Abstract: A robotic milking system suitable for use with conventional milking clusters. Clusters are withdrawn to a generally known position upon release from a cow with the cups hanging down below the bowl. The cups are then located in a confined region from where they are picked up by a robotic arm and attached to teats of a cow. The cups may be located into recesses or slots or be drawn through a guide. The arrangement allows a single robotic arm to service multiple bales of a rotary milking parlour. The application of a vacuum to milking cups may be controlled by applying sufficient pressure to the pulsation line of a cup to collapse the cup liner when that cup is not attached to a teat or by bending a feed line to a cup to close the flow path.

Abstract: First calculation means calculates a TCP velocity error vector Verr when wrist axes performs rotational following movement, second calculation means selects a component, including the sign, of the TCP velocity error vector Verr, third calculation means decomposes the selected velocity error vector into a joint velocity vector ?err, fourth calculation means integrates the joint velocity ?err and calculates a position correction amount vector ?add, and the position correction amount vector ?add is fed back to position control means with torque limits.

Abstract: A minimally invasive surgical system includes a pair of surgical instruments having end effectors to hold and suture tissue, a pair of robotic arms coupled to the surgical instruments, a controller, and a pair of master handles coupled through the controller to the robotic arms, so that surgeon manipulation of the handles produces corresponding movement of the end effectors in an adjustably scaled fashion. An input button allows the surgeon to adjust the position of the handles without moving the end effectors, so that the handles may be moved to a more comfortable position. An optionally included robotically controlled endoscope allows the surgeon to remotely view the surgical site. Using the system, a cardiac procedure can be performed by making small incisions in the patient's skin, inserting the instruments and endoscope through the incisions, and manipulating the handles to move the end effectors to perform the cardiac procedure.

Abstract: A device is provided for positioning a patient with respect to a radiation, the device being a polyarticulated robot including: —at least one linear horizontal displacement rail, —a connecting part capable of carrying out translations with respect to the linear rail and pivoting about an axis of rotation vertical to that linear rail, and —a robotic arm connected to the connecting part, the robotic arm including a wrist with concurrent axes of rotation connected to a patient support.

Abstract: A robotic 5D ultrasound system and method, for use in a computer integrated surgical system, wherein 3D ultrasonic image data is integrated over time with strain (i.e., elasticity) image data. By integrating the ultrasound image data and the strain image data, the present invention is capable of accurately identifying a target tissue in surrounding tissue; segmenting, monitoring and tracking the target tissue during the surgical procedure; and facilitating proper planning and execution of the surgical procedure, even where the surgical environment is noisy and the target tissue is isoechoic.

Abstract: An article carrier robot includes: a horizontal base; a horizontally movable unit supported by the horizontal base so as to be movable in a horizontal direction; a robot main body supported by the horizontally movable unit; at least one of wiring and piping introduced into the robot main body from the horizontal base; and a restriction unit supported by the horizontally movable unit so as to be swayable about a pivot provided to the horizontally movable unit. The restriction unit is configured to restrict deformation of a part of the at least one of wiring and piping.

Abstract: A method according to the invention for controlling a manipulator, in particular a robot (1), includes the following steps: controlling of the manipulator by means of an operating device (4) of a first safety level, which is connected to a control device (2) of the manipulator, and monitoring of a permissible state by means of a protective device (3, 3.1, 3.2) of a second, higher safety level, which is connected to the control device of the manipulator, wherein the manipulator executes an action prescribed by the operating device only as long as the protective device is communicating a permissible state to the control device.

Abstract: A storage library is described including a first tape drive that is identified as a target tape drive to a host via a first address and a second tape drive that is masked from being identified by the host. The storage library further includes a controller that is linked with a switch system that shifts the first address to the second tape drive, from the first tape drive, such that after the shift, the second drive is identified as the target drive to the host and the first tape drive is masked from being identified by the host.

