39 - Transport, packaging, storage and travel services
42 - Scientific, technological and industrial services, research and design
Goods & Services
Providing information in the field of warehouse automation; consulting in the field of warehouse automation; Warehouse automation services. Platform as a service featuring computer software platforms for automated warehouse management.
09 - Scientific and electric apparatus and instruments
42 - Scientific, technological and industrial services, research and design
Goods & Services
Downloadable computer software using artificial intelligence (AI) for automated warehouse management featuring industrial robots. Platform as a service (PAAS) featuring computer software platforms for automated warehouse management featuring industrial robots.
39 - Transport, packaging, storage and travel services
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Providing information in the field of warehouse automation; consulting in the field of warehouse automation; Warehouse automation services
(2) Platform as a service featuring computer software platforms for automated warehouse management
A method for estimating a pose of a robot using two co-planar points on an object plane in the environment and two co-planar lines on the object plane, includes capturing with a camera on the robot an image of the object in the environment, including two observed points corresponding to the two co-planar points on the object and two observed lines corresponding to the two co-planar lines on the object; projecting onto the image plane the two co-planar points to obtain two projected points and projecting the two co-planar lines to obtain two projected lines; determining a point projection error by comparing the two projected co-planar points to corresponding observed points; determining a line projection error by comparing the two projected co-planar lines to corresponding observed lines; and estimating a current robot pose if the point projection error and the line projection error are below a predetermined error threshold.
A method for estimating a pose of a robot using two co-planar points on an object plane in the environment and two co-planar lines on the object plane, includes capturing with a camera on the robot an image of the object in the environment, including two observed points corresponding to the two co-planar points on the object and two observed lines corresponding to the two co-planar lines on the object; projecting onto the image plane the two co-planar points to obtain two projected points and projecting the two co-planar lines to obtain two projected lines; determining a point projection error by comparing the two projected co-planar points to corresponding observed points; determining a line projection error by comparing the two projected co-planar lines to corresponding observed lines; and estimating a current robot pose if the point projection error and the line projection error are below a predetermined error threshold.
09 - Scientific and electric apparatus and instruments
42 - Scientific, technological and industrial services, research and design
Goods & Services
Downloadable computer software using artificial intelligence (AI) for automated warehouse management featuring industrial robots Platform as a service (PAAS) featuring computer software platforms for automated warehouse management featuring indsutrial robots
39 - Transport, packaging, storage and travel services
42 - Scientific, technological and industrial services, research and design
Goods & Services
providing information in the field of warehouse automation; consulting in the field of warehouse automation; Warehouse automation services Platform as a service featuring computer software platforms for automated warehouse management
39 - Transport, packaging, storage and travel services
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Industrial Robots (1) Subscription based rental of industrial robots for use in warehouse automation; consulting in the field of robotics; providing information in the field of robotics
42 - Scientific, technological and industrial services, research and design
Goods & Services
Platform as a service featuring computer software platforms for automated warehouse management for coordination of industrial robots for processing and fulfilling orders
09 - Scientific and electric apparatus and instruments
Goods & Services
Industrial robots; automated material handling system consisting of industrial robots embedded with operating software, cameras and sensors. Recorded computer software and computer hardware for automated material handling systems.
09 - Scientific and electric apparatus and instruments
Goods & Services
(1) Industrial robots
(2) Automated material handling system consisting primarily of recorded computer software and computer hardware and also including industrial robots embedded with operating software, cameras and sensors
09 - Scientific and electric apparatus and instruments
Goods & Services
Industrial robots Automated material handling system consisting primarily of recorded computer software for warehouse automation and computer hardware and also including industrial robots embedded with operating software, cameras and sensors
09 - Scientific and electric apparatus and instruments
42 - Scientific, technological and industrial services, research and design
Goods & Services
(1) Automated material handling system, namely, computer software, computer hardware and robotic systems comprised primarily of robots, operating software, cameras, and sensors all for task and labor management at distribution warehouses and manufacturing facilities. (1) Operation of industrial robots for labor management and task management at distribution warehouses and manufacturing facilities.
Systems and methods are provided for robot congestion management including a robot monitoring server configured to track a location of a plurality of robots within a navigational space and a plurality of robots in communication with the robot monitoring server, each robot including a processor and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to determine, from a task list assigned to the robot, a first pose location corresponding to a first task, receive, from the robot monitoring server, congestion information associated with the first pose location, identify a congested state of the first pose location indicated by the congestion information, select, responsive to the identification of the congested state, a second task from the task list, and navigate to a second pose location corresponding to the second task.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system, namely, computer
software, computer hardware and robotic systems comprised
primarily of robots, operating software, cameras, and
sensors all for processing and order fulfillment, material
handling, mechanized automation, at distribution warehouses
and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system, namely, computer
software, computer hardware and robotic systems comprised
primarily of robots, operating software, cameras, and
sensors all for processing and order fulfillment, material
handling, mechanized automation, at distribution warehouses
and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system, namely, computer
software, computer hardware and robotic systems comprised
primarily of robots, operating software, cameras, and
sensors all for processing and order fulfillment, material
handling, mechanized automation, at distribution warehouses
and manufacturing facilities.
27.
