Abstract: Disclosed is a system and method for calculation a location in a real-time manner using a combination of odometry and artificial landmarks.

Abstract: A robot 100 includes an image input means 201 that receives an image and outputs image data, an image processing means 202 that receives the image data and generates and outputs an image recognition result, a restraint processing means 204 that outputs an operation instruction for altering a behavior while the image processing means 202 performs a process for identifying or registering a person's face, and an operation means 205 that is operated on the basis of the operation instruction.

Abstract: An autonomous moving body includes: an omnidirectional moving mechanism for moving the moving body; a detecting unit for detecting an obstacle; and a movement control unit for generating a movement instruction signal for avoiding the obstacle detected by the detecting unit while maintaining a frontal direction of the moving body to be substantially constant and transmitting the generated signal to the omnidirectional moving mechanism.

Abstract: Disclosed are a robot, a robot hand, and a method of controlling the robot hand, in which the robot hand rapidly and correctly approaches an object to be gripped and safely grips the object regardless of the shape and material of the object. The method of controlling a robot hand, which has a palm, and a plurality of fingers, each having a plurality of segments, connected to the palm, includes causing the palm to approach an object using at least one first distance sensor installed on the palm; causing the plurality of fingers to approach the object using at least one second distance sensor installed on the plurality of fingers; and causing the palm and the plurality of fingers to come into contact the object to grip the object.

Abstract: An autonomous floor cleaning robot includes a transport drive and control system arranged for autonomous movement of the robot over a floor for performing cleaning operations. The robot chassis carries a first cleaning zone comprising cleaning elements arranged to suction loose particulates up from the cleaning surface and a second cleaning zone comprising cleaning elements arraigned to apply a cleaning fluid onto the surface and to thereafter collect the cleaning fluid up from the surface after it has been used to clean the surface. The robot chassis carries a supply of cleaning fluid and a waste container for storing waste materials collected up from the cleaning surface.

Abstract: A simulator for a visual inspection apparatus is provided. The apparatus is equipped with a robot having an arm and a camera attached to a tip end of the arm, the camera inspecting a point being inspected of a workpiece. Using 3D profile data of a workpiece, information of lenses of cameras, operational data of a robot, simulation for imaging is made for a plurality of points being inspected of the workpiece. For allowing the camera to image the points being inspected of the workpiece, a position and an attitude of the tip end of the arm of the robot are obtained. Based on the obtained position and attitude, it is determined whether or not the imaging is possible. When the imaging is possible, installation-allowed positions of the robot are decided and outputted as candidates of positions for actually installing the robot.

Abstract: A method and apparatus are provided for autonomous data download. The method includes the steps of navigating an autonomous data download device to a first data storage device located in a mobile vehicle and parking the autonomous data download device adjacent to the first data storage device. The method further includes the steps of connecting the autonomous data download device to the first data storage device and downloading data from the first data storage device to the autonomous data download device. The method thereafter includes the steps of navigating the autonomous data download device to a location determined to be suitable for transmission of the data and transmitting the data from the autonomous data download device to a second data storage device after determining that the autonomous data download device has reached the location determined to be suitable for transmission of the data.

Abstract: A system, method, and device may include software and hardware which simplify and quicken configuration of the system for testing a device, enhance testing procedures which may be performed, and provide data via which to easily discern a cause and nature of an error which may result during testing. A camera may capture still images of a display screen of a tested device and another camera may capture video images of the tested device and a partner device. A wizard may be used to generate a configuration file based on one previously generated for a similar device. A mount for a tested device may be structured so that: it is suitable for mounting thereon a plurality of differently structured devices; and adjustments in a vertical direction and a horizontal direction in a plane and adjustments of an angle of the device relative to the plane may be easily made.

Abstract: A vacuum cleaner includes a housing, a height adjust mechanism disposed on the housing and a height adjust motor, disposed within said housing that controls a height of the height adjust mechanism. A position element is mounted to said housing. A sensor processor, mounted to said housing, is in communication with the position element to provide a signal that relates to a position of the height adjust mechanism based at least in part upon data received from the position element. A controller processor, mounted to said housing, is in communication with the sensor processor for selectively controlling a height of the height adjust mechanism relative to a subjacent surface on which the vacuum cleaner is positioned. A height adjust mechanism height motor controller is in communication with the controller processor, for driving the height adjust motor to locate the height adjust mechanism in an appropriate position relative to the subjacent surface.

