A robot includes a controller configured to: detect a virtual wall signal; identify a virtual wall according to a signal threshold and the virtual wall signal; and when the virtual wall is identified, adjust the signal threshold, and control the robot to travel along an outer side of the virtual wall according to an adjusted signal threshold and the virtual wall signal, such that a driving wheel of the robot is located at the outer side of the virtual wall when the robot is traveling along the outer side of the virtual wall; wherein the outer side of the virtual wall is a side of the virtual wall within an active region of the robot.

A method for automatically following a preceding object by an autonomous vehicle is provided and includes the following steps: providing a first predetermined path; locating the preceding object and the autonomous vehicle on the first predetermined path; measuring the distance between the autonomous vehicle and the preceding object by a distance measuring unit disposed on the autonomous vehicle; determining a predetermined distance to be maintained between the autonomous vehicle and the preceding object through a central processor; and when the preceding object moves along the first predetermined path, the central processor drives the autonomous vehicle to be following the preceding object along the first predetermined path with the predetermined distance and a moving velocity.

A virtual guide sensor processing unit of an automatic guided vehicle (AGV) computes the position of a virtual guide tape on the basis of the position of the AGV which a vehicle body coordinate value calculation processing unit has computed, and virtual guide tape layout data. A guide sensor switching processing unit outputs to a vehicle body deviation degree calculation processing unit the position of a magnetic guide tape which a magnetic guide sensor has detected, or the position of the virtual guide tape which the virtual guide sensor processing unit has computed.

In one embodiment, a virtual boundary is provided in the global coordinates of the area map and is converted into a plurality of line segments corresponding to a plurality of partial maps. In one embodiment, a physical boundary indicator is used during a training/mapping run, with the location added to the area map and the physical boundary indicator later moved. In one embodiment, the virtual boundary changes over time to change cleaning areas, act as a gate, change associated cleaning mode, etc. In one embodiment, virtual areas with boundaries are selected by a user.

A method for determining if a user's gaze is directed in the direction of a zone of interest in a 3D scene comprises: providing a 3D scene containing a zone of interest; associating a property with the zone of interest; creating a bitmap representing the location of the zone of interest in a projected view of the 3D scene, each pixel of the bitmap to which the zone of interest is projected storing the property of the zone of interest; detecting the direction of the user's gaze; using the bitmap to determine if the detected user's gaze is directed in the direction of the zone of interest.

A mobile robotic system including a floor assembly having a support surface and a reconfigurable pathway, wherein an automated guided vehicle is configured to travel on the support surface and follow the reconfigurable pathway.

The various embodiments described herein generally relate to systems and methods for operating one or more self-driving vehicles. In some embodiments, the self-driving vehicles may include a vehicle processor being operable to: control the vehicle to navigate an operating environment in an initial vehicle navigation mode; monitor for one or more trigger conditions indicating a possible change for the vehicle navigation mode; detect a trigger condition; determine a prospective vehicle navigation mode associated with the detected trigger condition; determine whether to change from the initial vehicle navigation mode to the prospective vehicle navigation mode; and in response to determining to change from the initial vehicle navigation mode to the prospective vehicle navigation mode, adjust one or more vehicle attributes corresponding to the prospective vehicle navigation mode, otherwise continue to operate the vehicle in the initial vehicle navigation mode.

A system and method for independently routing vehicles and delivering containers and closures to unit operation stations are disclosed. The containers and closures can, in some cases, be transported on the same vehicle. In other cases, the containers and closures can be transported on different vehicles.

The present invention discloses a module for robot navigation, an address marker and an associated robot. The module divides a whole workspace area for robot traveling into a plurality of module areas, and each module area is internally provided with a first magnetic piece having a polarity of an N pole or an S pole and a second magnetic piece having a polarity different from the polarity of the first magnetic piece. The first magnetic piece is a first magnetic strip, and the second magnetic piece is a second magnetic strip. The first magnetic strip is arranged in the Y-axis direction, and the second magnetic strip is arranged in the X-axis direction. A third magnetic strip and a fourth magnetic strip are further included. The four strips are in cross arrangement. The polarity of the second magnetic strip, the polarity of the third magnetic strip and the polarity of the fourth magnetic strip are the same. A plurality of magnetic induction sensors and an address marker recognition device are installed at the bottom of the robot. The robot can travel forward or backward or turn to a target module area according to instructions and collected marker information. The module for robot navigation, the address marker and the associated robot according to the present invention have beneficial effects of reliable and accurate positioning, low cost and convenient maintenance.

The present invention discloses a module for robot navigation, an address marker and an associated robot. The module divides a whole workspace area for robot traveling into a plurality of module areas, and each module area is internally provided with a first magnetic piece having a polarity of an N pole or an S pole and a second magnetic piece having a polarity different from the polarity of the first magnetic piece. The first magnetic piece is a first magnetic strip, and the second magnetic piece is a second magnetic strip. The first magnetic strip is arranged in the Y-axis direction, and the second magnetic strip is arranged in the X-axis direction. A third magnetic strip and a fourth magnetic strip are further included.