Abstract: A robotic arm system includes first robotic arm, second robotic arm and main controller. The first robotic arm and the second robotic arm are configured to grab object. The main controller is configured to: determine whether first force vector of first force applied by the first robotic arm to the object is equal to second force vector of second force applied by the second robotic arm to the object; when the first force vector and the second force vector are not equal, obtain a first difference between the first force vector and the second force vector; and according to the first difference, change at least one of the first force applied by the first robotic arm to the object and the second force applied by the second robotic arm to the object so that the first force vector and the second force vector are equal.

Abstract: A retainer that holds a plurality of first balls is arranged between a slide body constituting a slide portion and a base plate constituting a table portion, the plurality of first balls are arranged around an axis of the slide portion that coincides with the Z-axis, and a single second ball is arranged on the axis of the slide portion between a ball receiving plate constituting the slide portion and a ball receiving plate constituting the table portion.

Abstract: A transfer apparatus including a frame, multiple arms connected to the frame, each arm having an end effector and an independent drive axis for extension and retraction of the respective arm with respect to other ones of the multiple arms, a linear rail defining a degree of freedom for the independent drive axis for extension and retraction of at least one arm, and a common drive axis shared by each arm and configured to pivot the multiple arms about a common pivot axis, wherein at least one of the multiple arms having another drive axis defining an independent degree of freedom with respect to other ones of the multiple arms.

Abstract: A self-centering compliant joint for connecting an actuator and an effector, provides five degrees of freedom, minimizes the effects of side loads, transfers compressive loads into tensile loads on internal components, and self-centers.

Abstract: An object can be moved via a robotic system with a combination of force and position control. The control system can include the object to be moved, the robotic system that moves the object, at least one force sensor, at least one position sensor, and a controller. A position control output, a force control output, and a hybrid weighting value can each be determined by the controller based on sensor data and then combined to determine an amount of position control and/or force control to be applied to move the object and/or modify an object in motion's trajectory.

Abstract: Processes and systems for cleaned storage of high level cleanliness articles, such as extreme ultraviolet (EUV) reticle carriers. A decontamination chamber cleans the stored workpieces. A purge gas system prevents contamination of the articles stored within the workpieces. A robot detects the condition of the storage compartment before delivering the workpiece. A monitor device monitors the conditions of the stocker.

Abstract: A method of controlling an operation of a robotically-controlled surgical instrument can include receiving a first input signal at a controller indicative of a user's readiness to actuate the surgical instrument to perform a surgical procedure, outputting an output signal from the controller to provide feedback to the user in response to the received first input signal, receiving a second input signal at the controller confirming the user's readiness to actuate the surgical instrument, outputting an actuation signal from the controller in response to receiving the second input signal, and actuating the surgical instrument to perform the surgical procedure based on the actuation signal.

Abstract: Provided is a method to load a patterning device (1010) onto a reticle stage (RS) of a lithography system, a Rapid Exchange Device (RED) configured to load a patterning device (1010) onto a reticle stage (RS) of a lithography system, and a system for manufacturing a semiconductor device lithographically. The method involves sharing compliance among six degree of freedom between the reticle stage (RS) and the RED. The RED complies in only a first three degrees of freedom and the reticle stage (RS) in only a second three degrees of freedom until the reticle stage (RS) and patterning device (1010) are substantially in contact and coplanar.

Abstract: A machining apparatus for grinding, milling, polishing or the like of a dental workpiece. The machining apparatus contains a machining tool, a housing to which the machining tool is mounted rotatably about an axis of rotation relative to the housing, and a holding device to which the housing is fixed. The housing is mounted yieldingly movably to the holding device in dependence on forces exerted on the machining tool.

Abstract: A plurality of interconnected phalanges form robotic fingers configured to grasp an object. The phalanges interact with a resilient compliant element for adjustable resilient cushioning of movement of the phalanges.

Abstract: A robot, such as a painting robot for painting components such as motor vehicle body components, is disclosed having a plurality of robot elements that are pivotable relative to each other. At least one flexible supply line may run from a proximal robot element to a distal robot element. The supply line may be axially displaceable in the proximal robot element relative to the longitudinal axis of the supply line, so that the supply line can perform an axial compensating motion during a pivot motion of the robot.

