Method and apparatus for human arm supporting exoskeleton

What is claimed is: 1 . An arm supporting exoskeleton configured to be coupled to a person comprising: a shoulder base configured to be coupled to a trunk of the person; and an arm link mechanism configured to be coupled to said shoulder base, the arm link mechanism comprising: a proximal link and a distal link configured to rotate relative to each other about a rotating joint and along a first rotational axis substantially orthogonal to a gravity line when said person is standing upright; at least one arm-coupler adapted to couple an upper arm of the person to said distal link; a tensile force generator coupled to said proximal link at a first end of the tensile force generator and coupled to said distal link at a second end of the tensile force generator, the tensile force generator providing a torque to flex said distal link relative to said proximal link; and a protrusion located substantially at said rotating joint, wherein: when said distal link extends past a toggle angle, said protrusion constrains said tensile force generator, and the torque provided by said tensile force generator remains substantially small; and when said protrusion does not constrain said tensile force generator, said torque has the tendency to flex said distal link relative to said proximal link, thereby reducing human shoulder forces and torques required to raise said upper arm of the person. 2 . An arm supporting exoskeleton configured to be coupled to a person comprising: a shoulder base configured to be coupled to a trunk of the person; and an arm link mechanism configured to be coupled to said shoulder base, the arm link mechanism comprising: a proximal link and a distal link configured to rotate relative to each other about a rotating joint and along a first rotational axis substantially orthogonal to a gravity line when said person is standing upright; at least one arm-coupler adapted to couple an upper arm of the person to said distal link; and a tensile force generator coupled to said proximal link at a first end of the tensile force generator and coupled to said distal link at a second end of the tensile force generator, the tensile force generator providing a torque to flex said distal link relative to said proximal link, wherein: when said arm support exoskeleton is coupled to said person and an angle between said proximal link and said distal link is smaller than a toggle angle, said torque has the tendency to flex said distal link relative to said proximal link, thereby reducing human shoulder forces and torques required to raise said upper arm of the person, and imposing reaction forces and torques on said shoulder base; and when said angle between said proximal link and said distal link is larger than said toggle angle, said tensile force generator provides a substantially small torque between said proximal link and said distal link, allowing said person to move said upper arm of the person freely. 3 . An arm supporting exoskeleton configured to be coupled to a person comprising: a shoulder base configured to be coupled to a trunk of the person; an arm link mechanism configured to be coupled to said shoulder base, the arm link mechanism comprising: a proximal link and a distal link configured to rotate relative to each other along a first rotational axis substantially orthogonal to a gravity line when said person is standing upright; at least one arm-coupler adapted to couple an upper arm of the person to said distal link; at least one torque generator configured to generate a torque between said proximal link and said distal link, wherein: when said arm support exoskeleton is coupled to said person and an angle between said proximal link and said distal link is smaller than a toggle angle, said torque has a tendency to flex said distal link relative to said proximal link, thereby reducing human shoulder forces and torques required to raise the upper arm of the person and imposing reaction forces and torques on said shoulder base; and when said angle between said proximal link and said distal link is larger than said toggle angle, said torque generator provides a substantially small torque between said proximal link and said distal link allowing said person to move said upper arm of the person freely. 4 . The arm supporting exoskeleton of claim 3 , wherein said shoulder base comprises: a load bearing structure coupled to said arm link mechanism supporting said reaction forces and torques on said shoulder base; and a coupling mechanism coupling said load bearing structure to the trunk of the person such that the shoulder base moves in unison with the trunk of the person. 5 . The arm supporting exoskeleton of claim 4 , wherein said load bearing structure comprises: a back frame located substantially behind a back of the person, the back frame coupled to said arm link mechanism and supporting at least a portion of said reaction forces and torques from said arm link mechanism; and at least one hip loading belt coupled to said back frame, wherein said hip loading belt transfers at least a portion of said reaction forces and torques from said back frame to hips of the person. 6 . The arm supporting exoskeleton of claim 4 , wherein said load bearing structure comprises: a back frame located substantially behind a back of the person, the back frame coupled to said arm link mechanism and supporting at least a portion of said reaction forces and torques from said arm link mechanism; and a lower extremity exoskeleton configured to be coupled to said back frame and to legs of the person, wherein said lower extremity exoskeletons transfers at least a portion of said reaction forces and torques from said back frame to a support surface on which the person is standing. 7 . The arm supporting exoskeleton of claim 5 , wherein said back frame comprises: an upper frame coupled to said arm link mechanism; a lower frame coupled to said hip loading belt; and a spine frame, wherein said spine frame is coupled to said upper frame on an upper end of the spine frame and is rotatably coupled to said lower frame on a lower end of the spine frame, allowing for rotation of said upper frame relative to said lower frame in a frontal plane of the person. 8 . The arm supporting exoskeleton of claim 5 , wherein said back frame comprises: an upper frame coupled to said arm link mechanism; a lower frame coupled to said hip loading belt; and a spine frame, wherein said spine frame is coupled to said lower frame on a lower end of the spine frame, and is rotatably coupled to said upper frame on an upper end of the spine frame, allowing for rotation of said upper frame relative to said lower frame along a major axis of said spine frame. 9 . The back frame of claim 8 , wherein said lower frame comprises: a lower middle bar; and first and second lower corner bars, wherein each of the first and second lower corner bars is adapted to be coupled to said lower middle bar at various locations on said lower middle bar to provide selective hip width adjustment for said lower frame. 10 . The back frame of claim 8 , wherein said lower frame further comprises first and second lower side brackets, wherein each of said first and second lower side brackets is adapted to be coupled to a body of said lower frame at various locations on said lower frame to provide selective hip depth adjustment for said lower frame. 11 . The back frame of claim 8 , wherein said upper frame comprises: a upper middle bar; and first and second upper corner bars, wherein each of the first and second upper corner bars is adapted to be coupled to said upper middle bar at various locations on said upper middle ba