Abstract: Distance meters measure distances from a reference position to a first area including an upper pitch circle portion and a second area including a lower pitch circle portion. Center coordinates of the hub is calculated based on respective center coordinates of two hub bolts included within the first and second areas. Coordinates of three points defining apexes of a triangle are acquired. Inclination angle of the hub relative to a vertical plane is calculated based on the coordinates of the three points, and an orientation of each of the hub bolts is calculated based on the center coordinates of the hub and the center coordinates of the hub bolt.

Abstract: The inventive concept of the metrology system (the system) actively determines the 6 Degree of Freedom (6-DOF) pose of a motion device such as, but not limited to, an industrial robot employing an end of arm tool (EOAT). A concept of the system includes using laser pointing devices without any inherent ranging capability in conjunction with the EOAT-mounted targets to actively determine the pose of the EOAT at distinct work positions of at least one motion device.

Abstract: A robot system that includes a remote station and a robot face. The robot face includes a camera that is coupled to a monitor of the remote station and a monitor that is coupled to a camera of the remote station. The robot face and remote station also have speakers and microphones that are coupled together. The robot face may be coupled to a boom. The boom can extend from the ceiling of a medical facility. Alternatively, the robot face may be attached to a medical table with an attachment mechanism. The robot face and remote station allows medical personnel to provide medical consultation through the system.

Abstract: The system includes a closed loop process line, multiple carts which traverse the process line, a substrate magazine installed to each cart, evacuation tube connectors (each holding an evacuation tube) installed to each cart, an evacuation unit installed to each cart to connect with the evacuation tube connector, a heat treating oven in which a sealing and evacuation process is conducted, a loading-unloading station provided at the process line, substrate and evacuation tube delivery conveyors, control data driven robots provided at the loading-unloading station, a panel discharge conveyor which removes panels from the loading-unloading station, and robot controllers which actuate the robots.

Abstract: A robot platform includes perceptors, locomotors, and a system controller. The system controller executes instructions for producing an occupancy grid map of an environment around the robot, scanning the environment to generate a current obstacle map relative to a current robot position, and converting the current obstacle map to a current occupancy grid map. The instructions also include processing each grid cell in the occupancy grid map. Within the processing of each grid cell, the instructions include comparing each grid cell in the occupancy grid map to a corresponding grid cell in the current occupancy grid map. For grid cells with a difference, the instructions include defining a change vector for each changed grid cell, wherein the change vector includes a direction from the robot to the changed grid cell and a range from the robot to the changed grid cell.

Abstract: A method and apparatus for removing wires from a bale includes a conveyor system for moving one or more bales and a de-wiring station positioned adjacent the conveyor system. The de-wiring station includes a robot with an end tool. A bale that is bound by one or more wires is transferred by the conveyor system to a position proximate the de-wiring station. The robot with end tool moves to sense the location of the wires, cut the wires, collect the wires and deposit the wires in a collection hopper.

Abstract: A method of confining a robot in a work space includes providing a portable barrier signal transmitting device including a primary emitter emitting a confinement beam primarily along an axis defining a directed barrier. A mobile robot including a detector, a drive motor and a control unit controlling the drive motor is caused to avoid the directed barrier upon detection by the detector on the robot. The detector on the robot has an omnidirectional field of view parallel to the plane of movement of the robot. The detector receives confinement light beams substantially in a plane at the height of the field of view while blocking or rejecting confinement light beams substantially above or substantially below the plane at the height of the field of view.

Abstract: A method for self-localization of a robot, the robot including a camera unit, a database storing a map around a robot traveling path, and a position arithmetic unit estimating the position of the robot, includes: acquiring an image around the robot, in the camera unit. Further, the method includes recognizing, in the position arithmetic unit, an individual object in the image acquired by the camera unit, to generate position values on a camera coordinate system of local feature points of the individual objects and local feature points of a surrounding environment including the individual objects; and estimating, in the position arithmetic unit, the position of the robot on the basis of the map and the position values on the camera coordinate system of local feature points of the individual objects and local feature points of a surrounding environment including the individual objects.