Abstract: A compensation device that is positioned between a robot and a robotic tool. The device 10 generally includes a first section that connects to the robot and a second section that connects to the tool. The second section is movable relative to the first section for the tool to comply to accommodate variations in its positioning. The second section 12 may comply rotationally about x, y, and z orthogonal axes relative to the first section.

Abstract: Various embodiments of the invention provide a control framework for robots such that a robot can use all joints simultaneously to track motion capture data and maintain balance. Embodiments of the invention provide a framework enabling complex reference movements to be automatically tracked, for example reference movements derived from a motion capture data system.

Abstract: Telerobotic, telesurgical, and surgical robotic devices, systems, and methods selectively calibrate end effector jaws by bringing the jaw elements into engagement with each other. Commanded torque signals may bring the end effector elements into engagement while monitoring the resulting position of a drive system, optionally using a second derivative of the torque/position relationship so as to identify an end effector engagement position. Calibration can allow the end effector engagement position to correspond to a nominal closed position of an input handle by compensating for wear on the end effector, the end effector drive system, then manipulator, the manipulator drive system, the manipulator/end effector interfacing, and manufacturing tolerances.

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 invention relates to a method and to a system for aligning and controlling the position of a robot tool, wherein a monitoring device is equipped with a detection unit and processing unit which co-operates with the control device of the robot and automatically determines the alignment of the robot tool by means of the detection unit by taking into account at least one pre-determined reference direction of the robot tool, in addition to at least one predetermined tolerance angle which defines a tolerance range for the at least one reference direction of the robot tool. The processing unit compares the determined alignment to the predetermined reference direction and/or to the tolerance values predetermined by the defined tolerance range and/or of the at least one tolerance range is not respected, the respective robot tool is disconnected and/or deactivated in co-operation with the control device of the robot.

Abstract: The present disclosure is directed to a system and method for managing communications with robots. In some implementations, a computer network, where operators interface with the network to control movement of robots on a wireless computer network includes a network arena controller and a plurality of robot controllers. The network arena controller is configured to provide firewall policies to substantially secure communication between robot controllers and the associated robots. Each controller is included in a different robot and configured to wirelessly communicate with the network arena controller. Each robot controller executes firewall policies to substantially secure wireless communication.

Abstract: A method of controlling a robotic manipulator of a force- or impedance-controlled robot within an unstructured workspace includes imposing a saturation limit on a static force applied by the manipulator to its surrounding environment, and may include determining a contact force between the manipulator and an object in the unstructured workspace, and executing a dynamic reflex when the contact force exceeds a threshold to thereby alleviate an inertial impulse not addressed by the saturation limited static force. The method may include calculating a required reflex torque to be imparted by a joint actuator to a robotic joint. A robotic system includes a robotic manipulator having an unstructured workspace and a controller that is electrically connected to the manipulator, and which controls the manipulator using force- or impedance-based commands. The controller, which is also disclosed herein, automatically imposes the saturation limit and may execute the dynamic reflex noted above.

Abstract: A robot compliance device includes first and second discs (12, 30) spaced along a first axis (X). A column (24) is interconnected between the first disc (12) and a beam (14) intermediate the first and second discs (12, 30). A compliance member (40) is mounted around the column (24) between the first disc (12) and the beam (14). First and second canted resilient plates (50) are interconnected between the compliance member (40) and the beam (14) and spaced from each other along a second axis (Y) perpendicular to the first axis (X) and are at a first acute angle with and spaced from the first axis (X). Third and fourth canted resilient plates (52) are interconnected between the second disc (30) and the compliance member (40) and spaced from each other along a third axis (Z) perpendicular to the first and second axes (X, Y) and are at a second acute angle with and spaced from the first axis (X).

Abstract: A robot controlling device includes: a position error calculator calculating a position error between an endpoint position of a robot and a position commanded value for the endpoint position; an external force calculator calculating an external force applied to the endpoint position; a force commanded value generator generating a force commanded value for the endpoint position; a force error calculator calculating a force error between the external force and the force commanded value; a storage storing the compliance model for the endpoint position; a first correction amount calculator calculating a first correction amount for the position commanded value, according to the force error, using the compliance model; and a second correction amount calculator calculating a second correction amount for the position commanded value, on the basis of the first order lag compensation for the first correction amount. The position error calculator calculates the position error, using the second correction amount.

