In this thesis, we investigate various novel architectures for enhancing performances of organic light-emitting devices (OLEDs). First, we propose hole-injection and electron-injection schemes that are insensitive to electrode materials. Such schemes can be used to improve electrical characteristics of OLEDs. Then, an effective connecting structure based on such carrier injection schemes is used in tandem white-emitting devices, giving superior electrical and optical performances. Next, by employing the wavelength-selective mirror as the cathode and the reflecting mirror to reshape the spectra of devices, we realize the three-peak white-emitting OLEDs that show sharp peaks at RGB wavelengths and have spectra matching better with transmission spectra of typical color filters and thus give much enhanced color gamuts of 87%. Based on quite similar concept, another wavelength-selective mirror is designed to enhance the color saturation of blue OLEDs. Through carefully designing the wavelength-selective mirror and choosing suitable emitter-to-mirror distance, the CIE coordinates of Perylene-based blue devices can achieve (0.151, 0.092), which is very close to the NTSC recommendations. Finally, we investigated theoretically and experimentally the influences of the reflectance of the exit mirror on the emission characteristics of microcavity OLEDs having resonant wavelength set at the peak wavelength of the intrinsic emission by adjusting the thickness of dielectric capping layer.