A device for establishing a communication network and collecting situation information at a site of a collapse disaster is disclosed. The device includes a ground drone 10 deployed at the site of the collapse disaster, the ground drone 10 having a communication device 80 mounted thereon, a flying drone 32 mounted on and carried by the ground drone 10 to fly and photograph the site of the collapse disaster, a camera device 40 mounted on the ground drone 10 to photograph surroundings of the ground drone 10, a storage 50 installed on the ground drone 10, and a plurality of repeater modules 60 connected by the wireless communication network to relay wireless communications between the ground drone 10, the flying drone 32, and a command and control center 100, wherein the storage 50 accommodates the repeater modules 60, and throws the repeater modules 60 in response to an operation signal.

A management device includes: a processor, wherein the processor specifies a first mobile machine that is not scheduled to operate during a predetermined period, based on data of operation plans of a plurality of mobile machines that are autonomously movable and have a function of a positioning base station, and transmits, to the first mobile machine, an instruction to operate the first mobile machine as the base station during the predetermined period.

The present invention relates to a method for controlling hand-over in a drone network. A method for controlling hand-over in a drone network that is established by a plurality of drones that constitute a formation, and controlled by a ground control station (GCS) that controls the location, configuration and mobility of each of the plurality of drones according to the present invention includes a phase via which the GCS predicts, based on previously stored control information, a drone that is to be newly deployed or transferred from another formation and allocates network connection information to the drone thus predicted; a phase via which the GCS generates a virtual routing table including the drone that is thus predicted to be deployed or transferred; a phase via which the GCS, upon actual deploying or transferring the predicted drone, changes the virtual routing table into an actual routing table; and a phase via which the GCS, upon the drone thus deployed or transferred transmitting a control message of the formation routing protocol, calibrates and optimizes the routing table.

A device for establishing a communication network and collecting situation information at a site of a collapse disaster is disclosed. The device includes a ground drone 10 deployed at the site of the collapse disaster, the ground drone 10 having a communication device 80 mounted thereon, a flying drone 32 mounted on and carried by the ground drone 10 to fly and photograph the site of the collapse disaster, a camera device 40 mounted on the ground drone 10 to photograph surroundings of the ground drone 10, a storage 50 installed on the ground drone 10, and a plurality of repeater modules 60 connected by the wireless communication network to relay wireless communications between the ground drone 10, the flying drone 32, and a command and control center 100, wherein the storage 50 accommodates the repeater modules 60, and throws the repeater modules 60 in response to an operation signal.

An information processing apparatus is provided, including: a prediction result obtainment unit which obtains a result of prediction of weather in stratosphere; and a flight path determination unit which determines a flight path of a flight vehicle based on the result of prediction of weather in stratosphere such that the flight vehicle flies through an area in stratosphere that has been predicted to satisfy a predetermined stratospheric path condition, wherein the flight vehicle functions as a stratospheric platform, and forms a wireless communication area by emitting a beam and provides a wireless communication service to a user terminal in the wireless communication area.

A local server includes a controller configured to select a processing function for processing offload, and receive, from a traffic filter, target data that originates from a local network; and a processing platform comprising one or more processors and configured to apply the processing function to the target data to obtain processed data; and wherein the controller is further configured to send the processed data to a remote server for remote processing.

A swarm robot control system for safety inspection and surveillance patrol, and an operating method thereof are disclosed. The swarm robot control system includes one or more management robots which are placed in each safety management area, and collect and transmit safety management data while traveling autonomously in a safety management area based on control command data, a local controller which is placed in each safety management area, and transmits the control command data to the management robot and receives the safety management data from the management robot, one or more relay robots which are placed in each safety management area, and move to a predetermined relay location so as to relay communication between the local controller and the management robot, a charging robot which is equipped with a rechargeable battery, and provides power for charging the battery to at least one of the management robot or the relay robot, and a central controller which receives the safety management data from the local controller in each safety management area and transmits the control command data to the local controller so as to remotely control the management robot.

Systems, tools and methods for deploying a mesh sensor network. The system comprises one or more aircraft configured to carry one or more drop pods into an environment and the deploying of the drop pods at points of interest. The aircraft and drop pods may comprise arrays of sensors for monitoring the areas that they are operating in. The aircraft and drop pods may include mesh radio communication devices and operate as nodes in the mesh network. The location at which each drop pod is to be deployed may be determined based on the type of sensors carried by the drop pod.

Techniques and methods for wirelessly communicating with equipment such as, but not necessarily limited to, automatic swimming pool cleaners (APCs) are detailed. An accelerometer or other sensor on-board an APC may recognize such communications. In some cases, varying operation of a motor or other feedback generator of the APC may provide sonic or other feedback in response to the communications.

The present disclosure relates to a wireless access point deployment method, apparatus, electronic device, and readable storage medium. The method includes: in a process of a mobile robot traveling along a moving path determined by an environment map, detecting wireless signal coverage information of each moving position in the moving path, where the wireless signal coverage information is used to generate a wireless signal coverage map of an environment where the mobile robot is currently located, and the wireless signal coverage map is used to update a deployment position of the wireless access point in the environment.