Abstract: An apparatus for performing fault tolerance against a failure occurring during driving robot software components includes: a component executor for executing the robot software components, which are assigned with one thread from an operating system and have a same priority and cycle, by using the assigned thread; and an executor monitor for periodically monitoring the operation of the component executor and determining whether or not there is a failure in the robot software components executed by the component executor. The apparatus further includes: an executor manager for generating the component executor which is assigned with the robot software components having the same priority and cycle and, when the executor monitor determines that there is a failure in the execution of the robot software components, generating a new component executor.

Abstract: A method for adjusting a program including program instructions for controlling an industrial robot to carry out work at a plurality of target points on a work object. The robot includes a tool having two arms adapted to clamp the work object and at least one of the arms is arranged movable relative the other arm in an opening and a closing direction, a manipulator adapted to hold the tool or the work object, and a controller controlling the movements of the manipulator and the tool arm and configured to switch between a normal control mode and a compliant control mode in which the manipulator has a reduced stiffness in at least one direction. The method includes moving the manipulator and the tool according to the program instructions until one of the target points is reached.

Abstract: A gripper includes a connecting member and two clamping assemblies fixed on the connecting member. Each clamping assembly includes a main body and two positioning shafts. The main body defines two pivot holes, in which the positioning shafts are slidably received. Each of the positioning shafts includes a shaft sleeve, a positioning pin, a driving pin, and a plurality of balls. The positioning pin and the driving pin are received in the shaft sleeve, and the driving pin resists the positioning pin. The shaft sleeve defines a plurality of receiving holes for receiving the balls. An inner wall in the pivot hole defines a restricting groove. The driving pin is capable of driving the balls partially into the restricting groove, and driving the positioning pin partially out of the shaft sleeve.

Abstract: An apparatus and a method for controlling at least one machine, such as an industrial robot, having drives, safety peripheral components and a controller for a machine, and also having a safety controller. In this arrangement, the safety controller has superordinate access over the respective machine controller both to the machine drives and to the safety peripherals. This achieves the most easily configurable integration of the safety control loop into the operating control loops.

Abstract: A robotic painting system includes a device for generating a vacuum and a dump line disposed upstream from a connection between an isolation line and a canister, wherein the device for generating a vacuum and the dump line are employed for filling and cleaning the robotic painting system.

Abstract: A ratcheting end-of-arm (EOM) tool having a spring-loaded level compensator, a distally mounted gripper, and a ratcheting mechanism. In operation, upon a selectively adequate contact between the gripper and a payload, the ratcheting mechanism is engaged which holds the position of the gripper with respect to the robot arm at a fixed position, independent of spring biasing. Upon conclusion of robotic movement of the payload, the gripper is deactivated, the ratcheting mechanism is disengaged, and the spring returns the ratcheting EOA tool to its nominal configuration.

Abstract: A system and method for operating robots in a robot competition. One embodiment of the system may include operator interfaces, where each operator interface is operable to control movement of a respective robot. A respective operator interface may be in communication with an associated operator radio, where each radio may have a low power RF output signal. A robot controller may be coupled to each robot in the robot competition. A robot radio may be coupled to a respective robot and in communication with a respective robot controller and operator radio. The robot radios may have a low power RF output signal while communicating with the respective operator radios. Alternatively, the radios may be short range radios, where a distance of communication may be a maximum of approximately 500 feet.

Abstract: A method and apparatus for estimating a position and an orientation of a mobile robot. The apparatus includes: a ceiling image grabber for obtaining a ceiling image of an area where the mobile device travels; a mark detector for detecting a retro-reflective artificial mark from the ceiling image, the retro-reflective artificial mark including a first mark and a second mark, each including a non-reflective portion and an infrared reflective portion; and a position & orientation estimator for estimating a position and an orientation of the mobile device using a position of the artificial mark or encoder information according to whether detection of the artificial mark is successful.