Abstract: A medical robotic system has a joint coupled to medical device or a slave manipulator or robotic arm adapted to hold and/or move the medical device for performing a medical procedure, and a control system for controlling movement of the joint according to user manipulation of a master manipulator. The control system includes at least one joint controller having a sliding mode control for reducing stick-slip behavior on its controlled joint during fine motions of the joint. The sliding mode control computes a distance to a sliding surface, computes a reaching law gain, and processes the distance and reaching law gain to generate a sliding mode control action that is in absolute value less that a maximum desired feedback control action. The sliding mode control action is then further processed to generate a feedback torque command for the joint motor.

Abstract: A control method for a power assist device provided with an operation handle, a force sensor that detects an operation force applied to the operation handle and an orientation of the operation force, a robot arm, and an actuator. When the orientation of the operation force is detected to be within a predetermined angle range with respect to a preset advancing direction of the operation handle, the actuator is controlled so as to move the operation handle along the advancing direction by employing only a component of the operation force along the advancing direction; and when the orientation of the operation force is detected to be outside the predetermined angle range, the actuator is controlled to move the operation handle by the operation force applied to the operation handle and the orientation of the operation force.

Abstract: The present disclosure provides a system for fabricating a semiconductor device. The system includes a semiconductor fabrication tool. The semiconductor fabrication tool has an integrated inter interface that measures a first process parameter of the fabrication tool. The system also includes a wireless sensor. The wireless sensor is detachably coupled to the fabrication tool. The wireless sensor measures a second process parameter of the fabrication tool. The second process parameter is different from the first process parameter.

Abstract: An apparatus and method for performing manufacturing operations using position sensing for robotic arms that efficiently and accurately finds the location of a workpiece or features on a workpiece, with minimal need for adjustments.

Abstract: If a manipulator of a robot falls in local minima when expanding a node to generate a path, the manipulator may efficiently escape from local minima by any one of a random escaping method and a goal function changing method or a combination thereof to generate the path. When the solution of inverse kinematics is not obtained due to local minima or when the solution of inverse kinematics is not obtained due to an inaccurate goal function, an optimal motion path to avoid an obstacle may be efficiently searched for. The speed to obtain the solution may be increased and thus the time consumed to search for the optimal motion path may be shortened.

Abstract: Automated apparatuses and related methods for scanning, spraying, pruning, and harvesting crops from plant canopies. The apparatuses include a support structure comprising a frame, a central vertical shaft, and at least one module support member capable of rotating around a plant canopy. The support member supports a plurality of movable arms, each arm having at least one detector for probing the plant canopy. Embodiments further comprise applicators and/or manipulators for spraying, pruning, and harvesting crops from within the plant canopy. The methods of the present invention include causing the moveable arms attached to the support structure to be extended into the plant canopy, searching for crops, and transmitting and/or storing the search data. Embodiments further comprise detaching crops from the plant canopy and transporting them to a receptacle, applying a controlled amount of material within the plant canopy, or pruning inside of the plant canopy.

Abstract: In a legged mobile robot control system having leg actuators each driving the individual legs and arm actuators each driving the individual arms, an external force acting on the right arm is detected, operation of the right arm actuators is controlled to produces a handshake posture, and operation of the leg actuators is controlled based on the detected external force acting on the right hand during handshaking, thereby improving communication capability by enabling it to shake hands with humans and to maintain a stable posture during the handshaking.

Abstract: After switching a control method for a robot arm based upon characteristic information containing pieces of information relating to a grabbed position of the robot arm by a person and a presence/absence of detection of a force as well as to presence/absence of influences from a drag, during an operation of the robot arm, by a control method switching unit, information relating to the force of operation information is corrected by an operation correcting unit in response to a manipulation of the person.

Abstract: An apparatus, a method and a control system for controlling an industrial robot with at least one axis of rotation and/or translation. The robot includes at least one actuator or motor at each of the axes for driving a movement of an arm of the robot and at least one sensor at each of the rotatable shafts. A dither-signal generator for generation of a periodic signal is used to provide a varying dither signal to a servo of the actuator. Automatic adaption of the dither signal is provided. A computer program for carrying out the method and a graphical user interface.

