Second harmonic generation (SHG) microscopy has already established as a viable and useful technics in imaging collagen scaffold; it is also holds promise as a noninvasive, less photodamage imaging technics for characterizing collagen structure. Since collagen, especially type-I collagen, is one of the most abundant protein in human body, its assembly into functioning units is an important process in maintaining homeostasis of many tissue types. However, the kinetic details of collagen self-assembly process remains unclear. Therefore, in this study, we used SHG microscopy based on a pulsed laser scanning system to monitor the collagen self-assembly process in real-time. Using SHG microscopy to monitor collagen self-assembly process can provide structural informationsI that is important for understanding the fibrillogenesis process. We used self-assembly in collagen hydrogel as our model as this system has already been investigated extensively using other many different techniqus. Electron microscopy, reflected confocal microscopy, and spectrophotometry had been widely used to investigate the process of collagen self-assembly. However, only the non-centrosymmetric requirement of SHG allows the assembly into collagen fibrils to be studied unequivocably and without additional specimen processing. Moreover, the informations of forwad and backward SHG ratio provide information of the fibril diameter. Our results demonstrate that the collagen self assembly process can be studied by SHG microscopy in vitro, with additional development; our approach can be extended to in vivo investigations of the fibrillogenesis process.