A MOBILE ROBOT HAVING A REMOVABLE WHEEL-DRIVE ASSEMBLY
A mobile robot (100) having a removable wheel-drive assembly, comprising a mobile base (104) having a chassis (120) and a first wheel well member (180) with a flange. There is a removable wheel drive assembly (110, 112) with a mounting bracket (140, 150). There is a motor drive unit (170) disposed on the mounting bracket (140, 150) and a wheel/tire connected to the motor drive unit (170) via an axle. There is a second wheel well member (180) on the mounting bracket (140, 150) and positioned between the motor drive unit (170) and the wheel (160). The second wheel well member (180) includes a central section (210, 216) having an aperture (182) through which the axle passes and a top surface (310). The top surface (310) of the central section (210, 216) of the second wheel well member (180) engages with the flange of the first wheel well member (180) of the mobile base (104).
B62D 61/04 - Motor vehicles or trailers, characterised by the arrangement or number of wheels, not otherwise provided for, e.g. four wheels in diamond pattern with two road wheels in tandem on the longitudinal centre line of the vehicle with two other wheels which are coaxial
Robot charging dock includes a charge connector configured to mate with a charging port of a mobile robot. There is a charge connector frame having a front surface on which the charge connector is mounted. The front surface has a first side edge and a second side edge. There is a front cover disposed over the charge connector frame which has an aperture through which the charge connector protrudes. At least a portion of the front cover is spaced from the front surface of the charge connector frame, defining an internal region. There is an opening to the internal region formed along at least a portion of a perimeter of the aperture and there is a light source disposed in the internal region. The light source is directed toward the opening to allow the light source to illuminate charge connector.
A mobile robot having a removable wheel-drive assembly, comprising a mobile base having a chassis and a first wheel well member with a flange. There is a removable wheel drive assembly with a mounting bracket. There is a motor drive unit disposed on the mounting bracket and a wheel/tire connected to the motor drive unit via an axle. There is a second wheel well member on the mounting bracket and positioned between the motor drive unit and the wheel. The second wheel well member includes a central section having an aperture through which the axle passes and a top surface. The top surface of the central section of the second wheel well member engages with the flange of the first wheel well member of the mobile base.
B62D 65/12 - Joining sub-units or components to, or positioning sub-units or components with respect to, body shell or other sub-units or components the sub-units or components being suspensions, brakes or wheel units
B25J 5/00 - Manipulators mounted on wheels or on carriages
Robot charging dock includes a charge connector configured to mate with a charging port of a mobile robot. There is a charge connector frame having a front surface on which the charge connector is mounted. The front surface has a first side edge and a second side edge. There is a front cover disposed over the charge connector frame which has an aperture through which the charge connector protrudes. At least a portion of the front cover is spaced from the front surface of the charge connector frame, defining an internal region. There is an opening to the internal region formed along at least a portion of a perimeter of the aperture and there is a light source disposed in the internal region. The light source is directed toward the opening to allow the light source to illuminate charge connector.
B25J 19/00 - Accessories fitted to manipulators, e.g. for monitoring, for viewingSafety devices combined with or specially adapted for use in connection with manipulators
B25F 5/02 - Construction of casings, bodies or handles
B25J 13/08 - Controls for manipulators by means of sensing devices, e.g. viewing or touching devices
B60L 53/30 - Constructional details of charging stations
B60L 53/35 - Means for automatic or assisted adjustment of the relative position of charging devices and vehicles
B60L 53/37 - Means for automatic or assisted adjustment of the relative position of charging devices and vehicles using optical position determination, e.g. using cameras
H02J 7/00 - Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
B25J 11/00 - Manipulators not otherwise provided for
F21V 33/00 - Structural combinations of lighting devices with other articles, not otherwise provided for
F21W 131/403 - Lighting for industrial, commercial, recreational or military use for machines
09 - Scientific and electric apparatus and instruments
Goods & Services
(1) Automated material handling system, namely, computer software, computer hardware and robotic systems comprised primarily of robots, operating software, cameras, and sensors all for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
(1) Automated material handling system, namely, computer software, computer hardware and robotic systems comprised primarily of robots, operating software, cameras, and sensors all for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
(1) Automated material handling system, namely, computer software, computer hardware and robotic systems comprised primarily of robots, operating software, cameras, and sensors all for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system, namely, robotic systems comprised of robots, operating software, cameras, and sensors all for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities. Computer software, computer hardware for automated material handling system for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system, namely, robotic systems comprised of robots, operating software, cameras, and sensors all for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities. Computer software, computer hardware for automated material handling system for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system, namely, robotic systems comprised of robots, operating software, cameras, and sensors all for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities. Computer software, computer hardware for automated material handling system for processing and order fulfillment, material handling, mechanized automation, at distribution warehouses and manufacturing facilities.
A system for determining pose of a lidar sensor in an environment in order to calibrate the lidar sensor. The system includes at least two calibration boards, each having a first edge and a second edge. There is a controller coupled to the lidar sensor to cause the lidar sensor to direct a lidar scan at the calibration boards. The controller causes the lidar sensor to receive a reflection of the lidar scan from the calibration boards and determine locations of a first crossing point on the first edge and a second crossing point on the second edge of the calibration boards. The controller determines a reference plane defined by the first and second crossing points of each of the calibration boards, performs a plane transform of the reference frame to obtain a lidar sensor plane and determine from the lidar sensor plane a pose of the lidar sensor.
