Abstract: A device for constructing an assembly of building components includes an articulating arm unit and a gripper/nailer mounted on an end of the articulating arm unit. The gripper/nailer includes a gripping unit for grasping building components and positioning them in a predetermined arrangement and a nailing unit for inserting a fastener to secure the building components together.

Abstract: A laser processing head mounted on a robot arm moves from with a constant speed in a direction from a welding point to a next welding point, while a reflection mirror continuously turns in order to maintain laser beams focused on the welding point until the welding at the welding point is completed, and the reflection mirror quickly turns to shift the focus of the laser beams onto the next welding point when the welding at the welding point is completed.

Abstract: A robot system is disclosed which includes at least two robots, each having a related processing unit. The processing units are connected to each other via a network bus for data transmission, and distributed sensors are provided for gathering first and/or second measurement data within a local extension of the robot system. First measurement data gathered by at least one first sensor are transmissible to at least one processing unit related thereto. Second measurement data gathered by at least one second sensor are feedable into the network bus and provided to the at least two processing units connected thereto. The processing units can analyze the second measurement data as a variable dynamic share of workload for feeding result-data of the analysis into the network bus.

Abstract: A robotic system that includes a mobile robot and a remote input device. The input device may be a joystick that is used to move a camera and a mobile platform of the robot. The system may operate in a mode where the mobile platform moves in a camera reference coordinate system. The camera reference coordinate system is fixed to a viewing image provided by the camera so that movement of the robot corresponds to a direction viewed on a screen. This prevents disorientation during movement of the robot if the camera is panned across a viewing area.

Abstract: Methods correcting wafer position error are provided. The methods involve measuring wafer position error on a robot, e.g. a dual side-by-side end effector robot, during transfer to an intermediate station. This measurement data is then used by a second robot to perform wafer pick moves from the intermediate station with corrections to center the wafer. Wafer position correction may be performed at only one location during the transfer process. Also provided are systems and apparatuses for transferring wafers using an intermediate station.

Abstract: A robot control unit (30) comprises: a setting means (40) for setting operating ranges of each shaft and a working tool of the robot (20); a storage means (33) for storing an inertial running distance of the robot decided by at least one of the operating speed of the robot and the weight of the working tool; and an arriving range calculation means (36) for calculating an arriving range to which the robot arrives according to the operating range, which has been set by the setting means, and the inertial running distance stored by the storage means. Due to the foregoing, while consideration is being given to the inertial running distance of a robot, the arriving range of the robot is made. Further, a display means (41) for displaying the arriving range may be provided. In the case where each shaft of the robot and the working tool deviate from the operating range, a stopping means (34) for stopping the robot may be provided.

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: Systems and methods are provided for controlling one or more servos coupled to a model vehicle. An input signal having a series of input pulses encoded at an input pulse repetition frequency is received at a receiver coupled to a model vehicle having one or more servos. The input signal is decoded at the receiver. A servo control pulse is generated using at least one of the input pulses at the receiver. The servo control pulse is outputted to at least one of the servos at an output pulse repetition frequency that is different from the input pulse repetition frequency.

Abstract: In an automatic machine system comprising a mechanism unit (1) including at least one driving mechanism, a controller (2) for controlling a driving operation of the mechanism unit (1), and a teaching unit (3) for operating the mechanism unit (1), the teaching unit (3) includes a teaching unit communicating portion for carrying out a wireless communication with the controller (2) and a first field intensity monitoring portion (13) for monitoring a field intensity of communication data in the teaching unit communicating portion, and the controller (2) includes a controller communicating portion for carrying out a wireless communication with the teaching unit (3), a second field intensity monitoring portion (26) for monitoring a field intensity of communication data in the controller communicating portion, and a driving portion for driving the mechanism unit (1) based on an operation signal sent from the teaching unit (3) in the controller communicating portion.

Abstract: In the present invention, through a provision of a relay stand including a first relaying point, a second relaying point and a plurality of work mounting bases, a discharge/feed process of works between the relay stand and the work feed container and the work accommodation container is performed at the first relaying point and a load/unload process of works between the relay stand and the plurality of work inspection machines is performed at the second relaying point.