Abstract: To make it possible, in a robot apparatus that performs actions in response to external environment, to distinguish the image of a part of its own body contained in three dimensional data of the external environment. A robot 1 includes a visual sensor 101 to visually recognize external environment, an environment restoration portion 102 to create three dimensional data of the external environment based on the information acquired by the visual sensor 101, and a body estimation portion 104 to determine whether or not an image of the body of the robot apparatus 1 is contained in the three dimensional data, and to specify, when the image of the body of the robot apparatus 1 is determined to be contained in the three dimensional data, an area occupied by the image of the body of the robot apparatus 1 in the three dimensional data.

Abstract: An example method for allowing a robot to assist with a task, the task being carried out in an environment including one or more non-human objects each having associated object locations, comprises detecting one or more changes in object locations within the environment, predicting a task requirement (such as a future object location change, or task goal) by comparing the change in the object location with stored data, the stored data including object location changes associated with previously observed tasks; and providing robotic assistance to achieve the task requirement. Example apparatus are also disclosed.

Abstract: A door opener arrangement for a robot coating device, used for detecting a position of a part (6) of a door (7) so that the door can be opened and/or closed for interior painting. The door opener is arranged with at least one non-contact sensor member (1), preferably for detecting changes in a field strength of a magnetic or electromagnetic field in a Z and vertical direction, and may be arranged with a plurality of sensors to detect a collision etc. A method, system and computer program are also described.

Abstract: The present disclosure relates to an arrangement and an electronic navigational control system for a self-propelling device (5), preferably a lawn-mowing robot. The system comprises at lease one navigational control system (3) connected to at least one signal generator (1) and a sensing unit arranged at the self-propelling device (5). The sensing unit senses at least one, in the air medium propagating, time and space varying magnetic field, at least transmitted via the navigational control station (3) and in turn retransmits at least one signal processed by the unit to at least one driving source which contributes to the device's movements across the surface. The system comprises structure by which the signal generator (1) sends a current through the navigational control station (3), the current generating the time and space varying magnetic field, whereby the sensing unit comprises structure by which the device (5) is maneuvered based on the properties of the sensed magnetic field.

Abstract: Robots and methods implemented therein implement an active repurposing of temporal-spatial information. A robot can be configured to analyze the information to improve the effectiveness and efficiency of the primary service function that generated the information originally. A robot can be configured to use the information to create a three dimensional (3D) model of the facility, which can be used for a number of functions such as creating virtual tours of the environment, or porting the environment into video games. A robot can be configured to use the information to recognize and classify objects in the facility so that the ensuing catalog can be used to locate selected objects later, or to provide a global catalog of all items, such as is needed for insurance documentation of facility effects.

Abstract: In accordance with aspects of the present invention, a service robot and methods for controlling such a robot are provided. In particular, the robot is configured to sense the presence of a person and to take a next action in response to sensing the presence of the person. As examples, the robot could leave the area, await commands from the person, or enter an idle or sleep state or mode until the person leaves.

Abstract: An object search apparatus acquires, from each IC tag of IC tags corresponding to objects respectively, an object information item including an identifier of an object, a hierarchical level, a detection method for detection of the object, and a manipulation method for the object, to obtain a plurality of object information items including a target object information item of a target object, selects, from the object information items, an object information item higher in the hierarchical level than the target object, detects an object corresponding to selected object information item by using the detection method in the selected object information item, manipulates detected object in accordance with the manipulation method in the selected object information item, selects target object information item from the object information items, and detects the target object from the detected object by using the detection method in the target object information item.

Abstract: A working apparatus comprises a working unit which executes work on a work subject, and a calibration jig on which a plurality of markers is arranged in a radial pattern from a center point of markers, the plurality of markers being arranged in three dimensions, and the calibration jig being attached to a working unit such that a calibration reference point set of a working unit coincides with a center point of markers. According to such a composition, it becomes possible to calibrate a position of a working unit even when a portion of the jig containing a center point of markers is occluded during image measurement.

