We propose an exoskeleton’s intention prediction method for adaptive learning of assistive joint torque profiles in periodic tasks. Assistive devices, like exoskeletons or prosthesis, often make use of physiological data that allow the detection or prediction of movement onset. Movement onset can be detected at the executing site, the skeletal muscles, by means of EMG or inertial sensors. The ultimate goal of the research is to detect and predict the human movement activity and orientation signaling an assistive joint torque behavior in a way that the movement activity of the exoskeleton system can be modified. An experimental investigation is carried out with the placement of IMU sensors at the lower limb positions to acquire the orientation, shift in the center of mass (COM) and the change in velocity of the human-robot interaction to know the muscle activity during human locomotion. Force sensors are placed at the bottom of the foot to acquire the center of pressure (COP) and the ground reaction force (GRF) in alignment to exoskeleton and human locomotion. Based on the acquired data indigenous gait algorithm is built for the maximum possible walking patterns. Our proposed learning system uses GAIT algorithm as a trajectory generator, and parameters of GAIT are modulated using linear regression. Then, in the future, the learning system will be combined with the dynamics of the human-robot structure to alter the desired dynamics as the final command to the main controller. The advantage of the proposed method is that it does not require specific biomechanical models as the system can adapt itself to predict the intention of the user to have efficient human robot interaction between the human and exoskeleton robot.