ROBOT MANAGEMENT SYSTEMS FOR DETERMINING DOCKING STATION POSE INCLUDING MOBILE ROBOTS AND METHODS USING SAME
First Claim
1. A mobile robot system comprising:
- a docking station including at least two pose-defining fiducial markers, the at least two pose-defining fiducial markers having a predetermined spatial relationship with respect to one another and/or to a reference point on the docking station such that a docking path to the base station can be determined from one or more observations of the at least two pose-defining fiducial markers;
a mobile robot including;
a chassis,a motorized drive connected to the chassis for moving the mobile robot to a docked position, anda pose sensor assembly comprising a sensor configured to output a signal in response to the at least two pose-defining fiducial markers in a pose sensor field of view;
a controller configured to analyze the output signal from the pose sensor assembly, the controller having the predetermined spatial relationship of the at least two pose-defining fiducial markers stored in a controller memory,wherein the controller is configured to determine a docking station pose that is based on the spatial relationship of the pose-defining fiducial markers and the signals from the pose sensor assembly, and to locate a docking station pose on a map of a surface traversed by the mobile robot, andthe controller is further configured to path plan a docking trajectory including a curve having a terminal portion aligned with a docking lane of the docking station, based on a current robot position on the map of the surface and the docking station pose and to provide instructions to the motorized drive to move the mobile robot along the curve of the docking trajectory and into a docking lane aligned with the docking station.
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Accused Products
Abstract
A mobile robot system is provided that includes a docking station having at least two pose-defining fiducial markers. The pose-defining fiducial markers have a predetermined spatial relationship with respect to one another and/or to a reference point on the docking station such that a docking path to the base station can be determined from one or more observations of the at least two pose-defining fiducial markers. A mobile robot in the system includes a pose sensor assembly. A controller is located on the chassis and is configured to analyze an output signal from the pose sensor assembly. The controller is configured to determine a docking station pose, to locate the docking station pose on a map of a surface traversed by the mobile robot and to path plan a docking trajectory.
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Citations
20 Claims
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1. A mobile robot system comprising:
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a docking station including at least two pose-defining fiducial markers, the at least two pose-defining fiducial markers having a predetermined spatial relationship with respect to one another and/or to a reference point on the docking station such that a docking path to the base station can be determined from one or more observations of the at least two pose-defining fiducial markers; a mobile robot including; a chassis, a motorized drive connected to the chassis for moving the mobile robot to a docked position, and a pose sensor assembly comprising a sensor configured to output a signal in response to the at least two pose-defining fiducial markers in a pose sensor field of view; a controller configured to analyze the output signal from the pose sensor assembly, the controller having the predetermined spatial relationship of the at least two pose-defining fiducial markers stored in a controller memory, wherein the controller is configured to determine a docking station pose that is based on the spatial relationship of the pose-defining fiducial markers and the signals from the pose sensor assembly, and to locate a docking station pose on a map of a surface traversed by the mobile robot, and the controller is further configured to path plan a docking trajectory including a curve having a terminal portion aligned with a docking lane of the docking station, based on a current robot position on the map of the surface and the docking station pose and to provide instructions to the motorized drive to move the mobile robot along the curve of the docking trajectory and into a docking lane aligned with the docking station. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 19)
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15. A computer program product for determining a docking path, the computer program product comprising a non-transitory computer readable storage medium having computer readable code embodied in the medium, the computer code comprising:
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computer readable code configured to analyzean output signal from a pose sensor assembly on a mobile robot, wherein the output signal is responsive to an observation by the pose sensor assembly of at least two fiducial markers on a docking station, determine a docking station pose that is based on a predetermined spatial relationship of the pose-defining fiducial markers and the signals from the pose sensor assembly, locate a docking station pose on a map of a surface traversed by the mobile robot, and path plan a docking trajectory including a curve having a terminal portion aligned with a docking lane of the docking station, based on a current robot position on the map of the surface and the docking station pose and to provide instructions to the motorized drive to move the mobile robot along the curve of the docking trajectory and into a docking lane aligned with the docking station. - View Dependent Claims (16, 17, 18)
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20. A method for determining a docking path, method comprising:
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analyzing an output signal from the pose sensor assembly on a mobile robot, wherein the output signal is responsive to an observation by the pose sensor assembly of at least two fiducial markers on a docking station, determining a docking station pose that is based on a predetermined spatial relationship of the pose-defining fiducial markers and the signals from the pose sensor assembly, locating a docking station pose on a map of a surface traversed by the mobile robot, and path planing a docking trajectory including a curve having a terminal portion aligned with a docking lane of the docking station, based on a current robot position on the map of the surface and the docking station pose and to provide instructions to the motorized drive to move the mobile robot along the curve of the docking trajectory and into a docking lane aligned with the docking station.
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Specification