System and method for providing biomechanically suitable running gait in powered lower limb devices

What is claimed is: 1. A lower limb device comprising: a powered knee joint comprising a first motor for providing an output torque at the powered knee joint; a powered ankle joint comprising a second motor for providing an output torque at the powered ankle joint; at least one sensor for collecting real-time sensor information for the lower limb device; at least one processor communicatively coupled to the at least one sensor and to the powered knee joint; and a computer-readable medium, having stored thereon instructions for causing the at least one processor to: operate the powered knee joint and the powered ankle joint according to a finite state model for a running mode, wherein the finite state model comprises an absorption phase, a propulsion phase, a swing flexion phase, and a swing extension phase, wherein the absorption phase is configured to transition to the propulsion phase, wherein the propulsion phase is configured to transition to the swing flexion phase, wherein the swing flexion phase is configured to transition to the swing extension phase, and wherein the swing extension mode is configured to transition to the absorption phase, wherein transitions occur repeatedly until an activity mode of the lower limb device changes from the running mode, wherein the absorption phase comprises: transitioning into the absorption phase by detecting, at the at least one sensor, that a load on the lower limb device increased above a first threshold; and, wherein the knee and ankle joints are each configured in the absorption phase to behave as a combined stiffness and damping, wherein the stiffness and damping components are configured such that the powered knee and ankles joints synchronously absorb energy associated with decelerating a vertical motion of a body center of mass; wherein the propulsion phase comprises: transitioning into the propulsion phase by detecting, at the at least one sensor, that the powered knee joint has absorbed the load on the lower limb device; and, wherein the knee and ankle joints are each configured in the propulsion phase such that the powered knee and ankles joints synchronously generate energy associated with accelerating the vertical motion of the body center of mass. 2. The lower limb device of claim 1 , wherein a duration of the propulsion phase is roughly equal to a length of the absorption phase. 3. The lower limb device of claim 1 , wherein the propulsion phase further comprises a first sub-mode and a second sub-mode, wherein the first sub-mode comprises active extension and plantarflexion of both the powered knee joint and the powered ankle joint, and wherein the second sub-mode comprises flexing of the powered knee joint while the powered ankle joint continues to plantarflex to assist the flexing of the powered knee joint. 4. The lower limb device of claim 3 , wherein the lower limb device transitions from the first sub-mode to the second sub-mode when the powered knee joint reaches a peak stance knee extension. 5. The lower limb device of claim 1 , wherein the swing flexion phase comprises: transitioning into the swing flexion phase by detecting, at the at least one sensor, a load on the lower limb device decreased below a second threshold; flexing the powered knee joint; and configuring the powered ankle joint to a dorsiflexed state. 6. The lower limb device of claim 1 , wherein the swing extension phase comprises: transitioning into the swing extension phase by detecting, at the at least one sensor, that a velocity of the powered knee joint is at a threshold velocity for extension; further extending the powered knee joint; detecting, at the at least one sensor, that a load on the lower limb device increased above the first threshold; and completing the swing extension mode. 7. The lower limb device of claim 1 , wherein the computer-readable medium further comprises instructions for causing the at least one processor to: selecting the running mode for the lower limb device based on the real-time sensor information during a walking mode prior to operating the powered knee joint and the powered ankle joint, wherein a transition between the walking mode and the running mode is based on a measurement of at least one of a load or acceleration at foot strike, a stance time, a swing time, or a stride time. 8. The lower limb device of claim 1 , wherein the transitioning into the absorption phase further comprises: providing for a plantarflexion of the powered ankle joint under the load; and providing for, based on the real-time sensor information, a dorsiflexion of the powered ankle joint as a center of mass of the load passes over a foot associated with the powered ankle joint. 9. The lower limb device of claim 1 , wherein the transitioning into the absorption phase further comprises configuring the stiffness and damping components for the powered knee joint to cause a flexion of the powered knee joint under the load. 10. The lower limb device of claim 1 , wherein the transitioning of the propulsion phase further comprises detecting, at the at least one sensor, that a velocity of the powered knee joint is at a threshold velocity for flexion. 11. The lower limb device of claim 1 , wherein operating the powered knee joint and the powered ankle joint further comprises: selecting an impedance parameter value and an equilibrium angle parameter value for each of the powered knee joint and the powered ankle joint according to a current phase of the finite state model, wherein the impedance parameter value characterizes a resistance to change in a joint angle and wherein the equilibrium angle parameter value indicates the joint angle required in the absence of the load, and generating an output torque of the powered knee joint and an output torque of the powered ankle joint according to a pre-defined relationship between a joint torque, the impedance parameter value, the equilibrium angle parameter value, a joint angle, and a joint angular velocity. 12. The lower limb device of claim 1 , wherein the knee and ankle joints are each configured in the propulsion phase to behave as a combined stiffness and damping, wherein the stiffness and damping components are configured such that the powered knee and ankles joints synchronously generate energy associated with accelerating the vertical motion of the body center of mass.