Systems and methods are provided for aerostat deployable from sonobuoy launch container. One embodiment is an apparatus that includes a capsule configured to launch from an aircraft and float in seawater with one or more sonobuoys. The capsule includes a receiver configured to receive sonobuoy data from the one or more sonobuoys, a transmitter configured to transmit the sonobuoy data to the aircraft, a cable configured to power the transmitter via a battery, and a reaction chamber including a reactant and configured to generate a gas from the seawater mixing with the reactant. The capsule also includes an aerostat tethered to the capsule via the cable and configured to inflate with the gas produced by the reaction chamber, and to ascend above the capsule with the transmitter to increase a distance for transmitting the sonobuoy data to the aircraft.

Systems and methods are provided for aerostat deployable from sonobuoy launch container. One embodiment is an apparatus that includes a capsule configured to launch from an aircraft and float in seawater with one or more sonobuoys. The capsule includes a receiver configured to receive sonobuoy data from the one or more sonobuoys, a transmitter configured to transmit the sonobuoy data to the aircraft, a cable configured to power the transmitter via a battery, and a reaction chamber including a reactant and configured to generate a gas from the seawater mixing with the reactant. The capsule also includes an aerostat tethered to the capsule via the cable and configured to inflate with the gas produced by the reaction chamber, and to ascend above the capsule with the transmitter to increase a distance for transmitting the sonobuoy data to the aircraft.

A docking device includes a docking station capable of being connected to a carrying vessel by means of a cable, the docking station comprising a guide device which comprises a set of arms which are connected to the body and each comprise a distal end and a proximal end, the set of arms being capable of being in a deployed configuration wherein it defines a space flaring towards the rear so as to enable the underwater vehicle to be guided to the stop, the distal end of each arm being located behind the proximal end of the arm in the deployed configuration, the set of arms being capable of being in a collapsed configuration wherein a distal end of each arm of the set of arms is closer to the longitudinal axis than in the deployed configuration and wherein the distal end is located in front of the position occupied by the distal end in the deployed configuration, such that a length, along the axis x, of a space defined by the set of arms behind the stop is smaller in the collapsed configuration than in the deployed configuration

A docking device includes a docking station capable of being connected to a carrying vessel by means of a cable, the docking station comprising a guide device which comprises a set of arms which are connected to the body and each comprise a distal end and a proximal end, the set of arms being capable of being in a deployed configuration wherein it defines a space flaring towards the rear so as to enable the underwater vehicle to be guided to the stop, the distal end of each arm being located behind the proximal end of the arm in the deployed configuration, the set of arms being capable of being in a collapsed configuration wherein a distal end of each arm of the set of arms is closer to the longitudinal axis than in the deployed configuration and wherein the distal end is located in front of the position occupied by the distal end in the deployed configuration, such that a length, along the axis x, of a space defined by the set of arms behind the stop is smaller in the collapsed configuration than in the deployed configuration

A method for surveying a body of water includes providing a plurality of vehicles to a body of water. Each the plurality of vehicles includes a vehicle body, an electric-propulsion motor system mounted on the vehicle body, a rechargeable battery, at least one sonar device attached to the vehicle body, and a first communication device. The method also includes submerging each of the plurality of vehicles in the body of water, surveying an area, using the at least one sonar device, to map the body of water and to determine a location of each of the plurality of vehicles, and determining, based on the surveying, that a target object is detected within the area. The method also includes resurfacing each of the plurality of vehicles and transferring data, using the first communication device, between at least two of the plurality of vehicles at the surface of the body of water.

A method for surveying a body of water includes providing a plurality of vehicles to a body of water. Each the plurality of vehicles includes a vehicle body, an electric-propulsion motor system mounted on the vehicle body, a rechargeable battery, at least one sonar device attached to the vehicle body, and a first communication device. The method also includes submerging each of the plurality of vehicles in the body of water, surveying an area, using the at least one sonar device, to map the body of water and to determine a location of each of the plurality of vehicles, and determining, based on the surveying, that a target object is detected within the area. The method also includes resurfacing each of the plurality of vehicles and transferring data, using the first communication device, between at least two of the plurality of vehicles at the surface of the body of water.

An underwater work system of the present disclosure acquires a relative position of an underwater vehicle relative to a surface ship at the start of searching work, the relative position being measured based on a sound wave transmitted from a wave transmitter. The underwater work system calculates a position of the underwater vehicle based on the acquired relative position. When a measurement error region whose center corresponds to the calculated position of the underwater vehicle and an expected laid region of a pipeline extending in a predetermined direction overlap each other, the underwater work system moves the underwater vehicle to such a position that the measurement error region and the expected laid region do not overlap each other, and then, makes the underwater vehicle perform crossing detection in which the underwater vehicle detects the presence or absence of the pipeline while crossing the expected laid region.

An underwater work system of the present disclosure acquires a relative position of an underwater vehicle relative to a surface ship at the start of searching work, the relative position being measured based on a sound wave transmitted from a wave transmitter. The underwater work system calculates a position of the underwater vehicle based on the acquired relative position. When a measurement error region whose center corresponds to the calculated position of the underwater vehicle and an expected laid region of a pipeline extending in a predetermined direction overlap each other, the underwater work system moves the underwater vehicle to such a position that the measurement error region and the expected laid region do not overlap each other, and then, makes the underwater vehicle perform crossing detection in which the underwater vehicle detects the presence or absence of the pipeline while crossing the expected laid region.

An apparatus for artificial intelligence (AI) bathymetry is disclosed. The apparatus includes a sonic unit attached to a boat, the sonic unit configured to generate a plurality of metric data as a function of a plurality of ultrasonic pulses and a plurality of return pulses. An image processing module is configured to generate a bathymetric image as a function of the plurality of metric data, identify, as a function of the bathymetric image, an underwater landmark, and register the bathymetric image to a map location as a function of the underwater landmark. A communication module is configured to transmit the registered bathymetric image to at least a computing device. An autonomous navigation module is configured to determine a heading for the boat as a function of a path datum and command boat control to navigate the boat as a function of the heading.

A passive ballast device, system and method of using same, configured for use with a submersible vehicle in a liquid environment, including a chamber having at least one rigid wall to define at least a portion of a chamber volume, and a passively movable compensator having at least first and second surfaces, the first surface configured to be exposed to the liquid environment, the second surface excluded from the liquid environment, and forming, together with the at least one wall of the chamber, a fluid-tight seal to establish the remainder of the chamber volume, to exclude the liquid environment from the chamber volume and configured to adjust the chamber volume to at least a first chamber volume and a second chamber volume. The chamber volume is configured to establish at least a first buoyancy and second buoyancy, the compensator is configured to respond to a change in environmental pressure within the liquid environment, and the compensator is passively moved by the change in environmental pressure to change the first chamber volume to the second chamber volume, thereby changing from the first buoyancy to the second buoyancy.