Robotic actuator

What is claimed is: 1. A robotic device that comprises: a plurality of fluidic actuators configured to bend about an axis in response to fluid being introduced to or fluid being released from at least a first and second separate fluid chamber of the fluidic actuators, with each fluidic actuator having position, pressure and stiffness individually controlled by fluid being introduced to or fluid being released from at least a first and second separate fluid chamber, with each fluidic actuator configured to expand and elongate along a central axis length in response to fluid being introduced to the respective fluid chambers, and with each fluidic actuator comprising a first and second fluid valve collocated with the fluidic actuator; a plurality of networked embedded nodes being collocated at a respective fluidic actuator, with each of the nodes configured for sensing and computation, including estimation of at least a portion of a state of the robotic device, execution of at least a portion of control of the robotic device, the plurality of networked embedded nodes configured for coordinated control of position, pressure and stiffness at each fluidic actuator based on data from the plurality of networked embedded nodes; and a plurality of couplers respectively associated with at least one fluidic actuator including a first fluidic actuator coupled to a first coupler, a second fluidic actuator coupled to a second coupler and the second fluidic actuator coupled to the first coupler, wherein the first and second fluidic actuator and first and second coupler define a length between a first and second end with the first coupler disposed between the first and second fluidic actuator and with the second fluidic actuator disposed between the first and second coupler. 2. The robotic device of claim 1 , wherein the robotic device further comprises a manipulator and wherein the coordinated control of position, pressure and stiffness at each fluidic actuator based on data from the plurality of networked embedded nodes controls at least one of movement of the manipulator, position of the manipulator, configuration of the manipulator, or force applied between the manipulator and external objects. 3. The robotic device of claim 1 , wherein position, pressure and stiffness of the fluidic actuators is controlled by the embedded nodes based at least in part on obtained sensing signals associated with two or more of: actuator position, actuator velocity, volume flow rate to or from each fluid chamber of an actuator, mass flow rate into or out of each fluid chamber of an actuator, and properties in each fluid chamber of an actuator, and wherein control signals to control the fluidic actuators are determined based at least in part on the obtained sensing signals to close a feedback loop. 4. The robotic device of claim 1 , wherein the fluid chambers of the fluidic actuators expand axially when fluid is introduced to the fluid chambers and wherein the fluid chambers of the fluidic actuators contract axially when fluid is removed from the fluid chambers. 5. The robotic device of claim 1 , wherein the fluid chambers comprise a fabric coupled to an outside face of the fluid chambers, the fabric comprising: circumferential fibers configured to constrain a fabric circumference for resisting a fluid chamber associated with the fabric from expanding circumferentially when fluid is introduced to the fluid chamber associated with the fabric. 6. The robotic device of claim 5 , wherein the fabric is further configured to guide a bend of the fluid chamber associated with the fabric that occurs when fluid is introduced to the fluid chamber associated with the fabric and wherein the fabric is configured to stop expansion of the fluid chamber associated with the fabric at a maximum length defined by the fabric. 7. The robotic device of claim 6 , wherein the first and second fluid chambers of the fluidic actuators comprise respective wedge-shaped fluid chambers and wherein an angular size of the respective wedge-shaped fluid chambers increases by fluid being introduced to the wedge-shaped fluid chambers. 8. The robotic device of claim 1 , wherein the first and second fluid chambers of the fluidic actuators are mechanically constrained to each other or are coupled to a spine that extends between a pair of couplers. 9. A robotic device that comprises: a plurality of fluidic actuators configured to bend about an axis in response to fluid being introduced to or fluid being released from portions of the fluidic actuators, with each fluidic actuator configured to elongate in response to fluid being introduced to the respective portions of the fluidic actuators; and a plurality of couplers respectively associated with at least one actuator including a first actuator coupled to a first coupler, a second actuator coupled to a second coupler and the second actuator coupled to the first coupler, wherein the first and second actuator and first and second coupler define a length between a first and second end with the first coupler disposed between the first and second actuator and with the second actuator disposed between the first and second coupler. 10. The robotic device of claim 9 , wherein position, pressure and stiffness of each fluidic actuator is individually controlled by fluid being introduced to or fluid being released from at least a first and second separate fluid chamber of each actuator. 11. The robotic device of claim 9 , further comprising a first and second fluid valve collocated with each fluidic actuator and respectively associated with a first and second separate fluid chamber of each actuator. 12. The robotic device of claim 9 , further comprising a plurality of embedded nodes respectively collocated at respective fluidic actuators, with each of the nodes configured for estimation of at least a portion of a state of the robotic device and configured for execution of at least a portion of control of the robotic device. 13. The robotic device of claim 12 , wherein the plurality of networked embedded nodes are configured for control of one or more of position, pressure and stiffness at each fluidic actuator based at least in part on data from the plurality of networked embedded nodes. 14. The robotic device of claim 13 , wherein the control of each fluidic actuator based on data from the plurality of networked embedded nodes includes control of at least one of movement of a manipulator, position of a manipulator, configuration of a manipulator, or force applied between a manipulator and external objects. 15. The robotic device of claim 12 , wherein the fluidic actuators are controlled by the embedded nodes based at least in part on obtained sensing signals associated with two or more of: actuator position, actuator velocity, volume flow rate to or from each fluid chamber of an actuator, mass flow rate into or out of each fluid chamber of an actuator, and properties in each fluid chamber of an actuator. 16. The robotic device of claim 15 , wherein control signals to control the fluidic actuators are determined based at least in part on the obtained sensing signals to close a feedback loop. 17. The robotic device of claim 9 , wherein the fluidic actuators comprise two or more fluid chambers that expand axially when fluid is introduced to the fluid chambers and wherein the fluid chambers of the fluidic actuator contract axially when fluid is removed from the fluid chambers. 18. The robotic device of claim 17 , wherein the fluid chambers comprise: axial fibers configured to straighten as the fluid c