In this thesis, we develop a homemade simulator based on the finite-difference frequency-domain (FDFD) method to acquire the steady-state electromagnetic field distributions and the modal distributions in optical waveguide systems efficiently and accurately. To implement this simulator, first we discretize the concerned space and arrange the electric and magnetic fields on the Yee grid. The concerned space was truncated by using perfectly matched layers to restrict the computation in a finite domain and to prevent numerical reflections at the boundaries. In addition, the computational domain is divided into two regions: the total field domain and the scattering field domain. Next, the electromagnetic wave equations are approximately discretized into a sequence of linear equations by using finite-difference method on the Yee grids. The distributions of the electric and magnetic fields are obtained by solving these linear equations Ax=b. In addition, in order to apply to the optical waveguide systems, the mode solver being able to realize the modal distributions and propagation constants of the concerned waveguides is very important. Then, we use this method to develop the corresponding mode solver by solving the eigenvalue/eigenfunction problems. At last, we use two examples of a two-dimensional plasmonic bandstop filter and a three-dimensional crossing waveguide based on the silicon on insulator substrate to verify these simulators. The simulated results obtained by our FDFD method are well agreement with those attained by the commercial software, manifesting that our developed simulator is an accurate and efficient solver for the optical waveguide systems.