Abstract: A method of controlling a power assist device that includes an operating handle, a force sensor, a robot arm, an actuator that drives the robot arm, and a conveying portion for conveying the robot arm. When a body in motion, the conveying portion is controlled to move in synchronization with the body, and when the motion of the body is stopped or has resumed, the drive of the robot arm is stopped for a predetermined time, and does not resume until after a predetermined time has elapsed.

Abstract: The present invention provides a substrate processing system capable of extending and changing a substrate processing module easily according to changes of processing contents for a substrate. An embodiment of the present invention is the substrate processing system including a main device (100) and sub devices (200 and 300).

Abstract: In a robot system, and a method for operating a robot system, for loading general cargo units, a gripper unit of the robot is operated to stack the general cargo units in a stack, by movements controlled by a computerized control unit. In order to avoid unstable loading patterns, the computerized control unit automatically determines the loading pattern of the stack of general cargo units, and also automatically determines at least one characteristic that represents the stability of the loading pattern.

Abstract: The present invention relates to a method and a device for the machining of an object using a tool, in which the tool (2) or the object (18) is guided using a handling apparatus, which has multiple movement axes for the coarse positioning of the tool (2) or object (18), which form a kinematic chain. In the method, an additional actuator (3), which has a higher positioning precision in at least one dimension or axis than the other movement axes, is inserted between a terminal link (1) of the kinematic chain and the tool (2) or object (18). A relative movement of the tool (2) or terminal link (1) of the kinematic chain to the object (18) is detected using at least one sensor (5) and a deviation from a target movement path is compensated for using the additional actuator (3). The method and the associated device allow the use of robots or other handling apparatuses having lower path precision for applications which require a high precision during the guiding of the tool.

Abstract: This invention discloses highly scalable and modular automated optical cross connect switch devices which exhibit low loss and scalability to high port counts. In particular, a device for the programmable interconnection of large numbers of optical fibers (100's-1000's) is provided, whereby a two-dimensional array of fiber optic connections is mapped in an ordered and rule-based fashion into a one-dimensional array with tensioned fiber optic circuit elements tracing substantially straight lines there between. Fiber optic elements are terminated in a stacked arrangement of flexible fiber optic circuit elements with a capacity to retain excess fiber lengths while maintaining an adequate bend radius. The combination of these elements partitions the switch volume into multiple independent, non-interfering zones, which retain their independence for arbitrary and unlimited numbers of reconfigurations.

Abstract: A manipulator is provided with an arm, an arm, a holding section, a first joint section pivotally interconnecting the arm and the arm, a second joint section pivotally interconnecting the arm and the holding section, a first joint driving section capable of driving the first joint section, a second joint driving section capable of driving the second joint section, a member specifying section for specifying one of the arms which has a possibility of collision with an obstacle or which has collided with the obstacle, and a control device for controlling the first joint driving section and the second joint driving section to pivotally move the one of the arms specified by the member specifying section in a direction away from the obstacle, and pivotally move the other of the arms in a direction toward the obstacle.

Abstract: In a controller, a first switch unit establishes electrical connection between a power-off brake and a power source when a servomotor is energized. The electrical connection causes the power-off brake to be released. A second switch unit is provided between the power-off brake and the power source. The second switch unit establishes electrical connection between the power-off brake and the power source upon being manually operated during the servomotor being deenergized. A calculating unit calculates a driving speed of the joint by the servomotor. A determining unit determines whether the calculated driving speed of the joint is greater than a predetermined threshold speed. An interrupting unit interrupts a supply of electrical power from the power source to the power-off brake through the electrical connection established by the second switch unit when it is determined that the calculated driving speed of the joint is greater than the predetermined threshold speed.

Abstract: The inventive method consists in supplying motion instructions (300) at least including information about the path geometry (320) and load instructions (310) to a path generator (400), calculating an allied load signal (800), transmitting said applied load signal (800) to the path generator (400), calculating motion instructions (500) along the path in such a way that the deviation between the projection of the applied load on a tangent to said path and the projection of the instruction on said tangent is minimized and in transmitting said motion instructions (500) to means for actuating a robot (600). A device comprising means (200, 400, 700) for carrying out said control is also disclosed.