A system for determining pose of a lidar sensor in an environment in order to calibrate the lidar sensor. The system includes at least two calibration boards, each having a first edge and a second edge. There is a controller coupled to the lidar sensor to cause the lidar sensor to direct a lidar scan at the calibration boards. The controller causes the lidar sensor to receive a reflection of the lidar scan from the calibration boards and determine locations of a first crossing point on the first edge and a second crossing point on the second edge of the calibration boards. The controller determines a reference plane defined by the first and second crossing points of each of the calibration boards, performs a plane transform of the reference frame to obtain a lidar sensor plane and determine from the lidar sensor plane a pose of the lidar sensor.
A method for rolling shutter compensation for a camera sensor mounted on a moving vehicle includes estimating, based on a plurality of images of an object, a speed and a direction of movement of the vehicle; acquiring an additional image of the object having four corners; estimating a location of each of the four corners of the object in an image plane defined by the additional image; determining a corrected location in 3D space for each of the four corners of the object; determining a first compensated location for each of the four corners of the object in the image plane; determining a second compensated location for each of the four corners of the object in the image plane; and determining a difference between the first compensated locations of the four corners of the object and the second compensated locations of the four corners of the object.
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system consisting primarily of industrial robots embedded with operating software and also including cameras and sensors, and the system also includes recorded computer software and computer hardware, all for order processing and fulfillment, material handling, and mechanized automation at distribution warehouses and manufacturing facilities Automated material handling system consisting primarily of recorded computer software and computer hardware, and also including industrial robots embedded with operating software, cameras and sensors, all for order processing and fulfillment, material handling, and mechanized automation at distribution warehouses and manufacturing facilities
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system consisting primarily of industrial robots embedded with operating software and also including cameras and sensors, and the system also includes recorded computer software and computer hardware, all for order processing and fulfillment, material handling, and mechanized automation at distribution warehouses and manufacturing facilities Automated material handling system consisting primarily of recorded computer software and computer hardware, and also including industrial robots embedded with operating software, cameras and sensors, all for order processing and fulfillment, material handling, and mechanized automation at distribution warehouses and manufacturing facilities
09 - Scientific and electric apparatus and instruments
Goods & Services
Automated material handling system consisting primarily of industrial robots embedded with operating software and also including cameras and sensors, and the system also includes recorded computer software and computer hardware, all for order processing and fulfillment, material handling, and mechanized automation at distribution warehouses and manufacturing facilities Automated material handling system consisting primarily of recorded computer software and computer hardware, and also including industrial robots embedded with operating software, cameras and sensors, all for order processing and fulfillment, material handling, and mechanized automation at distribution warehouses and manufacturing facilities
43.
Rolling shutter compensation for moving digital optical camera sensors
A method for rolling shutter compensation for a camera sensor mounted on a moving vehicle includes estimating, based on a plurality of images of an object, a speed and a direction of movement of the vehicle; acquiring an additional image of the object having four corners; estimating a location of each of the four corners of the object in an image plane defined by the additional image; determining a corrected location in 3D space for each of the four corners of the object; determining a first compensated location for each of the four corners of the object in the image plane; determining a second compensated location for each of the four corners of the object in the image plane; and determining a difference between the first compensated locations of the four corners of the object and the second compensated locations of the four corners of the object.
H04N 5/232 - Devices for controlling television cameras, e.g. remote control
B60R 1/00 - Optical viewing arrangementsReal-time viewing arrangements for drivers or passengers using optical image capturing systems, e.g. cameras or video systems specially adapted for use in or on vehicles
Systems and methods for presorting and executing robot-assisted putaway tasks in a navigational space include assigning each of a plurality of item storage arrays to one of a plurality of zones defined within the navigational space, scanning an item identifier of at least one of a plurality of unsorted items to be stored at locations throughout the warehouse, retrieving, in response to receiving identifying information corresponding to the at least one scanned unsorted item, item data describing a storage location for putaway within the warehouse of each of the at least one scanned items, determining, from the storage location, a corresponding one of the plurality of zones of the warehouse in which the storage location is located, and placing each scanned unsorted item into an interconnected container of one of the item storage arrays assigned to the corresponding one of the zones.
A method for executing orders assigned to a plurality of robots operating in a warehouse, including receiving an order with a plurality of items, each item associated with an item location. The method includes defining a plurality of regions and identifying the regions which include at least one item location associated with the order received by the robot. The method also includes determining, from the regions identified, which regions which include at least one operator and assessing criteria relating to a current location of the robot and to the item locations associated with the regions having at least one operator. The method further includes selecting an item location to which the robot is to navigate from a current location based on an assessment of criteria relating to the current location of the robot and to the item locations associated with the regions in which are located at least one operator.
Processes are provided for dynamically sorting and storing items in a warehouse without the need for presorting items and without delaying or negatively impacting the efficiency of operators in the warehouse. Items are individually scanned and placed in totes of a tote-array provided on a mobile robot. An optimized route is calculated based on the items in the tote-array, and the robot navigates to a first location on the route. When the item has been put away, a replacement item is placed in the just-emptied tote of the tote-array, and an updated route is calculated. A robot capable of navigating to predefined locations for storing items is a warehouse is provided.
