Self powered computing buoy

We claim: 1. A single-body fluidic computational task processing apparatus, comprising: a buoyant vessel having an upper deck surface, a fluid conduit having a lower tubular portion fixedly positioned beneath the upper deck surface and a constricting section with a cross-sectional area that decreases in a direction away from a lower aperture and toward the upper deck surface; a fluid turbine, a power-take-off, a plurality of computers fixedly positioned relative to the fluid conduit, and a first propulsive system; said fluid conduit having a lower aperture at a distal end of the lower tubular portion of the fluid conduit through which water may flow into and out of the fluid conduit; said lower tubular portion adapted to have a submerged and approximately vertical orientation when the buoyant vessel floats adjacent to an upper surface of a body of water; said fluid turbine configured to rotate in response to fluid flowing in the fluid conduit; said power-take-off being operatively connected to the fluid turbine such that the power-take-off is configured to produce electrical power in response to rotation of the fluid turbine; said plurality of computers configured to be energized by electrical power from the power-take-off; said plurality of computers configured to execute computational tasks specified by encoded signals received by the apparatus; said plurality of computers configured to produce computational results by the execution of computational tasks specified by encoded signals received by the apparatus; and said propulsive system configured to move the apparatus across the surface of the body of water; wherein the apparatus is configured to receive, via encoded signals, computational tasks from a remote transmission antenna; and wherein the apparatus is configured to transmit, via encoded signals, computational results to a remote receiving antenna. 2. The single-body fluidic computational task processing apparatus of claim 1 , wherein the first propulsive system includes a propeller. 3. The single-body fluidic computational task processing apparatus of claim 1 , wherein the first propulsive system includes a water jet. 4. The single-body fluidic computational task processing apparatus of claim 1 , further including a second propulsive system. 5. The single-body fluidic computational task processing apparatus of claim 4 , wherein the first and second propulsive systems include water jets. 6. The single-body fluidic computational task processing apparatus of claim 1 , wherein a portion of the fluid conduit is adapted to entrain pressurized gas to drive fluid through the fluid turbine. 7. The single-body fluidic computational task processing apparatus of claim 1 , further comprising a heat sink configured to communicate heat from the plurality of computers to at least one of a wall of the fluid conduit and water flowing in the fluid conduit. 8. A fluidic computational task processing system, comprising: a mobile fluidic task-processing float having an upper deck surface, a fluid conduit, a fluid turbine, a power-take-off assembly, a plurality of computers, a local data reception antenna, a local data transmission antenna, and a first propulsive system, said mobile fluidic task-processing float configured to drift buoyantly on a surface of water; said fluid conduit including first and second openings adapted to allow fluid to flow between an exterior of the mobile fluidic task-processing float and an interior of the fluid conduit; said fluid conduit further including a lower hollow tubular portion disposed below the upper deck surface; said fluid turbine positioned in the fluid conduit and configured to rotate in response to fluid flow in the fluid conduit; said power-take-off assembly adapted to generate electricity in response to rotation of the fluid turbine to energize the plurality of computers; said local data reception antenna adapted to receive encoded input data and relay received input data to the plurality of computers; said plurality of computers adapted to process received input data and relay output data derived from received input data to the local data transmission antenna; and said local data transmission antenna adapted to transmit encoded output data; wherein the mobile fluidic task-processing float is adapted to generate fluid flow in the fluid conduit and energize the plurality of computers when oscillating in a body of water traversed by waves. 9. The fluidic computational task processing system of claim 8 , wherein the fluid conduit includes an extended tubular duct depending from the hull enclosure and wherein the first opening is at a bottommost portion of the extended tubular duct. 10. The computational task processing system of claim 8 , wherein the local transmission antenna and the local reception antenna are the same antenna. 11. The computational task processing system of claim 8 , wherein one of the local transmission antenna and the local reception antenna is a phased-array antenna. 12. The fluidic computational task processing system of claim 8 , further comprising a remote data transmission antenna, a remote data transmission computer, a remote data reception antenna, and a remote data reception computer. 13. The fluidic computational task processing system of claim 12 , wherein the remote data transmission computer configured to transmit an input data packet to the plurality of computers via the remote data transmission antenna and the local data reception antenna; wherein the plurality of computers is configured to compute an output data packet using data of the input data packet; and wherein the plurality of computers is configured to transmit the output data packet to the remote data reception computer via the local data transmission antenna and the remote data reception antenna. 14. The computational task processing system of claim 12 , wherein the remote data transmission antenna and the remote data reception antenna are the same antenna. 15. The computational task processing system of claim 12 , wherein the remote data reception computer and the remote data transmission computer are the same computer. 16. The computational task processing system of claim 8 , wherein the fluid turbine is a Kaplan turbine. 17. The computational task processing system of claim 8 , wherein the power-take-off assembly includes an electrical generator operatively coupled to the fluid turbine. 18. The computational task processing system of claim 8 , wherein the power-take-off assembly includes an energy storage device. 19. The computational task processing system of claim 18 , wherein the energy storage device is a battery. 20. The computational task processing system of claim 8 , wherein the computational task processing system derives one of a neural network, a machine learning model, an artificially intelligent system, a cryptocurrency hash value, and a mathematical model consistent with a set of data values, from received input data. 21. The computational task processing system of claim 8 , wherein the power-take-off assembly is fixedly attached to the hull enclosure. 22. The computational task processing system of claim 8 , wherein the fluid turbine is rotatably attached to the hull enclosure. 23. The computational task-processing system of claim 8 , wherein the first propulsive system is a propeller. 24. The computational task-processing system of claim 8 , wherein the first pro