It has been claimed that part of the mechanism of the transmission enhancement is due to the formation of propagating surface plasmon, localized surface plasmon and slit waveguide mode resonance. For these mechanisms, localized surface plasmon and waveguide mode is analysis rely on a suited boundary condition within the slit waveguide. However, until now, it lacks a suited mathematical expression of the localized fields. In this thesis, we analyzed both a single metallic slit and metallic grating using electromagnetic theorem. A mathematical expression of the localized field within the slit is assumed to be similar to the form of surface-confined electromagnetic field, called surface modes in waveguide (SMW). This SMW theory is suited for the boundary condition of a nano-scaled metallic slit with a thick thickness. Through analyzing the EM fields inside of the slit, the analytical solutions of the propagating wave vector inside the slit can be solved. It is shown that the SMW has a good agreement with the simulation of the FDTD method. In addition, a semi-analytical model for the analysis of a metallic grating is modified with SMW theory. We call it modified semi-analytical model (MSAM). By using the MSAM, the transmission anomaly of metallic grating can be well-predicted which is more accurate than current analytical theories for a metallic gratings.