Abstract: Systems and apparatus are provided for locating the center of a substrate. The invention includes a frame, mounted between a slit valve assembly and a transfer chamber wall in substrate processing equipment; at least one emitter, housed in the frame, and adapted to emit a signal; at least one sensor, housed in the frame, and adapted to receive the emitted signal; and a controller adapted to determine a center of a substrate based on the signal received by the sensor. Numerous other aspects are provided.

Abstract: A robot system and method have been developed which are able to automatically load balls in semi-autogenous grinding mills so as to reduce the time used for maintenance. The robotic system is comprised of a robotic manipulator of at least 5 degrees of freedom, a grip mechanism which allows, in a sequential and programmed way, to take, manipulate and release a ball from a ball holder rack located at one of its sides.

Abstract: A directed beam emitter system for robot navigation in which a light beam emitter emits a modulated directed light beam of a first modulation and an omnidirectional diffuse light region emitter emits a modulated diffuse light region of a second modulation. The modulated directed light beam and the modulated diffuse light region overlap in a plane parallel to ground level such that a light beam receiver on a robot may detect either one or both of the modulated directed light beam and the modulated diffuse light region. The light beam emitter is responsive to a control system used to control one or more light beam emitters.

Abstract: A processing robot program generating device used in a robot system having a vision sensor, capable of accommodating an error in the shape of a workpiece and reducing man-hours required for a teaching operation. Image detection models are generated in a graphic image of a workpiece viewed from a virtual camera. A processing program including data of teaching points for processing segments of a processing line of the workpiece is generated. A detection program for actually imaging the workpiece is generated, and the position and orientation of each segment corresponding to each detection model generated are detected. A command line, for calculating an amount of change between the detection model and the actually captured image of the workpiece, is added to the processing program. Then, a correction program is inserted into the processing program, the correction program being capable of correcting the teaching point for processing each segment.

Abstract: A device for assembling electronic circuits comprises a placing station (7) for placing circuit components on a circuit carrier (1) held at a placing location (17), a fixing station (19) for fixing the circuit components to the circuit carrier (1) under the effect of heat, and a belt conveyor means (9) for conveying a circuit carrier from the placing location (17) to a take-over location (29) of the fixing station (19). The fixing station (19) comprises a heatable zone (22) and a manipulator (21) for raising the circuit carrier (1) from the take-over location (29) and placing it in the heatable zone (22). A continuous belt conveyor (9) of the belt conveyor means extends from the placing location (17) up to the take-over location (29).

Abstract: A method and system for creating exponential human artificial intelligence in robots, as well as enabling a human robot to control a time machine to predict the future accurately and realistically. The invention provides a robot with the ability to accomplish tasks quickly and accurately without using any time. This permits a robot to cure cancer, fight a war, write software, read a book, learn to drive a car, draw a picture or solve a complex math problem in less than one second.

Abstract: A mobile, remotely controlled robot includes a turret subsystem, a robot controller subsystem configured to control the robot, control the turret, and fire the weapon, a robot navigation subsystem configured to determine the position of the robot, a turret orientation determination subsystem, and a robot communications subsystem for receiving commands and for transmitting robot position data and turret orientation data. An operator control unit includes a user interface for commanding the robot, the turret, and the weapon. An operator control unit communications subsystem transmits commands to the robot and receives robot position data and turret orientation data from the robot. An operator control unit navigation subsystem is configured to determine the position of the operator control unit.

Abstract: A robot calibration system and method for robots in semiconductor wafer processing systems is disclosed. The calibration system comprises a calibration array, a dummy wafer and a control system programmed with a calibration routine. The calibration array has an plurality of inductive proximity sensors to determine parallelism of the robot relative to a station and a center locating sensor to determine the center of the station.

Abstract: A detecting apparatus and method of a robot cleaner is disclosed. The apparatus includes a detecting unit provided with a transmitting unit for sending a signal to detect the floor and a receiving unit for receiving a signal sent from the transmitting unit to be reflected on the floors an optic angle adjusting unit disposed at least one of the transmitting unit and the receiving unit and configured to adjust optic angles of the signals, and a light shielding unit configured to partially shield a signal sent through the optic angle adjusting unit in order to reduce a deviation of each signal of the transmitting unit and the receiving unit. Accordingly, a measurement deviation with respect to color and feel of the floor can be reduced. Also, an amount of light received at the receiving unit can be obtained as much as required, which allows an accurate detection of the detecting apparatus. In addition, even if there are both drop-off and bump on the floor, the robot cleaner can smoothly operate.

