Neuromorphic computing has been considered as an attracting next-generation computing paradigm. Thus, synaptic devices that play a critical role in neuromorphic computing are of great interest. Based on the memristor model proposed by Leon Chua in 1971, several two-terminal emerging devices have been widely discussed, including RRAM. RRAM is a promising synaptic device because of its 4F2 compact cell size, fast switching speed, low power consumption, etc. It has a very simple structure compare with other transistor-based devices, but the optimal process and material systems are still actively researched. In particular, numerous studies focus on improving the non-ideal effects of the RRAM device, especially the linearity of the weight update. These studies pointed out that more linearly weight update is favorable for achieving higher accuracy in neural networks. In this thesis, we introduce a Ni/HfO2/TiO2/TiN structure, non-filamentary type RRAM, as an artificial electronic synapse. We utilize the basic DC I-V measurement and the pulse measurement of long-term potentiation (LTP) and long-term depression (LTD) to compare the devices fabricated under different conditions. Nevertheless, the identical and continuous stimuli used for LTP and LTD measurements are not generally applicable in the practical pulse operating scheme of neural networks. We design an arbitrary combination of the input signal and the measurement procedure to get a better understanding of the device operation at pulse schemes. Finally, we propose a RC-based compact circuit model, which is capable of reproducing the DC I-V curve. Moreover, through the analysis of the time evolution of internal voltage in the device, we provide a better explanation to several unique features in DC I-V curve of this bilayer device. Finally, we successfully simulate the LTP and LTD and reproduce the results of the arbitrary combination of the stimulations. In particular, we report that the charging and discharging of the capacitors play an important role in the dynamic of resistive switching. In this study, we construct a new compact model for bilayer non-filamentary RRAM through comprehensive measurement and detailed understanding on device mechanism. The model reproduces DC and AC characteristics of weight update from the actual device. We expect that this model would assist accurate array- and system-level simulation for neural networks.