Soft body robot for physical interaction with humans

We claim: 1. A robot for human interaction, comprising: a robot controller including a joint control module; a link comprising a rigid support element and a body segment coupled to the rigid support element, wherein the body segment includes an outer sidewall enclosing an interior space; a pressure sensor sensing pressure in the interior space of the link; and a joint coupled to the rigid support element, wherein the robot controller operates the joint based on the pressure sensed by the pressure sensor, wherein the interior space is filled with a fluid, wherein the pressure is a pressure of the fluid in the interior space, and wherein the robot controller operates the joint based on the pressure when the pressure exceeds a predefined threshold pressure value or when a change greater than a predefined pressure change is identified by the controller. 2. The robot of claim 1 , wherein the robot controller modifies operation of the joint, when the pressure exceeds a predefined threshold pressure value or when a change greater than a predefined pressure change is identified by the controller, from a first operating state with a servo moving or positioning the joint to a second operating state with the servo operating to allow the joint to be moved or positioned in response to outside forces applied to the link. 3. The robot of claim 1 , wherein the joint is upstream of the link in the robot. 4. The robot of claim 1 , wherein the outer sidewall is flexible whereby the interior space has a first volume in a pre-contact state and a second volume less than the first volume in a second state in which a contact force is applied to the outer sidewall. 5. The robot of claim 4 , wherein the link further includes a deformation control member extending from the rigid support element to be positioned within the interior space to limit a magnitude of deformation of the outer sidewall. 6. The robot of claim 1 , wherein the link is fabricated as a single unit using a three dimensional (3D) printer. 7. The robot of claim 6 , wherein the single unit includes a threaded cap and an O-ring-like component that seals the interior space when the threaded cap is tightened during assembly of the robot. 8. A robot for human interaction, comprising: a robot controller including a joint control module; a link comprising a rigid support element and a body segment coupled to the rigid support element, wherein the body segment includes an outer sidewall enclosing an interior space; a pressure sensor sensing pressure in the interior space of the link; and a joint coupled to the rigid support element, wherein the robot controller operates the joint based on the pressure sensed by the pressure sensor, wherein the link is fabricated as a single unit, and wherein the rigid support element includes a connector for the pressure sensor providing a passageway to the interior space. 9. A robot for human interaction, comprising: a robot controller including a joint control module; a link comprising a rigid support element and a body segment coupled to the rigid support element, wherein the body segment includes an outer sidewall enclosing an interior space; a pressure sensor sensing pressure in the interior space of the link; and a joint coupled to the rigid support element, wherein the robot controller operates the joint based on the pressure sensed by the pressure sensor, and wherein the joint includes one of a thrust bearing and a friction bearing fabricated as a single unit. 10. The robot of claim 9 , wherein the thrust bearing is configured as a double direction thrust bearing and includes a lower roller cage assembly arranged in an arc and containing a number of rollers, the number of rollers being less than a number of rollers included in a corresponding upper roller cage assembly arranged in a full circle. 11. A robot, comprising: a plurality of body segments; and a set of servo-driven joints interconnecting the body segments, wherein one or more of the body segments includes a fluid-filled void enclosed by a sidewall, wherein the sidewall comprises a membrane of a flexible material, and wherein each of the body segments further comprises a rigid support element coupled to an edge of the sidewall and coupled to one of the servo-driven joints; and a pressure sensor in communication with the fluid-filled void of each of the body segments operating to sense a pressure in each of the body segments, a controller comparing the pressure in each of the body segments with a predefined threshold value or measuring a change in pressure in the body segments based on the pressure and based on the comparing or the measuring, modifying operations of at least one of the servo-driven joints. 12. The robot of claim 11 , wherein the modifying of the operations of the at least one of the servo-driven joints comprises powering off a servo or allowing a servo to freewheel. 13. The robot of claim 12 , wherein the at least one of the servo-driven joints is a parent joint for one of the body segments having a pressure exceeding the predefined threshold value or having a change in pressure exceeding a predefined maximum pressure change value. 14. The robot of claim 11 , wherein the body segments are printed using a 3D printer and the flexible material is a rubber, a plastic, or a rubber-like material. 15. The robot of claim 14 , wherein the robot is configured to have a predefined body shape and wherein the body segments are selected to each have an outer shape defined by one of a plurality of primitive modules. 16. The robot of claim 15 , wherein the outer shapes of the primitive modules are selected from the group consisting of a donut shape, a cylinder, and a cylinder with a round end. 17. A method of controlling operation of a robot, comprising: first transmitting a control signal to operate a joint upstream of a link in a first operating state, wherein the link includes a rigid support element coupled to the joint and a cavity enclosed by a sidewall affixed to the rigid support element; measuring a pressure of a fluid in the cavity; based on the measured pressure, determining when a contact force is being applied to the sidewall; and when the contact force is determined, second transmitting a control signal to operate the joint upstream of the link in a second operating state differing from the first operating state, wherein the second operating state comprises powering off an actuator or servo in the joint. 18. The method of claim 17 , further comprising measuring a second pressure in of the fluid in the cavity, determining when the contact force is removed from the sidewall, and, where the contact force is determined removed, third transmitting a control signal to operate the joint upstream of the link in a third operating state differing from the second operating state. 19. The method of claim 17 , wherein the robot is a humanoid robot and the link comprises a forearm link, an upper arm link, a torso link, a back link, or a chest link.