Abstract: A robot system according to one aspect of an embodiment includes a robot and a control unit. The robot performs multi-axis operations based on instructions on the operations from the control unit. The control unit causes a power source to supply power to a partially fabricated item that includes a movable member that is able to be controlled by receiving power, and instructs the robot to perform an operation of attaching a predetermined member to the partially fabricated item while controlling the movable member.

Abstract: Disclosed is an underwater exploration system using a multi-joint underwater robot having a novel complex movement concept in which the multi-joint underwater robot moves through walking or swimming with multi-joint legs closely to a seafloor, differently from a conventional underwater robot to obtain a thrust through a propeller scheme. The underwater exploration system includes the multi-joint underwater robot having the complex movement function according, a depressor, and a mother ship to store data of an underwater state transmitted from the multi-joint underwater robot and to monitor and control a movement direction of the multi-joint underwater robot. The depressor is connected to the mother ship through a primary cable, the multi-joint underwater robot is connected to the depressor through a second cable, and resistance force of the primary cable is applied to the depressor without being transmitted to the multi-joint underwater robot.

Abstract: A system including a mobile telepresence robot, a telepresence computing device in wireless communication with the robot, and a host computing device in wireless communication with the robot and the telepresence computing device. The host computing device relays User Datagram Protocol traffic between the robot and the telepresence computing device through a firewall.

Abstract: A system for remote object handling including a public safety vehicle having a front portion. An articulated arm has a first end and a second end distinct from the first end, the arm being coupled to the front portion at the first end, and has at least one pivot disposed between the first end and the second end. A gripping element is removably coupled to the second end, wherein the gripping element is one of a pincer device, a hand device having at least three fingers or a shovel. A video camera is also coupled to the second end. An arm control is disposed within the vehicle and is operable to control the operation of the arm, the manipulator and the video camera, and a video interface is coupled to the video camera which is operable to display output from the video camera.

Abstract: A robot (100) has a robot mechanism unit (1) having a sensor (10) and a control unit (2), and the control unit (2) includes a normal control unit (4) that controls the operation of the robot mechanism unit, and a learning control unit (3) that, when the robot mechanism unit (1) is operated by a speed command that is given by multiplying a teaching speed designated in a task program by a speed change ratio, performs learning to calculate, from a detection result by the sensor (10), a learning correction amount for making the trajectory or position of the control target in the robot mechanism unit (1) approach the target trajectory or target position, or for reducing the vibration of the control target, and performs processes so that the control target position of the robot mechanism unit (1) moves along a fixed trajectory regardless of the speed change ratio.

Abstract: The present invention determines the dimensions and volume of an object by using a novel 3-D camera that measures the distance to every reflective point in its field of view with a single pulse of light. The distance is computed by the time of flight of the pulse to each camera pixel. The accuracy of the measurement is augmented by capture of the laser pulse shape in each camera pixel. The camera can be used on an assembly line to develop quality control data for manufactured objects or on a moving or stationary system that weighs as well as dimensions the objects. The device can also ascertain the minimum size of a box required to enclose an object.

Abstract: The present invention is directed to the use and application of robotics in mining and post-mining applications, including smelting and processes associated with electrodeposition, electrorefining, cleaning, and disposal. In addition, the application of robotics includes functions associated with maintenance and operation of equipment used in mining operations.

Abstract: A robotic welding equipment station to detect deviation of a tool center point of a welding torch. The station is provided with pairs of light emitting and detecting devices to emit and detect two separate light beams. The pairs of light emitting devices and detectors are oriented at an angle and spaced apart from each other such that the two light beams are at an angle to one another and the weld wire electrode is able to simultaneously interrupt both light beams when there is no deviation in a tool center point. The spacing prevents the weld wire electrode from interrupting both light beams when an increasing deviation of the tool center point propagates along the length of the weld wire electrode. First and second output signals generated by the first and second light detectors are received by a means for detecting deviation of the tool center point.

