An autonomous moving apparatus control system including a range sensor, a reflection plate, and a control unit. The range sensor is installed in a cage of an elevator and detects a distance to an object by receiving reflected light of signal light applied to the object. The reflection plate is disposed in an elevator hall of a floor on which the elevator stops, and reflects the signal light. The control unit determines whether or not a mobile robot, which is an autonomous moving apparatus, can get on and off the elevator based on a detected distance, the detected distance being a distance to the reflection plate detected by the range sensor.

A method and a device for controlling a number of robots to emergency stop are provided. The method includes arranging multiple position points in a site where robots work and position identifiers corresponding to the position points, and providing corresponding recognizers at bottoms of the robots; when fault signals reported by the robots are detected, determining, according to the fault signals, whether all the robots in the site need to be controlled to emergency stop, wherein if yes, according to current positions and moving speeds of the robots, position points in the site are allocated to the robots as respective emergency stop positions, the robots are controlled to move to the corresponding emergency stop positions, and thereafter the robots are controlled to stop movement. The device comprises a configuration module, a determination module, an allocation module and a control module.

A system for configuring generic maintenance activity scheduling is provided. For example, user input may help define a maintenance process for a plurality of mobile drive units of the physical workspace. The maintenance process may be defined through a configuration of activity templates and input templates. Input may be received to configure maintenance activities and the system may automatically correlate failure rules with the activity template. The system may generate the configurable electronic instructions for the mobile drive units and transmit them with the failure rules, if generated, to one or more mobile drive units of the physical workspace. When the one or more mobile device units receive the configurable electronic instruction, the mobile drive units may operate in accordance with the configurable electronic instruction.

An indoor location system includes mobile transceiver units to support a manufacturing control of process courses in an industrial manufacturing of workpieces in a manufacturing plant. The indoor location system includes an analysis unit configured to determine a position of a mobile transceiver unit to be localized from runtimes of electromagnetic signals between transceiver units, and an energy consumption control unit configured to output a control signal for deactivating a localizing mode of a position signal module of at least one of the mobile transceiver units if participation of the at least one mobile transceiver unit in position determination operations is not required and to output a control signal for activating the localizing mode of the position signal module of the at least one of the mobile transceiver units from a deactivated state when participation of the at least one mobile transceiver unit in a position determination operation is required.

In an embodiment an automated material handling system (AMHS) for a semiconductor fabrication facility (FAB) includes: a sensor supported by a rail, wherein the sensor is configured to collect sensor data characterizing a vehicle that moves along the rail, wherein the vehicle is configured to carry at least one wafer; and a monitoring module configured to: detect a trigger event based on the sensor data, and initiate a remediation action in response to the trigger event.

A stacker crane includes a transporter, a slide fork, first to third sensors, a counter, and a main controller. The transporter moves from a shelf on which an article is supported to an empty shelf. The slide fork is mounted on the lift stage and transfers the article to and from the shelf. The first, second and third sensors recognize an abnormality of the article moved by the movement of the transporter. The counter counts the number of event occurrences. When an abnormality is recognized by the sensor, the main controller reduces a moving speed of the transporter, and when no abnormality is recognized by the sensor upon reduction in the moving speed, the movement of the transporter is continued. When the number of event occurrences reaches a first threshold, the stacker crane is brought into an abnormal-stop state.

Techniques and apparatus for performing a power-on self-test for a braking system in an autonomous delivery robot are described. One technique includes moving each wheel of the autonomous delivery robot in a first direction in accordance with predefined criteria, while brake module(s) of the braking system are engaged to one or more of the wheels to stop movement of the one or more wheels. A first amount of movement of at least a first wheel that is engaged to a first brake module is determined. Upon determining that the first amount of movement satisfies a predetermined condition, a determination is made that the braking system has failed the test and the brake module(s) of the braking system are kept in an engaged state.

Provided are a method for discharging a first battery and a second battery included in a mobile robot, the method including determining that the mobile robot is to begin driving, determining which of a plurality of predetermined intervals a charge amount of the first battery and a charge amount of the second battery at a time point of the determination fall within, respectively, determining an interval to discharge the first battery based on which intervals the charge amount of the first battery and the charge amount of the second battery fall within, and performing a switching operation to begin discharging of the second battery after the first battery has completed discharging in the determined interval, a mobile robot performing the method, and a computer-readable recording medium having a computer program for executing the method stored thereon.

The present disclosure discloses a dispatching method and device for robots, and a non-transitory readable storage medium, and relates to the field of computer technology. The method of the present disclosure includes: obtaining path condition information within a warehouse; calculating pickup time of each candidate robot of a plurality of candidate robots according to a location of the candidate robot and the path condition information; dispatching a target robot to perform a pickup task according to the pickup time of each candidate robot.

Techniques for providing an entity monitoring safety feature in an inventory management system may be described. For example, information that indicates respective locations for a plurality of mobile drive units within an inventory management system may be received. Tracking information may be received from a mobile location unit that is moving within a bounded area around a signal transmitter that is coupled to an entity. The tracking information may include an approximate location of the signal transmitter relative to the mobile location unit. Pathway information may be generated that indicates to the plurality of mobile drive units within the inventory management system to stay outside of a radius distance of the mobile location unit based on the received tracking information. The generated pathway information may be provided to the plurality of mobile drive units to enable safe passage for the entity within the inventory management system.