Abstract: An integrated tool and automatic calibration systems that enable wet chemical processing chambers, lift-rotate units and other hardware to be quickly interchanged without having to recalibrate the transport system or other components to the replacement items. These tools are expected to reduce the down time associated with repairing or maintaining processing chambers and/or lift-rotate units so that the tools can maintain a high throughput. Several aspects of these tools are particularly useful for applications that have stringent performance requirements because components are more likely to require maintenance more frequently, and reducing the down time associated with maintaining such components will significantly enhance the integrated tool.

Abstract: An apparatus calculates, based on unimproved behavior amounts, behavior amount variations of living behaviors when each of living behaviors increases by one unit behavior amount, calculates environmental load variation of living behavior when the living behavior increases by one unit behavior amount, by calculating sum of values each obtained by multiplying one of behavior amount variations by corresponding one of basic units, to obtain environmental load variations of living behaviors, assigns messages to living behaviors based on environment load variations of living behaviors, calculates environmental load reduction of living behavior by (a) calculating variation between one of unimproved behavior amounts and one of improved behavior amounts of living behavior, and (b) multiplying variation by environmental load variation of living behavior, to obtain environmental load reductions of living behaviors, and selects one of messages which is assigned to one of living behaviors has the largest environmental loa

Abstract: In a method for controlling the movement of a manipulator associated with an interpretation of a given point sequence of poses (positions and orientations) by splines, the motion components are separately parameterized. Thus, marked, subsequent changes to the orientation of robot axes have no undesired effects on the Cartesian movement path of the robot. Suitable algorithms are provided for orientation control by using quaternions or Euler angles.

Abstract: A manipulator operative in a master/slave operative mode includes a master unit commanding an operation; a slave unit having a work unit; a detector detecting the orientation of the master unit and the orientation of the slave unit; and a control device controlling the slave unit in response to a command from the master unit. The control device determines a non-master/slave operative mode or a master/slave operative mode, and calculates a difference between the orientation of the master unit and the orientation of the slave unit. The absolute value of the calculated difference is compared with a preset reference value, and depending upon the result of the comparison, a normal master/slave operative mode or a transitional master/slave operative mode is determined, wherein in the master/slave operative mode, the transitional master/slave operative mode is a transitional mode from the non-master/slave operative mode to the master/slave operative mode.

Abstract: In the articulated robot, types of teaching a moving track of the robot can be optionally selected. The articulated robot comprises: a switch for manually selecting a moving axis to move an arm section along the selected axis; a manual pulse generator generating pulses; first controller for controlling motors to linearly move a front end of the arm section a prescribed distance, which corresponds to number of pulses; an operating board including a selecting switch, which is used to move the arm section along the selected axis; second controller for automatically controlling the motors so as to move the arm section while the selecting switch is turned on; third controller for stopping the motors to freely move the arm section while the arm section is manually moved; and a switch for selecting a type of teaching action.

Abstract: A robot system that includes a robot and a remote station. The remote station may be a personal computer coupled to the robot through a broadband network. A user at the remote station may receive both video and audio from a camera and microphone of the robot, respectively. The remote station may include a graphical user interface that can be selected to generate an alert input to the robot. The user initially establishes a voice communication between the remote station and the robot. To obtain video access the user may select a graphical icon to generate and transmit the alert input to the robot. The caller recipient at the robot may grant the request for video of themselves by inputting a response into the robot. This procedure allows someone at the robot to control the initiation of a video-conference with the user of the remote station.

Abstract: According to the hand control system (2), the position and posture of a palm (10) are controlled such that the object reference point (Pw) and the hand reference point (Ph) come close to each other and such that the i-th object reference vector (?wi) and the i-th hand reference vector (?hi) come close to each other. During the controlling process of the position and posture of the palm, the operation of a specified finger mechanism is controlled such that the bending posture of the specified finger mechanism gradually changes (for example, such that the degree of bending gradually increases). This ensures accurate grasping of an object of an arbitrary shape.

Abstract: A method for remotely monitoring a patient. The method includes generating and transmitting input commands to the robot from a remote station. The remote station may include a personal computer that is operated by a doctor. The input commands can move the robot so that a video image and sounds of the patient can be captured by a robot camera and microphone, respectively, and transmitted back to the remote station. The robot may also have a monitor and a speaker to allow for two-way videoconferencing between the patient and a doctor at the remote station. The robot can move from room to room so that a doctor can make “patient rounds” within a medical facility. The system thus allows a doctor visit patients from a remote location, thereby improving the frequency of visits and the quality of medical care.

Abstract: A dual purpose media drive exchanges data with removable media items. The drive includes at least one port to receive various control signals, including (1) data exchange commands directing the drive to read and/or write data to a media item mounted by the drive, and (2) robotic device management commands. The drive includes a processor that responds to incoming data exchange commands by reading and/or writing to the loaded media item. The processor responds to at least some robotic device management signals by forwarding them to a robotic media transport device. The processor withholds the data exchange commands from the robotic device, since they are only pertinent to operations of the drive itself. The robotic device may be configured to restrict host access to library components according to predefined logical partitions.