Abstract: An article take-out apparatus including, acquiring a reference container image including an open end face of a container by imaging operation by an camera, setting an image search region corresponding to a storage space of the container based on the reference container image, setting a reference plane including the open end face of the container, calculating a search region corresponding to the image search region based on a calibration data of the camera stored in advance, converting the search region to a converted search region, taking out 3D points included in the converted search region by projecting a plurality of 3D points measured by the 3D measuring device on the reference plane, and recognizing positions of articles inside the container using the 3D points.

Abstract: A method and apparatus comprising an energy source, a position system, and a movement system. The energy source is configured to generate a beam of energy directed at an area on a target for a vehicle. The position system is configured to identify a first position of the area on the target at which the beam of energy is directed. The movement system is configured to move the vehicle in a manner that reduces a difference between the first position of the area on the target at which the beam of energy is directed and a reference position on the target.

Abstract: Embodiments of the invention provide systems and methods for obstacle avoidance. In some embodiments, a robotically controlled vehicle capable of operating in one or more modes may be provided. Examples of such modes include teleoperation, waypoint navigation, follow, and manual mode. The vehicle may include an obstacle detection and avoidance system capable of being implemented with one or more of the vehicle modes. A control system may be provided to operate and control the vehicle in the one or more modes. The control system may include a robotic control unit and a vehicle control unit.

Abstract: A camera is used to take an image of an end surface of a honeycomb structure gripped by a hand. Based on the image, an initial rotation angle of the honeycomb structure around a vertical axis at a reference position where the image has been taken is recognized. An arm turning section is driven to convey the honeycomb structure gripped by the hand from the reference position to above a plugging mask. A rotation angle required to adjust the rotation angle of the honeycomb structure on the plugging mask to a desired final rotation angle is acquired based on the initial rotation angle recognized at the reference position and a rotation angle of the honeycomb structure around the vertical axis associated with the driving of the arm turning section from the reference position to above the plugging mask. The honeycomb structure is rotated based on the required rotation angle.

Abstract: A manufacturing method for joining first and second members to create a joined piece using a robot with pre-inputted instruction data. The method includes operating the robot to hold the second member for joining to the first member and photographing the second member to obtain an image of the second member at the holding position; comparing the image to a reference image of a joining position of a reference second member joined to a reference first member; determining a deviation amount by which the holding position of the second member deviates from the joining position in the reference image; determining a correction amount for correcting the holding position of the second member is to be corrected in order to reduce the deviation amount of the holding position of the second member; correcting the holding position of the second member according to the correction amount, and then subsequently joining the first and second members.

Abstract: Various interfaces allowing users to directly manipulate an automatic moving apparatus manually, thus enhancing user convenience and efficiency, are provided. An automatic moving apparatus includes: a storage unit configured to store a traveling method; an image detection unit configured to acquire a captured image; a driving unit having one or more wheels and driving the wheels according to a driving signal; and a control unit configured to extract a traveling direction from the traveling method stored in the storage unit in a first mode, extract a traveling direction indicated by a sensing target from the captured image acquired by the image detection unit in a second mode, and generate a driving signal for moving the automatic moving apparatus in the extracted traveling direction.

Abstract: The present invention relates to an apparatus for transferring a glove (100) from a conveyor (200) characterized by: a camera (10); a pick-up assembly (20) comprising a pair of inner grippers (21) and two pairs of outer grippers (22); a pair of sensors (30); a robotic arm (40) mounted with the pick-up assembly (20); a processor.

Abstract: A three-dimensional measurement method three-dimensionally restores an edge having a cross angle close to parallel to an epipolar line. Edges e2L, e3L and e4L on the same plane of a work are selected, and among these edges, at least two edges e2L and e4L residing in a predetermined angle range with reference to the cross angle of 90° crossing the epipolar line are three-dimensionally restored by a stereo method. Then, a three-dimensional plane P1 including these three-dimensionally restored e2L and e4L is found, and the edge e3L residing beyond a predetermined angle range with reference to the cross angle of 90° crossing the epipolar line is projected to this three-dimensional plane P1, thus three-dimensionally restoring the edge e3L.

