Due to the waveguiding effect of the glass substrate, organic layers and/or transparent electrode, only portion of light escape outside the atmosphere and be detected by the human eyes. Hence, the efficiency improvement is considered as an important issue for an organic light-emitting device (OLED). In this thesis, we investigate the luminous enhancement effect of different microlens array films (MAFs) attachment to a bottom emission OLED (BOLED) experimentally. Besides, we also establish a theoretical program to simulate the optical characteristics of a top-emission OLED (TOLED) with dielectric and passivation layers. MAF-BOLED with higher coverage ratio, smaller base area and higher height ratio exhibits higher luminous efficiency. The normal direction luminous efficiency of 42.5% enhancement and luminous power efficiency improvement of 45% are shown. The image blur phenomenon due to MAFs attachment is quantitatively defined and it is found to be positively related to luminous enhancement ratio. We demonstrated a MAF, which has acceptable blur-width of 45 μm and more than 20% white light efficiency enhancement on an active-matrix OLED (AM-OLED). In our TOLED simulation, we validated the correctness of the program and the design rules are given. We conclude that TOLED devices, which have: (1) total optical cavity thickness of half the desired wavelength, (2) the optical distance between dipole and the reflective anode of quarter of the desired wavelength, and (3) the anode reflectivity larger than that of cathode by around 16%, have optimized peak intensity in desired wavelength.