Metal-organic hybrid systems are promising materials because of their special properties and applications. Such as, spin filter, organic spintronics, half-metal and spin injection. A self-assembly structure which consists of iron (Fe) and 3, 4, 9, 10-perylene-tetracarboxylic-dianhydride (PTCDA) on Au(111) is an interesting material due to the coupling of the magnetic material and the organic molecule. Not only the electronic structure but also the magnetic properties are important. Base on the scanning tunneling microscopy (STM) measurements, the growth mode and electronic structures can be resolved. To understand the details of this system, density functional theory (DFT) has been performed. The calculation results are signi_cant to compare with the STM measurements. Under ultra-high vacuum condition, we controlled the growth mode of Fe-PTCDA self-assembly structures on the Au(111) substrate. Based on the STM and STS measurements, we set up a reliable geometry structure for DFT calculations. For electronic structure, we analyzed the bonding mechanism between Fe and PTCDA, which is due to the d-orbital hybridization. Otherwise, the charging limitation of PTCDA in self-assembly system can be observed not only in DFT but also in STS measurements. For magnetic properties, we calculated the spin configurations of this system. The PTCDA molecules present spin-polarized and RKKY-like oscillations in different spin configurations. Our results show that the combination of magnetic materials and organic molecules has potentials for spintronic devices. Due to the significant energy difference between spin configurations, it's possible to build up a long range magnetic transport device. Moreover, our results provide a different insight in magnetism for metal-organic hybrid system.