In this thesis, we investigate the metastable state and magnetization processes of Permalloy thin film by means of numerical micromagnetic simulation and experiment. Besides, we study the effect of interparticle dipole interaction on Permalloy thin film arrays. A metastable state for the elongated permalloy elements is found to exist within a short field range before magnetization reversal. From the micromagnetic simulation it exhibits a wave-like structure, and the corresponding magnetic pole density distribution shows a pattern with periodic spots along the boundary. We also use magnetic force microscopy imaging and magnetoresistance measurement, which measures the nucleation field and coercive field, to study the non-coherent magnetization reversal properties of Permalloy ellipse. The metastable state before switching is found to be repeatable. The magnetic structures and hysteresis loops of permalloy thin film arrays are investigated here using magnetic force microscopy and vibrating sample magnetometer. The strength of interparticle dipole interaction can be revealed by the number of single-domain pairs with antiparallel magnetizations when the array is relaxed from a strong hard-axis field. Besides, hysteresis loops obtained by vibrating sample magnetometer measurements show that arrays with narrower interparticle spacings have lower coercivities and remanences. The results obtained from vibrating sample magnetometer are in very good agreement with magnetic force microscopy imaging. In the research on magnetic thin films with special geometries, we investigate the possible equilibrium states existing in the square network composed of four-arm junctions. Our result shows that different magnetization states in the junctions can be classified by counting the net magnetic pole densities accumulated over there. The pattern which has higher energy density, is for the first time observed experimentally in the square network. This provides a promising chance to use Permalloy network junctions as bit ultrahigh-density storage media.