The present disclosure discloses a universal method for controlling recharge of robot, chip and robot, the method includes: S1, whether the robot has detected the navigation target point or not is determined, if yes, the robot is controlled to move along a planned navigation path, otherwise, the process proceeds to S3; in the moving process, when the charging station signal is received or all the pre-marked navigation target points are traversed, the process proceeds to S2; S2, whether the robot has received the charging station signal or not is determined, if yes, charging on the station is carried out, otherwise, the charging station signal is searched, and when the robot does not receive the charging station signal, the process returns to S1; S3: the robot is controlled to search for the charging station signal until searching the charging station signal, returning to S2, otherwise, walking along the boundary is continued.

The present disclosure discloses a universal method for controlling recharge of robot, chip and robot, the method includes: S1, whether the robot has detected the navigation target point or not is determined, if yes, the robot is controlled to move along a planned navigation path, otherwise, the process proceeds to S3; in the moving process, when the charging station signal is received or all the pre-marked navigation target points are traversed, the process proceeds to S2; S2, whether the robot has received the charging station signal or not is determined, if yes, charging on the station is carried out, otherwise, the charging station signal is searched, and when the robot does not receive the charging station signal, the process returns to S1; S3: the robot is controlled to search for the charging station signal until searching the charging station signal, returning to S2, otherwise, walking along the boundary is continued.

The invention is intended for organizing the process of targeted delivery of small doses of liquid chemical treatment agents from unmanned aerial vehicles, for example, in precision agriculture or animal husbandry. Delivery of the required dose of liquid chemical treatment agents to the required application area by series of one or more targeted ejections of a continuous, and optimally laminar, jet from the unmanned aerial vehicle in flight, according to the method and/or delivery system according to the invention, is performed without significant deflection of the liquid and its losses outside the application area compared to known methods and spraying devices, and, therefore, more environmentally friendly and economical; and the application system has a minimal negative impact on the application areas and ensures the motion of unmanned aerial vehicles along optimal and safe routes.

The invention is intended for organizing the process of targeted delivery of small doses of liquid chemical treatment agents from unmanned aerial vehicles, for example, in precision agriculture or animal husbandry. Delivery of the required dose of liquid chemical treatment agents to the required application area by series of one or more targeted ejections of a continuous, and optimally laminar, jet from the unmanned aerial vehicle in flight, according to the method and/or delivery system according to the invention, is performed without significant deflection of the liquid and its losses outside the application area compared to known methods and spraying devices, and, therefore, more environmentally friendly and economical; and the application system has a minimal negative impact on the application areas and ensures the motion of unmanned aerial vehicles along optimal and safe routes.

The disclosure discloses a method and device in UE and a base station for channel coding. A first node first determines a first bit block and then transmits a first radio signal, wherein bits of the first bit block are used to generate bits of a second bit block, a third bit block comprises bits of the second bit block and the first bit block, and the third bit block is used to generate the first radio signal. The first bit block, the second bit block and the third bit block comprise P1, P2 and P3 bits, respectively.

A delivery system S performs authenticating process of authenticating at least any one of an UGV 1 and an article delivered by the UGV 1 in a case where the UGV 1 arrives at a delivery destination, and performs opening/closing control of a first carry-in port from which the article is carried in at the delivery destination on the basis of the authentication result of the UGV 1 or the article delivered by the UGV 1.

The present disclosure relates to a station apparatus, including an Ultra-wideband (UWB) module to receive a first UWB signal transmitted by a moving robot, and a control unit to calculate a reception angle of the first UWB signal upon the reception of the first UWB signal, and control the UWB module to transmit a second UWB signal, including a direction value determined based on the reception angle, to the moving robot for return of the moving robot.

In some examples, a dual-mode autonomous guided vehicle (AGV) is provided for docking a module in a fabrication bay. An example AGV may comprise a chassis for supporting the module on the AGV; drive means to transport the AGV under autonomous guidance, in a module transportation mode, to a specified location within the fabrication bay; a Cartesian x-y movement table to move the module under autonomous guidance, in a module docking mode, in an x- or y-docking direction, into a specific docking position; and a z-direction lift mechanism to move the module in a z-docking direction during the module docking mode.

In some examples, a dual-mode autonomous guided vehicle (AGV) is provided for docking a module in a fabrication bay. An example AGV may comprise a chassis for supporting the module on the AGV; drive means to transport the AGV under autonomous guidance, in a module transportation mode, to a specified location within the fabrication bay; a Cartesian x-y movement table to move the module under autonomous guidance, in a module docking mode, in an x- or y-docking direction, into a specific docking position; and a z-direction lift mechanism to move the module in a z-docking direction during the module docking mode.

A computing device for navigation of a vehicle, the computing device comprising a processor and a display screen presenting a map showing multiple routes for navigating to a destination. The display screen also presents prices and travel times for the multiple routes. Responsive to a user selection of one of the multiple routes, the processor cooperates with a radiofrequency data transceiver to communicate with one or more other vehicles or with a central server to negotiate a traffic reprioritization for a user-selected route to the destination.