Autonomous ROVs with offshore power source that can return to recharge

What is claimed is: 1. A resident remotely operated vehicle (RROV) system, comprising: a. a remotely operated vehicle (ROV) configured to be disposed and remain resident subsea for an extended time, the ROV comprising an ROV electrical power connector port and an ROV controller; b. an electrical power supply dedicated to the ROV, the electrical power supply comprising: i. a housing configured for use subsea; ii. a power source having electrical capacity sufficient to power the ROV for a predetermined time; iii. an electrical power supply outlet operatively connected to the power source and configured to be selectively operably engagable with the ROV electrical power connector port; c. a resident tether management system (RTMS) configured to be disposed subsea for an extended time, the RTMS comprising: i. an RTMS power supply; ii. a hub signal connector; and iii. an RTMS power supply power outlet configured to be selectively operatively connected to the electrical power supply outlet; d. a subsea docking hub, comprising: i. a structure signal connector port; and ii. an RTMS signal connector port and e. a hub umbilical operatively in communication with the RTMS signal connector port and the hub signal connector port. 2. The resident remotely operated vehicle (RROV) system of claim 1 , wherein the RTMS power supply comprises the electrical power supply. 3. The resident remotely operated vehicle (ROV) system of claim 1 , wherein: a. the ROV comprises a skid operatively connected to the ROV; b. the electrical power supply is disposed within the skid; and c. the battery comprises electrical capacity sufficient to power the ROV for a predetermined time. 4. The resident remotely operated vehicle (RROV) system of claim 1 , further comprising a data transceiver operatively in communication with an operator onshore, a vessel, or an FPSO and with the ROV controller. 5. The resident remotely operated vehicle (RROV) system of Claim 1 , wherein the subsea docking hub signal connector port comprises a power signal connector port or a data signal connector port. 6. The resident remotely operated vehicle (ROV) system of claim 1 , wherein the ROV is configured to operate as either: a. a conventional, tethered ROV comprising a connection to a surface deployed tether; or b. a tethered ROV configured to be selectively connected to a tether deployed from the RTMS or to be selectively disconnected from the tether and function as an autonomous underwater vehicle (AUV) that is not coupled to the tether and draws power from the electrical power supply. 7. The resident remotely operated vehicle (ROV) system of claim 6 , wherein the selectively connected tether comprises: a. a data and power connector for power, data and control; and b. a connector configured to latch and unlatch the tether to the ROV. 8. The resident remotely operated vehicle (ROV) system of claim 7 , wherein the connector comprises an electro-mechanical or hydraulic type collet connector. 9. The resident remotely operated vehicle (ROV) system of claim 1 , wherein: a. the RTMS comprises a plurality of RTMS; and b. the tether comprises a length sufficient to provide coverage for a predetermined area for work. 10. The resident remotely operated vehicle (ROV) system of claim 1 , wherein each of the ROV and the RTMS further comprises a power management system. 11. A method of deploying a remotely operated vehicle subsea, comprising: a. deploying a remotely operated vehicle (ROV) subsea, the ROV configured to be disposed and remain resident subsea for an extended time, the ROV comprising an ROV electrical power connector port; b. operatively connecting an electrical power supply to the ROV, the electrical power supply dedicated to the ROV, the electrical power supply comprising: i. a power source having electrical capacity sufficient to power the ROV for a predetermined time; and ii. an electrical power supply outlet operatively connected to the power source and configured to be selectively operably engagable with the ROV electrical power connector port; c. deploying an RTMS subsea, the RTMS configured to be disposed subsea for an extended time, the RTMS comprising: i. an RTMS power supply; and ii. an RTMS power supply power outlet configured to be selectively operatively connected to the electrical power supply outlet; d. deploying a subsea docking hub subsea, the subsea docking hub comprising a signal connector port operatively in communication with a subsea structure which is operatively in communication with a surface structure; e. operatively connecting the ROV and the RTMS to the subsea docking hub; f. connecting an umbilical from the subsea docking hub to a subsea structure; and g. supplying a signal from the subsea structure to the ROV. 12. The method of deploying a remotely operated vehicle subsea of claim 11 , wherein supplying the signal comprises: a. operatively connecting the subsea structure to a surface structure or shore base where a control console is manned; b. supplying a signal to the subsea structure from the control console; and c. supplying the signal to the ROV and the RTMS via the umbilical. 13. The method of deploying a remotely operated vehicle subsea of claim 12 , wherein the signal comprises a power signal and a data communications signal. 14. The method of deploying a remotely operated vehicle subsea of claim 11 , further comprising: a. configuring the ROV for operations in either a tethered ROV mode or an untethered autonomous underwater vehicle (AUV) mode where the ROV is not coupled to an ROV tether and draws power from the battery skid mounted to the ROV; and b. when operating in the AUV Mode, providing the ROV with a predetermined set of pre-programmed mission objectives, the predetermined set of pre-programmed mission objectives comprising: i. navigating to a position subsea; ii. performing a predetermined function; iii. navigating the ROV to the RTMS. 15. The method of deploying a remotely operated vehicle subsea of claim 14 , further comprising reconnecting the returned ROV to the ROV tether to return to ROV Mode and recharge the batteries. 16. The method of deploying a remotely operated vehicle subsea of claim 11 , further comprising: a. allowing the amount of power delivered from the subsea umbilical to the resident system to vary; and b. using the actual amount of power delivered from the subsea umbilical to the resident system to determine battery configurations and capacity. 17. The method of deploying a remotely operated vehicle subsea of claim 11 , further comprising: a. deploying a buoy-based electric power system proximate a location at which the remotely operated vehicle (ROV) subsea is deployed, the buoy-based electric power system comprising: i. a surface buoy, comprising: 1. a housing; 2. a controller disposed within the housing; 3. an electric power generator disposed within the housing and operatively in communication with the controller; and 4. a surface buoy power outlet operatively in communication with the electrical power generator; and ii. a battery bank configured for use subsea, comprising: 1. a housing configured to withstand subsea pressure; 2. a predetermined set of batteries disposed within the housing; 3. a subsea battery bank power inlet operatively in communication with the surface buoy power outlet and with the predetermined set of batteries; and 4. a subsea battery bank power outlet operatively in communication with the predetermined set of batteries; b. generating electrical po