Abstract: Methods and apparatus are provided for the use of a dual Selective Compliant Assembly Robot Arm (SCARA) robot. In some embodiments two SCARAs are provided, each including an elbow joint, wherein the two SCARAs are vertically stacked such that one SCARA is a first arm and the other SCARA is a second arm, and wherein the second arm is adapted to support a first substrate, and the first arm is adapted to extend to a full length when the second arm supports the first substrate, and wherein the first substrate supported by the second arm is coplanar with the elbow joint of the first arm, and the second arm is further adapted to move concurrently in parallel (and/or in a coordinated fashion) with the first arm a sufficient amount to avoid interference between the first substrate and the elbow joint of the first arm. Numerous other embodiments are provided.

Abstract: A robot controller (7) controlling a robot (1) used combined with a machine tool (5, 6) provided with a communication unit (9) connecting the robot controller to a machine tool, a detection unit (52) detecting through the communication unit a type and number of machine tools, and a setting unit (55) setting the robot controller based on the type and number of machine tools detected by the detection unit. Due to this, machine tool and robot startup work can be simply and easily performed without requiring skill or increasing the startup man-hours. The setting unit selects one setting file from among a plurality of setting files for the robot controller, stored in the robot controller, based on the type and number of machine tools detected by the detection unit.

Abstract: The invention relates to a method and a device for applying films (10) to interior wall sections of the bodywork (7) of a vehicle with the aid of an instrument or robot (6) comprising a multi-membered articulated arm (18, 19) and gripping elements (21) for the films. To reduce the mounting time, the robot (6) is driven through an opening (14) in the interior of the bodywork (7), the films (10) to be applied are transported by transport elements (11) to the vicinity of the interior or into the interior of the bodywork (7) and the delivered films (10) are taken from the transport elements by the robot (6) and its gripping elements (21) and are applied to the respective interior wall sections.

Abstract: A joint of a robot is controlled by a torque command. The joint has a position controller with a position feedback loop. The torque command is received for the joint, and a velocity feedforward command is determined for realizing the torque command using the position controller. The velocity feedforward command is sent to the position controller and the position feedback loop is canceled. The position feedback loop is canceled by sending a position command to the position controller, where the position command is an actual measured position of the joint. The position feedback loop is also canceled by setting the gain of the position feedback loop to zero.

Abstract: A work handling apparatus includes a pair of traveling guides (20, 20?) provided so as to extend in a front-and-rear direction X at right and left sides, and a pair of direct-acting arms (30, 30?) provided so as to travel independently on the pair of traveling guides. The direct-acting arms are extendable from contracted positions, at which the arms oppose each other and avoid mutual interference in a right-and-left direction Y, to extended positions at which the arms overlap with each other. An operation spot (41) is arranged in an operation area (40) sandwiched between the pair of traveling guides for performing a predetermined operation to a work. Also, work tools (60, 60?) are attached to the pair of direct-acting arms (30, 30?), respectively, for transferring the work between a work storage area (50) and the operation spot (41) or performing an operation after transfer.

Abstract: A device for retrieving data from radio frequency identification (RFID) tags is disclosed. The device includes a mobile base, a robotic arm, and a data reading device. The robotic arm is attached to the mobile base. The data reading device employed to collect the data of electric tags is attached to the end of the robotic arm. A device for retrieving data from an RFID tag arrives at the position, where the electric tag is, by moving the mobile base and adjusting the height of the robotic arm. The movement is controlled according to the position and the height of the electric tag. Finally, the data reading device reads the data stored in the electric tag.

Abstract: A control device of a work positioning apparatus includes an operating limit line storage unit for storing position coordinates of an operating limit line, a speed reduction zone storage unit for storing a width of a speed reduction zone ranging from a reduction start position to the operating limit line, a check point storage unit for storing position coordinates of check points set in the work, a check point updating unit for determining position coordinates of the check points moved in accordance with an operation of the work positioning apparatus by calculation, an in-speed-reduction-zone determining unit for determining whether the check points enter the speed reduction zone in accordance with the updated position coordinates of the check points, and a work positioning apparatus control unit for instructing a work positioning apparatus motor to reduce a speed if the check points are determined to enter the speed reduction zone.

Abstract: In a method and device to control a multiple-machine arrangement with at least one first controller and one second controller, specific data packages for the controllers are generated, these specific data packages are transferred to the controllers, the transferred data packages are selectively activated, and downloading of the data packages is implemented in the controllers as a result of an activation, in particular installation of at least one program and/or one configuration file.