Abstract: A gap/height difference measurement system for a vehicle may include a reflection light sensing unit on a the transportation conveyor line and sensing reflection light reflected from the vehicle body transported depending on illuminance of an illumination, a measurement robot measuring the gap and the height difference between the vehicle body and each panel that move while being installed at both sides of the transportation conveyor line in a width direction of the vehicle body at one side spaced from the reflection light sensing unit in a movement direction of the vehicle body, and a controller receiving a signal sensed by the reflection light sensing unit and comparing the received signal with a predetermined value to control the illuminance of the illumination and outputting a specification depending on a vehicle type of the vehicle body transported to the measurement robot to control the measurement robot.

Abstract: A robot obstacle detection system including a robot housing which navigates with respect to a surface and a sensor subsystem aimed at the surface for detecting the surface. The sensor subsystem includes an emitter which emits a signal having a field of emission and a photon detector having a field of view which intersects the field of emission at a region. The subsystem detects the presence of an object proximate the mobile robot and determines a value of a signal corresponding to the object. It compares the value to a predetermined value, moves the mobile robot in response to the comparison, and updates the predetermined value upon the occurrence of an event.

Abstract: A robot system includes: a touchscreen panel; and an image processing apparatus configured to recognize a workpiece in an image of the workpiece acquired by photography, in accordance with a registered image recognition program. The image processing apparatus includes: a storage unit configured to store a base program serving as the image recognition program by inputting a plurality of parameters regarding the workpiece, a workpiece registration guiding portion configured to display an input screen to prompt input of the parameters on the touchscreen panel and acquire the parameters via the touchscreen panel, and a registration portion configured to build and register the image recognition program by applying the parameters acquired by the workpiece registration guiding portion to the base program in the storage unit.

Abstract: A robot system includes: a robot arm; a camera; a calibration jig with a marker that allows image recognition; and a calibration apparatus configured to derive a correlation between camera coordinates being coordinates in a photographed image and robot coordinates using the robot arm as a reference. The robot arm is configured to have a posture corresponding to a relative position of the camera with respect to the marker. The calibration apparatus sets a plurality of photographing positions by changing the relative position, acquires the camera coordinates of the marker in the plurality of photographing positions and information of the posture of the robot arm, and derives the correlation.

Abstract: A machine vision system for use with a robotic system that takes frozen sample cores from frozen samples that are in containers includes a camera and a fill level detection system. A processor is configured to receive signals from the fill level detection system and use the signals to determine where to position the camera to obtain an image of the frozen samples. The processor can be configured to receive image data from the camera and to determine locations of bores where frozen sample cores have already been taken. The processor uses this data to move a coring probe into an open end of at least one bore to clear the bore of debris. The system can include a light for illuminating the containers. The majority of the light energy emitted by the light has a wavelength of 620-750 nm or 495-570 nm.

Abstract: A robot system includes robot, an image capture device, a plurality of illumination devices, and a control device. The robot is configured to perform a predetermined work on a to-be-processed material. The image capture device is configured to capture an image of the to-be-processed material and has a dynamic range. The plurality of illumination devices are configured to illuminate the to-be-processed material. The control device is configured to control at least one illumination device among the plurality of illumination devices to keep an amount of light received by the image capture device within the dynamic range of the image capture device.

Abstract: Systems and methods for establishing and tracking virtual boundaries. The virtual boundaries can delineate zones in which an instrument is not permitted during a surgical procedure. The virtual boundaries can also delineate zones in which the surgical instrument is permitted during the surgical procedure. The virtual boundaries can also identify objects or structures to be treated by the instrument or to be avoided by the instrument during the surgical procedure.

Abstract: Disclosed herein is a surgical robot including a slave device performing a surgical operation upon a patient and a master device controlling the surgical operation of the slave device. The slave device includes an image capture unit including a first lighting unit radiating visible light, a second lighting unit radiating UV light, and a camera capturing a visible-light image and a surgical tool coated with a UV reactive material emitting light in response to UV light radiated by the second lighting unit.

