The purpose of this study was to analyze the effects of step aerobics with various heights (6 inch, 8 inch, 10 inch) and loadings (0% BW, 10% BW, 15% BW) in leg stiffness. Ten female students (aged: 19.91 ± 1.14 years; eight: 162.95 ± 3.79 cm; weight: 54.29 ± 4.82 kg) from the University of Physical Education were voluntarily participated in this study. A Mega high-speed camera (100 Hz) synchronized with an ATMI force plate (1,000 Hz) was used to collect the relative parameters during a cycle of step aerobics. The videos were derived by the APAS motion analysis system to gain the kinematical parameters and the original force signal is processed by DasyLab 6.0 software. The joint stiffness was calculated by the inverse dynamics process which was used to integrate the body segment parameters, kinetics and ground reaction force. Mixed design two-way ANOVA was used for statistical analyses (p＜.05). In the results, the leg stiffness was significantly greater with 10 inch condition compared to 6 and 8 inch condition while loading 15% BW weights. The ankle stiffness was significantly greater with 8 inch condition compared to 6 inch condition while loading 0% BW weights. Ankle stiffness was higher with 10 inch condition compared to 6 inch condition while loading 10% BW weights. These results indicate that the step height increased would reduce the human leg stiffness. It shows that the increasing step height might increase the impact to human body, which would produce higher vertical displacement on the center of gravity, and the subjects would increase the angles of ankle dorsiflexion to reduce the increasing ground reaction force. Hence, it might result in a greater probability of injury to lower extremity joints when the step heights increased. Furthermore, it might also result in a greater probability of injury to lower extremity joints when loading weight on 10 inch condition.