Smart soft actuation unit for underwater applications

What is claimed is: 1. A device for underwater applications, comprising: a photodiode tube; an LED tube; a soft origami fluidic actuator that is extendable and compressible along a longitudinal axis, wherein the soft origami fluidic actuator is axially disposed between the photodiode tube at a first axial end of the soft origami fluidic actuator and the LED tube disposed at a second axial end of the soft origami fluidic actuator that is disposed opposite the first axial end; a plurality of optical waveguides each arranged external to the soft origami fluidic actuator and configured to follow motion of the soft origami fluidic actuator along the longitudinal axis, wherein the plurality of optical waveguides are configured, and arranged relative to the soft origami fluidic actuator, to buckle into geometric concavities of the soft origami fluidic actuator in response to compression of the soft origami fluidic actuator along the longitudinal axis; and a plurality of sensors configured to obtain an optical signal from the plurality of optical waveguides. 2. The device for underwater applications according to claim 1 , wherein each of the plurality of optical waveguides comprises a core layer comprising transparent silicone rubber. 3. The device for underwater applications according to claim 1 , wherein at least one of the plurality of sensors is an optical sensor. 4. The device for underwater applications according to claim 1 , further comprising a hydraulic control system and gripper. 5. The device for underwater applications according to claim 1 , wherein the plurality of optical waveguides are axially disposed and axially compressible between the photodiode tube and the LED tube. 6. The device for underwater applications according to claim 1 , comprising three optical waveguides that are each configured, and arranged relative to the soft origami fluidic actuator, to buckle into different geometric concavities, of the geometric concavities of the soft origami fluidic actuator, in response to compression of the soft origami fluidic actuator along the longitudinal axis. 7. The device for underwater applications according to claim 6 , wherein the three optical waveguides are arranged relative to the soft origami fluidic actuator to be in contact with water in response to submergence of the device, and wherein each of the three optical waveguides is disposed absent any cladding layer along any length thereof that is exposed to the water. 8. The device for underwater applications according to claim 1 , wherein opposite side portions of the soft origami fluidic actuator, each extending along the longitudinal axis, are non-symmetrical to one another. 9. The device for underwater applications according to claim 1 , wherein the soft origami fluidic actuator comprises three portions contiguous with one another and extending circumferentially around and along the longitudinal axis, wherein each of the three portions comprises a different overall geometric shape along the longitudinal axis. 10. The device for underwater applications according to claim 9 , wherein, in a rest state of the device, centers of geometric concavities, of the geometric concavities, at each of the three portions, is spaced along the longitudinal axis from centers of geometric concavities at each of the other two portions. 11. An underwater robot, comprising: a photodiode tube; an LED tube; a soft origami fluidic actuator that is extendable and compressible along a longitudinal axis, wherein the soft origami fluidic actuator is axially disposed between the photodiode tube at a first axial end of the soft origami fluidic actuator and the LED tube disposed at a second axial end of the soft origami fluidic actuator that is disposed opposite the first axial end; a plurality of optical waveguides each arranged external to the soft origami fluidic actuator and configured to follow motion of the soft origami fluidic actuator along the longitudinal axis, wherein the plurality of optical waveguides are configured, and arranged relative to the soft origami fluidic actuator, to buckle into geometric concavities of the soft origami fluidic actuator in response to compression of the soft origami fluidic actuator along the longitudinal axis; and a plurality of sensors configured to obtain an optical signal from the plurality of optical waveguides. 12. The underwater robot according to claim 11 , wherein each of the plurality of optical waveguides comprises a core layer comprising transparent silicone rubber and is disposed absent any cladding layer along any length thereof along the longitudinal axis. 13. The underwater robot according to claim 11 , wherein at least one of the plurality of sensors is an optical sensor. 14. The underwater robot according to claim 11 , further comprising a hydraulic control system and gripper. 15. The underwater robot according to claim 11 , wherein the plurality of optical waveguides are axially disposed and axially compressible between the photodiode tube and the LED tube. 16. The underwater robot according to claim 11 , comprising three optical waveguides that are each configured, and arranged relative to the soft origami fluidic actuator, to buckle into different geometric concavities, of the geometric concavities of the soft origami fluidic actuator, in response to compression of the soft origami fluidic actuator along the longitudinal axis. 17. The underwater robot according to claim 16 , wherein the three optical waveguides are arranged relative to the soft origami fluidic actuator to be in contact with water in response to submergence of the device, and wherein each of the three optical waveguides is disposed absent any cladding layer along any length thereof that is exposed to the water. 18. The underwater robot according to claim 11 , wherein opposite side portions of the soft origami fluidic actuator, each extending along the longitudinal axis, are non-symmetrical to one another. 19. The underwater robot according to claim 11 , wherein the soft origami fluidic actuator comprises three portions contiguous with one another and extending circumferentially around and along the longitudinal axis, wherein each of the three portions comprises a different overall geometric shape along the longitudinal axis. 20. The underwater robot according to claim 19 , wherein, in a rest state of the device, centers of geometric concavities, of the geometric concavities, at each of the three portions, is spaced along the longitudinal axis from centers of geometric concavities at each of the other two portions.