Abstract: A robot compliance device includes first and second discs (12, 30) spaced along a first axis (X). A column (24) is interconnected between the first disc (12) and a beam (14) intermediate the first and second discs (12, 30). A compliance member (40) is mounted around the column (24) between the first disc (12) and the beam (14). First and second canted resilient plates (50) are interconnected between the compliance member (40) and the beam (14) and spaced from each other along a second axis (Y) perpendicular to the first axis (X) and are at a first acute angle with and spaced from the first axis (X). Third and fourth canted resilient plates (52) are interconnected between the second disc (30) and the compliance member (40) and spaced from each other along a third axis (Z) perpendicular to the first and second axes (X, Y) and are at a second acute angle with and spaced from the first axis (X).

Abstract: A workpiece transfer system or method is provided for transferring workpieces one set of pallets to another set of pallets using a workpiece transfer device that is movably attached to a robot. The workpiece transfer device uses mechanical devices to align the workpiece relative to the robot so that different types of workpieces can be placed into a pallet without the need of troublesome, expensive and complex image processing in which the workpiece holding positions are processed as images by using an imaging device such as a visual sensor. Preferably, the workpiece transfer device cooperates with a positional adjustment part such that the workpiece that is held by the transfer device contacts the the positional adjustment part to position the workpiece in a depthwise direction of the workpiece, a widthwise direction of the workpiece and a longitudinal direction of the workpiece.

Abstract: A compensating unit for a tool unit for inserting an element into a workpiece, in particular a setting unit for inserting a joining element into a workpiece. The tool unit is fastened to a mounting and being mounted, oriented in an axial direction, in such a way that, during the machining operation, a compensating movement in a plane oriented at least approximately perpendicular to the axial direction is made possible.

Abstract: A painting robot outer arm includes a non-conductive housing mounting a color changer on the outside and a paint canister on the inside connected by an isolating paint transfer line. The paint canister is releasably attached to a piston ram and drive motor by a quick disconnect coupling. The paint supply is isolated from the applied high voltage by cleaning and drying the transfer line. The rate of filling of the canister can be controlled in response to sensed torque applied by a drive motor moving a piston in the paint canister.

Abstract: A workpiece regrasping system for a robot. The system includes a manipulator grippable a workpiece; a deck member having a deck surface on which a workpiece is placeable; a support mechanism rotatably supporting the deck member about an axis parallel to the deck surface; a workpiece-orientation control section for controlling the manipulator so as to grip a workpiece at a first point of the workpiece and to bring the workpiece into abutment with the deck surface of the deck member, and configured to displace the workpiece together with the deck member about the axis, while maintaining a mutually abutted condition, until the workpiece occupies a desired orientation, with at least a part of a weight of the workpiece being carried on the deck surface; and a regrasping control section for controlling the manipulator so as to temporarily release the workpiece placed on the deck surface in the desired orientation and to regrasp the workpiece at a second point different from the first point.

Abstract: A system and method for operating robots in a robot competition. One embodiment of the system may include operator interfaces, where each operator interface is operable to control movement of a respective robot. A respective operator interface may be in communication with an associated operator radio, where each radio may have a low power RF output signal. A robot controller may be coupled to each robot in the robot competition. A robot radio may be coupled to a respective robot and in communication with a respective robot controller and operator radio. The robot radios may have a low power RF output signal while communicating with the respective operator radios. Alternatively, the radios may be short range radios, where a distance of communication may be a maximum of approximately 500 feet.

Abstract: A system and method for operating robots in a robot competition. One embodiment of the system may include operator interfaces, where each operator interface is operable to control movement of a respective robot. A respective operator interface may be in communication with an associated operator radio, where each radio may have a low power RF output signal. A robot controller may be coupled to each robot in the robot competition. A robot radio may be coupled to a respective robot and in communication with a respective robot controller and operator radio. The robot radios may have a low power RF output signal while communicating with the respective operator radios. Alternatively, the radios may be short range radios, where a distance of communication may be a maximum of approximately 500 feet.