Abstract: The invention relates to an industrial robot (1) having a control apparatus (8), and to a method for controlling the movement of the industrial robot (1). For the purposes of the method, an instruction which is intended for controlling the industrial robot (1) is checked, an interpreted instruction is produced by interpretation of the checked instruction by means of an interpreter (13), and the interpreted instruction is stored in a temporary store (10). This process is repeated until a first keyword is detected. A data record (15) is then produced from the interpreted instructions stored in the temporary store (10), wherein the data record (15) has information relating to at least one path element of a path on which the industrial robot (1) is intended to be moved. The data record (15) is loaded into a buffer store (11), is checked by the buffer store (11) and is interpolated by means of an interpolator (14), in order to move the industrial robot (1) on the path element.

Abstract: A controller of a leg type moving robot determines an action force to be input to an object dynamic model 2 such that a motion state amount (object model velocity) of the object dynamic model 2 follows a desired motion state amount based on a moving plan of an object, and also determines a manipulated variable of the motion state amount (object model velocity) of the object dynamic model 2 such that the difference between an actual object position and a desired object position approximates zero, and then inputs the determined action force and manipulated variable to the object dynamic model 2 to sequentially determine the desired object position. Further, a desired object reaction force to a robot from the object is determined from the determined reaction force.

Abstract: A burner system capable of inverting an optical disc has a control module, a burning module, a mechanical arm and an inverter. The control module controls the mechanical arm to grab the optical disc from a burner in the burning module and release the optical disc into the inverter. The optical disc passes through the inverter due to gravity, one side of the optical disc is tilted by the inverter so the optical disc is inverted. Therefore, the burner system automatically inverts the optical disc for double-sided data processing.

Abstract: A signal testing method of a printed circuit board (PCB) applies a robot arm and an oscilloscope to test the PCB. The method controls the robot arm to move to test points of electronic signals of the PCB. The method further controls the oscilloscope connected to the robot arm to measure the electronic signals.

Abstract: A robot system includes a robot and a robot controller including a drive unit, a memory that stores an arm-occupied region and a movement-forbidden region, a target position calculation unit that outputs a target position of a tool or a workpiece, a movement-forbidden region entry monitoring unit that checks whether the arm-occupied region based on the target position enters the movement-forbidden region and outputs a stop request if it is checked that the arm-occupied region enters the movement-forbidden region, and a predicted-coasting-position calculating unit that calculates a predicted coasting position of each axis and a coasting position of the tool or the workpiece in the case that the robot is urgently stopped. The movement-forbidden region entry monitoring unit checks whether the arm-occupied region at the coasting position enters the movement-forbidden region and outputs another stop request if it is checked that the arm-occupied region enters the movement-forbidden region.

Abstract: A system is capable of controlling the movements of a hand so as to ensure a further stable grasp of an object. In a state wherein an object is in contact with a plurality of finger mechanisms and a palm portion by being grasped by the hand, the load to be applied to the object from each of the plurality of finger mechanisms can be adjusted. Thus, the position of the load center on the palm portion can be displaced so as to be included in a target palm area. Further, the load to be applied to the palm portion can be adjusted so as to fall within a target load range.

Abstract: A load smart system for continuously loading preformed pouches into a fill-seal machine is provided. A plurality of pouches are disposed within a pouch delivery device, each of the pouches having an upper edge and an indicia. The fill-seal machine includes a rotating turret having a plurality of radially extending grippers. The rotating turret rotates the plurality of gripper pairs between a loading station, an opening station, a filling station, a sealing station, and an unloading station. A robotic transfer device is positioned between the pouch delivery device and the loading station of the fill-seal machine. The robotic transfer device includes an optical sensor positioned on a gripper member. During operation, the optical sensor scans the indicia to determine the pouch characteristics and a controlling station controls the gripper member to deposits the pouch within the gripper pairs at the loading station a predetermined distance from the upper edge of the pouch.