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 game system comprises a game board having a playing area and game pieces for playing a game on the game board. Each game piece comprises a mobile robot for sensing and decoding a position-coding pattern printed on the game board. Each game piece is in communication with a computer system. The computer system is configured to send instructions for moving each game piece relative to the playing area in response to position information corresponding to the game pieces.

Abstract: A master interface and a driving method for a surgical robot are disclosed. The master interface is mounted on a master robot, to manipulate a slave robot connected with the master robot, and includes: a main handle coupled to the master robot; a sub-handle coupled to the main handle; a first processor configured to generate a first signal in correspondence with user manipulation on the main handle; and a second processor configured to generate a second signal in correspondence with user manipulation on the sub-handle, where the first signal and the second signal are transmitted to the slave robot independently. As the interface for the surgical master robot includes not only the handle (main handle) for manipulating the robot arm, but also an additional controller (sub-handle) for a laparoscope, etc., the operator is able to simultaneously manipulate the laparoscope, etc., while manipulating the handle, without having to stop manipulating the handle or perform an additional action separately.

Abstract: This object aims to provide a work mounting system which has an improved usability and can be miniaturized. A work mounting system (1) is used to mount a sunroof member (3) on the inner panel (2A) of a body (2). The work mounting system (1) comprises a conveying robot (4) for holding and conveying the sunroof member (3), a mounting robot (5) with a nut runner for tightening bolts and a CCD camera, and a controller (6) for controlling the conveying robot (4) and the mounting robot (5).

Abstract: An automatic cell cultivation apparatus is provided which is capable of conveying the culture container, exchanging the culture medium, and operating other jobs promptly by a robot. The automatic cell cultivation apparatus has a cultivation apparatus main body for cultivating cells in a culture container, and the cultivation apparatus main body is equipped with one or more incubator accommodating the culture container, a chemical suction machine for sucking chemicals in the culture container, and a multijoint robot for conveying the culture container, the multijoint robot having functions of conveying the culture container, detaching and attaching the lid of the culture container, and inclining the container when sucking chemicals in the culture container, so that cell cultivation operations can be promptly carried out by only one robot.

Abstract: A partial surface of a total surface, divided into several partial surfaces, is allocated to one of several mobile units by determining the partial surface of the total surface and allocating one of the several mobile units with a reservation. The mobile unit transmits allocation information indicating the allocation of the partial surface. The reservation is lifted and the allocation of the partial surface is validated when the one of the several mobile units receives no allocation rejection information from at least one of the other mobile units, indicating a rejection of the allocation of the partial surface. If rejection information is received, the reservation is lifted and the allocation of the partial surface is invalidated.

Abstract: A network system including a plurality of mobile devices is provided. The plurality of mobile devices each have a sensor function and a wireless communication function, the mobile devices communicating sensor information about a target with one another and tracking the target; a target searching section configured to obtain sensor information while the plurality of the mobile devices move and for reporting the sensor information among the mobile devices by wireless communication; a target focusing section configured to, in response to one of the mobile devices detecting a target, focus a sensor on the target in cooperation with mobile devices adjacent to the mobile device detecting the target; and a target surrounding section configured to surround the target by using a plurality of mobile devices that focus their sensors on the same target.

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.

Abstract: A production plant, particularly for suitcases and trunks, such suitcases and trunks comprising at least two half-shells mutually associated so as to form at least one internal containment compartment. The plant comprises: at least one station for loading at least one half-shell; at least one work island which has at least one dispenser of perimetric gasket seals; at least one storage area for the half-shells; at least one centre for mating the half-shells, so as to form substantially the finished product, such as a suitcase and a trunk; at least one station for unloading the finished product.

Abstract: In a robot, a first determining unit determines whether there is an interference region in which a first occupation region and a second occupation region are at least partially overlapped with each other. A second determining determines whether a second movable part of another robot is at least partially located in the interference region based on an actual position of the second movable part. A stopping unit begins stopping, at a predetermined timing, movement of the first movable part if it is determined that there is the interference region, and that the second movable part is at least partially located in the interference region. The predetermined timing is determined based on a positional relationship between an actual position of the first movable part and the interference region.

Abstract: A method of controlling a redundant manipulator for assigning one or more redundant joints from a plurality of joints and obtaining the solution to an inverse kinematics problem at high-speed. The joints are arbitrarily classified into redundant joints and non-redundant joints, and an initial value is set for the joint angle of the classified redundant joint as a parameter. Then based on an evaluating function or a constraint condition defined by the joint angle of the redundant joint provided as a parameter and the joint angle of the non-redundant joint, which is determined by the inverse kinematics calculation according to the change of the parameter, an optimum solution of a set of joint angles is determined, and until the optimum solution covers the target range of the hand position, the procedure to determine the optimum solution is repeated with relaxing the constraint conditions.

