Powered leg prosthesis and control methodologies for obtaining near normal gait

What is claimed is: 1. A prosthesis, comprising: a powered joint including a joint and a motor unit configured to deliver power to the joint; at least one sensor configured to obtain at least one real-time measurement, the at least one real-time measurement comprising a joint torque for the joint and at least one of an angle of the joint and an angular velocity of the joint; and a controller electronically connected to the powered joint and configured to: calculate a passive portion of the joint torque for the joint based on a first pre-defined mathematical relationship between the passive portion and at least one of the angle of the joint and the angular velocity of the joint; calculate an active portion of the joint torque for the joint based on a second pre-defined mathematical relationship between the active portion, the passive portion, and the joint torque; and control operation of the motor unit based on the passive portion and the active portion of the joint torque to provide a net energy at the joint for a movement of the prosthesis for a selected gait. 2. The prosthesis of claim 1 , wherein the passive portion has a spring-dashpot behavior. 3. The prosthesis of claim 1 , wherein the controller is further configured to calculate the active and passive portions of the joint torque by solving a constrained optimization problem. 4. The prosthesis of claim 1 , wherein the controller is further configured to generate control signals for controlling movement of the motor unit based on a difference between the active portion of the joint torque and the passive portion of the joint torque. 5. The prosthesis of claim 4 , wherein the controller is further configured to modulate the control signals based on the at least one real-time measurement to smooth transition behavior within a current gait for the prosthesis or between a previous gait and the current gait for the prosthesis. 6. The prosthesis of claim 1 , further comprising a prosthetic foot including a ball and a heel, wherein the at least one real-time measurement further comprises a sagittal plane moment and ground interaction forces at the ball and the heel. 7. The prosthesis of claim 1 , wherein the at least one real-time measurement further comprises at least one of interaction forces and moments, imparted between a residual limb of a user and the prosthesis, and wherein the controller is further configured for inferring an intent of the user based the at least one of the interaction forces and the moments and determining the selected gait based on the intent. 8. The prosthesis of claim 7 , further comprising a socket for receiving the residual limb. 9. The prosthesis of claim 1 , wherein the first pre-defined mathematical relationship comprises: τ p =k 1 (θ-–θ e )+b*{dot over (θ)}, where τ p is the passive torque, θis the angle of the joint, {dot over (θ)}is the angular velocity of the joint, k 1 is a predefined linear stiffness coefficient for the joint, b is a pre-defined linear damping coefficient for the joint, and θ e is a predefined equilibrium angle for the joint. 10. The prosthesis of claim 1 , wherein the first pre-defined mathematical relationship comprises a generalized single-valued and odd function, and wherein the controller is further configured to calculate the passive portion by performing a least squares minimization to fit the first pre-defined mathematical relationship to the passive portion. 11. A control system for controlling a powered joint of a prosthesis, the control system comprising: at least one sensor configured to obtain at least one real-time measurement, the at least one real-time measurement comprising a joint torque for the joint and at least one of an angle of the joint and an angular velocity of the joint; and a controller electronically connected to the powered joint and configured to: calculate a passive portion of the joint torque for the powered joint based on a first pre-defined mathematical relationship between the passive portion and at least one of the angle of the powered joint and the angular velocity of the powered joint; calculate an active portion of the joint torque for the powered joint based on a second pre-defined mathematical relationship between the active portion, the passive portion, and the joint torque ; and control movement of the powered joint based on the passive portion and the active portion of the joint torque to provide a net energy at the joint for a movement of the prosthesis for a selected gait. 12. The control system of claim 11 , wherein the passive portion has a spring-dashpot behavior. 13. The control system of claim 11 , wherein the controller is further configured to calculate the active and passive portions of the joint torque by solving a constrained optimization problem. 14. The control system of claim 11 , wherein the controller is further configured to generate control signals for controlling movement of the powered joint based on a difference between the active portion of the joint torque and the passive portion of the joint torque. 15. The control system of claim 14 , wherein the controller is further configured to modulate the control signals based on the at least one real-time measurement to smooth transition behavior within a current gait for the prosthesis or between a previous gait and the current gait for the prosthesis. 16. The prosthesis of claim 7 , wherein the control of movement of the motor unit comprises causing the net energy delivered by the motor unit to be zero when the intent does not trigger a next internal phase of a gait cycle for an activity mode. 17. The prosthesis of claim 11 , wherein the at least one real-time measurement further comprises at least one of interaction forces and moments, imparted between a residual limb of a user and the prosthesis, and wherein the controller is further configured for inferring an intent of the user based the at least one of the interaction forces and the moments and determining the selected gait based on the intent. 18. The control system of claim 17 , wherein the control of movement of the motor unit comprises causing the net energy delivered by the motor unit to be zero when the intent does not trigger a next internal phase of a gait cycle for an activity mode. 19. The control system of claim 17 , wherein the prosthesis comprises a socket for receiving the residual limb.