In this study, we estimate ground heat flux and latent heat flux. This study is divided into two chapters. Ground heat flux plays an important role in surface energy balance. In this chapter we are going to evaluate the capability of using net radiation and objective hysteresis model (OHM) estimate ground heat flux and compare with the linear regression model. The experimental sites are including a suburban roof, a grassland in a city, a grassland pasture and a bog. Ground heat flux was measured directly or obtained with the surface energy balance. We choose clear and dry days and obtain OHM coefficients by binary linear regression in each month. We found coefficients would change in each month, and used OHM model estimating ground heat flux is better than linear regression model. In chapter two, we are going to estimate latent heat flux using a nonparametric method.Liu et al. proposed a nonparametric approach to estimating latent heat and sensible heat flux. In this chapter, we are going to evaluate the capability of the nonparametric approach and figure out the applicability and relationship with equilibrium evaporation equation. The experimental site are located in a grassland pasture (Dripsey) and a bog (Glencar). Latent heat flux, sensible heat flux, net radiant flux, air temperature, surface temperature and vapor pressure deficit were measured in two sites. Result showed that nonparametric approach and equilibrium evaporation are really close and they provide the best estimate after measured latent heat flux and sensible heat flux was corrected. Both methods have minimum error when evaporation fraction is 0.6. Equilibrium evaporation equation estimate latent heat flux is better than nonparametric approach when evaporation fraction is more than 0.6, on the contrary, nonparametric approach is better than equilibrium evaporation equation when evaporation fraction is less than 0.6. In all input parameters, air and surface temperature influence nonparametric approach most.