Prosthetic apparatus and method therefor

What is claimed is: 1. An apparatus comprising: a mechanical actuator configured and arranged to position a prosthetic foot having a front ball region and a rear heel region for respectively contacting a surface along which a user of the prosthetic foot is travelling, by moving the rear heel region relative to the front ball region; a sensor circuit configured and arranged to sense movement parameters pertaining to movement of the user; and a control circuit configured and arranged with the sensor circuit to determine a state of movement of the user, including a speed at which the user is travelling along the surface, based on the movement parameters sensed by the sensor circuit, and dynamically position the prosthetic foot in response to the speed at which the user is travelling along the surface, by manipulating the mechanical actuator to move the rear heel region relative to the front ball region while the user is travelling along the surface, based on changes in the speed. 2. The apparatus of claim 1 , wherein the control circuit is configured and arranged with the sensor circuit to dynamically position the prosthetic foot in response to the speed at which the user is travelling along the surface, by manipulating the mechanical actuator to move the rear heel region toward or away from the front ball region, based on the changes in the speed. 3. The apparatus of claim 1 , wherein the control circuit is configured and arranged with the sensor circuit to dynamically position the prosthetic foot in response to the speed at which the user is travelling along the surface, by manipulating the mechanical actuator to increase or decrease the height of the rear heel region relative to the front ball region, based on the changes in the speed. 4. The apparatus of claim 3 , wherein the control circuit is configured and arranged with the sensor circuit to dynamically position the prosthetic foot in response to the speed at which the user is travelling along the surface by manipulating the mechanical actuator to increase the height of the rear heel region relative to the front ball region as the speed increases, and to decrease the height of the rear heel region relative to the front ball region as the speed decreases. 5. The apparatus of claim 3 , wherein the mechanical actuator includes a lever system configured and arranged to raise and lower the heel region relative to the ball region and to lock the heel region in place. 6. The apparatus of claim 3 , further including a heel member and a ball member, respectively coupled to the heel region and the ball region and configured and arranged to support the user's weight when the prosthetic foot is in contact with the surface, the heel member being connected to the ball member at a joint, the actuator being configured and arranged to increase or decrease the height of the rear heel region by pivoting the heel member relative to the ball member at the joint. 7. The apparatus of claim 6 , wherein the actuator includes a screw mechanism affixed to the ball member and to the heel member, the screw mechanism being configured and arranged to pivot the heel member relative to the ball member via actuation of a screw. 8. The apparatus of claim 1 , wherein the control circuit is configured and arranged with the sensor circuit to dynamically position the prosthetic foot under conditions in which the prosthetic foot is not under load, and to lock the prosthetic foot in position under conditions in which the prosthetic foot contacts the surface. 9. The apparatus of claim 8 , wherein the control circuit is configured and arranged to use the sensed movement parameters to identify periods during which the prosthetic foot is not under load and periods during which the prosthetic foot is under load, and to dynamically position or lock the prosthetic foot based on the identified periods. 10. The apparatus of claim 1 , wherein the control circuit is configured and arranged with the sensor circuit to dynamically position the prosthetic foot in response to the speed at which the user is travelling along the surface by manipulating the mechanical actuator to move the ball region downward to promote a forefoot-striking running gait as the speed increases. 11. The apparatus of claim 1 , wherein the mechanical actuator is configured and arranged to alter stiffness of at least one region of the prosthetic foot that makes contact with the surface, and the control circuit is configured and arranged with the sensor circuit to manipulate the mechanical actuator to alter the stiffness of the at least one region of the prosthetic foot based on the determined speed. 12. The apparatus of claim 1 , wherein the mechanical actuator is configured and arranged to alter the effective length of the user's leg, with the effective length including the prosthetic foot, and the control circuit is configured and arranged with the sensor circuit to manipulate the mechanical actuator to alter the effective length of the user's leg based on the sensed movement parameters. 13. The apparatus of claim 1 , wherein the control circuit is configured and arranged with the sensor circuit to generate a real-time reconstruction of motion of the prosthetic foot, and to dynamically position the heel region relative to the ball region based on the real-time reconstruction of motion of the prosthetic foot. 14. The apparatus of claim 1 , further including the prosthetic foot and a motor, the motor being configured and arranged to move the mechanical actuator to position the prosthetic foot, in response to inputs from the control circuit. 15. The apparatus of claim 1 , wherein the control circuit is configured and arranged to predict future movement of the prosthetic foot relative to the surface based on the sensed movement parameters detected over time, and to dynamically position the prosthetic foot based on the predicted future movement of the prosthetic foot. 16. An apparatus comprising: a mechanical actuator configured and arranged to position a prosthetic foot having a front ball region and a rear heel region for respectively contacting a surface along which a user of the prosthetic foot is travelling; a sensor circuit configured and arranged to sense movement parameters pertaining to movement of the user; and a control circuit configured and arranged with the sensor circuit to determine a state of movement of the user, including a speed at which the user is travelling along the surface, based on the movement parameters sensed by the sensor circuit, and dynamically position the prosthetic foot while the user is moving in response to the speed at which the user is travelling along the surface by manipulating the mechanical actuator to move the rear heel region relative to the front ball region based on changes in the speed and to gradually eliminate the heel region from contributing to contact between the prosthetic foot and ground as the speed increases. 17. An apparatus comprising: a mechanical actuator configured and arranged to position a prosthetic foot having a front ball region and a rear heel region for respectively contacting a surface along which a user of the prosthetic foot is travelling; and a control circuit configured and arranged with the mechanical actuator to determine a state of movement of the user, including a speed at which the user is travelling along the surface, and to cause the mechanical actuator to move the rear heel region relative to the front ball region based on changes in the speed, by at least one of: increasing or decreasing the height of the rear heel reg