Diffraction is a basic characteristic of wave which can be described by the Huygens–Fresnel principle and the principle of superposition of waves. The propagation of a wave can be visualized by considering every particle of the transmitted medium on a wavefront as a point source for a secondary spherical wave. Diffraction phenomenon is one the real-world physics problems, however some of them are not analytically calculable. Computational numerical techniques can overcome the inability to obtain the solutions of governing equations under complex structure and boundary conditions. The techniques of computational electromagnetics into two major categories: full-wave methods and high-frequency methods, under the category of full-wave methods, techniques can be classified as partial differential equation (PDE) based or integral equation (IE) based. FDTD is under the category of full-wave methods which is used to solve Maxwell’s curl equations at points on space grids in the time domain. When one uses FDTD methods to study electromagnetic wave problems, the numerical dispersion errors play a key role to determine the accuracy of the numerical results. In the numerical calculations, the wave propagating through the grid causes a phase error that directly affects the numerical results. In other words, the numerical dispersion error could be reduced by choosing a finer grid or higher resolution. In this research, we interested in the effect of grid resolution on the far-field pattern, so we compared the four different far-field pattern under the selected resolution which is from λ/20 to λ/60. The validation is done by comparing the results to the analytical solutions of single-slit diffraction.