRs, a shortened physical length, a flat and lossless passband, and better return loss rather than the traditional waveguide filter. The circuit of the prospective bandpass filter has been designed and demonstrated via electromagnetic full-wave simulator CST. Lumped circuit of the filter has been implemented and discussed as well. The new design of the WBPF used complementary split-ring resonators (CSRRs) that both rings are located transversely on the metallic sheet. A waveguide bandpass filter (WBPF) based on the Chebyshev response that operates in the E-band system for downlink channel at 73.5 GHz resonant frequency has been designed and simulated.
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