The purpose of this thesis is to design a hip-knee exoskeleton that can assist the human body in maintaining standing balance when subjected to external forces. The design and application of the hip-knee exoskeleton are discussed, with the main focus being on providing balance assistance to the wearer with mobility. In the study, a plantar pressure sensor is used to measure the center of pressure (COP) of the human body, which is used as a basis for determining stability. Sensors and encoders in the lower limbs are used to calculate the location of the center of gravity (COG) of the body, and the reference angle of the hip joint is calculated using the zero moment point (ZMP). The design of fuzzy PD control and fuzzy sliding mode control aims to restore the human body to a balanced position, and the individual assistance effects are discussed. The results show that the hip-knee exoskeleton robot can effectively assist the balance of healthy individuals and mild Parkinson's disease patients after being subjected to external disturbance.