Amphibious vehicles comprising cycloidal propellers

What is claimed is: 1. An amphibious vehicle for traversing land and bodies of water, comprising: a chassis; and a cycloidal propeller coupled to the chassis, wherein the cycloidal propeller comprises: a plurality of cycloidal propeller blades rotatably coupled to the chassis and each extending parallel a rotational axis of the cycloidal propeller; and an extension/retraction system comprising a hub rotatably coupled to the plurality of cycloidal propeller blades and a linear actuator coupled between the hub and the chassis and configured to extend the plurality of cycloidal propeller blades away from the chassis and to retract the plurality of cycloidal propeller blades towards the chassis. 2. The amphibious vehicle of claim 1 , wherein: the hub houses a drive motor configured to rotate the plurality of cycloidal propeller blades about the rotational axis. 3. The amphibious vehicle of claim 1 , wherein the cycloidal propeller comprises a wheel rotatably coupled to the chassis, a drive motor, and a clutch actuable to transmit rotational torque from the drive motor to the wheel when the amphibious vehicle is in a land operational mode and from the drive motor to the plurality of cycloidal propeller blades when the amphibious vehicle is in a water operational mode. 4. The amphibious vehicle of claim 3 , wherein the extension/retraction system is configured to retract the plurality of cycloidal propeller blades into a cavity formed within the wheel when the amphibious vehicle is in the land operational mode and to project the plurality of cycloidal propeller blades from the cavity when the amphibious vehicle is in the water operational mode. 5. The amphibious vehicle of claim 3 , wherein: the clutch comprises a rotor configured to rotate in unison with the plurality of cycloidal propeller blades about the rotational axis, and wherein the rotor comprises a first clutch plate; the clutch comprises a rim coupled to the wheel and comprising a second clutch plate; and the extension/retraction system is configured to displace the first clutch plate relative to the second clutch plate such that the first clutch plate enters into interlocking engagement with the second clutch plate. 6. The amphibious vehicle of claim 1 , wherein the plurality of cycloidal propeller blades each comprises a blade shaft and the cycloidal propeller comprises a plurality of blade mounts coupled to the chassis and a blade pitching system comprising a plurality of blade pitching servos coupled between the plurality of blade mounts and the plurality of cycloidal propeller blades whereby the plurality of blade pitching servos are configured to rotate each of the cycloidal propeller blades about a longitudinal axis of the cycloidal propeller blade to alter a radial direction of a thrust vector produced by the cycloidal propeller and extending orthogonally from the rotational axis. 7. The amphibious vehicle of claim 1 , wherein: the cycloidal propeller comprises a plurality of blade pitching servos coupled to the plurality of cycloidal propeller blades, and wherein each of the plurality of blade pitching servos is configured to rotate one of the cycloidal propeller blades about a longitudinal axis of the cycloidal propeller blade; and wherein the amphibious vehicle comprises a control system configured to individually control the actuation of the plurality of blade pitching servos. 8. An amphibious vehicle for traversing land and bodies of water, comprising: a chassis; and a cycloidal propeller coupled to the chassis, wherein the cycloidal propeller comprises: a wheel rotatably coupled to the chassis; a plurality of cycloidal propeller blades rotatably coupled to the chassis and each extending parallel a rotational axis of the cycloidal propeller; a rotor configured to rotate in unison with the plurality of cycloidal propeller blades about the rotational axis, and wherein the rotor comprises a first clutch plate; a rim coupled to the wheel and comprising a second clutch plate, wherein the first clutch plate is displaceable between a first position spaced from the second clutch plate and a second position in interlocking engagement with the second clutch plate; and a drive motor configured to transmit rotational torque to the wheel when the amphibious vehicle is in a land operational mode and to transmit rotational torque to the plurality of cycloidal propeller blades when the amphibious vehicle is in a water operational mode. 9. The amphibious vehicle of claim 8 , further comprising, an extension/retraction system comprising a hub rotatably coupled to the plurality of cycloidal blades and a linear actuator coupled between the hub and the chassis and configured to displace the first clutch plate relative to the second clutch plate such that the first clutch plate enters into the interlocking engagement with the second clutch plate. 10. The amphibious vehicle of claim 8 , wherein the amphibious vehicle comprises a water propulsion system comprising at least one of a pump-jet and a propeller, the water propulsion system configured to provide a thrust to the amphibious vehicle when the amphibious vehicle is in the water operational mode. 11. The amphibious vehicle of claim 8 , wherein the plurality of cycloidal propeller blades each comprises a blade shaft and the cycloidal propeller comprises a plurality of blade mounts coupled to the chassis and a blade pitching system comprising a plurality of blade pitching servos coupled between the plurality of blade mounts and the plurality of cycloidal propeller blades whereby the plurality of blade pitching servos are configured to rotate each of the cycloidal propeller blades about a longitudinal axis of the cycloidal propeller blade to alter a radial direction of a thrust vector produced by the cycloidal propeller and extending orthogonally from the rotational axis. 12. The amphibious vehicle of claim 8 , wherein: the cycloidal propeller comprises a plurality of blade pitching servos coupled to the plurality of cycloidal propeller blades, and wherein each of the plurality of blade pitching servos is configured to rotate one of the cycloidal propeller blades about a longitudinal axis of the cycloidal propeller blade; and wherein the amphibious vehicle comprises a control system configured to individually control the actuation of the plurality of pitching actuators. 13. An amphibious vehicle, comprising: a chassis; a plurality of cycloidal propellers coupled to the chassis, wherein each of the cycloidal propellers comprises: a plurality of blade mounts coupled to the chassis; a plurality of cycloidal propeller blades each comprising a blade shaft rotatably coupled to the plurality of blade mounts and each extending parallel a rotational axis of the cycloidal propeller; a blade pitching system comprising a plurality of blade pitching servos coupled between the plurality of blade mounts and the plurality of cycloidal propeller blades whereby the plurality of blade pitching servos are configured to rotate each of the cycloidal propeller blades about the blade shaft of the cycloidal propeller blade to alter a radial direction of a thrust vector produced by the cycloidal propeller and extending orthogonally from the rotational axis; wherein the chassis comprises one or more control surfaces positioned on an exterior of the chassis to stabilize the vehicle during operation. 14. The amphibious vehicle of claim 13 , wherein the cycloidal propeller comprises an extension/retraction system comprising a hub rotatably coupled to the plurality of cycloidal propeller blades and a linear actuator coupled between the hub and the chas