Abstract: A toolhead assembly for a CNC machine displaceable along orthogonal x, y and z-axes generally consisting of a support assembly, a tool carrier supported on the support assembly having a rotatable tool axis and being displaceable relative to the support assembly between a first position wherein the tool axis is aligned with the z-axis and a second position wherein the tool axis is misaligned with the z-axis, structure for yieldably biasing the tool carrier assembly into the first position and structure responsive to a displacement of the tool carrier assembly to the second position for breaking an electrical grounding circuit of a controller operatively connected to the machine.

Abstract: A method of three-dimensional handling of an object by a robot uses a tool and one camera mounted on the robot and at least six target features which are normal features of the object are selected on the object. The features are used to train the robot in the frame of reference of the object so that when the same object is subsequently located, the robot's path of operation can be quickly transformed into the frame of reference of the object.

Abstract: A lockable elastic joint for anthropomorphous robot with a wrist and a handling organ, having a first part that is fastenable to the wrist of the robot and a second part that is fastenable to the handling organ of the robot. A first coupling is provided between the parts that is suitable to maintain the same parts at a pre-set distance and on planes parallel to each other and a second coupling is provided between the parts to allow in an elastic way or, as an alternative, to prevent mutual movements of the parts along two directions parallel to the planes of the two parts and perpendicular to each other and around an axis perpendicular to the aforesaid planes. Locking elastic joints may be provided that are suitable to lock the two parts to each other in any position, where one part is decentralized from the other.

Abstract: A method for controlling a hyper-redundant manipulator including a plurality of links coupled by joints by determining the shape the manipulator takes when the end of the manipulator is moved to a target position, includes modeling each link as an elastic body having a natural length and a suitable modulus of elasticity that enables the elastic body to stretch and contract, simulating the overall shape of the manipulator when the end has been moved to the target position with the joints locked at a freezed angle and the joints are unlocked to return each link to its natural length, and moving the manipulator end to the target position by controlling each joint angle to match the simulation outcome.

Abstract: Apparatus for teaching robot station location relative to a work piece apparatus includes an attachment that can be temporarily coupled to the apparatus and positioned in known relationship to the robot station location. A plurality of positional sensors are mounted on the attachment ring, the sensors each configured to produce a signal when a work piece carried by a robot arm is positioned a predetermined distance from the sensor. A signal receiver is configured to receive signals from the sensors and to indicate which of the sensors has produced the signal. The indication may be the activation of an LED display that indicates to an operator what the next movement of the robot arm should be in order to center the work piece with respect to the robot station location.

Abstract: A remote center compliance system having a variable center, an upper plate, a lower plate, and elastic bodies installed between the upper and lower plates, includes lower rotary plates, each having a rotation axis parallel to a center axis passing the center of the lower plate and the center of the upper plate, coupled to a lower end of each of the elastic bodies and coupled to the lower plate for rotating, and upper rotary plates, each being coupled to an upper end of each of the elastic bodies and concurrently coupled to the upper plate for rotating about the rotation axis of the lower rotary plate. A center axis of each of the elastic bodies is inclined with respect to the rotation axis of the lower rotary plate to which each of the elastic bodies is coupled. Thus, when parts having different lengths are to be assembled, the assembly of the parts can be easily performed only by rotating the rotary plates and the elastic bodies without changing the RCA system to cope with various lengths of the parts.

Abstract: The automated system includes a fluid dispenser having an applicator tip which is used to apply a fluid to an object. A compliance mechanism is utilized to assist in maintaining the applicator tip of the fluid dispenser in contact with the object during the coating operation. A robot can be utilized to advance the object past the applicator tip during the coating operation. The fluid dispenser is mounted on a movable arm to allow the fluid dispenser to be moved or rotated into and away from the position where fluid is applied to the object. The automated system provides a fluid application system that can apply a precise and repeatable layer of fluid to an object. The use of the robot allows larger objects to be easily handled and for the coating process to be done in a rapid fashion. The automated system is flexible and can readily accommodate changes in the object that is to be coated or the configuration of the coating that is to be applied to the object.

Abstract: The invention relates to a device for balancing the weight carried by a robot arm of a robot. Said device comprises a fluid spring, rotably a pneumatic spring, and a control device for controlling the movements of the robot. The device is characterized by a pressure sensor which measures the pressure of the fluid of the fluid spring. Said device and the method provided for by the invention permit the exact adjustment and balancing of the movements of the robot arm.

