tunability key, is loaded at each open-ended stub. Figure 12 illustrates a PCB of the resonator (Type D). The measured resonance characteristics of the PCB are provided in Figure 13. As the results of Figures 11 and 13 indicate, the measured results are in good accordance with the calculated results.
CONCLUSIONWe have examined the behavior of the dominant resonant frequency and location of the attenuation poles of the tunable halfwavelength resonators. In this study, the calculation and experiment of the tunable end-coupling resonator and three types of tunable tapped resonators have been carried out. It has been confirmed that the proposed tunable resonators are essential for realizing tunable characteristics for the attenuation pole and the dominant resonant frequency.In these investigations, the characteristics of the overall resonators have been calculated using a circuit simulator under lossless conditions and ideal lumped elements, as well as the discontinuity effect. We plan to measure the proposed resonators' Q and estimate the resonator characteristics, including various losses such as each capacitor used, the varactor, and the transmission lines. Also, we plan to apply these resonators to tunable filters.
ACKNOWLEDGMENTThis work was partially supported by a Grant-in-Aid for the 21 st Century COE Program from the Ministry of Education, Culture, Sports, Science, and Technology (MEXT) of the Japanese Government (Aoyama Gakuin University, Japan). and polarization-hole burning effects [5], and utilizing frequency shifters [6, 7]. Nevertheless, most of the above approaches are either inconvenient or costly for practical applications. In this paper, by utilizing the polarization-hole burning effect induced by intracavity birefringence, an L-band dual-wavelength erbium-doped fiber laser (EDFL) is presented and the operation principle of this EDFL is analyzed in detail. Moreover, by repeatedly scanning the laser spectrum, we find that this dual-wavelength laser has good stability at room temperature. Figure 1 shows the configuration of our L-band dual-wavelength EDFL. About 17.8-m of EDF with cutoff wavelength of 960 nm and an absorption coefficient of 15.2 dB/m at 979 nm serves as the gain medium. A 980-nm laser diode (LD) with pump power of 96.5 mW is used as the pump source. A section of high birefringence (HiBi) fiber with beat length of 3.1 mm at 1550 nm is combined with a fiber polarizer to constitute the fundamental elements of a Lyot filter. To minimize the high intracavity loss caused by the HiBi fiber and the polarizer, two 3-dB fiber-loop mirrors are placed on either side of the EDFL, serving as the cavity reflectors. The reflectivity of a 3-dB fiber-loop mirror (FLM) is theoretically nearly 100%. Factually, however, the coupling ratio of a 3-dB coupler is not vigorously 50% and the coupler has also inherent loss. Therefore, the 3-dB FLM can be used as a reflector with high reflectivity. In our experiment, reflectivity of the output FLM and the one splicing with the signal port of wavelength division...
