Abstract: Methods and systems are provided for improving operator performance by robot gamification, the method including parking a robot at a pose location within a navigational space, identifying, by a sensor in electronic communication with an interactive display device, an operator located within a zone proximate the robot for acquiring an item to be picked, receiving, at the interactive display device, operator performance data associated with the acquiring of the item, and rendering, on the interactive display device in response to the received operator performance data, at least one graphic representation of operator achievement within a gamified performance tracking environment.

Abstract: A method for recommending a tote type for an operator to select for use in robot induction process, wherein the robot operates under the control of a warehouse management system to fulfill orders, each order including one or more items and each item being located in a warehouse. The method includes grouping one or more orders from an order queue to form at least one order set. The method also includes identifying, based on a characteristic of the at least one order set, a preferred tote type to be assigned to the robot to carry the order set on the robot. The method further includes communicating to an operator the preferred tote type to enable the operator to select from a plurality of totes a tote of the preferred tote type to assign to the robot for execution of the order.

Abstract: A system and method for synchronizing database changes in an enterprise portal application. The system has a cache storing cache data having table data and index data of one or more databases. A schema layer generates schema objects representing the schema of the databases of the cache data. A change management system and a schema layer validates a cache of one or more databases and synchronizes the cache data to the databases by receiving a changeset, comparing the changeset to the schema data, verifying that the changeset is compatible with the cache data and the schema data, and passing the changeset to the cache for updating the cache data or for refreshing the schema data by the schema layer.

Abstract: A method and system for navigation of a robot along a goal path and avoiding obstacles. The method includes receiving goal pose for one or more robots and determining a goal path for a first robot while avoiding moving and fixed obstacles of a received obstacle map. A first objective function is evaluated to select a preferred velocity from a generated set of candidate velocities, the selecting based on one or more weighted cost functions. A set of velocity obstacles created based on the poses of the one or more robots and the preferred velocity is used in evaluating a second objective function to determine the motion of the robot in the next time cycle. Creating the set of velocity objects includes converting the preferred velocity from a non-holonomic to a holonomic velocity.

Abstract: An electrical charging system for charging an autonomous robot powered by a re-chargeable battery and having a first charging member. The charging station includes a second charging member configured to receive the first charging member on the autonomous robot when the autonomous robot is docked with the charging station for charging the re-chargeable battery. There is a power supply configured to charge the re-chargeable battery of the robot and a sensor configured to measure an amount of charge transferred from the power supply to the robot. There is a processor configured to determine from the amount of charge transferred from the power supply to the robot measured by the sensor, a state of charge (SOC) of the autonomous robot. There is also a communications device configured to transmit to the robot the SOC of the robot while docked at the charging station.

Abstract: An electrical charging station for charging an autonomous robot with first and second cameras used for docking the autonomous robot with the electrical charging station. There is a front side cover with a surface, the front side cover including a first charging member configured to receive a second charging member on the autonomous robot when the autonomous robot is docked with the charging station for charging. There is a first fiducial surface including a first fiducial marker affixed to the first surface. The first fiducial surface defines a plane disposed at a first non-zero angle relative to a plane defined by the surface of the front side cover. There is a second fiducial surface including a second fiducial marker affixed to the second surface. The second fiducial surface defines a plane disposed at a second non-zero angle relative to the plane defined by the surface of the front side cover.

Abstract: A method for navigating a robot from a current pose to a goal pose. A map represents obstacles and free space within an area for robot navigation. A matching map pyramid and an exclusion map pyramid are constructed based on the map and decimations from a highest resolution to successively lower resolutions of the map pyramids. Current pose for navigating from a current location to a goal pose along a goal path includes determining a search area and creating a search heap. Scoring of search tasks on the search heap determines a best candidate pose at a highest resolution matching map, or expands the search heap with search tasks at the next higher resolution matching map. Expanding the search heap at the next higher resolution matching map avoids search tasks that would localize the robot in an exclusion zone.