Abstract: A robotic system includes a robot having manipulators for grasping an object using one of a plurality of grasp types during a primary task, and a controller. Hie controller controls the manipulators dining the primary task using a multiple-task control hierarchy, and automatically parameterizes the internal forces of the system for each grasp type in response to an input signal. The primary task is defined at an object-level of control e.g., using a closed-chain transformation, such that only select degrees of freedom are commanded for the object. A control system for the robotic system has a host machine and algorithm for controlling the manipulators using the above hierarchy. A method for controlling the system includes receiving and processing the input signal using the host machine, including defining the primary task at the object-level of control, e.g., using a closed-chain definition, and parameterizing the internal forces for each of grasp type.

Abstract: Two robotic arms roam in separate, non-overlapping areas of a test station, avoiding collisions. A traveling buffer moves along x-tracks between a front position and a back position. In the front position, a first robotic arm loads IC chips from an input tray or stacker into buffer cavities in the traveling buffer. The traveling buffer then moves along the x-tracks to the back position, where a second robotic arm moves chips from the traveling buffer to test boards for testing. After testing, the second robotic arm moves chips to a second traveling buffer, which then moves along tracks to a front position for unloading by the first robotic arm. Two traveling buffers may move on the same tracks in a loop. The buffer cavities in the traveling buffer move on internal tracks to expand and contract spacing and pitch between the front and back positions to match test-board pitch.

Abstract: A conveyance system. The conveyance system includes a movable device for conveying an article, and a robot selected from the group consisting of an articulated robot and an orthogonal robot. The movable device is configured to be both vertically and horizontally movable; and, the robot is mounted on the movable device. The robot includes a hand and a gripper disposed on the hand. The gripper is configured to hold the article. The movable device and the robot are configured to convey the article in conveyance operations that include an extraction, a conveyance, and an installation, of the article; the range of the conveyance operations lies within a working range of the robot from a present position that is selected with priority. The movable device is configured to remain in a stationary state when the article is conveyed by the robot using the conveyance operations within the working range.

Abstract: A robotic system that includes a robot and a remote station. The remote station can generate control commands that are transmitted to the robot through a broadband network. The control commands can be interpreted by the robot to induce action such as robot movement or focusing a robot camera. The robot can generate reporting commands that are transmitted to the remote station through the broadband network. The reporting commands can provide positional feedback or system reports on the robot.

Abstract: A substrate holder and method for using it to move a substrate. The holder comprises a frame having an inner periphery defining a first opening for receiving the substrate, and a shoulder projecting laterally inward from the inner periphery of the frame for supporting the substrate in the first frame opening. The shoulder has an inner periphery defining a second opening smaller than the first opening for receiving a substrate support. The holder and a substrate therein is moved to a position above the substrate support and then lowered to a position in which the shoulder of the holder is positioned below a top surface of the substrate support and the substrate is deposited on the top surface of the substrate support.

Abstract: A gripping apparatus comprises an information acquisition unit (A 311, A315, A301) configured to acquire information about a position and orientation of an object (23) to be gripped by a gripper (12), a movement path generating unit (A610) configured to acquire a target state suitable for gripping the object, based on the acquired information, and generate a movement path of the gripper toward the target state, and a controller configured to move the gripper along the generated movement path and cause the gripper to grip the object.

Abstract: A component manipulating method includes recognizing, computing, and manipulating. The recognizing is a process in which a position and an attitude of a measured object is recognized by taking an image of a light spot group of the measured object with a camera, the measured object having the light spot group including a plurality of light spots, based on a light image expressing light spots constituting the light spot group on an image taken with the camera. The computing is a process in which a position and an attitude of the component are computed based on the position and the attitude of the recognized measured object and also on geometric arrangement positions of the measured object and the component. The manipulating is a process in which a robot being used to perform operations on the component is manipulated based on the computed position and the attitude.

Abstract: Wafers W are supported respectively on inner tables 52 of a table 13, and after a strip of sheet S is fed out to the upper surface side of the wafers W, a press roller 14 imparts a press force. The adhesive sheet S is cut along the outer periphery of the wafers by a cutter blade 63 mounted at the free-end side of a robot 15. The robot 15 has a function to exchange the cutter blade 63 with a suction arm 100, to transfer the wafer W from a magazine 200 to the table 13 and to transfer the wafer W stuck with the sheet to the next process.

