In this research, an adaptive lower limb exoskeleton (AEXO) has been designed and constructed as a rehabilitation device. It is important that the user gets assistance from the exoskeleton in an adaptive manner because the user may improve during the rehabilitation. The degree of assistance from the AEXO depends on the current situation of the user during the use of the exoskeleton. The question then arises as how the exoskeleton provide this adaptive adjustment. It was decided that a tangible idea was to measure the user status such as to measure user interaction force during the walking. In this design, force sensors are installed on each link of the exoskeleton to monitor the user walking effort during walking. By measuring this force, the control computer of this exoskeleton will understand for each cycle what the status of the user is and predict an adaptive torque according to this measured force. In order to generate a suitable torque, the compliant motion control, which is a combination of impedance and admittance control is used. Several walking experiments have been performed by a healthy user equipped with the AEXO. The first experiment verified the proposed algorithm by using a predefined reference trajectory for the user. The second experiment verified that even without the predefined gait trajectory to move the user’s leg, the exoskeleton can give the compliance to the user to walk properly under several walking speeds. For the future development, the method will be expanded to the people who have suffered from the stroke or other injuries.