Abstract: An ocular feedback system includes a first camera assembly including a first frame worn by a first user and at least one first camera supported by the first frame. The first camera produces a first camera output concerning the first user's eyes. A second camera assembly includes a second frame worn by a second user and at least one second camera supported by the second frame. The second camera produces a second camera output concerning the second user's eyes. At least one computer is configured to build an established outcome determiner based on an analysis of the at least one first and second camera outputs. The computer compares the established outcome determiner to at least one third camera output concerning a third user's eyes taken by at least one third camera supported by a third frame of a third camera assembly worn by the third user.

Abstract: A method includes: at a mobile robot, travelling according to a current path; using a sensor of the mobile robot, capturing sensor data representing a vicinity of the mobile robot; detecting, based on the sensor data, an obstacle obstructing the current path; in response to detecting the obstacle, outputting a request for a status change corresponding to the obstacle; receiving at the mobile robot, in response to the request for a status change, data defining an updated status of the obstacle; selecting, based on the updated status data, a navigational action between (i) continuing to travel according to the current path and (ii) generating a new path circumventing the obstacle; and executing the selected navigational action.

Abstract: A method includes: obtaining a batch of item group definitions, each item group definition having one or more item identifiers and corresponding quantities; for each item identifier, retrieving (i) a location of a corresponding item in a facility, and (ii) a dimensional attribute of the corresponding item; based on the locations and dimensional attributes, assigning sets of the item group definitions to respective receptacle configurations, each receptacle configuration including, for each item group definition in the set, a receptacle type with a predefined capacity; monitoring availability of a plurality of transporters in the facility, each transporter having a chassis configured to support a selectable set of receptacles; and responsive to detecting that a transporter is available, selecting one of the receptacle configurations, and presenting the selected receptacle configuration via an output device, to initiate placement of receptacles onto the chassis of the transporter according to the selected recep

Abstract: A mobile robot includes: a chassis supporting a locomotive assembly; a sensor; a processor configured, in a guided travel mode, to: detect an external force applied to the chassis in a first direction; control the sensor to capture sensor data corresponding to a physical environment of the mobile robot; detect, based on the sensor data, an operational constraint in the physical environment; determine, based on the detected operational constraint, a feedback force in a second direction opposite the first direction; and controlling the locomotive assembly according to the feedback force.

Abstract: A method includes: capturing, via a navigational sensor of a mobile automation apparatus, three-dimensional point cloud data depicting a portion of an aisle containing a support structure, the support structure having a forward plane facing into the aisle; generating, from the point cloud data, a two-dimensional projection in a facility coordinate system; retrieving, from a stored map, an expected location of the forward plane of the support structure in the facility coordinate system; selecting, from the projection, a subset of regions satisfying a positional criterion relative to the location of the forward plane; determining, based on the selected subset of regions from the projection, an actual location of the forward plane of the support structure in the facility coordinate system; and providing the actual location of the forward plane to a navigational controller of the mobile automation apparatus.

Abstract: A method includes: at a mobile robot, travelling according to a current path; using a sensor of the mobile robot, capturing sensor data representing a vicinity of the mobile robot; detecting, based on the sensor data, an obstacle obstructing the current path; in response to detecting the obstacle, outputting a request for a status change corresponding to the obstacle; receiving at the mobile robot, in response to the request for a status change, data defining an updated status of the obstacle; selecting, based on the updated status data, a navigational action between (i) continuing to travel according to the current path and (ii) generating a new path circumventing the obstacle; and executing the selected navigational action.

Abstract: A method includes: storing, at a mobile robot, a local repository of self-assigned task definitions; determining, at a processor of the mobile robot, that a local activity metric associated with tasks assigned to the mobile robot by a central server meets an idle criterion; in response to determining that the local activity metric meets the idle criterion, selecting, by the processor, one of the self-assigned task definitions from the local repository; and initiating execution of a self-assigned task corresponding to the selected self-assigned task definition at the mobile robot.

Abstract: A mobile robot includes: a chassis supporting a locomotive assembly; a sensor; a processor configured, in a guided travel mode, to: detect an external force applied to the chassis in a first direction; control the sensor to capture sensor data corresponding to a physical environment of the mobile robot; detect, based on the sensor data, an operational constraint in the physical environment; determine, based on the detected operational constraint, a feedback force in a second direction opposite the first direction; and controlling the locomotive assembly according to the feedback force.

Abstract: A method includes: receiving, at a mobile robot from a central server, a rescue command including a rescue location corresponding to an incapacitated mobile robot; controlling a locomotive assembly of the mobile robot to travel towards the rescue location; capturing, using a sensor of the mobile robot, sensor data representing the rescue location; at the mobile robot, identifying the incapacitated mobile robot from the sensor data; controlling the locomotive assembly to position the mobile robot in a predetermined pose relative to the incapacitated robot; and controlling a charging interface of the mobile robot to transfer energy from a battery of the mobile robot to a battery of the incapacitated mobile robot.

Abstract: A server for scheduling mobile robots to perform tasks includes: a memory; and a processor configured to: obtain a planning period divided into a plurality of timeslots; obtain input constraints including (i) a number of mobile robots in a robot pool, (ii) a number of docks and (iii) a target number of active robots; obtain robot parameters and generate a robot agent based on the robot parameters for each mobile robot; define a work weight and a charge weight for each timeslot; determine, by each respective robot agent, a schedule portion based on the work weights, the charge weights and the robot parameters, the schedule portion selecting, for each timeslot for the mobile robot to work or to charge; and in response to determining that a finalization condition and the input constraints are satisfied by the schedule portions, send the schedule portions to each mobile robot.

