System and method of controlling a strander by wireless visual monitoring of a subunit reel

We claim: 1. A stranding system, comprising: a first strander comprising; a first rotating structure comprising: a first chassis mounted to a central axle and configured to rotate around a center axis defined by the central axle; a first set of payoff units mounted to the first chassis, each payoff unit of the first set of payoff units comprising: a cradle mounted to the first chassis; a subunit package rotatably mounted to the cradle, comprising:  a subunit reel configured to rotate relative to the cradle;  a subunit wrapped around the subunit reel; at least one first vision device mounted to the first rotating structure, the at least one first vision device configured to capture a first view of at least a portion of the subunit package of at least one of the first set of payoff units to generate first vision data; at least one first wireless communication module mounted to the first rotating structure, the at least one wireless communication module configured to receive and wirelessly transmit the first vision data. 2. The stranding system of claim 1 , wherein the cradle is rotatably mounted to the first chassis and configured to rotate relative to the first chassis. 3. The stranding system of claim 1 , wherein the at least one first vision device is mounted to the first chassis. 4. The stranding system of claim 1 , wherein the at least one first vision device is mounted to the cradle of one of the first set of payoff units. 5. The stranding system of claim 1 , wherein the at least one first vision device comprises a plurality of first vision devices, each of the plurality of first vision devices mounted to a respective one of the first set of payoff units. 6. The stranding system of claim 1 , wherein each payoff unit of the first set of payoff units includes a dancer arm configured to measure tension of the subunit; wherein the at least one first vision device is configured to capture the first view of the subunit package and at least a portion of the dancer arm. 7. The stranding system of claim 1 , wherein the at least one first wireless communication module is configured to wirelessly transmit the first vision data at a rate of at least 1 Gb/s. 8. The stranding system of claim 1 , further comprising at least one image processor configured to receive and process the first vision data. 9. The stranding system of claim 8 , wherein the at least one vision device comprises the at least one image processor. 10. The stranding system of claim 8 , wherein the at least one image processor is at least one of: mounted to the at least one vision device; mounted to the cradle of one of the first set of payoff units; mounted to the first chassis and in wireless communication with the at least one first vision device; mounted to the first chassis and in wireless communication with the at least one first vision device and a wireless access point remote from the first strander; or mounted remotely from the first strander and in wireless communication with the at least one first vision device via a wireless access point. 11. The stranding system of claim 1 , further comprising an image analysis module configured to process the first vision data to identify payout hazards. 12. The stranding system of claim 11 , wherein the image analysis module processes the first vision data to recognize patterns in wrapping of the subunit on the subunit reel corresponding to payout hazards. 13. The stranding system of claim 11 , further comprising a line control module in communication with the at least one vision device via a wireless access point, the line control module configured to control operation of the strander. 14. The stranding system of claim 13 , wherein the image analysis module is configured to generate an alarm signal upon identification of a payout hazard; wherein the line control module is configured to slow or stop operation of the strander upon receipt of the alarm signal. 15. The stranding system of claim 1 , further comprising at least one second vision device and at least one second wireless communication module; wherein the first strander further comprises: a second rotating structure comprising: a second chassis mounted to the central axle and configured to rotate around the center axis; a second set of payoff units mounted to the second chassis, each payoff unit of the second set of payoff units comprising: a cradle rotatably mounted to the second chassis and configured to rotate relative to the second chassis; a subunit package rotatably mounted to the cradle, comprising:  a subunit reel configured to rotate relative to the cradle;  a subunit wrapped around the subunit reel; wherein the at least one second vision device is mounted to the second rotating structure, the at least one second vision device configured to capture a second view of at least a portion of the subunit package of at least one of the second set of payoff units to generate second vision data; wherein the at least one second wireless communication module is mounted to the second rotating structure, the at least one second wireless communication module configured to receive and wirelessly transmit the second vision data. 16. The stranding system of claim 1 , further comprising a second strander in tandem with the first strander and configured to receive an output from the first strander, the second strander comprising: a first rotating structure comprising: a first chassis mounted to a central axle and configured to rotate around a center axis defined by the central axle; a first set of payoff units mounted to the first chassis, each payoff unit of the first set of payoff units comprising: a cradle mounted to the first chassis; a subunit package rotatably mounted to the cradle, comprising: a subunit reel configured to rotate relative to the cradle; a subunit wrapped around the subunit reel; at least one first vision device mounted to the first rotating structure, the at least one first vision device configured to capture a first view of at least a portion of the subunit package of at least one of the first set of payoff units to generate first vision data; at least one first wireless communication module mounted to the first rotating structure, the at least one wireless communication module configured to receive and wirelessly transmit the first vision data. 17. The stranding system of claim 1 , wherein each of the first set of payoff units comprises fiducial markers to aid at least one of an image processor or an image analysis module. 18. A method, comprising: capturing, by at least one first vision device, a first view of at least a portion of a subunit package of at least one of a first set of payoff units of a first rotating structure of a first strander while: a subunit reel of the subunit package of the at least one of the first set of payoff units rotates relative to a cradle of one of the first set of payoff units mounted to a first chassis; the first chassis rotates around a center axis defined by a central axle of the first strander; generating, by the at least one first vision device, first vision data based on the first view; receiving, by at least one first wireless communication module mounted to the first rotating structure, the first vision data; wirelessly transmitting, by the at least one first wireless communication module, the first vision data. 19. The method of claim 18 , further comprising: capturing, by at least one second vision device, a second view of at least a porti