Organic light-emitting devices (OLEDs) are very attractive for applications in flat panel displays and solid state lighting due to their high contrast, fast response time, self-emissive nature, low cost and easy integration with various substrates. However, the out-coupling efficiency of OLEDs is low because of various optical trapping mechanisms such as the total reflection loss. The OLEDs can be made more efficient if one can improve the out-coupling efficiency of OLEDs, making OLED more suitable in various applications. In this thesis, we fabricated two different kinds of micro-optical films: microlens-array and micro-particle diffuser film. We applied microlens array to OLEDs of different color. In white organic light emitting devices, by integrating with micorlens array, the external quantum efficiency can be enhanced by 23%, and the brightness can be enhanced by 47%. Moreover, the emission pattern of the white OLED become more Lambertian with microlens arrays. The organic light-emitting device (OLEDs) with microcavity structures is often used to improve color saturation and to enhance device brightness. However, the device efficiencies and color performances of the device usually cannot be achieved at the same time. By integrating microcavity top-emitting OLEDs with micro-particle diffuser films, the external quantum efficiency can be enhanced by 2.1 times, the cd/A efficiency can be enhanced by 2.9 times compared to the conventional bottom-emitting OLEDs. With diffuser films, the angular dependence of the top-emitting OLEDs becomes closer to the Lambertian distribution. Without direct contact with the device, OLEDs integrated with micro-optical film not only enhances the device efficiencies but also improve the color performances. This approach is simple, effective and highly compatible with OLED fabrication.