In the past, LED solid-state lighting technology changed the way of 21st century lighting. Although these white LEDs can achieve efficiency of more than 150 (lm/W), but blue LED still has some significant performance limitations, including efficiency droop at high current density. The droop phenomenon limits the luminous power of the LED, making it difficult to meet the needs of high power density applications in today's LED solid state lighting technology. With the development of high-power density applications, the development of laser (LD) technology has become more mature, coupled with the performance and stability of laser light at high power, compared with the previous LED lighting, significantly better performance. Therefore, in this paper, it is desirable to be able to use high current density blue lasers with lenses and yellow phosphors to produce high-brightness, with different concentrations and thickness parameters of the phosphor. We use power meter (Thorlabs PM100D), thermocoupler, infrared thermal imager (Fluke Ti32), and the integrating sphere for measuring the watt of high current density blue laser light parameters, the relationship between temperature and time, the luminance with the surface temperature of the phosphors, and the spectrum and the relationship between luminance efficiency and quantum efficiency with time, respectively. We choose a suitable phosphor to match the subsequent secondary optics design for further application.