Abstract: A surgical robot system for a single port surgery includes: a first robot arm in which a joint-type instrument is installed and providing a motion displacement to the joint-type instrument with respect to a remote center of motion (RCM); and a second robot arm pairing the first robot arm, in which a non-joint-type instrument is installed and providing a motion displacement to the non-joint-type instrument with respect to the RCM.

Abstract: A robot cleaner is disclosed. The robot cleaner includes a cleaner body, a position sensor disposed in the cleaner body, the position sensor including a light transmission unit to emit light and a light reception unit to receive light reflected or scattered from an obstacle after being emitted from the light transmission unit, and a transparent member to transmit the light emitted from the light transmission unit and the light to be received by the light reception unit.

Abstract: Devices and methods for a low latency data telecommunication system and method for video, audio control data and other data for use with one or more robots and remote controls are disclosed. The data transmission can be digital. The data telecommunication system can enable the use of multiple robots and multiple remote controls in the same location with encrypted data transmission.

Abstract: The present invention provides an automated steering wheel leveling system and method. Particularly, the automated steering wheel leveling system includes a machine vision, a plurality of motor cylinders, a motor, and a robot, each operated by a process PC. The machine vision photographs a steering wheel to obtain position information of the steering wheel and determines a stroke of a motor cylinder and a grip position of a gripper using the position information. The plurality of motor cylinders move a plurality of grippers to steering wheel to secure the steering wheel. The motor rotates the steering wheel in order to adjust a zero-point of the steering wheel. The robot then moves the machine vision, the motor cylinder, and the motor to the steering wheel to align a shaft of the servo motor with a shaft of the steering wheel.

Abstract: A robot hand according to embodiments includes a holding unit, a bottom end, an optical sensor, and a reflecting member. The holding unit holds a thin-plate-shaped workpiece. In the bottom end, its leading part is coupled to the holding unit and its tail part is rotatably coupled to an arm. The optical sensor is provided in the bottom end and has a projector and a photoreceiver. The reflecting member is provided in the holding unit. The reflecting member reflects light from the projector, makes it pass through the holding area of the workpiece, and makes it reach the photoreceiver to form an optical path.

Abstract: The invention is related to methods and apparatus that use a visual sensor and dead reckoning sensors to process Simultaneous Localization and Mapping (SLAM). These techniques can be used in robot navigation. Advantageously, such visual techniques can be used to autonomously generate and update a map. Unlike with laser rangefinders, the visual techniques are economically practical in a wide range of applications and can be used in relatively dynamic environments, such as environments in which people move. One embodiment further advantageously uses multiple particles to maintain multiple hypotheses with respect to localization and mapping. Further advantageously, one embodiment maintains the particles in a relatively computationally-efficient manner, thereby permitting the SLAM processes to be performed in software using relatively inexpensive microprocessor-based computer systems.

Abstract: An apparatus for processing a tire-wheel assembly comprising a single-cell workstation including a plurality of sub-stations. The plurality of sub-stations includes a weight application sub-station, and an audit balancing sub-station. The apparatus also includes a tire/wheel transporting device positioned within reach of all of the plurality of sub-stations. A method is also disclosed.

Abstract: A robot system which requires no manual teaching operation in acquiring calibration values for coordinate transformation, and improves the calibration accuracy includes a robot body, a camera, and a control apparatus. The control apparatus measures, via the camera, a calibration plate at each position and orientation of a first position and orientation group including a reference measurement position and orientation and a position and orientation within a first offset range, calculates a first calibration value based on the measurement value, measures, via the camera, the calibration plate at each position and orientation of a second position and orientation group including a reference operation position and orientation different from the reference measurement position and orientation, and a position and orientation within a second offset range, calculates a second calibration value based on the measurement value, and activates the robot body by using the first and second calibration values.