Systems and methods for presorting and executing robot-assisted putaway tasks in a navigational space include assigning each of a plurality of item storage arrays to one of a plurality of zones defined within the navigational space, scanning an item identifier of at least one of a plurality of unsorted items to be stored at locations throughout the warehouse, retrieving, in response to receiving identifying information corresponding to the at least one scanned unsorted item, item data describing a storage location for putaway within the warehouse of each of the at least one scanned items, determining, from the storage location, a corresponding one of the plurality of zones of the warehouse in which the storage location is located, and placing each scanned unsorted item into an interconnected container of one of the item storage arrays assigned to the corresponding one of the zones.
Systems and methods are provided for robot navigation management including a server configured to define a first zone and a second, adjacent zone within an environment, a threshold along a border between the first and second zones, and a waypoint associated with the threshold. One or more autonomous robots in communication with the server are configured to determine a route from the first zone to the second zone crossing the threshold, the route including a waypoint; and navigate the robot along the route from the first zone to the second zone, including traversing the waypoint in conjunction with crossing the threshold.
A method for executing orders assigned to a plurality of robots operating in a warehouse, including receiving an order with a plurality of items, each item associated with an item location. The method includes defining a plurality of regions and identifying the regions which include at least one item location associated with the order received by the robot. The method also includes determining, from the regions identified, which regions which include at least one operator and assessing criteria relating to a current location of the robot and to the item locations associated with the regions having at least one operator. The method further includes selecting an item location to which the robot is to navigate from a current location based on an assessment of criteria relating to the current location of the robot and to the item locations associated with the regions in which are located at least one operator.
Processes are provided for dynamically sorting and storing items in a warehouse without the need for presorting items and without delaying or negatively impacting the efficiency of operators in the warehouse. Items are individually scanned and placed in totes of a tote-array provided on a mobile robot. An optimized route is calculated based on the items in the tote-array, and the robot navigates to a first location on the route. When the item has been put away, a replacement item is placed in the just-emptied tote of the tote-array, and an updated route is calculated. A robot capable of navigating to predefined locations for storing items is a warehouse is provided.
Systems and methods are provided for robot navigation management including a server configured to define a first zone and a second, adjacent zone within an environment, a threshold along a border between the first and second zones, and a waypoint associated with the threshold. One or more autonomous robots in communication with the server are configured to determine a route from the first zone to the second zone crossing the threshold, the route including a waypoint; and navigate the robot along the route from the first zone to the second zone, including traversing the waypoint in conjunction with crossing the threshold.
Systems and methods for presorting and executing robot-assisted putaway tasks in a navigational space include assigning each of a plurality of item storage arrays to one of a plurality of zones defined within the navigational space, scanning an item identifier of at least one of a plurality of unsorted items to be stored at locations throughout the warehouse, retrieving, in response to receiving identifying information corresponding to the at least one scanned unsorted item, item data describing a storage location for putaway within the warehouse of each of the at least one scanned items, determining, from the storage location, a corresponding one of the plurality of zones of the warehouse in which the storage location is located, and placing each scanned unsorted item into an interconnected container of one of the item storage arrays assigned to the corresponding one of the zones.
A method for executing orders assigned to a plurality of robots operating in a warehouse, including receiving an order with a plurality of items, each item associated with an item location. The method includes defining a plurality of regions and identifying the regions which include at least one item location associated with the order received by the robot. The method also includes determining, from the regions identified, which regions which include at least one operator and assessing criteria relating to a current location of the robot and to the item locations associated with the regions having at least one operator. The method further includes selecting an item location to which the robot is to navigate from a current location based on an assessment of criteria relating to the current location of the robot and to the item locations associated with the regions in which are located at least one operator.
Systems and methods are provided for robot navigation management including a server configured to define a first zone and a second, adjacent zone within an environment, a threshold along a border between the first and second zones, and a waypoint associated with the threshold. One or more autonomous robots in communication with the server are configured to determine a route from the first zone to the second zone crossing the threshold, the route including a waypoint; and navigate the robot along the route from the first zone to the second zone, including traversing the waypoint in conjunction with crossing the threshold.
Processes are provided for dynamically sorting and storing items in a warehouse without the need for presorting items and without delaying or negatively impacting the efficiency of operators in the warehouse. Items are individually scanned and placed in totes of a tote-array provided on a mobile robot. An optimized route is calculated based on the items in the tote-array, and the robot navigates to a first location on the route. When the item has been put away, a replacement item is placed in the just-emptied tote of the tote-array, and an updated route is calculated. A robot capable of navigating to predefined locations for storing items is a warehouse is provided.
A method for predicting a collision between a mobile robot and an obstacle in an environment includes obtaining laser scan data for the mobile robot at a current location in the environment. The method also includes predicting a future location of the mobile robot in the environment and producing predicted laser scan data corresponding to the future location of the mobile robot in the environment. The method further includes assessing the predicted laser scan data relative to the mobile robot at the current location to determine whether a collision with an obstacle is predicted.
B60R 21/013 - Electrical circuits for triggering safety arrangements in case of vehicle accidents or impending vehicle accidents including means for detecting collisions, impending collisions or roll-over
G01S 17/931 - Lidar systems, specially adapted for specific applications for anti-collision purposes of land vehicles
G05D 1/242 - Means based on the reflection of waves generated by the vehicle
G05D 1/43 - Control of position or course in two dimensions
A method for predicting a collision between a mobile robot and an obstacle in an environment includes obtaining laser scan data for the mobile robot at a current location in the environment. The method also includes predicting a future location of the mobile robot in the environment and producing predicted laser scan data corresponding to the future location of the mobile robot in the environment. The method further includes assessing the predicted laser scan data relative to the mobile robot at the current location to determine whether a collision with an obstacle is predicted.