Abstract: A method, system, and wheeled base for navigating a robot for docking with a charger docking station. The robot receives an initial pose associated with a robot charger docking station and a mating pose associated with the robot charger docking station. The robot first navigates from a location to an initial pose using scan matching to a first map. The robot performs a second navigation from the initial pose to the mating pose using scan matching to a second map, thereby causing an electrical charging port of the robot to mate with an electrical charging assembly of the robot charger docking station. Localization during charger docking may use a higher resolution map than when navigating to the docking station. Localizing against the robot charger docking station may be performed on a higher resolution map of the docking station alone.

Abstract: An electrical charging station for charging an autonomous robot includes a charging station frame having a frame base with a plurality of interconnected frame elements configured to be secured to a floor. One of the frame elements is a front side frame element. There is a charging station cover mounted on the charging station frame and the charging station cover includes a front side cover having a front surface with a charging member. There is a protective member extending across and having a front surface projecting outwardly from the front surface of the front side cover. The protective member is interconnected to the front side frame element through a plurality of apertures in the front side cover and the front side frame element is located adjacent to a back surface of the front side cover, opposite the front surface.

Abstract: An electrical charging system including an electrical charger assembly with a charger base coupled to an electrical power source. There is a first male terminal member terminating in a first electrical contact with at least two curved external surfaces and one flat surface. There is a second male terminal member terminating in a second electrical contact with at least two curved external surfaces and one flat surface. There is a cavity formed between the first male terminal member and the second male terminal member having an opening between the first and second electrical contacts. The cavity is defined by the flat surface of the first male terminal member and the flat surface of the second male terminal member. The flat surface of the second male terminal member has a flared surface portion proximate the opening of the cavity and angled relative to the second axis.

Abstract: A robot capable of autonomously navigating through a warehouse to execute orders on items at locations in the warehouse with the assistance of the human operators. There is a mobile base unit and a display device associated with the mobile base unit having a display area to allow the human operators to interact with the robot. And, there is a processor configured to display on a first portion of the display area information corresponding to an item on which an operator is to assist the robot execute the order at a first location and to display on a second portion of the display area icons representing other robots within a predetermined area surrounding the first location.

Abstract: A system for identifying and tracking performance of operators in a warehouse. The system comprises at least one robot configured to interact with the operators in the warehouse. The at least one robot includes a first transceiver, a proximity detector, and a memory. The first transceiver defines a zone surrounding the robot and the proximity detector is coupled to the first transceiver. The proximity detector is configured to detect entry, into the zone, of an operator and to detect exit of the operator from the zone. The memory contains information identifying said operators who have entered and exited the zone.

Abstract: A method for performing tasks on items located in a space using a robot, the items being located proximate fiducial markers, each fiducial marker having a fiducial identification. The method includes receiving an order to perform a task on at least one item and determining the fiducial identification associated with the at least one item. The method also includes obtaining, using the fiducial identification of the at least one item, a set of coordinates representing a position of the fiducial marker with the determined fiducial identification, in a coordinate system defined by the space. The method further includes navigating the robot to the coordinates of the fiducial marker associated with said determined fiducial identification.

Abstract: A method for executing orders by at least one robot on a plurality of items stored at locations throughout a warehouse including reading a bar code affixed to an item storage array disposed on said at least one robot. The item storage array includes a plurality of interconnected containers each for storing items associated with an order. The method also includes using the read bar code to retrieve information about at least one characteristic of the item storage array and assigning an order associated to each of the plurality of containers of the item storage array. The orders are based in part on the at least one characteristic of the item storage array. The method further includes navigating the at least one robot to locations throughout the warehouse to execute the orders associated with each of the plurality of containers of the item storage array.

Abstract: A method for performing tasks on items located in a space using a robot, the items being located proximate fiducial markers, each fiducial marker having a fiducial identification. The method includes receiving an order to perform a task on at least one item and determining the fiducial identification associated with the at least one item. The method also includes obtaining, using the fiducial identification of the at least one item, a set of coordinates representing a position of the fiducial marker with the determined fiducial identification, in a coordinate system defined by the space. The method further includes navigating the robot to the coordinates of the fiducial marker associated with said determined fiducial identification.