In recent decades, robots have gradually taken on more tasks that require mobility. Unlike animals, which are capable of coordinating complex sensing organs and muscles to achieve dynamic motion on all kinds of terrains, robots have difficulties traversing rough terrains at high speeds due to limitations of computational resources, actuator strength, etc. The aim of this research is to build a new model incorporating the interaction between the leg and the ground based on the previously developed dynamic model, which can achieve dynamic running on rigid ground. Extensive experiments were conducted to examine how the rolling contact and energy-flowing characteristics of the TDR-SLIP model interact with one another in the process of dynamic motion. Following this work, a position-torque hybrid control method was developed to enable the robot’s force-sensing ability. Then, in order to determine the effect of the leg-terrain interaction on the dynamic motion, a new model was developed, in which the ground is described by a combination of linear springs and dampers and which can model a wide range of terrains. Simulation results show chaotic behavior, and such behavior was verified by an experiment. This work provides the basis for future research on how the ground impacts the locomotion of the animal and can serve as a foundation for the building of better terrain models, which may make robots capable of dynamically traversing on all kinds of terrain.