Electromagnetic bandgap (EBG) structures had been widely investigated in literature in recent years, and the planar corrugated surface is one of them. In studying such structures, the dispersion and reflection phase diagrams are two of the most important characteristics. In this thesis, we will study how to retrieve the dispersion diagram of the corrugations accurately and rapidly. By an asymptotic method and the use of classical vector potentials, we can derive the characteristic equation, thereby obtaining the surface-wave dispersion diagram. To demonstrate its accuracy and quickness, the method we proposed will be compared to a full wave simulator and the transverse resonance technique (TRT), the latter being a traditional method for getting the dispersion diagram. Finally, we fabricated a corrugation, and measure its scattering parameters to indirectly verify the dispersion diagram obtained by the method we proposed. In traditional studies of corrugations, surface-wave propagations along only the two principal directions are considered, pertaining to the so-called soft and hard surfaces. In this thesis, we will further explore the situation whereby the wave propagates obliquely on the surface. By observing the dispersion diagram of the corrugations, we will notice its difference compared to normal periodic structures, and then explain the wave propagation properties on the corrugation surface. At the measurement stage, it is difficult to get the dispersion diagram directly, and usually the scattering parameters are used to explain the width and position in the frequency spectrum of the bandgaps. In the thesis, the relationship of the scattering parameters and wavenumbers are discussed, so that the measured scattering parameters can be transformed to the dispersion diagram effectively. So far we succeed in transforming the simulated scattering parameters to the dispersion diagram, and we hope this method can be applied to measured data in the future.