Human machine interfaces for lower extremity orthotics

We claim: 1. A powered lower extremity orthotic, configurable to be coupled to a person, said powered lower extremity orthotic comprising: an exoskeleton including, a waist portion configurable to be coupled to an upper body of the person, leg supports configurable to be coupled to lower limbs of the person and actuators for shifting of the leg supports relative to the waist portion to enable movement of the lower limbs of the person; a gait aid for use in further supporting the person; a controller configured to receive an intended motion of the person from a human machine interface configured to estimate the intended motion by directly observing motion of an upper arm, a lower arm or a palm of a hand of the person; said controller further configured to monitor which of the leg supports of said powered lower extremity orthotic are in contact with the ground; said controller further configured to store in a memory a current state of the powered lower extremity orthotic, said current state containing information including which of said leg supports are in contact with the ground, if the gait aid is in contact with the ground, and a sequence in which said leg supports and the gait aid contacted the ground; said controller further configured to maintain, in the memory, a set of safe states to which the powered lower extremity orthotic can transition from the current state without causing the person to fall; said controller further configured to wait until the intended motion appears to request one of said safe states; and said controller further configured to transition to said one of said safe states. 2. The powered lower extremity orthotic of claim 1 , wherein said safe states in said memory are determined through reachability analysis. 3. The powered lower extremity orthotic of claim 1 , wherein said leg supports include sensors that are configured to measure a first distribution of weight on the ground when said leg supports contact the ground and are also configured to measure a second distribution of weight on the ground when said gait aid contacts the ground; and said controller being further configured to determine said set of safe states based on said first and second weight distributions on the ground. 4. The powered lower extremity orthotic of claim 1 , wherein the exoskeleton has a camera and said human machine interface is configured to estimate the intended motion by observing, with the camera, motion of an upper arm, a lower arm or a palm of a hand of the person. 5. The powered lower extremity orthotic of claim 1 , wherein said human machine interface is configured to estimate the intended motion by directly observing motion of the gait aid. 6. A powered lower extremity orthotic, configurable to be coupled to a person, said powered lower extremity orthotic comprising: an exoskeleton including a waist portion configurable to be coupled to an upper body of the person, at least one leg support configurable to be coupled to at least one lower limb of the person and at least one actuator for shifting of the at least one leg support relative to the waist portion to enable movement of the at least one lower limb of the person; a controller configured to receive an intended motion of the person from a human machine interface that is configured to estimate the intended motion by directly observing motion of an upper arm, a lower arm or a palm of a hand of the person; said controller further configured to maintain a plurality of states representing various gait cycles and phases of the gait cycles; said controller further configured to maintain at least one transition from each of said plurality of states to at least one other of said plurality of states, said at least one transition being allowed to be taken based on the intended motion and said plurality of states; said controller further configured to operate said powered lower extremity orthotic in a current state until conditions of said at least one transition are met and then transition to the at least one other of said plurality of states; and said controller is further configured to use machine learning to determine said transitions. 7. The powered lower extremity orthotic of claim 6 , further including: said controller further configured to receive desired state transitions; and said controller further configured to use the machine learning to modify when a transition may be taken based on the intended motion of the person and said plurality of states so that said transitions will closely match said desired state transitions. 8. The powered lower extremity orthotic of claim 7 , wherein said desired state transitions are configured to be selected by a second person who is medically trained. 9. The powered lower extremity orthotic of claim 7 , wherein said desired state transitions are configured to be selected retrospectively. 10. A method of controlling a powered lower extremity orthotic including an exoskeleton having, a waist portion configurable to be coupled to an upper body of a person utilizing a gait aid, leg supports configurable to be coupled to lower limbs of the person and actuators for shifting of the leg supports relative to the waist portion to enable movement of the lower limbs of the person, the method comprising: estimating an intended motion by directly observing motion of an upper arm, a lower arm or a palm of a hand of the person; receiving the intended motion of the person from a human machine interface; monitoring which of the leg supports of said powered lower extremity orthotic are in contact with the ground; storing in a memory a current state of the powered lower extremity orthotic, with said state containing information including which of said leg supports are in contact with the ground, if the gait aid is in contact with the ground, and a sequence in which said leg supports and the gait aid contacted the ground; determining if the intended motion appears to request one of a set of safe states, stored in the memory, to which the powered lower extremity orthotic can transition from the current state without causing the person to fall; and transitioning the powered lower extremity orthotic to said one of said safe states. 11. The method of claim 10 , further comprising: determining where said safe states are through reachability analysis. 12. The method of claim 10 , wherein said leg supports include sensors that are configured to measure a first distribution of weight on the ground when said leg supports contact the ground and are also configured to measure a second distribution of weight on the ground when said at least one gait aid contacts the ground, said method further comprising: determining said set of safe states based on said first and second weight distributions. 13. The method of claim 10 , further comprising estimating the intended motion with the human machine interface by observing motion of an upper arm, a lower arm or a palm of a hand of the person. 14. The method of claim 10 , further comprising estimating the intended motion with the human machine interface by observing motion of the gait aid.