Poppet valve system and method

What is claimed is: 1. A fluidic robot comprising: a plurality of inflatable fluidic actuators that define a plurality of pressure cavities, the inflatable fluidic actuators configured to be associated with and move one or more joints by inflation of the plurality of inflatable fluidic actuators; and a plurality of poppet valve systems disposed within respective pressure cavities of the inflatable actuators and configured to inflate the pressure cavity, the poppet valve systems comprising: a valve body having a first and second end and defining a valve cavity; and a poppet assembly extending from the first end to the second end and through the valve cavity, the poppet assembly comprising: a poppet head disposed at the first end of the poppet assembly and configured to move along a first axis and generate a seal by contacting a portion of the valve body and configured to define an opening between the valve cavity and a pressure cavity of an inflatable fluidic actuator; a movable diaphragm coupled at the second end of the valve body configured to move along the first axis; and a shaft extending from the first end to the second end and coupled to the poppet head and diaphragm, the shaft configured to move along the first axis. 2. The fluidic robot of claim 1 , further comprising an actuator configured to drive the poppet assembly. 3. The fluidic robot of claim 2 , wherein the actuator is disposed within the valve cavity. 4. The fluidic robot of claim 2 , wherein the actuator is coupled with one or more portion of the valve body via one or more cooling fins, the cooling fins configured to transfer heat generated by the actuator to the valve body and to an external portion of the valve body to cool the actuator. 5. The fluidic robot of claim 1 wherein the poppet valve system is configured to define a flow path that comprises: a first flow from an inlet port into the valve cavity; and a second flow from the valve cavity into the pressure cavity via the opening defined by the poppet head and the valve body, wherein an actuator is disposed in the flow path defined by the poppet valve system and configured to be cooled by fluid moving in the flow path. 6. The fluidic robot of claim 1 , wherein the poppet head and diaphragm comprise matching effective cross-sectional areas such that a valve cavity pressure inside the valve cavity applies substantially the same force on the poppet head as on the diaphragm and balances a force on the poppet assembly due to the valve cavity pressure. 7. The fluidic robot of claim 1 , wherein a poppet valve system comprises a plurality of poppet assemblies, and wherein the plurality of poppet assemblies are driven by a single actuator. 8. The fluidic robot of claim 1 , wherein the seal generated by contact between the valve body and the poppet head comprises at least one co-molded portion, wherein the at least one co-molded portion is defined by a portion of at least one of the valve body and the poppet head. 9. The fluidic robot of claim 1 , further comprising a vent that extends from the first end to the second end. 10. The fluidic robot of claim 1 wherein the poppet valve systems comprise a position sensor configured to determine a position of at least a portion of the poppet assembly. 11. The fluidic robot of claim 1 , wherein the poppet assembly comprises a return spring configured to force the poppet assembly into the closed position when an actuation force is not applied to the poppet assembly. 12. A poppet valve system comprising: a valve body having a first and second end and defining a valve cavity; and a poppet assembly extending from the first end to the second end and through the valve cavity, the poppet assembly comprising: a movable poppet head disposed at the first end of the poppet assembly and configured generate a seal by contacting a portion of the valve body and configured to define an opening between the valve cavity and a pressure cavity; and a movable guiding element disposed at the second end of the valve body. 13. The poppet valve system of claim 12 , wherein the poppet assembly further comprises a shaft extending from the first end to the second end and coupled to the poppet head and guiding element, and wherein the poppet head, guiding element and shaft are configured to move along a common first axis. 14. The poppet valve system of claim 12 , further comprising inlet and outlet ports disposed along the common first axis. 15. The poppet valve system of claim 12 , further comprising an actuator that includes an actuator drive shaft disposed along the common first axis, the actuator drive shaft coupled to the poppet assembly and configured to drive the poppet assembly along the common first axis. 16. The poppet valve system of claim 12 , wherein the pressure cavity is defined at least in part by an inflatable fluidic actuator; and wherein the inflatable fluidic actuator is part of a fluidic robot with the inflatable fluidic actuator positioned about a joint and configured to move the joint when the inflatable fluidic actuator is inflated by the poppet valve system. 17. The poppet valve system of claim 12 wherein the poppet assembly is configured such that a valve cavity pressure acting on an inside face of the guiding element and an inside face of the poppet head exerts substantially the same force on the poppet head as the guiding element, which results in a substantially net zero-force on the poppet assembly; and wherein an external pressure acting on an external face of the poppet head and on an external face of the guiding element exerts substantially the same force on the poppet assembly in opposite directions to result in a substantially net-zero force. 18. The poppet valve system of claim 12 , further comprising a vent that extends from the first end to the second end and configured to operably connect a separate first and second portion of the pressure cavity. 19. The poppet valve system of claim 12 , wherein the guiding element comprises a diaphragm. 20. The poppet valve system of claim 12 further comprising an actuator, at least a portion of the actuator being disposed within the valve cavity.