Powered ankle-foot prosthesis

What is claimed is: 1. An artificial ankle-foot device for an orthosis, prosthesis or exoskeleton, comprising: a) a first member and a second member that are connected for movement relative to one another and thereby define an ankle joint; b) an ankle actuator linked between the first and second members, the actuator including i) a motor, ii) a transmission, and iii) a series spring in series with the motor, iv) wherein the transmission is non-backdriveable; c) at least one of i) a joint position sensor, ii) a motor position sensor, and iii) an inertial measurement unit (IMU); d) a processor communicatively linked to the ankle actuator and the at least one sensor, the processor configured to receive sensory information from the at least one sensor, wherein the processor controls the motor to adjust the ankle joint spring equilibrium position during the swing phase of a gait cycle to improve ankle-foot device function during the subsequent stance phase, wherein once the ankle joint spring equilibrium position has been adjusted during the swing phase, the motor turns off to conserve power-supply energy during the subsequent stance period. 2. The ankle-foot device of claim 1 , wherein the processor adapts the ankle joint spring equilibrium position to environmental conditions. 3. The ankle-foot device of claim 2 , wherein the environmental conditions include walking speed and surface terrain. 4. The ankle-foot device of claim 1 , wherein the at least one sensor includes the IMU, and wherein accelerations measured using the IMU are integrated with the processor after subtracting the acceleration component of gravity to estimate linear positions of the ankle-foot device. 5. The ankle-foot device of claim 4 , wherein the estimated linear positions are used to detect stair ascent and descent, and ramp ascent and descent patterns, and based on these gait patterns the processor adjusts ankle joint spring equilibrium position to improve ankle function. 6. The ankle-foot device of claim 1 , wherein the first member is a composite foot and the second member is a spring housing. 7. An artificial ankle-foot device for an orthosis, prosthesis or exoskeleton, comprising: a) a first member and a second member that are connected for movement relative to one another and thereby define an ankle joint; b) an ankle actuator linked between the first and second members, the actuator including i) a motor, ii) a transmission, and iii) a series spring, iv) wherein the transmission is non-backdriveable; c) at least one sensor including an inertial measurement unit (IMU); d) a processor communicatively linked to the ankle actuator and the at least one sensor, the processor configured to receive sensory information from the at least one sensor, wherein the processor controls the ankle joint spring equilibrium position during the swing phase of a gait cycle to improve ankle-foot device function during the subsequent stance phase, wherein accelerations measured using the IMU are integrated with the processor after subtracting the acceleration component of gravity to estimate linear positions of the ankle-foot device, the estimated linear positions being used to detect stair ascent and descent, and ramp ascent and descent patterns, and based on these gait patterns the processor adjusting ankle joint spring equilibrium position to improve ankle function. 8. An artificial ankle-foot device for an orthosis, prosthesis or exoskeleton, comprising: a) a first member and a second member that are connected for movement relative to one another and thereby define an ankle joint; b) an ankle actuator linked between the first and second members, the actuator including i) a motor, ii) a transmission, and iii) a series spring in series with the motor, iv) wherein the transmission is non-backdriveable; c) at least one sensor including an inertial measurement unit (IMU); and d) a processor communicatively linked to the ankle actuator and the at least one sensor, the processor configured to receive sensory information from the at least one sensor, wherein the processor controls the motor to adjust the ankle joint spring equilibrium position during the swing phase of a gait cycle to improve ankle-foot device function during the subsequent stance phase, wherein accelerations measured using the IMU are integrated with the processor after subtracting the acceleration component of gravity to estimate linear positions of the ankle-foot device.