A novel self-coupled dual-mode ring resonator and its applications to bandpass filters

• Published in: IEEE transactions on microwave theory and techniques Vol. 54; no. 5; pp. 2146 - 2152
• Main Authors: Yng-Huey Jeng, Chang, S.-F.R., Yi-Ming Chen, Yu-Jen Huang
• Format: Journal Article
• Language: English
• Published: New York, NY IEEE 01.05.2006; Institute of Electrical and Electronics Engineers; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Applied sciences; Band pass filters; Bandpass filter; Bandpass filters; Ceramics; Circuit properties; Coupling circuits; Cutting; dual mode; Electric, optical and optoelectronic circuits; Electronic circuits; Electronics; even-odd mode; Exact sciences and technology; Filtering theory; Frequency filters; Impedance; Microwaves; Optical ring resonators; Oscillators, resonators, synthetizers; Passband; perturbation; Perturbation methods; Resonance; Resonant frequency; Resonator filters; Resonators; Segments; self-coupled; dual mode; Perturbation; Bandpass filter; Digital filter; Ring resonator; Coupling coefficient; even-odd mode; self-coupled; Coupled modes; Band pass filter; Finite impulse response filter; Coupling factor; Transmission mode; Passband; Impedance; Ceramic materials; Comparative study; Coupled resonator; Low temperature
• ISSN: 0018-9480; 1557-9670
• DOI: 10.1109/TMTT.2006.873632

A novel dual-mode ring resonator with self-coupled segments, called a self-coupled ring resonator, is proposed. The self-coupling between ring segments provides the same mode perturbation effect as the conventional methods of adding stub, cutting notch, or varying line impedance on the ring resonator. The mode perturbation and transmission-zero generation due to the self-coupling effect are analyzed with the even-odd mode theory. The self-coupled ring resonator can have the capacitive or inductive perturbation simply by controlling the impedance ratio and coupling coefficients of self-coupled sections. For both perturbation cases, the transmission zeros exist at even multiples of the passband center frequency, resulting in wide stopband range. Also, only for the capacitive perturbation case, two transmission zeros are found on both sides of the passband, which brings a pseudo-elliptic bandpass response. In comparison with the regular uniform ring resonator, the self-coupled ring resonator takes shorter ring length, giving the compact size feature when applied to a bandpass filter design. A 2.45-GHz low-temperature co-fired ceramic bandpass filter based on the self-coupled ring resonator was designed to verify the proposed theory.