Water environment mobile robots

1 . A water environment robotic system, comprising: a control station; an underwater robotic vehicle; a water-surface robotic vehicle; first and second communication modules associated with the underwater robotic vehicle and the water-surface robotic vehicle, respectively, wherein the first and second communication modules provide communication between the vehicles through the water; third and fourth communication modules associated with the water-surface robotic vehicle and the control station, respectively, wherein the third and fourth communication modules provide communication between the water-surface robotic vehicle and the control station over air; wherein the control station is configured to control operation of the underwater robotic vehicle using control signals that are communicated between the control station and the water-surface robotic vehicle via the third and fourth communication modules and are relayed by the water-surface robotic vehicle to the underwater robotic vehicle via the first and second communication modules; and wherein the underwater robotic vehicle is configured to transmit data collected by underwater robotic vehicle using data signals that are communicated between the underwater robotic vehicle and the water-surface robotic vehicle via the first and second communication modules and are relayed by the water-surface robotic vehicle to the control station via the third and fourth communication modules. 2 . The water environment robotic system of claim 1 , further including an alignment control system, comprising: a position signal emitter associated with the underwater robotic vehicle; a position signal detector associated with the water-surface robotic vehicle, wherein the position signal emitter emits signals that are capable of being detected by the position signal detector; and an alignment control processor associated with the water-surface robotic vehicle that receives signal data from the position signal detector and determines the relative positions of the underwater robotic vehicle and the water-surface robotic vehicle. 3 . The water environment robotic system of claim 2 , wherein the water-surface robotic vehicle further includes a surface propulsion system and wherein the alignment control processor controls the operation of the surface propulsion system in order to move the water-surface robotic vehicle along the surface of the water in such a way as to maintain general vertical alignment between the water-surface robotic vehicle and the underwater robotic vehicle. 4 . The water environment robotic system of claim 2 , wherein the position signal emitter and the position signal detector is selected from the group comprising of LED light, acoustic, laser, and various combinations thereof. 5 . The water environment robotic system of claim 1 , further comprising: a tether extending between the water-surface robotic vehicle and the underwater robotic vehicle; an alignment control system associated with the water-surface robotic vehicle, comprising: sensors that provides tether force signal data related to forces on the tether; and an alignment control processor that receives the tether force signal data and determines the relative positions of the underwater robotic vehicle and the water-surface robotic vehicle. 6 . The water environment robotic system of claim 1 , wherein the first and second communication modules are configured to communicate using at least one of visible light, radio frequencies, laser light, acoustic communications, and a tether. 7 . The water environment robotic system of claim 1 , wherein the water-surface robotic vehicle and the underwater robotic vehicle are configured to dock together. 8 . The water environment robotic system of claim 7 , wherein the water-surface robotic vehicle and the underwater robotic vehicle are configured to electrically couple to provide electrical power from the water-surface robotic vehicle to the underwater robotic vehicle. 9 . The water environment robotic system of claim 7 , wherein the water-surface robotic vehicle and the underwater robotic vehicle are configured to mechanically couple. 10 . The water environment robotic system of claim 1 , wherein the water-surface robotic vehicle is configured to provide at least one of pressurized water, compressed air, or sandblasting material and various combination thereof to the underwater robotic vehicle via at least one of a mechanical couple or a tether and various combinations thereof. 11 . The water environment robotic system of claim 1 , wherein the underwater robotic vehicle includes at least one underwater motion module and at least one underwater crawling module. 12 . The water environment robotic system of claim 11 , wherein the least one underwater motion module includes at least one of a vertical thruster, a horizontal thruster, or a buoyancy control device and various combinations thereof. 13 . The water environment robotic system of claim 11 , wherein the least one underwater crawling module includes at least one of a crawling skid, a track, a wheel, an actuated leg and various combinations thereof. 14 . The water environment robotic system of claim 1 , wherein the underwater robotic vehicle includes at least one environmental sensor. 15 . The water environment robotic system of claim 15 , wherein the at least one environmental sensor includes at least one of a camera, imaging sonar, altimeter, pressure sensor, depth sensor, or temperature sensor and various combinations thereof. 16 . The water environment robotic system of claim 1 , wherein the underwater robotic vehicle includes at least one inspection device. 17 . The water environment robotic system of claim 15 , wherein the at least one inspection device includes at least one of a ultrasonic testing probe, cathodic protection probe, eddy current probe, infrared camera, 3D scanning system, and various combinations thereof. 18 . The water environment robotic system of claim 1 , wherein the underwater robotic vehicle includes at least one marine life cleaning system. 19 . The water environment robotic system of claim 1 , further including at least one additional water-surface robotic vehicle wherein the multiple water-surface robotic vehicles are in wireless communication to provide communication relay between the multiple water-surface robotic vehicles and the control unit.