In this thesis, a full 3D simulation model is applied to analyze the alloy fluctuation, QW thickness or composition fluctuation in the green LEDs. Recently, studies show that alloy fluctuation could influence electric property due to localized state or the percolation due to the fluctuation potential. Furthermore, we found that in order to make the prediction more accurately, the QW thickness fluctuation or large scale QW composition fluctuation will be needed. After we compare the structure with and without thickness fluctuation, we have found that models with (thickness fluctuation/or composition fluctuation) can make the turned-on voltage obtained by the simulation smaller and match well to the experimental result. The thinner of QW provides a smaller barrier induced by polarization field and it allows carriers to be injected at this low barrier side so that the turn-on voltage will be smaller. However, the drawback for thickness fluctuation is the reduction of active volume size so that local carrier density at the same current is much larger than the case without thickness fluctuation. Therefore, a smaller IQE and a stronger droop was observed if the ratio of thin QW to thick QW region was too large. Finally, we tried to under the influence of lateral carrier diffusion to the potential fluctuation through the diffusion model. We compared the differences between the QW with or without random alloy fluctuation, QW with thickness fluctuation. Our studies show that the fluctuation reduce the diffusion length of electron and holes by 2 or 3 times. Electrons are limited to be less than 1um and holes to be less than 100nm. However, if the thickness fluctuation is further considered, the diffusion length was observed to be limited by the periods of thickness fluctuation.