Abstract: A method includes: storing an occupancy map for a facility, the occupancy map defining: for each of a plurality of regions in the facility, a current occupancy for a present time value, and for each of at least a subset of the regions, a future occupancy for a subsequent time value; generating a path from a current pose of a mobile robot in the facility to a target pose, based on the current and future occupancies; in response to execution of the path at the mobile robot, capturing sensor data representing a vicinity of the mobile robot; detecting an obstacle from the sensor data; and transmitting occupancy data for generating an updated occupancy map including an updated future occupancy for at least one of the subset of regions, the occupancy data including obstacle data indicating a location of the obstacle, and path data defining the path.

Abstract: A method includes: storing, at a mobile robot, a local repository of self-assigned task definitions; determining, at a processor of the mobile robot, that a local activity metric associated with tasks assigned to the mobile robot by a central server meets an idle criterion; in response to determining that the local activity metric meets the idle criterion, selecting, by the processor, one of the self-assigned task definitions from the local repository; and initiating execution of a self-assigned task corresponding to the selected self-assigned task definition at the mobile robot.

Abstract: A method includes: at a mobile robot, travelling according to a current path; using a sensor of the mobile robot, capturing sensor data representing a vicinity of the mobile robot; detecting, based on the sensor data, an obstacle obstructing the current path; in response to detecting the obstacle, outputting a request for a status change corresponding to the obstacle; receiving at the mobile robot, in response to the request for a status change, data defining an updated status of the obstacle; selecting, based on the updated status data, a navigational action between (i) continuing to travel according to the current path and (ii) generating a new path circumventing the obstacle; and executing the selected navigational action.

Abstract: A method includes: receiving, at a mobile robot from a central server, a rescue command including a rescue location corresponding to an incapacitated mobile robot; controlling a locomotive assembly of the mobile robot to travel towards the rescue location; capturing, using a sensor of the mobile robot, sensor data representing the rescue location; at the mobile robot, identifying the incapacitated mobile robot from the sensor data; controlling the locomotive assembly to position the mobile robot in a predetermined pose relative to the incapacitated robot; and controlling a charging interface of the mobile robot to transfer energy from a battery of the mobile robot to a battery of the incapacitated mobile robot.

Abstract: A mobile robot includes: a chassis supporting a locomotive assembly; a sensor; a processor configured, in a guided travel mode, to: detect an external force applied to the chassis in a first direction; control the sensor to capture sensor data corresponding to a physical environment of the mobile robot; detect, based on the sensor data, an operational constraint in the physical environment; determine, based on the detected operational constraint, a feedback force in a second direction opposite the first direction; and controlling the locomotive assembly according to the feedback force.

Abstract: A system includes: a mobile robot comprising a sensor, the robot further comprising a computer, the robot operating in an environment; a server operably connected to the robot via a communication system, the server configured to manage the robot; a controller operably connected to the robot, the controller operably connected to the server, the controller configured to control the robot; and an object of interest marked with a marker at one or more of an approximate height and an approximate field of view of the sensor, the sensor generating data describing the object of interest, the computer configured to identify one or more of the object of interest and the location using one or more of a shape of the object of interest and an intensity of data describing the object of interest.

Abstract: A method includes: capturing, via a navigational sensor of a mobile automation apparatus, three-dimensional point cloud data depicting a portion of an aisle containing a support structure, the support structure having a forward plane facing into the aisle; generating, from the point cloud data, a two-dimensional projection in a facility coordinate system; retrieving, from a stored map, an expected location of the forward plane of the support structure in the facility coordinate system; selecting, from the projection, a subset of regions satisfying a positional criterion relative to the location of the forward plane; determining, based on the selected subset of regions from the projection, an actual location of the forward plane of the support structure in the facility coordinate system; and providing the actual location of the forward plane to a navigational controller of the mobile automation apparatus.

Abstract: A system includes: a cart including: four legs; at least one shelf, each shelf attached to each of the legs; the cart having a generally rectangular shape, a width of the cart being longer than a length of the robot, a length of the cart being longer than a length of the robot; four wheels, each wheel attached to a different leg at a bottom of the leg, the wheels configured to roll to facilitate movement of the cart; and a robotic dock, the robotic dock comprising four docking receptacles at ninety degree angles from adjacent docking receptacles; and a robot comprising: a sensor; and a docking module, the docking module comprising retractable docking pins, each retractable docking pin configured, when extended upward, to mate with a corresponding docking receptacle, thereby securing the robot to a bottom shelf of the cart.

Abstract: An ocular feedback system includes a first camera assembly including a first frame worn by a first user and at least one first camera supported by the first frame. The first camera produces a first camera output concerning the first user's eyes. A second camera assembly includes a second frame worn by a second user and at least one second camera supported by the second frame. The second camera produces a second camera output concerning the second user's eyes. At least one computer is configured to build an established outcome determiner based on an analysis of the at least one first and second camera outputs. The computer compares the established outcome determiner to at least one third camera output concerning a third user's eyes taken by at least one third camera supported by a third frame of a third camera assembly worn by the third user.

Abstract: A trailer has a rear floor assembly having a threshold plate and at least a pair of supports extending downwardly from the threshold plate, a rear lower cross member secured to the rear floor assembly, and a rear impact guard assembly having at least a pair of supports and a horizontal member secured to lower ends of the supports, upper ends of respective ones of the supports of the guard assembly secured to lower ends of respective ones of the supports of the rear floor assembly.