TY - GEN
T1 - Continuously-tunable-bandwidth acoustic-wave resonator-based bandstop filters and their multimode modeling
AU - Psychogiou, Dimitra
AU - Gómez-García, Roberto
AU - Peroulis, Dimitrios
N1 - Publisher Copyright:
© 2016 EuMA.
PY - 2016
Y1 - 2016
N2 - This paper reports on high-quality-factor (Q) acoustic-wave resonator (AWR)-based bandstop filters (BSFs) with continuously-variable stopband bandwidth (BW). They are based on mixed-technology resonant branches that are shaped by one acoustic-wave-lumped-element resonator (AWLR) and two lumped-element (LE) impedance inverters that are in-parallel cascaded to an all-pass-type network. Despite the use of AWRs, transfer functions with fractional bandwidths (FBWs) that are wider than the electromechanical coupling coefficient (kt2) of the AWRs can be created and controlled through the integration of variable LE capacitors that preserve the AWR's high-Q characteristics. A coupling-matrix-based design approach that facilitates the prediction of high- and low-frequency spurious modes-typically present in a realistic AWR filter response - already at the synthesis level is presented for the first time for AWR-based BSFs. An experimental BSF prototype constructed with commercially-available surface acoustic wave (SAW) resonators was built and tested at 418 MHz for proof-of-concept purposes. It exhibits tunable BW between 0.18-0.71 MHz (0.55-2.2kt2), passband insertion loss (IL) between 0.55-2 dB and maximum stopband attenuation between 25-40 dB (i.e., Q>8,000).
AB - This paper reports on high-quality-factor (Q) acoustic-wave resonator (AWR)-based bandstop filters (BSFs) with continuously-variable stopband bandwidth (BW). They are based on mixed-technology resonant branches that are shaped by one acoustic-wave-lumped-element resonator (AWLR) and two lumped-element (LE) impedance inverters that are in-parallel cascaded to an all-pass-type network. Despite the use of AWRs, transfer functions with fractional bandwidths (FBWs) that are wider than the electromechanical coupling coefficient (kt2) of the AWRs can be created and controlled through the integration of variable LE capacitors that preserve the AWR's high-Q characteristics. A coupling-matrix-based design approach that facilitates the prediction of high- and low-frequency spurious modes-typically present in a realistic AWR filter response - already at the synthesis level is presented for the first time for AWR-based BSFs. An experimental BSF prototype constructed with commercially-available surface acoustic wave (SAW) resonators was built and tested at 418 MHz for proof-of-concept purposes. It exhibits tunable BW between 0.18-0.71 MHz (0.55-2.2kt2), passband insertion loss (IL) between 0.55-2 dB and maximum stopband attenuation between 25-40 dB (i.e., Q>8,000).
KW - Acoustic wave (AW) filter
KW - Bandstop filter (BSF)
KW - Bandwidth (BW) tuning
KW - High-quality-factor (Q) filter
KW - Kt enhancement
UR - https://www.scopus.com/pages/publications/85015172675
U2 - 10.1109/EuMC.2016.7824488
DO - 10.1109/EuMC.2016.7824488
M3 - Conference proceeding
AN - SCOPUS:85015172675
T3 - European Microwave Week 2016: "Microwaves Everywhere", EuMW 2016 - Conference Proceedings; 46th European Microwave Conference, EuMC 2016
SP - 894
EP - 897
BT - European Microwave Week 2016
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 46th European Microwave Conference, EuMC 2016
Y2 - 4 October 2016 through 6 October 2016
ER -