Abstract: A system for handling vehicle frames. The system includes a conveyor assembly including a loading end and an unloading end, and the conveyor assembly carries a plurality of vehicle frames thereon. The system also includes a frame transfer assembly disposed at the unloading end of the conveyor assembly. The frame transfer assembly may be adapted to grasp a vehicle frame from the conveyor assembly and transfer the vehicle frame from the conveyor assembly. A vehicle frame inversion system is also provided that includes a first robotic inversion device that may include a first clamping system, and a second robotic inversion device that may include a second clamping system. The first and second clamping systems are adapted to grasp a vehicle frame, and the first and second robotic inversion devices are adapted to lift and invert the vehicle frame.

Abstract: Damping material is installed on a structure by moving a material placement head over the structure, and using the head to place the material on the structure.

Abstract: The invention relates to an automated method for positioning eggs on a tray that comprises the automated detection of the presence/absence of eggs in the cells of a tray, and the picking-up of eggs from a supply and the placement thereof in the empty cells of a tray. The invention also relates to a system or positioning eggs on a stabilizing tray, the tray including evenly distributed cells in which the eggs are placed, one or more cells being likely not to contain eggs, this information being stored in an information processing unit, wherein said system includes a means in the form of a robot having an egg pick-up head that are driven by the information processing unit in order to pick up eggs from a supply tray and to place them in the empty cells of the stabilizing tray.

Abstract: A conveyance device (10) constructed from a multijoint robot having first to sixth arms (15A-15F) that are each numerically controlled. A suction arm (12) for sucking and holding a semiconductor wafer (W) is provided on the free end side of the conveyance device (10). The suction arm (12) has a suction section (12C) on the forward end side of the arm and is mounted so as to be movable in three perpendicular axes (X, Y, Z axes) through the arms (15A-15F) and so as to be rotatable in the direction tilting relative to an imaginary plane (S). Accordingly, even if the semiconductor wafer (W) is tilted relative to the imaginary plane (S), the suction section (12C) can be brought to intimate contact with the wafer (W) by changing the angle of the suction arm (12).

Abstract: A system for performing minimally invasive cardiac procedures. The system includes a pair of surgical instruments that are coupled to a pair of robotic arms. The instruments have end effectors that can be manipulated to hold and suture tissue. The robotic arms are coupled to pair of master handles by a controller. The handles can be moved by the surgeon to produce a corresponding movement of the end effectors. The controller controls and limits movement of robotic arms relative to the patient.

Abstract: A method for controlling a multi-axis industrial robot or manipulator arranged with a robot control unit. The robot or the control unit includes at least one first computer running a servo controller. A motion limit is configured for at least one axis of the robot arm. A reference signal for a robot position is sent to a robot controller together with a measurement of a position of the robot arm. The reference position is processed and the measured position and the processed reference position are then compared in an evaluator for the purpose of limiting the motion of an arm of the robot.

Abstract: A board game system comprises a touch screen, a computing device and a robot arm. The computing device comprises a processor and a memory. At least one type of board game program is stored in the memory so that the processor can execute the board game program present a corresponding board game interface on the touch screen. The robot arm controlled by the computing device can touch the touch screen and play the board game with a user.

Abstract: In accordance with an embodiment of a system for handling and processing chemical and/or biological samples, a MicroChamber comprises a substrate, a reservoir formed on the substrate for receiving a chemical and/or biological sample, and an encoder such as a barcode or other suitable device. The encoder encodes information describing at least one characteristic of the substrate and/or reservoir.

Abstract: In a control system of a legged mobile robot having a body and legs connected to the body and driven by a leg actuator, there is provided an operation controller which generates gaits based on an external force, more specifically gaits for walking by taking a hand of a human being or with the hand being taken by the hand of the human being and controls operation of at least the leg actuator based on the generated gaits. With this, it becomes possible to control the robot to come contact with a human being to establish communication therewith, while enabling to keep a stable posture during the contact.

Abstract: Surgical robots and other telepresence systems have enhanced grip actuation for manipulating tissues and objects with small sizes. A master/slave system is used in which an error signal or gain is artificially altered when grip members are near a closed configuration.