The interaction between organic and ferromagnetic (FM) materials provides a new direction for controlling the spin-injection and spin-transport. Depending on the structure and the coupling of the hybridization of organic/FM materials, the magnetic structure of organic materials alters drastically. Hence a simulation technique is needed to guide the experiments. Here, combining the density functional theory (DFT) and the nonequilibrium Greens function (NEGF), we investigate the electronic/magnetic structures and the transport properties affected by the coupling between perylene-3,4,9,10-tetracarboxylic-3,4,9,10-dianhydride (PTCDA) and different FM materials. Firstly we investigate the Fe(PTCDA) complex. Our calculation predicts that 1D and 2D structure are both half-metallic. For the 1D structure, half-metallic state is ensured by the strong PTCDA-Fe coupling, causing the spin charge redistribution of the molecule. From the band structure and transport calculation, we show that transport behaviors are affected by the d-pz hybridized states. Negative differential resistance (NDR) induced by the band symmetry matching is observed. For the 2D structure, much higher thermal and magnetic stabilities are expected. Secondly we investigate the possibility of adsorbing PTCDA at different sites on the hcp Co(0001) surface by comparing the corresponding adsorption energy (AE). Analysis of the density of states for this system shows that spin polarization at the organic/FM interface is altered according to different adsorption sites.