For years, light-emitting diodes (LEDs) have been recognized as a generation of new light sources because they possess the properties of energy-saving, environmental friendly, and long lifetime, and those surpassing in traditional lighting. To satisfy the requirements for different applications, such as for displays and illuminations, determining LED radiation patterns is important to utilizing their viewing angle and lighting efficiency, so that the difficulties of thermal dissipation (power consumption) and safety are resolved. To achieve the objectives, a fast LED radiation pattern characterization system is proposed. In this thesis, we focus on two major works as follows. The first is to give a mathematical formulation for the PD sensing measurement methods and to quantitatively analyze the different methods (e.g., two-dimensional irradiation measurement) through experiments. In the experiments, the spatial bandwidth of LED radiation patterns and the spatial filtering effect due to PD sensing are to be verified. The second is to design and develop a fast measurement system for the radiation patterns of wide-range brightness LEDs. Due to the real-time noise suppression performance of the proposed system, the requirements of fast of quality control and classification for a variety of LEDs will be achieved. In this thesis, a fast lock-in amplifier (LIA) technique has been presented to perform real-time noise suppression. The LIA scheme of the system simply employs a PD sensing circuit, two stepping motors, a fast analog dual LIA device, and a DSP-platform to achieve the measurement. Thus, the configuration of such a system is quite simple and it is consequently cost-effective. The system has been achieved and verified through the experiments. Experimental results indicate that the proposed system gives a satisfactory result. It appears that the proposed approach can establish an accurate optical modeling for LED devices. Finally, the proposed system can evaluate the uniformity of the multiple-LED module to determine the optimum packing density of LED arrays for display/illumination technologies. We expect that it would be highly beneficial to the development of related industries for the techniques of LED applications/manufacturing.