This study aims to develop a nutrient solution and light quality control system for crop production in plant factory by microcontroller and verify the suitability of the system. The nutrient solution system uses an electrical conductivity sensor and pH sensor as a sensing element; through power adjustment circuit to regulate the peristaltic pump flow rate to adjust the electrical conductivity and pH of the nutrient solution. Light control regulates the output current of the drive circuit through pulse width signal to control light panel RGB 0-255 stages of brightness. All sensors wireless transmits data via microcontroller and Bluetooth to Android application provides a real-time monitoring system. In this study, we first investigate the effects of different light quality treatments on four leafy vegetable crops growth. Experiment uses four different light quality: Cool White LED (R25:G49:B26), Red-Blue LED (R87.5:G0:B12.5), Red-White LED (R73.5:G16:B10.5) and Red-Blue-White LED (R81.9:G6.4:B11.7). The results showed that Komatsuna (Brassica rapa var. perviridis) and Mizuna (Brassica rapa var. laciniifolia) planted by RBW LED, Curled Lettuce (Lactuca sativa L. var. crispa) planted by RW LED has the best growth performance. Kale (Brassica oleracea var. sabellica) cultivation is more special, the seedling stage uses RBW LED , final growh stage uses RW LED has the best growth result. In addition, we investigate the regulation of nutrient solution system control methods for different crops. First of all, to explore the impact of the use of the developed automatic adjustment system (real-time adjustment) and traditional manual control (adjust once a week) on the growth of Komatsuna and Mizuna. Second, explore how to use the nutrient solution control system developed to reduce the nitrate concentration of Komatsuna. The results show plants grown slowly under traditional manual control and the big fluctuation of EC and pH values should be the reason. The automatic control nutrient solution treatment fresh weight was 34~54 % higher than manual control treatment. Before harvesting, the setting of the concentration of nutrient solution should be calibrate, and the nitrate concentration of the Komatsuna can be effectively reduced, but still high. The results show that the deficiency of this adjustment mode, by increasing the combination of light quality (increasing the red light ratio) or the adjustment of the light intensity or the photoperiod (Daily Light Integral) can be reduced. The system developed in this study allows the light quality to be adjusted according to the light recipe without changing the light source during cultivation, and can also provide stable nutrient solution conditions throughout the process, providing the best above-ground light environment and the best underground nutrient solution environment for plant. System construction costs are much lower than those using a PC or PLC system and should be more valuable.