Abstract: A structured light pattern including a set of patterns in a sequence is generated by initializing a base pattern. The base pattern includes a sequence of colored stripes such that each subsequence of the colored stripes is unique for a particular size of the subsequence. The base pattern is shifted hierarchically, spatially and temporally a predetermined number of times to generate the set of patterns, wherein each pattern is different spatially and temporally. A unique location of each pixel in a set of images acquired of a scene is determined, while projecting the set of patterns onto the scene, wherein there is one image for each pattern.

Abstract: An object is highly precisely moved by an industrial robot to an end position by the following steps, which are repeated until the end position is reached within a specified tolerance: Recording a three-dimensional image by means of a 3-D image recording device. Determining the present position of the object in the spatial coordinate system from the position of the 3-D image recording device the angular orientation of the 3-D image recording device detected by an angle measuring unit, the three-dimensional image, and the knowledge of features on the object. Calculating the position difference between the present position of the object and the end position. Calculating a new target position of the industrial robot while taking into consideration the compensation value from the present position of the industrial robot and a value linked to the position difference. Moving the industrial robot to the new target position.

Abstract: A registration system and method includes a configurable device (104) having one or more moveable features (122) such that movement of the moveable features can be determined relative to a reference to define a specific configuration of the configurable device. An imaging system (110) has a display on which the configurable device is viewable. A processing device (112) is configured to register the configurable device with a coordinate system of the imaging system based on the specific configuration of the configurable device.

Abstract: Provided is a robot device including an image input unit for inputting an image of surroundings, a target object detection unit for detecting an object from the input image, an object position detection unit for detecting a position of the object, an environment information acquisition unit for acquiring surrounding environment information of the position of the object, an optimum posture acquisition unit for acquiring an optimum posture corresponding to the surrounding environment information for the object, an object posture detection unit for detecting a current posture of the object from the input image, an object posture comparison unit for comparing the current posture of the object to the optimum posture of the object, and an object posture correction unit for correcting the posture of the object when the object posture comparison unit determines that there is a predetermined difference or more between the current posture and the optimum posture.

Abstract: A navigational control system for altering movement activity of a robotic device operating in a defined working area, comprising a transmitting subsystem integrated in combination with the robotic device, the transmitting subsystem comprising means for emitting a number of directed beams, each directed beam having a predetermined emission pattern, and a receiving subsystem functioning as a base station that includes a navigation control algorithm that defines a predetermined triggering event for the navigational control system and a set of detection units positioned within the defined working area in a known spaced-apart relationship, the set of detection units being configured and operative to detect one or more of the directed beams emitted by the transmitting system.

Abstract: A robot apparatus includes an arm that includes an outer skin and a detector that detects the deformation of the outer skin. The detector includes a sending unit that sends a signal, a receiving unit that receives the signal, and a transmission route that is provided along the outer skin so as to lead the signal. The detector detects the deformation of the outer skin based on whether a signal reaches the receiving unit.

Abstract: A telepresence robot may include a drive system, a control system, an imaging system, and a mapping module. The mapping module may access a plan view map of an area and tags associated with the area. In various embodiments, each tag may include tag coordinates and tag information, which may include a tag annotation. A tag identification system may identify tags within a predetermined range of the current position and the control system may execute an action based on an identified tag whose tag information comprises a telepresence robot action modifier. The telepresence robot may rotate an upper portion independent from a lower portion. A remote terminal may allow an operator to control the telepresence robot using any combination of control methods, including by selecting a destination in a live video feed, by selecting a destination on a plan view map, or by using a joystick or other peripheral device.

Abstract: According to an embodiment, a target trajectory that takes into account the hardware constraints of a robot is generated, based on results obtained by calculating, temporally interpolating, and estimating image feature amounts from a captured image.

Abstract: An object searching method includes: capturing an image in front of a cleaning robot by a camera. Comparing the image with a number of reference images to determine whether the image is the same as one of the reference images. Storing a position of the cleaning robot and the image when the image is the same as one of the reference images, adjusting the path of the cleaning robot to stop the cleaning robot from cleaning the object; and emitting an alarm.