A method for predicting a collision between a mobile robot and an obstacle in an environment includes obtaining laser scan data for the mobile robot at a current location in the environment. The method also includes predicting a future location of the mobile robot in the environment and producing predicted laser scan data corresponding to the future location of the mobile robot in the environment. The method further includes assessing the predicted laser scan data relative to the mobile robot at the current location to determine whether a collision with an obstacle is predicted.
G01S 17/931 - Lidar systems, specially adapted for specific applications for anti-collision purposes of land vehicles
B60R 21/013 - Electrical circuits for triggering safety arrangements in case of vehicle accidents or impending vehicle accidents including means for detecting collisions, impending collisions or roll-over
G01S 17/89 - Lidar systems, specially adapted for specific applications for mapping or imaging
G05D 1/02 - Control of position or course in two dimensions
41 - Education, entertainment, sporting and cultural services
Goods & Services
Charitable services, namely, academic and employment mentoring in the fields of science, technology, engineering and math (STEM), specifically in the field of robotics; charitable services, namely, providing training in the fields of science, technology, engineering and math (STEM), specifically robotics; charitable education services, namely, providing workshops and courses in the fields of science, technology, engineering and math (STEM), specifically robotics
A docking station for charging a robot including an electrical charger assembly affixed to the charger docking station and configured to mate with an electrical charging port on the robot when the robot is docked at the docking station for charging. There is at least one compliant member interconnecting the electrical charger assembly to a portion of the docking station to allow movement of the electrical charger assembly relative to the electrical charging port on the robot when the robot is mating with the docking station.
A method for assigning orders to a plurality of robots fulfilling orders in a warehouse with the assistance of a plurality of operators. The method includes providing a first robot of the plurality of robots to a be assigned an order set, including one or more orders to be fulfilled and assessing the locations of at least one of the plurality of robots or at least one of the plurality of operators in the warehouse. The method also includes selecting an anchor location in the warehouse and generating an order set for the first robot correlated to the anchor location in the warehouse. The method also includes assigning the order set to the first robot for fulfillment.
Systems and methods for robot assisted personnel routing including a plurality of autonomous robots operating within a navigational space, each robot including a processor and a memory storing instructions that, when executed by the processor, cause the autonomous robot to detect completion of a task operation by a human operator, receive status information corresponding to at least one other robot, the status information including at least one of a location or a wait time associated with the other robot, determine, from the status information, at least one next task recommendation for directing the human operator to a next robot for a next task operation, and render, on a display of the robot, the at least one next task recommendation for viewing by the human operator, the next task recommendation including a location of the next robot corresponding to the next task.
G06F 3/0481 - Interaction techniques based on graphical user interfaces [GUI] based on specific properties of the displayed interaction object or a metaphor-based environment, e.g. interaction with desktop elements like windows or icons, or assisted by a cursor's changing behaviour or appearance
G06Q 10/087 - Inventory or stock management, e.g. order filling, procurement or balancing against orders
Systems and methods for robot assisted personnel routing including a plurality of autonomous robots operating within a navigational space, each robot including a processor and a memory storing instructions that, when executed by the processor, cause the autonomous robot to detect completion of a task operation by a human operator, receive status information corresponding to at least one other robot, the status information including at least one of a location or a wait time associated with the other robot, determine, from the status information, at least one next task recommendation for directing the human operator to a next robot for a next task operation, and render, on a display of the robot, the at least one next task recommendation for viewing by the human operator, the next task recommendation including a location of the next robot corresponding to the next task.
Systems and methods are provided for robot congestion management including a robot monitoring server configured to track a location of a plurality of robots within a navigational space and a plurality of robots in communication with the robot monitoring server, each robot including a processor and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to determine, from a task list assigned to the robot, a first pose location corresponding to a first task, receive, from the robot monitoring server, congestion information associated with the first pose location, identify a congested state of the first pose location indicated by the congestion information, select, responsive to the identification of the congested state, a second task from the task list, and navigate to a second pose location corresponding to the second task.
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.
A method for assigning orders to a plurality of robots fulfilling orders in a warehouse with the assistance of a plurality of operators. The method includes providing a first robot of the plurality of robots to a be assigned an order set, including one or more orders to be fulfilled and assessing the locations of at least one of the plurality of robots or at least one of the plurality of operators in the warehouse. The method also includes selecting an anchor location in the warehouse and generating an order set for the first robot correlated to the anchor location in the warehouse. The method also includes assigning the order set to the first robot for fulfillment.
Systems and methods are provided for robot congestion management including a robot monitoring server configured to track a location of a plurality of robots within a navigational space and a plurality of robots in communication with the robot monitoring server, each robot including a processor and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to determine, from a task list assigned to the robot, a first pose location corresponding to a first task, receive, from the robot monitoring server, congestion information associated with the first pose location, identify a congested state of the first pose location indicated by the congestion information, select, responsive to the identification of the congested state, a second task from the task list, and navigate to a second pose location corresponding to the second task.
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.
