This thesis discusses thermal simulations of semiconductor laser devices, techniques of die bonding process, and studies of power conversion efficiency. In thermal simulations of semiconductor laser devices, we utilize four different models to simulate thermal distribution between semiconductor lasers and submount. These four models are successively considering heat sources in active region, calibration of current diffusion and joule heat, calibration of laser characteristic temperature, and calibration of interface thermal resistance between chip and submount. In our simulation results, we identify there are temperature differences over 100℃ in P-side-up packaging, and 80℃ in P-side-down packaging if we merely consider heat sources in active region other than considering these four factors. This result illustrates in thermal simulation, simply evaluating heat sources in active region will cause significant inaccuracy. Therefore, we can’t ignore other three factors whenever the semiconductor laser devices are operated at high injection current or their internal temperatures are extremely high. In techniques of die bonding process, semiconductor lasers packaging are typically utilizing hard solder of AuSn. This kind of hard solder requires adequate bonding temperature and bonding force to provide best condition of heat dissipation in laser devices. Normally we use shear test to confirm packaging condition is good or bad by observing surface quality. However, such test will cause damage to the devices. On the other hand, if we want to confirm packaging condition via non-destructive test, we need long-period constant light output aging measurement. Owing to these drawbacks, we combine packaging condition and transient thermal resistance measurement to implement a non- destructive test confirming packaging quality. Transient thermal resistance provides the values of interface thermal resistance between chip and solder and rapidly tells us each interface thermal resistance corresponding to its packaging condition. The thermal rollover power of semiconductor laser is merely 135mW before packaging. By employing the optimized packaging condition, we get nearly 1W thermal rollover power improvement. The output power of semiconductor laser device is about 830mW operated under 1000mA continuously after packaging. In studies of power conversion efficiency, we provide analyses of optimum cavity length for high power efficiency and power pie chart. We verify that implementing current blocking region design in high power broad area semiconductor lasers will enhance the maximum of power conversion efficiency of devices. Furthermore, we perceive whenever there are only minor differences in threshold current condition between high-power semiconductor lasers, increasing differential quantum efficiency is the best way to improve power conversion efficiency from the analysis of power pie chart.