Abstract: In an automatic chip test machine for testing electronic components, a novel quick disconnect articulated chuck for securing a chip nest, allowing rapid changes of the chuck and plunger head with minimum production downtime. The chuck is comprised of a chuck base and a quick disconnect assembly. The quick disconnect assembly includes a vacuum seal a retractable piston with vacuum cup attachment for securing a chip, a plunger head, alignment pins, and accessible disconnect screws. The base housing is mounted in a manner that permits articulation of the chuck to allow the chuck to align with the electrical test fixture; and a vacuum introduction port. A slide frame is supported on slide rails with a roller ball and detent mechanism to permit relatively low forces of the initial mating action between the chuck and the fixture to move the chuck into a position of better alignment, and therefore lower stress and wear.

Abstract: A dual paddle end effector robot is disclosed which is capable of parallel processing of workpieces. The end effector includes a lower paddle rotatably coupled to an end of the distal link, and an upper paddle rotatably coupled to the lower paddle. The lower paddle supports a drive assembly capable of rotating the upper paddle with respect to the lower paddle. In one embodiment of the present invention, the dual paddle end effector robot may be used within a wafer sorter to perform parallel processing of workpieces on a pair of aligners within the sorter. In such an embodiment, the robot may first acquire a pair of workpieces from adjacent shelves within the workpiece cassette. After withdrawing from the cassette, the respective paddles on the end effector may fan out and transfer the wafers to the chucks of the respective aligners.

Abstract: A remote center compliance system having a variable center having an upper plate and a lower plate, and a plurality of elastic bodies installed between the upper and lower plates, includes a plurality of lower rotary plates, each having a rotation axis parallel to a center axis passing the center of the lower plate and the center of the upper plate, and coupled to a lower end of each of the elastic bodies and coupled to the lower plate to be capable of rotating, and a plurality of upper rotary plates, each being coupled to an upper end of each of the elastic bodies and concurrently coupled to the upper plate to be capable of rotating about the rotation axis of the lower rotary plate, in which a center axis of each of the elastic bodies is inclined with respect to the rotation axis of the lower rotary plate to which each of the elastic bodies is coupled.

Abstract: A DSP of a servo control circuit obtains a movement value of a servomotor for each axis for each position-speed feedback processing cycle in accordance with a move command value for each axis delivered from a main processor with every distribution cycle, and also obtains a position correction value in accordance with pressure information detected by a sensor. The DSP of the servo control circuit carries out position-speed feedback processing with the use of a move command value which is obtained by correcting the movement value with the obtained position correction value, and drives the servomotor.

Abstract: A compliant controller implements a biological model of a primate muscle so as to provide simultaneous position and force control with nonlinear damping for an actuator. The compliant controller uses one or more position sensors but does not require the use of a force sensor to provide force control. The compliant controller implements a force determining algorithm that is a function of an initial actuator position, a subsequently sensed actuator position, a desired actuator position and a position calculated from a nonlinear damping function. The algorithm updates or resets the initial actuator position or the calculated position depending upon the amount of actuator movement sensed. The compliant controller in accordance with the force determining algorithm and resetting of the various position values allows a desired position to be quickly attained while allowing the controller to compliantly respond to the presence or removal of an unknown or unexpected disturbing force.

Abstract: The present invention is a method of controlling a robotic mechanism comprising both active and passive joints, where the motion of one or more of the passive joints is constrained by one or more constraints imposed on the mechanism by the environment, the mechanical construction of the mechanism or the nature of the task. The method is capable of controlling mechanisms with multiple sets of passive joints with multiple environmental constraints restricting the motion of the mechanism. In a preferred embodiment the novel method is used to control a surgical robot holding a surgical instrument inserted into a patient through a natural or man-made orifice.

Abstract: A floating object is attached to a shipboard hoisting crane through its attachment device under high seawave conditions, by maintaining alignment of the crane attachment device under maneuvering thrust control with a location on the floating object during lowering of the attachment device onto the floating object. Such maneuvering thrust control is established by thrust jets emitted from the attachment device under control of optical scanning detection cells mounted on the attachment device for reception of a reception location indicating beam emitted from the floating object.