Fluidic robotic actuator system and method

What is claimed is: 1. A robotic manipulator comprising: a plurality of actuators configured to assume at least a neutral position, each of the actuators including: a first and second plate defining respective planar portions that are disposed in parallel planes in the neutral position; four elongated cylindrical bellows extending between the first and second plate and disposed in a square arrangement, the bellows each having a central main axis that is parallel to the central main axis of the other bellows in the neutral position, the main axis of the bellows being perpendicular to the parallel planes of the first and second plate in the neutral position, the bellows being coupled to the first and second plate at respective first and second ends, the bellows comprising convolutions along a length of the bellows between the first and second plate with the convolutions being defined by valley and peak portions; an elongated spine extending between and coupled to the first and second plate, the spine disposed centrally within a cavity between the four bellows, the spine configured to bend but not expand or contract along the length of the spine; dampening foam disposed in at least one of: within an internal cavity defined by the bellows; within the cavity between the four bellows and engaging the four bellows; and surrounding the four bellows; and a plurality of ribs disposed within the cavity and extending between the four bellows, each of the ribs engaging each of the four bellows in the valley portions of the convolutions, with the ribs extending in respective rib planes that are parallel to the parallel planes of the first and second plate in the neutral position; a plurality of linkages, with a first linkage coupling a first and second actuator of the plurality of actuators, the first linkage disposed between the first and second actuator in series; an end effector coupled to a distal end of the robotic manipulator; a shared fluid source that is fluidically coupled with each of the bellows of the plurality of actuators via one or more fluid lines that at least extend internally through the series of the first linkage and the first and second actuator down the center of the first and second actuators; and a control system configured to control movement of the actuators by selectively changing a fluid pressure of individual bellows of the plurality of actuators via control lines that extend internally through the series of the first linkage and the first and second actuator. 2. The robotic manipulator of claim 1 , further comprising a further actuator, the further actuator configured to assume a neutral position and comprising: a first and second further plate defining respective planar portions that are disposed in parallel planes in the neutral position; eight elongated cylindrical bellows extending between the first and second plate and disposed in an octagonal arrangement, the bellows of the further actuator each having a central main axis that is parallel to the central main axis of the other bellows of the further actuator in the neutral position, the main axis of the bellows of the further actuator being perpendicular to the parallel planes of the first and second further plate in the neutral position, the bellows of the further actuator being coupled to the first and second further plate at respective first and second ends, the bellows of the further actuator comprising convolutions along a length of the bellows between the first and second further plate with the convolutions of the further actuator being defined by valley and peak portions; an elongated further spine extending between and coupled to the first and second further plates, the further spine disposed centrally within a second cavity between the eight bellows of the further actuator, the further spine configured to bend but not expand or contract along the length of the further spine; and a plurality of further ribs disposed within the second cavity and extending between the eight bellows of the further actuator, each of the further ribs engaging each of the eight bellows in the valley portions of the convolutions, with the further ribs extending in respective rib planes that are parallel to the parallel planes of the first and second further plates in the neutral position. 3. The robotic manipulator of claim 1 , wherein each of the plurality of actuators comprise a sensor configured to measure a joint angle of the actuator. 4. The robotic manipulator of claim 1 , wherein each of the plurality of actuators comprise a reinforcing line that surrounds and resides within a portion of a valley of at least one bellows, the reinforcing line being a portion of a wrapping that includes one of: a wrapping that peripherally surrounds the four bellows on respective external faces of the bellows and within valleys of the four bellows; a wrapping that completely surrounds at least one valley of a single bellows; and a wrapping that incompletely surrounds at least one valley of a single bellows. 5. A fluidic robotic actuator configured to assume at least a neutral position, the fluidic robotic actuator comprising: a first and second plate defining respective planar portions that are disposed in parallel planes in the neutral position; four elongated cylindrical bellows extending between the first and second plate and disposed in a square arrangement, the bellows each having a central main axis that is parallel to the central main axis of the other bellows in the neutral position, the main axis of the bellows being perpendicular to the parallel planes of the first and second plate in the neutral position, the bellows being coupled to the first and second plate at respective first and second ends, the bellows comprising convolutions along a length of the bellows between the first and second plate with the convolutions being defined by valley and peak portions; an elongated spine extending between and coupled to the first and second plate, the spine disposed centrally within a cavity between the four bellows, the spine configured to bend but not expand or contract along the length of the spine; dampening foam disposed in at least one of: within an internal cavity defined by the bellows; within the cavity between the four bellows and engaging the four bellows; and surrounding the four bellows; and a plurality of ribs disposed within the cavity and extending between the four bellows, each of the ribs engaging each of the four bellows in the valley portions of the convolutions, with the ribs extending in respective rib planes that are parallel to the parallel planes of the first and second plate in the neutral position. 6. The fluidic robotic actuator of claim 5 , further comprising a sensor configured to measure changes in a distance between two locations of the actuator occurring during actuation of the actuator, the measured changes for calculating a joint angle in one plane of the actuator. 7. The fluidic robotic actuator of claim 5 , further comprising a reinforcing line that surrounds and resides within a portion of a valley of at least one bellows, the reinforcing line being a portion of a wrapping that includes one of: a wrapping that peripherally surrounds the four bellows on an external face within valleys of the four bellows; a wrapping that completely surrounds at least one valley of a single bellows; and a wrapping that incompletely surrounds at least one valley of a single bellows. 8. A fluidic robotic actuator configured to assume at least a neutral position, the fluidic robotic actuator comprising: a first and second plate defining respective planar portions that are disposed in parallel planes in the neutral position; and a plurality of elongated bellows