Title :
LTCC Bandpass Filter With Wide Stopband Based on Electric and Magnetic Coupling Cancellation
Author :
Xin Dai ; Xiu Yin Zhang ; Hsuan-ling Kao ; Bai-Hong Wei ; Jin-Xu Xu ; Xiaohuan Li
Author_Institution :
Sch. of Electron. & Inf. Eng., South China Univ. of Technol., Guangzhou, China
Abstract :
This paper presents a new method of using electric and magnetic coupling cancellation to extend the stopband of bandpass filters (BPFs). The mechanism is theoretically analyzed based on the lumped-element equivalent circuit. Due to the cancellation of electric and magnetic coupling between two resonators, three transmission zeros (TZs) can be generated and controlled by manipulating the coupling strength. Using the proposed method together with source-load coupling, a low temperature cofire ceramic (LTCC) BPF is designed with four TZs at the passband edges and within the stopband, resulting in high skirt selectivity and harmonic suppression. Due to the LTCC multilayer structure, the filter size is 0.054 λg*0.045λg*0.013λg, or 2.48 mm ×2.02 mm ×0.6 mm. The theoretical, simulated and measured results of the LTCC BPF are presented to validate the proposed design.
Keywords :
band-pass filters; equivalent circuits; multilayers; resonator filters; LTCC band-pass filter; LTCC multilayer structure; electric-magnetic coupling cancellation; harmonic suppression; high skirt selectivity; low temperature cofire ceramic; lumped element equivalent circuit; size 0.6 mm; size 2.02 mm; size 2.48 mm; wide stopband filter; Band-pass filters; Couplings; Equivalent circuits; Magnetic multilayers; Magnetic separation; Passband; Resonant frequency; Bandpass filter (BPF); electric and magnetic (EM) coupling cancellation; low temperature cofired ceramic (LTCC); transmission zero (TZ); wide stopband;
Journal_Title :
Components, Packaging and Manufacturing Technology, IEEE Transactions on
DOI :
10.1109/TCPMT.2014.2346240
