Author :
Somkuarnpanit, S. ; Koosirivanichakorn, P. ; Khuntaweetep, S.
Author_Institution :
Fac. of Eng., King Mongkut´´s Inst. of Technol., Bangkok, Thailand
Abstract :
This paper presents an algorithm for use in designing a racetrack microresonator on silicon substrate, whose structure is illustrated. The accurate numerical FDTD has been used to calculate the characteristics of the device in the range of optical communication wavelengths. The optimum size of the guide, as well as the curvature of the curved guide, is considered from the results. From the optimum size of the device, the spectral response is consequently calculated, which leads to two important relationships between half-power bandwidth, HPBW, against the coupling efficiency, K, and free spatial range, FSR, against the racetrack round trip, Xrt. Having used these parameters of L and R, in conjunction with the optimum size of the guide, in FDTD simulation, the transfer characteristics can be obtained as following: Xrt = 17.94 μm, K = 0.223, FSR = 29.45 nm, HPBW= 4.45 nm, Q = 346.07 and finesse of 6.62, which are close to the design values. Therefore, our design procedure could be used in design of the dimensions of racetrack microresonators on silicon substrates in the communication wavelengths.
Keywords :
cavity resonators; elemental semiconductors; finite difference time-domain analysis; optical communication equipment; optical waveguide theory; silicon; FSR; HPBW; Si; coupling efficiency; finite-difference time-domain method; free spatial range; half-power bandwidth; optimum device size; racetrack microcavity resonator design; spectral response; Algorithm design and analysis; Bandwidth; Coupling circuits; Finite difference methods; Maxwell equations; Microcavities; Optical fiber communication; Optical resonators; Silicon; Time domain analysis;