A method for executing an order with a plurality of items assigned to a first robot of a plurality of robots operating in a warehouse with the assistance of a plurality of operators. The method includes navigating the first robot to a first location in the warehouse proximate a location of a first item in the order and pausing for an operator of to assist the first robot to execute a function. The method includes determining if the first robot has been paused for greater than a maximum dwell time without being assisted by an operator. If it has been, the method causes the first robot to leave the first location without completing the function on the first item and causing the first robot to proceed to a second location proximate a storage a second item to execute a function.
Systems and methods are provided for robot congestion management including a robot monitoring server configured to track a location of a plurality of robots within a navigational space and a plurality of robots in communication with the robot monitoring server, each robot including a processor and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to determine, from a task list assigned to the robot, a first pose location corresponding to a first task, receive, from the robot monitoring server, congestion information associated with the first pose location, identify a congested state of the first pose location indicated by the congestion information, select, responsive to the identification of the congested state, a second task from the task list, and navigate to a second pose location corresponding to the second task.
Systems and methods for proximate robot object detection and avoidance are provided herein which include a receiver in electronic communication with an autonomous robot and configured to receive a broadcast message from a beacon, a processor, and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to detect, based on the received broadcast message, a proximity of the beacon to the autonomous robot, determine, from the received broadcast message, a beacon status, the beacon status indicating whether the beacon is stationary, approaching the autonomous robot, or withdrawing from the autonomous robot, identify, according to the detected proximity and the determined beacon status, a corresponding proximity operation, and control the autonomous robot to stop an ordinary operation and operate according to the identified proximity operation.
G05D 1/246 - Arrangements for determining position or orientation using environment maps, e.g. simultaneous localisation and mapping [SLAM]
G05D 1/247 - Arrangements for determining position or orientation using signals provided by artificial sources external to the vehicle, e.g. navigation beacons
Systems and methods for proximate robot object detection and avoidance are provided herein which include a receiver in electronic communication with an autonomous robot and configured to receive a broadcast message from a beacon, a processor, and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to detect, based on the received broadcast message, a proximity of the beacon to the autonomous robot, determine, from the received broadcast message, a beacon status, the beacon status indicating whether the beacon is stationary, approaching the autonomous robot, or withdrawing from the autonomous robot, identify, according to the detected proximity and the determined beacon status, a corresponding proximity operation, and control the autonomous robot to stop an ordinary operation and operate according to the identified proximity operation.
B25J 5/00 - Manipulators mounted on wheels or on carriages
B66F 9/06 - Devices for lifting or lowering bulky or heavy goods for loading or unloading purposes movable, with their loads, on wheels or the like, e.g. fork-lift trucks
73.
ROBOT DWELL TIME MINIMIZATION IN WAREHOUSE ORDER FULFILLMENT OPERATIONS
A method for executing an order with a plurality of items assigned to a first robot of a plurality of robots operating in a warehouse with the assistance of a plurality of operators. The method includes navigating the first robot to a first location in the warehouse proximate a location of a first item in the order and pausing for an operator of to assist the first robot to execute a function. The method includes determining if the first robot has been paused for greater than a maximum dwell time without being assisted by an operator. If it has been, the method causes the first robot to leave the first location without completing the function on the first item and causing the first robot to proceed to a second location proximate a storage a second item to execute a function.
Systems and methods for robot assisted personnel routing including a plurality of autonomous robots operating within a navigational space, each robot including a processor and a memory storing instructions that, when executed by the processor, cause the autonomous robot to detect completion of a task operation by a human operator, receive status information corresponding to at least one other robot, the status information including at least one of a location or a wait time associated with the other robot, determine, from the status information, at least one next task recommendation for directing the human operator to a next robot for a next task operation, and render, on a display of the robot, the at least one next task recommendation for viewing by the human operator, the next task recommendation including a location of the next robot corresponding to the next task.
Systems and methods for proximate robot object detection and avoidance are provided herein which include a receiver in electronic communication with an autonomous robot and configured to receive a broadcast message from a beacon, a processor, and a memory, the memory storing instructions that, when executed by the processor, cause the autonomous robot to detect, based on the received broadcast message, a proximity of the beacon to the autonomous robot, determine, from the received broadcast message, a beacon status, the beacon status indicating whether the beacon is stationary, approaching the autonomous robot, or withdrawing from the autonomous robot, identify, according to the detected proximity and the determined beacon status, a corresponding proximity operation, and control the autonomous robot to stop an ordinary operation and operate according to the identified proximity operation.
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.
A method for assigning orders to a plurality of robots fulfilling orders in a warehouse with the assistance of a plurality of operators. The method includes providing a first robot of the plurality of robots to a be assigned an order set, including one or more orders to be fulfilled and assessing the locations of at least one of the plurality of robots or at least one of the plurality of operators in the warehouse. The method also includes selecting an anchor location in the warehouse and generating an order set for the first robot correlated to the anchor location in the warehouse. The method also includes assigning the order set to the first robot for fulfillment.
G05D 1/02 - Control of position or course in two dimensions
G05B 19/418 - Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
78.
Optimized tote recommendation process in warehouse order fulfillment operations
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.
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.
A method for executing an order with a plurality of items assigned to a first robot of a plurality of robots operating in a warehouse with the assistance of a plurality of operators. The method includes navigating the first robot to a first location in the warehouse proximate a location of a first item in the order and pausing for an operator of to assist the first robot to execute a function. The method includes determining if the first robot has been paused for greater than a maximum dwell time without being assisted by an operator. If it has been, the method causes the first robot to leave the first location without completing the function on the first item and causing the first robot to proceed to a second location proximate a storage a second item to execute a function.