Abstract: The invention relates to a device for inserting and crimping a ring on an attachment rod in a hole, comprising a robot, a monitoring and control system and an end tool designed to crimp the ring on the rod. The end tool includes a crimping device and a ring installation device which are solidly connected to a fine-positioning device, by means of which the end tool is attached to an end element of the robot. A ring insertion subassembly of the ring installation device and a crimping nose of the crimping device can move on the end tool so as to be positioned alternatively on an axis of an attachment to be installed, with no controlled movement of the robot when the end tool has been pre-positioned.

Abstract: Systems and methods are disclosed for automatically or semi-automatically depositing retail items into a bag using a robotic arm. Embodiments of the present disclosure comprise a camera, an image processor, and a robotic arm control module to analyze and attempt to identify an item. Human intervention may be utilized to assist in item identification and/or robotic arm control. A human operator may visually identify the item and/or remotely control the robotic arm from a remote control station.

Abstract: A automation equipment control system comprises a general purpose computer with a general purpose operating system in electronic communication with a real-time computer subsystem. The general purpose computer includes a program execution module to selectively start and stop processing of a program of equipment instructions and to generate a plurality of move commands. The real-time computer subsystem includes a move command data buffer for storing the plurality of move commands, a move module linked to the data buffer for sequentially processing the moves and calculating a required position for a mechanical joint. The real-time computer subsystem also includes a dynamic control algorithm in software communication with the move module to repeatedly calculate a required actuator activation signal from a joint position feedback signal.

Abstract: The treatment device for hemiplegia comprises a robot which is putted on the hemiplegic side of the body of a subject; a motion measurement unit for measuring the motion of the healthy side of the body of the subject; and a control which is connected with the robot and the motion measurement unit, wherein the control unit is configured to receive the healthy side's motion measured by the motion measurement unit and to control the robot, whereby the hemiplegic side having the robot put thereon moves in accordance with the motion of the healthy side of the body.

Abstract: A system includes a milking box and a robotic attacher. The milking box has a stall to accommodate a dairy livestock. The robotic attacher extends under the dairy livestock and comprises a nozzle. The robotic attacher is operable to rotate such that, during a first operation, the nozzle is positioned generally on the bottom of the robotic attacher, and during a second operation, the nozzle is positioned generally on the top of the robotic attacher.

Abstract: A method comprises determining a tangent to the rear of an udder of a dairy livestock, and determining a tangent to the bottom of the udder of the dairy livestock. The method continues by determining a position relative to the intersection of the two tangents, and extending a robot arm to the determined position.

Abstract: A measurement apparatus for determining a position of a tool center point (31) of a tool (30), which is attached to a tool attachment surface (32) of a robot (1), with respect to the tool attachment surface (32) includes: a camera (4) attached to the arm tip portion of the robot (1); a touch-up point (an origin of ?m) disposed in a working space of the robot; a measurement section (11a) for measuring the position of the touch-up point by using the robot and the camera; a first storage section (12a) for storing the measured position of the touch-up point; a second storage section (12b) for storing a position of the robot (1) when the tool center point is aligned with the touch-up point by moving the robot; and a calculation section (11b) for calculating the position of the tool center point with respect to the tool attachment surface of the robot by using the stored positions of the touch-up point and the robot.

Abstract: A robotic system that includes a mobile robot linked to a plurality of remote stations. One of the remote stations includes an arbitrator that controls access to the robot. Each remote station may be assigned a priority that is used by the arbitrator to determine which station has access to the robot. The arbitrator may include notification and call back mechanisms for sending messages relating to an access request and a granting of access for a remote station.

Abstract: An autonomous electronic apparatus and a navigation method thereof are provided. The navigation method includes the following steps. Firstly, a calling signal from a target is received through a wireless sensor network. A position relationship between the target and the autonomous electronic apparatus is analyzed to generate a first speed. Next, an image set is captured and an image relationship between the image set and the target is analyzed to generate a second speed. Afterwards, a weighting value related to the position relationship is calculated. Besides, a moving speed is calculated according to the weighting value, the first speed and the second speed, and a moving status of the autonomous electronic apparatus moving toward the target is controlled via the moving speed.