A control method includes the following. First information indicating a group control level is determined based on operation skills of operators who each perform remote monitoring or remote operation on a moving body. Second information indicating an attribute-dependent control level is determined based on attribute information on the operators. Third information indicating individual control levels of the operators is determined based on the first and second information. Moving bodies present within a predetermined range from a predetermined notification device are identified. Fourth information indicating a device control level is determined based on the third information determined for operators of the moving bodies identified. A detail of notification to be output from the predetermined notification device is determined based on the fourth information. A control command for notifying of the detail is output.

A method for controlling a subsea vehicle. The method includes receiving sensor data representing a subsea environment from one or more sensors of the subsea vehicle. The method identifies one or more objects present in the subsea environment based on the sensor data using an artificial intelligence machine. The method transmits at least a portion of the sensor data, including an identification of the one or more objects, to a user interface. The method includes receiving a requested vehicle task from the user interface. The requested vehicle task being selected by a user via the user interface. The method performs the requested vehicle task without vehicle position control from the user.

Vehicles and methods described herein include a vehicle that operates with a rider according to an operating parameter. The vehicle includes: a physiological monitoring sensor configured to measure a physiological parameter of the rider; an experience hybrid neural network trained on outcomes related to a rider in-vehicle experience associated with the physiological parameter to determine an emotional state of the rider; an augmented reality system configured to present augmented reality content to the rider of the vehicle based, at least in part, on the operating parameter; and an optimization hybrid neural network that identifies a variation in the operating parameter to change the emotional state of the rider and that generates a command to vary the operating parameter and the augmented reality content according to the variation.

The invention relates to a method, to a device, and to a computer-readable storage medium with instructions for monitoring the movement of a transportation device. In one embodiment, first, information about the trajectory of the transportation device is received by a mobile device. The trajectory is then displayed on a display unit of the mobile device in the form of an augmented reality representation. In response thereto, an input of the user of the mobile device for influencing the trajectory is detected. Finally, information is transmitted to the transportation device on the basis of the input of the user.

A vehicle control system includes at least one imaging device attached to a vehicle and that captures multiple images, and a control circuit that generates a composite image from the multiple images and displays the composite image on a display unit. The vehicle is operated according to a user operation on a portion of the display unit on which the composite image is being displayed.

This remote operation terminal is provided with: an image acquisition unit that acquires an image shot by a suspended load camera; a display device that displays the image; an image rotation operation part that rotates the image; a suspended load moving operation part that sets the moving direction of the tip of a boom; and a terminal-side control device that is configured to be communicable with a control device of a crane, wherein when the image rotation operation part is operated during the operation of the suspended load moving operation part, the terminal-side control device rotates the image displayed on the display device in accordance with a rotation amount of the image rotation operation part, and rotates the moving direction of the tip of the boom set through operation of the suspended load moving operation part reversely to the rotating direction of the image displayed on the display device, by an amount of the rotation of the image.

The present invention discloses a wirelessly controlled vehicle that is configured to travel in air, on liquid and under liquid with an ability to communicate with a remote operator through wireless communication.

An unmanned aircraft includes: a microphone including a plurality of elements; and a processor that processes signals output from target elements included in the plurality of elements. In the unmanned aircraft, the processor performs a detection process of detecting a target sound signal of a target sound from the signals output from the target elements included in the plurality of elements, and changes the target elements that output the signals to be processed by the processor to select at least one target element that outputs a signal to be processed by the processor from among the plurality of elements, in accordance with a result of the detection process.

An inspection system for inspecting a machine includes an inspection vehicle constructed for wireless operation while submersed in a dielectric liquid medium. The inspection vehicle is self-propelled. A controller is operative to direct the activities of the inspection vehicle. A plurality of status interrogation systems is disposed on the inspection vehicle. The status interrogation systems are operative to capture inspection data regarding a plurality of inspection procedures performed on the machine.

A method for controlling image capture includes: receiving, from a movable device, an image of a target imaging area; adjusting, by a first control apparatus, one or more first imaging parameters for imaging the target imaging area based at least in part on the image to obtain one or more first adjusted imaging parameters; adjusting, by operating on an interactive interface of a second control apparatus, one or more second imaging parameters for imaging the target imaging area based at least in part on the image to obtain one or more second adjusted imaging parameters, the interactive interface being configured to receive user interaction to control an attitude of a gimbal device configured on the movable device, the gimbal device carrying an imaging device for imaging the targeted area; and sending, by the first control apparatus and/or the second control apparatus, an instruction carrying the one or more first adjusted imaging parameters and the one or more second adjusted imaging parameters to the movable device.