The present disclosure provides a positioning method and system for an underwater cleaning robot, an apparatus, and a storage medium, and relates to the field of cleaning robots. The method includes: obtaining position information of the underwater cleaning robot relative to a base station; and determining a position of the underwater cleaning robot based on position information of a positioning sensor connected to the base station and the position information of the underwater cleaning robot relative to the base station. The method can improve the positioning accuracy of the underwater cleaning robot to a certain extent.

This application discloses a cleaning device control method and a cleaning device. The method comprises: controlling the cleaning device to move to a starting point at which the cleaning device moves along an edge of a target water region; controlling the cleaning device to move along the edge of the target water region from the starting point by at least one round; constructing a target map of the target water region, wherein the target map comprises a map of at least one of a bottom of the target water region or a water surface of the target water region; and performing path planning on the target water region based on the target map and controlling the cleaning device to clean the target water region in a process of moving along a planned path.

This application provides a swimming pool robot, including a robot body, a filter, a control unit, and a moving mechanism. Operating environments of the swimming pool robot at least include a first operating environment and a second operating environment. The moving mechanism at least includes a first moving mechanism configured to drive the swimming pool robot to move in the first operating environment and a second moving mechanism configured to drive the swimming pool robot to move in the second operating environment. The first operating environment is an underwater environment. The second operating environment is a non-underwater environment. The control unit is capable of controlling, based on a current operating environment of the swimming pool robot, a moving mechanism corresponding to the current operating environment of the swimming pool robot to drive the swimming pool robot to move. According to this application, operating efficiency of the robot can be improved.

A method for steering an Autonomous Underwater Vehicle along an object buried below a seabed: the AUV being equipped with at least one acoustic transmitter for generating acoustic signal towards the buried object and the seabed; arranging a first sensor assembly flush with the AUV hull of the starboard side of the AUV for recording reflected acoustic signal from the buried object and the seabed, arranging a second sensor assembly flush with the AUV hull of the port side of the AUV for recording reflected acoustic signal from the buried object and the seabed.

A robot, includes: a driver; a plurality of sensors; a memory; and at least one processor configured to transmit a first signal for identifying a presence or absence of an object within a sensing area of the plurality of sensors through a first sensor operating in the signal transmitting mode from among the plurality of sensors during a first time period, identify, a second sensor to transmit a second signal during a third time period after elapse of the second time period from among the plurality of sensors, transmit the second signal by operating the identified second sensor in the signal transmitting mode, identify a location of the object based on whether a second reflection signal corresponding to the second signal is received at the second sensor, and control the driver to travel by avoiding the object based on the identified location of the object.

A self-propelled pool cleaner may be operable in a swimming pool or spa. Systems and methods may allow for the pool cleaner to find or locate a docking station within the swimming pool or spa, may allow the pool cleaner to properly dock with the docking station, and/or may allow for the pool cleaner to navigate to a docking station from anywhere within the pool. Docking of the pool cleaner with the docking station may not require physical handling by a user or pool owner.

An autonomous system and method for capturing event-driven aerial imagery utilizes a drone equipped with advanced sensors and navigation subsystems to operate without human intervention. Upon detecting predefined target events, such as structure fires, explosions, gunshots, emergency sirens, a specific license place, or a specific face, the drone autonomously launches and employs direction-finding triangulation to pinpoint the event's latitude, longitude, and elevation. The drone autonomously executes optimized flight profiles. Data transmission utilizes bonded and blended communication channels to ensure reliable video streaming to users, such as first responders or news agencies. Compliance with FAA altitude regulations is enforced, and the system can be controlled remotely via internet or cellular connections. Continuous operation is enabled through tethered power or automated battery replacement stations. Applications include law enforcement, emergency services, and news gathering, providing immediate aerial reconnaissance without requiring human operators to be present at unpredictable event locations.

An unmanned device for a marine environment comprises a location sensor configured to gather location data corresponding to the unmanned device; at least one propulsion system; a transmitter and memory including computer program code. The computer program code is configured to, when executed, cause the processor to cause the propulsion system to propel the unmanned device in a pattern along the body of water, cause the sonar transducer to emit the one or more sonar beams into the body of water, receive sonar return data corresponding to sonar returns, and generate a sonar image corresponding to the sonar return data. Further, the computer program code is configured to cause the processor to detect an object within the sonar image, assign a score to the object indicating the likelihood that the object is a desired object type, and send an alert to the remote electronics device upon assignment of the score.

A system for 3D navigation of a magnetic rotating swimmer includes a magnetic manipulator with coils defining a 3D workspace, a probe positioned to obtain a 2D image of an imaging plane from the 3D workspace, a robotic arm coupled to the probe and to move the probe and the imaging plane, and a processor network in communication with instructions to operate the magnetic manipulator to move the swimmer on a path in the 3D workspace, to obtain 2D images with the probe while the swimmer is moving in the 3D workspace, to detect the swimmer in the images, and to start, in response to detecting the swimmer, a closed-loop control of the robotic arm to move the probe to track the swimmer movement in the 3D workspace.

An information processing apparatus including a first system having first acquisition circuitry and first output circuitry and a second system having second acquisition circuitry, third acquisition circuitry, and second output circuitry. The first acquisition circuitry may acquire sensor information regarding an environment of a predetermined mobile object by at least one or more sensors installed in the mobile object. Also, the first output circuitry may output auxiliary information for assisting determination of control information for controlling an action of the mobile object. Further, the second acquisition circuitry may acquire partial sensor information from at least one sensor of the one or more sensors, the third acquisition circuitry may acquire the auxiliary information output by the first output circuitry, and the second output circuitry may output control information, using at least part of the partial sensor information or the auxiliary information.