Title :
100 MHz-bandwidth response of a fiber phase modulator with thin piezoelectric jacket
Author :
Imai, M. ; Satoh, S. ; Sakaguchi, T. ; Motoi, K. ; Odajima, A.
Author_Institution :
Dept. of Electr. & Electron. Eng., Muroran Inst. of Technol., Hokkaido, Japan
Abstract :
100 MHz-bandwidth response of an all-fiber phase modulator composed of a single-mode optical fiber jacketed with a 10 μm-thick vinylidene fluoride/trifluoroethylene copolymer, radially poled is presented. Multiple peaks of optical phase shifts induced are observed over the frequency range of 10-100 MHz and ascribed to radial resonances of a fiber-jacket composite. The theoretical analysis of phase shifts is performed based on vibration theory of elasticity taking the exact geometry and composition of the cylindrical multilayer structure into account. The analysis also shows that the phase modulation is strongly dependent on jacket thickness and the maximum induced phase shift will be obtained in the 100 MHz region when the jacket is chosen to be thin as 0.7 μm.
Keywords :
electro-optical devices; optical fibres; optical modulation; phase modulation; piezoelectric devices; polymer blends; 10 mum; 10 to 100 MHz; 100 MHz; all-fiber phase modulator; bandwidth response; composition; cylindrical multilayer structure; exact geometry; fiber-jacket composite; frequency range; jacket thickness; optical phase shifts; phase modulation; radial resonances; single-mode optical fiber; theoretical analysis; thin piezoelectric jacket; vibration theory of elasticity; vinylidene fluoride/trifluoroethylene copolymer; Elasticity; Frequency; Geometrical optics; Nonhomogeneous media; Optical fiber theory; Optical fibers; Optical modulation; Performance analysis; Phase modulation; Resonance;
Journal_Title :
Photonics Technology Letters, IEEE
