According to the papers, humans do adjust their leg stiffness to accommodate changes in stride frequency or surface stiffness, while hopping in places or running forward. The purpose of this study was to determine the mechanisms by which humans adjust leg stiffness during drop landing on surfaces of different stiffnesses, and analyzed the kinematic, kinetic and EMG differences. Ten male six-grade children served as the subjects for this study. The mean height, mass and age were 155.3±8.2 cm, 48.0±10.5 kg and 11.9±0.3 years, respectively. Kinematic, kinetic and EMG data were acquired simultaneously by using a Redlake high speed camera (250Hz) and a Kistler (model 9287) force platform (1000Hz), and a Biovision EMG system (1000Hz). The Inverse Dynamics method was used to acquire the horizontal forces, vertical forces in the three lower extremity joints, net muscle joint moments, muscle joint powers and works done on the extensor muscles of the ankle, knee, and hip joints. The mechanism of leg stiffness adjustment for children landing on surfaces of different stiffnesses was checked using Pearson product-moment correlation between leg stiffness and hip , knee and ankle joint stiffnesses. The selected variables were tested by two-way repeated ANOVA (a = .05) and Scheffe method posterior comparisons. The results could be summarized as following: 1. The leg stiffness was affected by landing time or stiffness of landing surface. The shorter in landing time, or the lower in stiffness of landing surface, the higher in leg stiffness. 2. The mechanisms of leg stiffness adjustment for children landing on surfaces of different stiffnesses in this study were hip and knee joint stiffnesses. 3. There were significant decreases in first peak vertical reaction force, second peak vertical reaction force, the peak vertical force in the three lower extremity joints and the peak moment of knee joint as the landing time increases. Also, there were significant decreases in first peak vertical reaction force, second peak vertical reaction force, the peak horizontal force in the three lower extremity joints, and the time between the moment of landing and first peak vertical reaction force was significant increases as the stiffness of landing surface decreases. So longer landing time or usage of softer mat was suggested when teaching children landing, in order to prevent the possibility of injury.