A method for customer assisted robot picking includes navigating a robot to a pose location within a retail space in proximity to an item to be picked, the retail space having items for purchase by customers, the robot identifying, by a sensor in communication with the robot, a customer located within a zone proximate the robot, communicating to the customer information identifying the item to be picked, detecting presentation of the item by the customer for identification, and updating customer performance data stored in a customer account to include data corresponding to picking of the item by the customer.
A method for customer assisted robot picking includes navigating a robot to a pose location within a retail space in proximity to an item to be picked, the retail space having items for purchase by customers, the robot identifying, by a sensor in communication with the robot, a customer located within a zone proximate the robot, communicating to the customer information identifying the item to be picked, detecting presentation of the item by the customer for identification, and updating customer performance data stored in a customer account to include data corresponding to picking of the item by the customer.
A method for customer assisted robot picking includes navigating a robot to a pose location within a retail space in proximity to an item to be picked, the retail space having items for purchase by customers, the robot identifying, by a sensor in communication with the robot, a customer located within a zone proximate the robot, communicating to the customer information identifying the item to be picked, detecting presentation of the item by the customer for identification, and updating customer performance data stored in a customer account to include data corresponding to picking of the item by the customer.
Systems and methods for contextually mapping zones within a space for regulating robotic navigation within the space include defining, by at least one fiducial marker positioned within the space, a zone within the space, associating a rule with the zone, the rule at least partially dictating operation of one or more robots within the zone, and operating the one or more robots within the zone consistent with the rule.
G05D 1/225 - Remote-control arrangements operated by off-board computers
G05D 1/244 - Arrangements for determining position or orientation using passive navigation aids external to the vehicle, e.g. markers, reflectors or magnetic means
G06Q 10/087 - Inventory or stock management, e.g. order filling, procurement or balancing against orders
85.
ZONE ENGINE FOR PROVIDING CONTEXT-AUGMENTED MAP LAYER
Systems and methods for contextually mapping zones within a space for regulating robotic navigation within the space include defining, by at least one fiducial marker positioned within the space, a zone within the space, associating a rule with the zone, the rule at least partially dictating operation of one or more robots within the zone, and operating the one or more robots within the zone consistent with the rule.
Systems and methods for contextually mapping zones within a space for regulating robotic navigation within the space include defining, by at least one fiducial marker positioned within the space, a zone within the space, associating a rule with the zone, the rule at least partially dictating operation of one or more robots within the zone, and operating the one or more robots within the zone consistent with the rule.
A method and system for data retrieval in an enterprise portal application. The method and system include receiving, in a data access layer, a request for object data from a business logic layer. The method and system further includes validating, by a schema layer in communication with the data access layer, that cache data of a cache and data of one or more databases of the enterprise portal application are synchronized. The cache data may include table data and index data of the one or more databases of the enterprise portal application. The method and system further include retrieving, if the cache is validated, table data from the cache, and returning the object data to the business logic layer, the object data corresponding to the retrieved table data.
G06F 16/27 - Replication, distribution or synchronisation of data between databases or within a distributed database systemDistributed database system architectures therefor
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.
G06F 16/27 - Replication, distribution or synchronisation of data between databases or within a distributed database systemDistributed database system architectures therefor
G06F 16/21 - Design, administration or maintenance of databases
A retainer device for removably connecting a first tote to a second tote in a stacked arrangement includes an elongated body member including a top surface, a bottom surface, and a channel disposed in the bottom surface and extending along a length of the elongated body member. There is a leg member affixed to the elongated body member at a first angle with respect to the top surface of the elongated body member and extending at least partially along the length of the elongated body member. There is also at least one foot member having a top surface; the at least one foot member affixed to the leg member at a second angle such that the top surface of at least one foot member faces the bottom surface of the elongated body member to define a region for receiving portions of the first and second totes.
A method for performing tasks on items located in a space using a robot, includes receiving an order to perform a task on at least one item and obtaining a pose associated with the at least one item. The pose is in a coordinate system defined by the space and the pose is where the task is to be performed on the at least one item. The method includes navigating the robot toward the pose associated with the at least one item and detecting, when in proximity to the pose, if the pose is obstructed by an object. If the pose is obstructed by an object, halting the robot at a location spaced from the pose and then causing the robot to provide a first signal indicating that the robot is in a holding mode at the location spaced from the pose.
A method for performing tasks on items located in a space using a robot, includes receiving an order to perform a task on at least one item and obtaining a pose associated with the at least one item. The pose is in a coordinate system defined by the space and the pose is where the task is to be performed on the at least one item. The method includes navigating the robot toward the pose associated with the at least one item and detecting, when in proximity to the pose, if the pose is obstructed by an object. If the pose is obstructed by an object, halting the robot at a location spaced from the pose and then causing the robot to provide a first signal indicating that the robot is in a holding mode at the location spaced from the pose.
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.
G06Q 10/06 - Resources, workflows, human or project managementEnterprise or organisation planningEnterprise or organisation modelling
G06K 9/00 - Methods or arrangements for reading or recognising printed or written characters or for recognising patterns, e.g. fingerprints
H04W 4/80 - Services using short range communication, e.g. near-field communication [NFC], radio-frequency identification [RFID] or low energy communication
93.