Abstract: A user interface device of a remote control system for a robot and a method using the same are provided. The user interface device includes: a radio frequency (RF) unit for receiving, from a remote control robot, camera data and at least one sensor data detecting a distance; a display unit having a main screen and at least one auxiliary screen; and a controller having an environment evaluation module for determining whether the received camera data are in a normal condition, and having a screen display mode change module for displaying, if the received camera data are in a normal condition, the camera data on the main screen and displaying, if the received camera data are in an abnormal condition, the sensor data on the main screen.

Abstract: An apparatus for cleaning and pre-milking a teat of a milking animal prior to the milking animal being milked comprises a teat cleaning and pre-milking device (51) having cleaning means and pre-milking means, wherein, during cleaning and pre-milking, the teat of the animal is exposed to the cleaning and pre-milking means. The apparatus comprises further means (60; 84) for establishing that milk is actually extracted from the teat of the milking animal during the cleaning and pre-milking, means (62; 84) for measuring a quality, preferably a somatic cell count value, of the milk extracted from the teat of the animal during the cleaning and pre-milking, means for comparing the measured quality of the milk with a reference quality value, and means for indicating, depending on the comparison, whether or not milk drawn from the teat of the animal during a subsequent milking should be mixed with milk drawn from another animal.

Abstract: System and method for graphically allocating robot's working space are provided. The system includes an image extractor, a task-allocating server and a robot. A graphic user interface (GUI) of the task-allocating server includes a robot's working scene area, a space attribute allocating area and a robot's task area. Thus, a user assigns one certain space area in the robot's working scene area with a “wall” attribute, or another space area with a “charging station” attribute. Meanwhile, by using the GUI, the user directly assigns the robot to execute a specific task at a certain area. Hence, the user or remote controller facilitates the robot to provide safer and more effective service through his/her environment recognition.

Abstract: A robot vision system for outputting a disparity map includes a stereo camera for receiving left and right images and outputting a disparity map between the two images; an encoder for encoding either the left image or the right image into a motion compensation-based video bit-stream; and a decoder for extracting an encoding type of an image block, a motion vector, and a DCT coefficient from the video bit-stream. Further, the system includes a person detector for detecting and labeling person blocks in the image using the disparity map between the left image and the right image, the block encoding type, and the motion vector, and detecting a distance from the labeled person to the camera; and an obstacle detector for detecting a closer obstacle than the person using the block encoding type, the motion vector, and the DCT coefficient extracted from the video bit-stream, and the disparity map.

Abstract: A three-dimensional map-generating apparatus and method using structured light. The apparatus for generating a three-dimensional map using structured light includes an odometer detecting the pose of a mobile robot, and a distance-measuring sensor including a light source module that emits light upward and a camera module that captures an image formed by light reflected from an obstacle, and measuring a distance to the obstacle using the captured image. The apparatus measures a distance to the obstacle using the distance-measuring sensor while changing the relative pose of the mobile robot, thereby generating a three-dimensional map.

Abstract: Described herein is a robot having a camera mount that is movable along a curved surface of an upper part of the head, on a front side thereof, and two units of cameras that are mounted in the camera mount. The cameras are disposed such that the cameras are laterally separated from each other at an interval substantially equivalent to a lateral width of the head, respective extremities of the cameras are substantially flush with the front end of the head, and the cameras are positioned in close proximity of the upper end of the robot.

Abstract: Disclosed is a method and system for finding a relationship between a tool-frame of a tool attached at a wrist of a robot and robot kinematics of the robot using an external camera. The position and orientation of the wrist of the robot define a wrist-frame for the robot that is known. The relationship of the tool-frame and/or the Tool Center Point (TCP) of the tool is initially unknown. For an embodiment, the camera captures an image of the tool. An appropriate point on the image is designated as the TCP of the tool. The robot is moved such that the wrist is placed into a plurality of poses. Each pose of the plurality of poses is constrained such that the TCP point on the image falls within a specified geometric constraint (e.g. a point or a line). A TCP of the tool relative to the wrist frame of the robot is calculated as a function of the specified geometric constraint and as a function of the position and orientation of the wrist for each pose of the plurality of poses.

