In 1996, the first white light-emitting diode (WLED) was developed by Nichia Chemical Company, Japan. The advantages of WLED are small size, lower heat generation, long lifetimes and many more favorable properties. The conventional lamp could be replaced by WLED. The luminous efficiency has been improved by 60 lm/W in 2005 to 150 lm/W in 2010. WLED will become the newest lighting source in twenty-first century. However, the above mentioned strategy of white light generation faces serious problems such as low conversion of blue LED, low color rendering index, high color temperature and so on. For this reason, UV excitable phosphors have attracted much attention to improve the drawbacks. UV-LED fitted with three phosphors emitting blue, red and green, this type offers superior color uniformity with a high color rendering index and excellent quality of light. The aim of this study is to focus on UV excitable phosphate which has high luminous efficiency and high stability. The work is to use the combinatorial chemistry to develop (Y,Gd)VO4 phosphor. The host matrixes were doped with different rare earth elements such as Bi3+ ions and Eu3+ ions. The purposes of combinatorial chemistry approach are initial -selected and fast- optimize. In order to verify the results in combinatorial chemistry approach, using the solid-state reaction to synthesis vanadate phosphor. According to the bulk sample, they will be discussed the further luminous properties and energy transfer mechanism. Finally, a practical white LED lamp has been prepared from an optimal (Y0.956Bi0.040Eu0.004)VO4 phosphor and a commercially available blue phosphor of Sr3MgSiO8:Eu2+ (3128) which lead to obtain the color rendering index (Ra) up to 90.3.