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This book introduces optical soliton control in micro- and nanoring resonator systems. It describes how the ring resonator systems can be optimized as optical tweezers for photodetection by controlling the input power, ring radii and coupling coefficients of the systems. Numerous arrangements and configurations of micro and nanoring resonator systems are explained. The analytical formulation and optical transfer function for each model and the interaction of the optical signals in the systems are discussed. This book shows that the models designed are able to control the dynamical behaviour of generated signals.
About the author
Dr. Suzairi bin Daud obtained his Ph.D., M.Sc., and B.Sc. degrees in Physics from Universiti Teknologi Malaysia. Prior to entering academia, he gained experience as an engineer and completed one-year professional attachment in a variety of industries, including plastics, metal stamping, and electronics companies. His research interests include fibre Bragg grating, fibre sensor, optical solitons, nonlinear optical communication, CNTs, and nanowaveguides. He is a member of IEEE Asia Region, Malaysian Institute of Physics, and Malaysia Optics & Laser Technology Society. He is currently a Senior Lecturer at the Department of Physics, Faculty of Science, and a principal researcher at Laser Center, Ibnu Sina Institute for Scientific & Industrial Research, Universiti Teknologi Malaysia.
Summary
This book introduces optical soliton control in micro- and nanoring resonator systems. It describes how the ring resonator systems can be optimized as optical tweezers for photodetection by controlling the input power, ring radii and coupling coefficients of the systems. Numerous arrangements and configurations of micro and nanoring resonator systems are explained. The analytical formulation and optical transfer function for each model and the interaction of the optical signals in the systems are discussed. This book shows that the models designed are able to control the dynamical behaviour of generated signals.