Abstract: A robotic system that includes a remote controlled robot. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform allows the robot to move about a home or facility to locate and/or follow a patient.

Abstract: A robotic system that includes a remote controlled robot. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform allows the robot to move about a home or facility to locate and/or follow a patient.

Abstract: At present, the tasks associated to the dislodging process and/or anode handling from casting wheels is characterized by the exposure of the personnel to harsh environmental conditions. As well as the use of take-off mechanisms with a high rate of failures. This, in the medium and long term, could generate serious occupational illnesses to the operators in charge of carrying out this activity such as decrease and/or delays in production. Due to the above, an integral robot system and method have been developed for the dislodging process and/or anode handling from casting wheels which allows to carry out this activity in an automated way. The robotic system is composed mainly of a robotic manipulator of at least 4 degrees of freedom which is mounted on a fixed and/or mobile system and is provided with a gripping mechanism to take anodes and deposit them in the cooling chain.

Abstract: The system includes a sensor for detecting a state of a space; a robot for executing a handling job for an article; an article identifying part for identifying, when an article is handled by a movable body, the article in response to a detection result obtained by the sensor; and an article handling subject identifying part for identifying an article handling subject that handles the article. When the movable body that handles the article is the robot, the article handling subject identifying part identifies a subject having issued a job instruction to the robot as the article handling subject.

Abstract: In one embodiment of the invention, a method for a robotic system is disclosed to track one or more robotic instruments. The method includes generating kinematics information for the robotic instrument within a field of view of a camera; capturing image information in the field of view of the camera; and adaptively fusing the kinematics information and the image information together to determine pose information of the robotic instrument. Additionally disclosed is a robotic medical system with a tool tracking sub-system. The tool tracking sub-system receives raw kinematics information and video image information of the robotic instrument to generate corrected kinematics information for the robotic instrument by adaptively fusing the raw kinematics information and the video image information together.

Abstract: In-process non-contact measurement systems and methods for automated lapping systems are disclosed. In an embodiment, a moveable frame can be controllably positioned proximate to a lapped work product. A control component can provide first control signals to control a movement of the moveable frame relative to the lapped work product. A non-contact measuring device can be coupled to the moveable frame measures a surface of the lapped work product and can transmit measurement data of the surface of the lapped work product to the control component. The control component can further provide second control signals to control a movement of the non-contact measuring device relative to the moveable frame.

Abstract: In a telemanipulation system for manipulating objects located in a workspace at a remote worksite by an operator from an operator's station, such as in a remote surgical system, the remote worksite having a manipulator with an end effector for manipulating an object at the workspace, such as a body cavity, a controller including a hand control at the control operator's station for remote control of the manipulator, an image capture device, such as a camera, and image output device for reproducing a viewable real-time image, the improvement wherein a position sensor associated with the image capture device senses position relative to the end effector and a processor transforms the viewable real-time image into a perspective image with correlated manipulation of the end effector by the hand controller such that the operator can manipulate the end effector and the manipulator as if viewing the workspace in true presence.

Abstract: A system, method, and computer program product for avoiding collision of a body segment with unconnected structures in an articulated system are described. A virtual surface is constructed surrounding an actual surface of the body segment. Distances between the body segment and unconnected structures are monitored. Responding to an unconnected structure penetrating the virtual surface, a redirected joint motion that prevents the unconnected structure from penetrating deeper into the virtual surface is determined. The body segment is redirected based on the redirected joint motion to avoid colliding with the unconnected structure.

Abstract: The object of the present invention is equipment (1) and a method for the fully automated final inspection of components (2), in particular of their driven modules, further comprising a robot (3) fitted with a testing system (8) to carry out the final inspection comprising the stages: Self-driven alignment of the robot (3) and/or the testing system (8) relative to the component (2) being checked and/or its module by means of orientation data, reproducible implementation of individual checks by the testing system (8), the stages of self-driven alignment and reproducible implementation being repeated until a termination criterion has been met and/or the final inspection has been completed.