Abstract: There is provided a control device for a robot arm which includes an operation procedure information acquisition means for acquiring information on the procedure of a domestic operation, a progress management means for managing information on the progress of the operation, and a control parameter setting means for setting a control parameter for the robot arm based on the operation procedure information and the progress information, whereby the control device controls an operation of the robot arm based on the control parameter from the control parameter setting means.

Abstract: A control device for a robot arm is designed such that, based on information on a transportation state database in which information on a transportation state of a person operating the arm is recorded, an impedance setting unit sets a mechanical impedance set value of the arm, and an impedance control unit controls a mechanical impedance value of the arm to the mechanical impedance set value thus set.

Abstract: A robot with a body, at least one leg on each side of the body, and a hip connecting the leg to the body. The hip is configured to abduct and adduct the leg. A linkage is configured to rotate the leg along a predetermined path.

Abstract: A system for lapping gear sets with a ring gear and a pinion gear. The system includes a lapping machine tool and a robot. The lapping machine tool has a first spindle and a second spindle. The second spindle is rotatable about an axis that is generally perpendicular to a rotational axis of the first spindle. The lapping machine tool has a loading zone for loading the first and second spindles. The robot has an end effector with a first end that is configured to hold one of the gear sets. The robot is configured to position the first end of the end effector into the loading zone and to load the first gear set to the lapping machine tool without removing the end effector from the loading zone such that the ring gear is loaded onto the first spindle and the pinion gear is loaded onto the second spindle.

Abstract: A system for performing minimally invasive cardiac procedures includes a pair of surgical instruments coupled to a pair of robotic arms with end effectors that can be manipulated to hold and suture tissue. The robotic arms are coupled to a pair of master handles by a controller to produce a corresponding movement of the end effectors. The movement of the handles is scaled such that the end effectors movement corresponds differently, typically smaller, than the movement performed by the hands of the surgeon. The input button allows the surgeon to adjust the position of the handles without moving the end effector, so that the handles can be moved to a more comfortable position. The system may include a robotically controlled endoscope allowing the surgeon to remotely view a surgical site. The surgeon may manipulate handles and move end effectors to perform a cardiac procedure.

Abstract: In a device for relocating a product, in particular a blister, in a packaging machine and with an associated method, the product is received at a supply location and deposited at a deposition location. The relocating device has a first pivotable relocating arm and a second pivotable relocating arm which each have a holding mechanism for the product. The relocating arms can be adjusted along different trajectories between a transfer position at the common supply location and a deposition position at the common deposition location, and pass each other during their adjustment motion.

Abstract: A configurable mutual exclusion function oversees movement of appliances mobile over a common physical space in an automated laboratory workstation. A configurable mutex is allotted for each moveable appliance and is configurable to protect a task site when obtained for the respective appliance.

Abstract: Scalable storage can be achieved with linear array storage of wafers, comprising two linear arrays of storage compartments on opposite walls, with a middle transfer mechanism. Together with a buffer station for automatic material handling system, a scalable bare wafer stocker can provide flexible and uninterrupted services to a fabrication facility.

Abstract: Methods correcting wafer position error are provided. The methods involve measuring wafer position error on a robot, e.g. a dual side-by-side end effector robot, during transfer to an intermediate station. This measurement data is then used by a second robot to perform wafer pick moves from the intermediate station with corrections to center the wafer. Wafer position correction may be performed at only one location during the transfer process. Also provided are systems and apparatuses for transferring wafers using an intermediate station.

Abstract: A control system is disclosed for controlling the movements of a plurality of mechanical units. The control system includes a plurality of independent control units, each including one or more control programs having instructions for controlling movements of at least one mechanical unit, and software for executing the control programs, wherein each control unit is configured to be put into any of a plurality of different states independent of states of remaining control units. A single server unit contains the plurality of independent control units, the server including memory for storing the control programs and the software for executing the control programs, a processor having at least one core, communication hardware for communicating with a network, and a resource-distributing unit adapted to distribute real and virtual hardware resources of the server unit to the control units, such that the control units share the real and virtual hardware resources of the server unit.

