A method of mowing multiple areas includes training a robotic mower to mow at least two areas separated by a space, including moving the robotic mower about the areas while storing data indicative of location of boundaries of each area relative to boundary markers, training the robotic mower to move across the space separating the areas, and initiating a mowing operation. Training the robotic mower to move across the space separating the areas includes moving the robotic mower to a traversal launch point of a first of the areas and moving the robotic mower to a traversal landing point of a second of the areas. The mowing operation causes the robotic mower to move to the traversal launch point, move from the traversal launch point across the space to the traversal landing point, and then mow the second of the areas.

A robotic lawn mower includes a first wheel driven by a first electric wheel motor, a second wheel driven by a second electric wheel motor, a cutting implement driven by an electric cutting implement motor, a power system for powering the electric wheel motors and the electric cutting implement motor, and a controller configured to control operation of the electric wheel motors and the electric cutting implement motor to autonomously mow a yard. The power system includes multiple removable rechargeable battery modules and multiple receptacles, each receptacle configured to receive one of the battery modules.

A robotic lawnmower system comprising a charging station (210) and a robotic work tool (100), the charging station comprising a signal generator (240) to which a boundary cable (250) is to be connected, the signal generator (240) being configured to transmit a signal (245) through the boundary cable (250), and the robotic working tool (100) comprising a sensor (170) configured to pick up magnetic fields generated by the signal (245) in the boundary cable (250) thereby receiving the signal (245) being transmitted and a controller (110) configured to analyse the picked up signal, wherein the signal generator (240) is further configured to: prefilter the signal through an filter model; and transmit the prefiltered signal to through the boundary cable (250) by means of a current generator.

A method navigates a robotic mower (2) by means of a wire (8). The robotic mower (2) comprises at least two sensors (12; 14). The method comprises detecting (S101), by means of the at least two sensors (12, 14), at least one signal from the wire (4a; 8; 10), measuring (S102) a polarity of the at least one signal of the wire (4a; 8; 10) by means of each one of the at least two sensors (12, 14), determining (S103) a direction based on the polarities measured by means of the at least two sensors (12, 14) and turning (S104) the robotic mower (2) towards the determined direction.

A robotic work tool system (200) comprising a robotic work tool (100), the robotic work tool (100) being configured to determine (410) that the robotic work tool (100) has entered a state of limited movement; determine (420) an exit path; and exit (430) the state of limited movement by navigating the exit path.

A method navigates a robotic mower by means of a wire. The robotic mower comprises at least one sensor. The method comprises detecting, by means of the at least one sensor, at least one signal from the wire, controlling the robotic mower to align with the wire, controlling the robotic mower to turn by an angle with respect to a section of the wire, controlling the robotic mower to increase the distance between the robotic mower and the wire by driving a displacement distance based on a random distance value, measuring, by means of the at least one sensor, a signal level of the at least one signal from the wire, and controlling the robotic mower to follow the wire based on the measured signal level.

A mobile robot includes a body, a propulsion module, an ultrasound sensor module that is configured to detect a boundary of a cleaning area using a sound wave, and a controller configured to control the propulsion module based on the determined boundary. The ultrasound sensor module may include an ultrasonic sensor unit and a boundary detector. The sensor unit may emit the sound wave, receive the reflected sound wave from a target, and output a sound wave signal. And, the boundary detector may analyze the sound wave signal to detect the boundary of the cleaning area.

A robotic work tool arranged to operate in an operational area bounded by a boundary wire, the operational area encompassing a first charging station and a second charging station, each charging station comprising a base station wire, the robotic work tool comprising a controller, wherein the controller is configured to: operate in the operational area according to a first control signal, the first control signal comprising a first boundary signal being transmitted through the boundary wire and a first base station signal being transmitted through the base station wire of the first charging station; navigate the robotic work tool to locate and move the robotic work tool to the first charging station based on the first control signal; navigate the robotic work tool to distance the robotic work tool from the first charging station in a predetermined manner; synchronize to a second control signal comprising a first boundary signal and a second base station signal both being transmitted through the base station wire of the second charging station; and navigate the robotic work tool to enter the second charging station based on the second control signal.

A robotic work tool system (200) for avoiding trails from a robotic work tool (100) in a transit zone (300) in which the robotic work tool (100) is allowed to travel from a start point (320) to a goal point (330) along a travel path (310). The system (200) comprises at least one memory (120,220) configured to store information about the transit zone (300), at least one robotic work tool (100) configured to travel along the travel path (310) and at least one controller (110,210) for controlling operation of the robotic work tool (100). The controller (110,210) is configured to receive, from the memory (120,220), information about the transit zone (300) and generate, based on the transit zone (300), the travel path (310) for the robotic work tool (100) from the start point (320) to the goal point (330). The generated travel path (310) is configured to differ from previously generated travel paths.

The disclosure relates to an automatic working system, a self-moving device and a control method therefor. The automatic working system includes a self-moving device configured to automatically move and work in a working region set by a user, a magnetic strip configured to generate a magnetic signal. The self-moving device includes a boundary recognizing module configured to recognize a boundary of the working region, a magnetic induction module configured to induce the magnetic signal, a control module configured to control the self-moving device to move along the boundary according to the boundary recognized by the boundary recognizing module and control the self-moving device to move along the magnetic strip according to the magnetic signal if the magnetic induction module induces the magnetic signal in process of moving along the boundary.