Title :
Improved compact, wideband, low-dispersion, metamaterial-based MEMS phase shifters
Author :
Gholizadeh, V. ; Ning, Y. ; Luo, X. ; Palego, C. ; Hwang, J.C.M. ; Goldsmith, C.L.
Author_Institution :
Lehigh Univ., Bethlehem, PA, USA
fDate :
March 30 2015-April 1 2015
Abstract :
This paper reports compact, wideband, low-dispersion, metamaterial-based phase shifters with lower loss, wider bandwidth, and fewer MEMS switches than previous designs. The present design is based on a novel 90° unit cell which uses two synchronized MEMS switches that are actuated and unactuated in unison for the through and delayed states, respectively. By combining three of these 90° unit cells with a 45° unit cell of previous design, a 3-bit phase shifter is designed to have smaller than 8 mm2 footprint, less than 20° root-mean-square phase error, less than 2.0 dB insertion loss, and higher than 17 dB return loss between 22 GHz and 27 GHz.
Keywords :
mean square error methods; metamaterials; micromechanical devices; MEMS phase shifters; compact; delayed states; low-dispersion; metamaterial; root-mean-square phase error; synchronized MEMS switches; wideband; Capacitance; Insertion loss; Micromechanical devices; Microswitches; Microwave theory and techniques; Phase shifters; Metamaterials; micro-electromechanical systems; microwave filters; phase shifters; switch; tuning;
Conference_Titel :
Wireless Symposium (IWS), 2015 IEEE International
Conference_Location :
Shenzhen
DOI :
10.1109/IEEE-IWS.2015.7164636
