Ankle-foot prosthesis device

What is claimed is: 1. A powered ankle-foot prosthetic device for restoring a required ankle torque for a gait to an amputee wearing the prosthetic device, the prosthetic device comprising: an ankle joint that defines an ankle angle between a shin bracket and a bracket support foot; a motor operably coupled to the ankle joint, wherein the motor is configured to: selectively provide a motor torque output to achieve the required ankle torque during phases of the gait, wherein selectively providing the motor torque output comprises: providing the motor torque output during an initial phase of a controlled dorsiflexion phase; providing the motor torque output during swing phase; and providing the motor output torque in a powered plantar flexion phase of a stance phase; and a parallel spring mechanism including a cam operably coupled with the ankle joint in parallel with the motor, wherein the parallel spring mechanism is configured to: provide a spring torque output during the controlled dorsiflexion phase and wherein the prosthetic device is configured such that the spring torque output and the motor torque output provide the required ankle torque that produces a curved torque versus ankle angle plot during the controlled dorsiflexion phase. 2. The device of claim 1 , wherein the cam is attached to the shin bracket, wherein the parallel spring mechanism further includes a slider, a roller, rods, and springs such that when the shin bracket rotates, engagement of the cam with the slider varies the spring torque output producing the curved ankle torque versus ankle angle plot. 3. The device of claim 2 , wherein the cam is configured to compress the springs thereby generating the spring torque output, when the ankle angle of the ankle joint of the prosthetic device is larger than zero, zero being when the shin bracket is perpendicular to the bracket support foot. 4. The device of claim 3 , wherein the cam is configured to operate according to a cam profile that is decomposed in a plurality of segments. 5. The device of claim 4 wherein a pitch curve slope of each segment of the cam profile is approximated by a third-order polynomial. 6. The device of claim 4 , wherein a pitch curve slope of each segment of the cam profile is a convex curve. 7. The device of claim 2 , wherein the cam is configured to operate according to a cam profile with several cam pitch curve slopes that are achieved based on a stiffness of the parallel spring mechanism which ensures the parallel spring mechanism produces the curved ankle torque versus ankle angle plot during the controlled dorsiflexion phase of the gait of the amputee. 8. The device of claim 2 , wherein the roller is an offset roller, and wherein the cam is operably engaged with the springs via the offset roller and slider. 9. The device of claim 2 , wherein the cam is configured to operate according to a cam profile with several pitch curve slopes. 10. The device of claim 2 , wherein the cam is configured to operate according to a cam profile, wherein the cam profile comprises one or more of: a convex segment, a concave segment, and a convex-concave segment. 11. The device of claim 1 , wherein the curved ankle torque versus ankle angle plot extends between an ankle torque of 0 Nm/Kg and 2 Nm/Kg. 12. The device according to claim 1 , further comprising a DC-DC converter configured to improve an induced voltage of the motor in the prosthetic device for charging a battery when the motor works as a generator to harvest a negative mechanical energy during some phases of the gait of the amputee. 13. The device of claim 1 , wherein the prosthetic device is configured to operate in both a powered mode and a passive mode, the prosthetic device having a total output torque at the ankle angle joint at any given time, wherein in the passive mode, the total output torque includes only the spring output torque of the parallel spring mechanism; and in the powered mode, the total output torque includes the motor output torque in addition to the spring output torque of the parallel spring mechanism. 14. The device of claim 13 , wherein the motor is configured to provide a damping torque during the initial phase of the controlled dorsiflexion. 15. The device of claim 1 , wherein the parallel spring mechanism is configured to engage only when the ankle angle is larger than zero, zero being when the shin bracket is perpendicular to the bracket support foot, to ensure the prosthetic device rotates freely during the swing phase. 16. The device of claim 1 , further comprising: an ankle angle sensor configured for detecting the ankle angle between the shin bracket and the bracket support foot; and a controller in communication with an output of the ankle angle sensor, the controller configured for distinguishing between gait phases of the amputee based, at least in part, on the output of the ankle angle sensor, wherein the prosthetic device is configured such that: after an initial phase of the controlled dorsiflexion phase, a total torque output of the prosthetic device is provided by the spring torque output of the parallel spring mechanism without any motor torque output; when the powered plantarflexion phase of the stance phase is indicated, the total torque output of the prosthetic device is provided by the motor output torque in addition to the spring torque output of the parallel spring mechanism. 17. The device of claim 16 , further comprising: a force sensor arranged and configured for measuring prosthetic axial force applied by the amputee on the prosthetic device, wherein the controller is in communication with an output of the force sensor and configured to distinguish between gait phases of the amputee based, at least in part, on the outputs of the force sensor and the ankle angle sensor.