Abstract: Disclosed herein is an aquatic vehicle torpedo launch system comprising of an aquatic vehicle. A torpedo launch system is coupled to the aquatic vehicle. The torpedo launch system is operable in a neutral buoyance position. A plurality of torpedoes is included. Each torpedo is coupled to the torpedo launch system with a locking means. Power cables are coupled to each torpedo providing power to the plurality of torpedoes. Fiber optic cables are coupled to each torpedo enabling programming of the plurality of torpedoes. The locking means, the power cables and the fiber optic cables are disengaged from the plurality of torpedoes prior to launch. Each torpedo is launched by buoyancy.
Abstract: Disclosed is a communication network for aquatic vessels. The network comprises an unmanned aquatic vehicle (UAQV) having a warhead. A fiber optic cable is bi-directional and in a closed ring configuration enabling communication within the network and to the UAQV. A power grid cable is in a closed ring configuration and coupled to a generator providing power. A node is coupled to the fiber optic cable and to the power grid cable. A relay station is coupled to the node and in communication with the UAQV. A control center is in communication with the UAQV and facilitates remote control of the UAQV, and programming of a navigational plan for the remote control of the UAQV prior to launch. The fiber optic cable, power grid cable, node and relay station are capable of being located underwater during operation. The UAQV is capable of being launched underwater from open water.
Abstract: Disclosed is a communication network for aquatic vessels. The network comprises an unmanned aquatic vehicle (UAQV) having a warhead. A fiber optic cable is bi-directional and in a closed ring configuration enabling communication within the network and to the UAQV. A power grid cable is in a closed ring configuration and coupled to a generator providing power. A node is coupled to the fiber optic cable and to the power grid cable. A relay station is coupled to the node and in communication with the UAQV. A control center is in communication with the UAQV and facilitates remote control of the UAQV, and programming of a navigational plan for the remote control of the UAQV prior to launch. The fiber optic cable, power grid cable, node and relay station are capable of being located underwater during operation. The UAQV is capable of being launched underwater from open water.
Abstract: Various aspects can be implemented to provide a reconfigurable underwater vehicle. In general, one aspect of the subject matter described in this specification can be embodied in a underwater vehicle that includes a hull that is angular in shape and capable of avoiding sonar detection. The hull can include a bow and a stern that are substantially similar in shape. The underwater vehicle can also include a plurality of reconfigurable modules that are interconnected to form the hull of the underwater vehicle. Each reconfigurable module is capable of performing a different function associated with operation of the underwater vehicle. Further, the plurality of reconfigurable modules can be built in a warehouse away from a shipyard and assembled to form the underwater vehicle at the shipyard.