Prosthetic knee with swing assist

What is claimed is: 1. A knee prosthesis, comprising: a shank link; a thigh link rotatably coupled to the shank link; at least one resistive control element configured to apply first, second, and third levels of resistance in resisting rotation of the thigh link relative to the shank link; at least one powered control element, distinct and separate from the resistive control element, configured to power rotation of the thigh link relative to the shank link; wherein the at least one powered control element comprises an electric motor coupled to the thigh link and the shank link through a power screw transmission; at least one sensor; and a controller, coupled to the at least one sensor, the controller configured to: receive sensor measurements from the at least one sensor and determine, based at least on the sensor measurements, a present state of a plurality of slates comprising at least a swing state, a stance state, and a stair descent state; cause the at least one resistive control element to apply a first level of resistance if the present state is a swing state; cause the at least one resistive control element to apply a second level of resistance if the present state is a stance state; cause the at least one resistive control element to apply a third level of resistance if the present state is a stair descent state; and cause the at least one powered control element to power rotation if the present state is a swing state. 2. The knee prosthesis of claim 1 , wherein the controller is further configured to: provide a desired swing knee motion trajectory if the present state is a swing state; determine a magnitude of the first level of resistance based on the desired swing knee motion trajectory; measure knee motion in the swing state; determine a knee motion error, wherein determining the knee motion error comprises determining a difference between the desired swing knee motion trajectory and the measured knee motion; and provide a powered assistance from the at least one powered control element to the knee prosthesis, wherein the powered assistance is configured to reduce the knee motion error in the swing state. 3. The knee prosthesis of claim 2 , wherein the plurality of states further comprises a stair descent swing state, and the controller is further configured to: provide a desired swing knee motion trajectory if the present state is a stair descent swing state; determine a magnitude of the first level of resistance based on the desired swing knee motion trajectory; measure knee motion in the stair descent swing state; determine a knee motion error, wherein determining the knee motion error comprises determining a difference between the desired swing knee motion trajectory and the measured knee motion; and provide a powered assistance from the at least one powered control element to the knee prosthesis, wherein the powered assistance is configured to reduce the knee motion error in the stair descent swing state. 4. The knee prosthesis of claim 2 , wherein the plurality of states further comprises a stair ascent swing state, and the controller is further configured to: provide a desired swing knee motion trajectory if the present state is a stair ascent swing state; measure knee motion in the stair ascent swing state; determine a knee motion error, Wherein determining the knee motion error comprises determining a difference between the desired swing knee motion trajectory and the measured knee motion; and provide a powered assistance from the at least one powered control element to the knee prosthesis, wherein the powered assistance is configured to reduce the knee motion error in the stair ascent swing state. 5. The knee prosthesis of claim 1 , where the at least one resistive control element further comprises a hydraulic actuator cylinder, the hydraulic actuator cylinder coupled to, knee joint and configured to provide the first, second, and third levels of resistance based on hydraulic fluid flow through a hydraulic valve, wherein the hydraulic fluid flow is generated by knee joint rotation. 6. The knee prosthesis of claim 5 , wherein the hydraulic valve comprises an orifice configured to couple to one of a first, second, and third orifice opening, wherein each orifice opening provides one of the first, second, and third levels of resistance. 7. The knee prosthesis of claim 5 , wherein the at least one powered control element comprises an electric motor coupled to the thigh link and the shank link through a power screw transmission, the power screw transmission located within a rod of the hydraulic cylinder actuator. 8. The knee prosthesis of claim 2 , Wherein a peak knee flexion of the desired swing knee motion trajectory depends on a measured walking cadence of a user. 9. A knee prosthesis, comprising: a shank link; a thigh link rotatably coupled to the shank link; at least one resistive control element configured to apply first, second, and third levels of resistance in resisting rotation of the thigh link relative to the shank link; at least one powered control element, distinct and separate from the resistive control element, configured to power rotation of the thigh link relative to the shank link; at least one sensor; and a controller, coupled to the at least one sensor, the controller configured to: receive sensor measurements from the at least one sensor and determine, based at least on the sensor measurements, a present state of a plurality of states comprising at least a swing state, a stance state, and a stair descent state; cause the at least one resistive control element to apply a first level of resistance if the present state is a swing state; cause the at least one resistive control element to apply a second level of resistance if the present state is a stance state; cause the at least one resistive control element to apply a third level of resistance if the present state is a stair descent state; and cause the at least one powered control element to power rotation if the present state is a swing state, wherein the at least one resistive control element further comprises a hydraulic actuator cylinder, the hydraulic actuator cylinder coupled to a knee joint and configured to provide the first, second, and third levels of resistance based on hydraulic fluid flow through a hydraulic valve, wherein the hydraulic fluid flow is generated by knee joint rotation, wherein the hydraulic valve comprises an orifice configured to couple to one of a first, second, and third orifice opening, wherein each orifice opening provides one of the first, second, and third levels of resistance, wherein the at least one powered control element comprises an electric motor coupled to the thigh link and the shank link through a power screw transmission, the power screw transmission located within a rod of the hydraulic cylinder actuator. 10. The knee prosthesis of claim 9 , wherein the controller is further configured to: provide a desired swing knee motion trajectory if the present state is a swing state; determine a magnitude of the first level of resistance based on the desired swing knee motion trajectory; measure knee motion in the swing state; determine a knee motion error, wherein determining the knee motion error comprises determining a difference between the desired swing knee motion trajectory and the measured knee motion; and provide a powered assistance from the at least one powered control element to the knee prosthesis, wherein the powered assistance is configured to reduce the knee motion error in the swing state. 11. The knee prosthesis of claim 10 , wherein the plurality of states further comprises a stair descent