Disclosed are a method and system for generating a virtual boundary of a working region of a self-moving robot, and a self-moving robot and a readable storage medium. The method comprises the following steps: acquiring several recording points of a mobile positioning module circling along a patrol path; storing recording points corresponding to the first circle walked in a first storage linked list, and storing the remaining recording points in a second storage linked list; successively retrieving each recording point in the first storage linked list and taking the recording point as a basic coordinate point, and querying the second storage linked list to successively select m recording point groups corresponding to each basic coordinate point; according to each basic coordinate point and the m recording point groups corresponding thereto, respectively acquiring a boundary fitting point corresponding to the basic coordinate point, and forming a boundary fitting point sequence; acquiring boundary points according to the boundary fitting point sequence; and successively connecting the boundary points to generate a virtual boundary of a working region. In the present disclosure, a virtual boundary is generated according to recording points corresponding to a patrol path, such that human labor costs are reduced, and the working efficiency is improved.

The present disclosure provides a method for docking a self-moving device with a charging station, wherein the charging station is connected to a boundary line, and the method comprises the following steps: controlling the self-moving device to move from the current position close to a docking boundary; judging whether the self-moving device senses the boundary line signal during the moving process; if the self-moving device senses the boundary line signal before it reaches the docking boundary or when it reaches the docking boundary, controlling the self-moving device to move towards the charging station through the boundary line signal until the docking is successful; if the self-moving device has not sense the boundary line signal when it reaches the docking boundary, controlling the self-moving device to move from the docking boundary to the boundary line until the boundary line signal is sensed. The present disclosure sets the docking boundary and controls the self-moving device to move close to the docking boundary to find the boundary line, thereby improving the regression efficiency of the self-moving device.

A conveyance system according to the present disclosure includes a conveyance vehicle configured to travel along a guide line laid on a traveling road. The conveyance vehicle includes: a guide line detection unit configured to detect the guide line; an object position detection unit configured to detect information on a position of an object around the conveyance vehicle; and a stop position determination unit configured to determine a stop position of the conveyance vehicle based on a result of detection by the object position detection unit.

An ID management unit allocates a first connection ID to a first vehicle in a first period and allocates the first connection ID to a second vehicle in a second period. A correction information acquisition unit connects to a distribution device using the first connection ID and receives correction information for the first vehicle from the distribution device in the first period. The correction information acquisition unit connects to the distribution device using the first connection ID and receives the correction information for the second vehicle from the distribution device in the second period. With the system, it is possible to reduce waste of connection IDs necessary for connection to the distribution device that distributes correction information for realizing high-accuracy positioning.

An embodiment of the present invention discloses a robot guidance device, comprising a pair of guidance cables, wherein the pair of guidance cables are disposed symmetrically relative to a center line and spaced apart from each other to form a spacing region, and a magnetic field in the spacing region is used to guide a robot to adjust its heading; and each guidance cable comprises a pair of electrically connected guidance wire segments, the pair of guidance wire segments are disposed opposite and spaced apart from each other, and a direction in which the pair of guidance wire segments are spaced apart is consistent with a direction in which the pair of guidance cables are spaced apart. An embodiment of the present invention also discloses a heading adjustment method, robot system and docking guidance method thereof.

The disclosure provides a self-moving robot charging system and a self-moving robot charging method. The self-moving robot charging system enables the self-moving robot to find the charging station faster by using the charging station guideline surrounding the charging station and cooperating with the positioning system of the self-moving robot, saving the time to find a charging station and increasing the power usage of the robot, and there are no restrictions on the installation position of the charging station and the starting position of the self-moving robot, which can cover more usage scenarios.

An information processing system is provided which can increase the possibility that a path along which work quality is high is set in a work area. In an acquisition step of the information processing system, boundary information is acquired, the boundary information indicating the boundary of the work area targeted by a work machine that can travel autonomously. In a setting step, a path of the work machine is set in order to minimize unreached areas from the work area on the basis of the acquired boundary information, and when the work quality in the case of using a path set by a first method does not meet a prescribed criterion, a path is set by a second method.

A method, system, self-moving robot, and/or readable storage medium can be used to generate a virtual boundary of a working region for a self-moving robot. A mobile positioning module circles for a predetermined number of loops along a patrol path formed by the boundary of the working region to acquire recording points which are stored and then retrieved in groups to acquire boundary fitting points forming a boundary fitting point sequence, from which boundary points are acquired. Successively connecting the boundary points generates the virtual boundary of the working region.

A robotic lawnmower system comprising a boundary wire and a robotic lawnmower arranged to operate in an operational area bounded by a virtual boundary, the robotic lawnmower comprising one or more magnetic sensors, one or more satellite navigation sensors and a controller, wherein the controller is configured to: cause the robotic lawnmower to operate in the operational area according to the virtual boundary based on the one or more satellite navigation sensors, determine that the robotic lawnmower is approaching the boundary wire, determine a boundary location, determine a distance (d) between the virtual boundary and the boundary wire at the boundary location, compare the determined distance (d) to a mode determination distance (D), and if the determined distance (d) is greater than the mode determination distance D, the robotic lawnmower is configured to cross the boundary wire and continue operating within the virtual boundary, or if the determined distance (d) is less than the mode determination distance, the robotic lawnmower is configured to continue to operate within the boundary wire.

A method for docking a self-moving device to a charging station includes controlling the self-moving device to move relative to a docking boundary using a radio detection device, the radio detection device including a positioning base station and a positioning tag. The method includes judging whether the self-moving device senses a signal from a boundary line, and then taking certain steps depending on whether the boundary line signal was sensed. Related docking devices, self-moving devices, and storage media are also disclosed.