A MOBILE ROBOT HAVING AN IMPROVED SUSPENSION SYSTEM
A mobile robot (18) configured to drive on a surface with irregularities, comprising: a chassis having a front end facing a forward direction of travel, a back end, a first side, and a second side. There is a first drive wheel (40) rigidly affixed to the chassis proximate the first side and interconnected to a motor to propel it. There is a second drive wheel (42) rigidly affixed to the chassis proximate the second side and interconnected to a motor to propel it. A first caster assembly (44) is rigidly affixed to the chassis proximate the front end and includes a first caster wheel configured to rotate about a first swivel axis. A second caster assembly (46) is rigidly affixed to the chassis proximate the back end and includes a second caster wheel configured to rotate about a second swivel axis and it includes a compliant member to absorb the irregularities.
B62D 61/04 - Motor vehicles or trailers, characterised by the arrangement or number of wheels, not otherwise provided for, e.g. four wheels in diamond pattern with two road wheels in tandem on the longitudinal centre line of the vehicle with two other wheels which are coaxial
A mobile robot configured to drive on a surface with irregularities, comprising: a chassis having a front end facing a forward direction of travel, a back end, a first side, and a second side. There is a first drive wheel rigidly affixed to the chassis proximate the first side and interconnected to a motor to propel it. There is a second drive wheel rigidly affixed to the chassis proximate the second side and interconnected to a motor to propel it. A first caster assembly is rigidly affixed to the chassis proximate the front end and includes a first caster wheel configured to rotate about a first swivel axis. A second caster assembly is rigidly affixed to the chassis proximate the back end and includes a second caster wheel configured to rotate about a second swivel axis and it includes a compliant member to absorb the irregularities.
B60G 11/18 - Resilient suspensions characterised by arrangement, location, or kind of springs having torsion-bar springs only
B62D 21/11 - Understructures, i.e. chassis frame on which a vehicle body may be mounted with resilient means for suspension
B62D 21/18 - Understructures, i.e. chassis frame on which a vehicle body may be mounted characterised by the vehicle type and not provided for in groups
B25J 5/00 - Manipulators mounted on wheels or on carriages
B25J 19/00 - Accessories fitted to manipulators, e.g. for monitoring, for viewingSafety devices combined with or specially adapted for use in connection with manipulators
B60G 3/02 - Resilient suspensions for a single wheel with a single pivoted arm
B62D 61/04 - Motor vehicles or trailers, characterised by the arrangement or number of wheels, not otherwise provided for, e.g. four wheels in diamond pattern with two road wheels in tandem on the longitudinal centre line of the vehicle with two other wheels which are coaxial
A method, system, and wheeled base for navigating a robot for docking with a charger docking station (500). The robot (18) receives an initial pose (604) associated with a robot charger docking station (500) and a mating pose (602) associated with the robot charger docking station (500). The robot (18) first navigates from a location to an initial pose (604) using scan matching to a first map. The robot performs a second navigation (742) from the initial pose (604) to the mating pose (602) 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 (500). 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.
A method and system for docking a robot with a charger docking station, including receiving an initial pose and receiving a mating pose associated with the robot charger docking station, performing a first navigation from a location to the initial pose, and performing a second navigation of the robot from the initial pose to the mating pose. The second navigation may proceed substantially along an arc path from the initial pose to the mating pose, thereby, upon arriving at the mating pose, an electrical charging port of the robot mates with an electrical charging assembly. The arc path may be associated with a section of a unique circle having a radius and a center equidistant from the initial pose and the mating pose. Controlling for error may include a proportional control and/or weighted control or switching between the controls to maintain an error below a threshold.
A method, system, and wheeled base for navigating a robot for docking with a charger docking station (500). The robot (18) receives an initial pose (604) associated with a robot charger docking station (500) and a mating pose (602) associated with the robot charger docking station (500). The robot (18) first navigates from a location to an initial pose (604) using scan matching to a first map. The robot performs a second navigation (742) from the initial pose (604) to the mating pose (602) 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 (500). 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.
A method and system for docking a robot with a charger docking station, including receiving an initial pose and receiving a mating pose associated with the robot charger docking station, performing a first navigation from a location to the initial pose, and performing a second navigation of the robot from the initial pose to the mating pose. The second navigation may proceed substantially along an arc path from the initial pose to the mating pose, thereby, upon arriving at the mating pose, an electrical charging port of the robot mates with an electrical charging assembly. The arc path may be associated with a section of a unique circle having a radius and a center equidistant from the initial pose and the mating pose. Controlling for error may include a proportional control and/or weighted control or switching between the controls to maintain an error below a threshold.
A method and system for docking a robot with a charger docking station, including receiving an initial pose and receiving a mating pose associated with the robot charger docking station, performing a first navigation from a location to the initial pose, and performing a second navigation of the robot from the initial pose to the mating pose. The second navigation may proceed substantially along an arc path from the initial pose to the mating pose, thereby, upon arriving at the mating pose, an electrical charging port of the robot mates with an electrical charging assembly. The arc path may be associated with a section of a unique circle having a radius and a center equidistant from the initial pose and the mating pose. Controlling for error may include a proportional control and/or weighted control or switching between the controls to maintain an error below a threshold.
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.