Abstract: The present invention provides an industrial robot which can reduce torque required for driving an object to be moved. By providing a third reduction device and a third driving device separately, the dimension in the third axial direction of the third reduction device can be reduced, thus the distance from a second axis to an end effecter can be decreased. As such, the torque required for a first driving device and a second driving device to rotate and drive the end effecter can be reduced. Accordingly, even when the weight of the end effecter is increased, an increase of the torque required for the first driving device and the second driving device can be suppressed. Therefore, a higher speed operation can be achieved as compared with the conventional industrial robot.

Abstract: The method is for interacting with a wearable interactive device. A pathway extends through an interactive device that is non-slidably attached to the pathway. The pathway has a first end and a second end. At least one end of the pathway is attached to a body of a user. The user accelerates the device in a first direction. A sensor senses the acceleration in the first direction. The sensor triggers a motor to move gears so that the device travels towards the first end of the pathway. The user accelerates the device in a second opposite direction. The sensor triggers the device to move towards the second end of the pathway.

Abstract: A drive system for a robot includes a track including opposed sidewalls, an electrified rail positioned between the sidewalls, a shoe mounted on the robot for contacting the electrified rail providing power to the robot, a drive motor mounted on the robot, a rotating drive member, the drive member engaging the track to drive the robot when the drive motor is actuated, means for coupling the drive member to the drive motor and means for increasing the friction between the drive system and the track at selected locations along the track.

Abstract: A method for controlling a robot during an interpolation of a trajectory or motion to any prescribed position, comprises the steps of a) ignoring at least one of the three originally prescribed or interpolated tool center point orientation values; b) finding new tool center point orientation values that place the wrist center point of the robot closest to its base while c) maintaining the originally prescribed or interpolated tool center point location values and d) maintaining the original prescribed or interpolated tool center point orientation values not ignored. Said method can preferably be used for carrying a load with a plurality of robots. Its main advantage is an increase of the available working volume.

Abstract: An ion implantation apparatus, system, and method are provided for transferring a plurality of workpieces between vacuum and atmospheric pressures, wherein an alignment mechanism is operable to align a plurality of workpieces for generally simultaneous transportation to a dual-workpiece load lock chamber. The alignment mechanism comprises a characterization device, an elevator, and two vertically-aligned workpiece supports for supporting two workpieces. First and second atmospheric robots are configured to generally simultaneously transfer two workpieces at a time between load lock modules, the alignment mechanism, and a FOUP. Third and fourth vacuum robots are configured to transfer one workpiece at a time between the load lock modules and a process module.

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 work treatment installation comprises several side-by-side machine tools and at least one work supply and discharge device. It further comprises a work transport device which bridges both of them and comprises a displaceable and vertically sliding lifting skid with a work grab. The work transport device comprises lowering stops for the lifting skid. They are fixed between charge and discharge positions of the machine tools and designed for engagement and disengagement in the charge and discharge positions.

Abstract: A parallel robot or parallel kinematics mechanism is provided for uses such as robotics or machining. The mechanism comprises a fixed base, a main arm, and a first and second support arm to position and orient an object in a cylindrical space with at least three degrees of freedom and retained inclination. The main arm includes an end component for supporting the object and linkage means to retain the inclination of the end component with respect to the base for all positions and orientations of the end component. The mechanism advantageously provides a large cylindrical workspace and a small footprint and is capable of moving an object at high accelerations and speeds. The mechanism can be equipped with an additional motor to orient an object, thereby providing the mobility of a SCARA robot. Alternatively, it can be equipped with passive transmission means that allow for an object to be displaced in parallel to itself.

Abstract: An operation control unit of a reception system includes a visitor ID information DB for storing therein visitor comparison information and visitor ID information including a phone number of a receiver of a visitor; an identifying unit for identifying the visitor when visitor information obtained by a camera or the like of the robot is identical to the visitor comparison information; a phone calling module for calling the phone number of a mobile terminal of the receiver via a phone network, when the visitor is identified; an informing content determining unit for determining an informing content to the receiver based on the visitor ID information, when the visitor is identified; and a speech generating part for converting the received information into a voice. The informing content is sent to the mobile terminal of the receiver via the phone network.

Abstract: A hair transplantation method and apparatus utilizes a robot, which includes a robotic arm, having a hair follicle effector associated with the robotic arm.

Abstract: A hair transplantation method and apparatus utilizes a robot, which includes a robotic arm, having a hair follicle effector associated with the robotic arm.