Abstract: A mobile robot which has a communication with a detection target by a motion of the mobile robot or by an utterance from the mobile robot, the mobile robot includes: a personal identification unit detecting an existence of the tag based on a signal transferred from the tag and obtaining the identification information stored on the tag; a position information acquisition unit obtaining distance information indicating a distance from the mobile robot to the detection target; a locomotion speed detection unit detecting a locomotion speed of the mobile robot; a personal information acquisition unit acquiring personal information based on the identification information; a communication motion determination unit determining contents of a communication motion based on the personal information; and an operation determination unit adjusting a start timing of each content of the communication motion based on distance information and on the locomotion speed of the mobile robot.

Abstract: An article transporting robot or an article transporting system includes a state recognizing means for recognizing the state of the article, a transportation method specifying means for specifying the transportation method according to the state recognized by the state recognizing means, and a transporting device for transporting the article according to the transportation method specified by the transportation method specifying means.

Abstract: A self-localization system uses both of a global search apparatus, which is based on grid-based Markov localization, and a local search apparatus, which uses an extended Kalman filter. If an observation result by the global search apparatus is valid, then updating of an observation result by the local search apparatus is permitted, but if the observation result is not valid, then updating of the observation result by the local search apparatus is not performed. On the other hand, if the observation result by the local search apparatus is valid, then a state of the local search is outputted, but if the observation result is not valid, then the local search apparatus is re-initialized. Accordingly, the self-localization of a robot can be performed based on sensor information of the robot and motion information performed by the robot in an environment including artificial landmarks.

Abstract: An internal pressure of a hydropneumatic drive actuator is measured by a pressure measurement device, a displacement amount of a movable mechanism is measured, a desired value and a measurement value of the displacement are inputted so that a position error is compensated by a position error compensation device, a desired value of a pressure difference of the actuator to which antagonistic driving is performed by the desired value is calculated by a desired pressure difference calculation device, outputs from the position error compensation device, the desired pressure difference calculation device, and the pressure measurement device are inputted, and a pressure difference error is compensated by pressure difference error compensation device.

Abstract: Set the first temporary attitude of an end effector for a plurality of work points (step S3). Determine the attitude of an articulated robot at one-end first work point out of a plurality of work points (step S4). Determine the attitude of an articulated robot at the other-end final work point out of a plurality of work points (step S5). Set the second temporary attitudes of an end effector respectively for the other work points so that the attitude of an end effector gradually changes from the first work point toward the final work point (step S6). Correct the first temporary attitude with the second temporary attitude (step S7).

Abstract: A robot control unit for controlling a robot mechanism unit constantly detects the status of a robot and stores it as robot status data. An operation command input by voice from a head set is converted into character data by a voice/character data conversion device, and input to a control device. The control device searches a command corresponding to an operation command input in operation commands stored in management data. An executing program group is specified for link and storage with the corresponding operation command.

Abstract: A medical system that allows a medical device to be controlled by one of two input devices. The input devices may be consoles that contain handles and a screen. The medical devices may include robotic arms and instruments used to perform a medical procedure. The system may include an arbitrator that determines which console has priority to control one or more of the robotic arms/instruments.

Abstract: When an operator attempts to move a robot from a current position to a desired position, she/he operates a manipulator lever (26) corresponding to a desired direction of a manipulator (23) of a remote control device (22), for example, a number of times corresponding to a predetermined moving amount in the moving direction. At this point, the moving amount for each moving direction depending on this number of operations is set, and a leg of the robot is actuated according to a setting value of the moving amount for each moving direction to move the robot. The moving amount that can be set by the operation of the manipulator lever (26) has a relatively small moving amount that the robot may be moved by performing a lifting/landing action once for each of the legs of the robot, and a relatively large moving amount requiring multiple walking steps of the lifting/landing action for each leg of the robot.

Abstract: An automation system for programming appliances having programmable controllers, programmable devices and trigger devices that communicate over a communication link. The user programs the programmable devices by placing the programmable controller in its training mode, activating the trigger device to generate a trigger signed and places select programmable devices in their programmed state. After all of the desired programmable devices have been put in then programmed states, the user takes the programmable controller out of its training mode. When the programmable controller is out of its training mode, it monitors the communication link for the trigger event. Upon detecting the trigger event, the programmable controller sends messages to the selected programmable devices instructing them to go to their programmed state.

Abstract: A remote controlled robot system that includes a robot and a remote control station. A user can control movement of the robot from the remote control station. The remote control station may generate robot control commands that are transmitted through a broadband network. The robot has a camera that generates video images that are transmitted to the remote control station through the network. The user can control movement of the robot while viewing the video images provided by the robot camera. The robot can automatically stop movement if it does not receive a robot control command within a time interval. The remote control station may transmit a stop command to the robot if the station does not receive an updated video image within a time interval.

Abstract: A robot system is provided and includes an autonomous mobile robot. In the system in which monitoring is performed using the autonomous mobile robot which travels along a predetermined path, an interval between the time when a user requests transmission of images and the time when the user obtains the images may be reduced. The autonomous mobile robot travels along a predetermined path at predetermined times, a camera takes photographs at predetermined locations during the travel along the predetermined path, images taken by the camera are stored, and the stored images are sent to a requesting cell phone in response to a transmission request from the cell phone.

Abstract: Torque control capability is provided to a position controlled robot by calculating joint position inputs from transformation of the desired joint torques. This is based on calculating the transfer function 1/E(s), which relates the desired joint torque to joint position. Here E(s) is a servo transfer function D(s) or an effective servo transfer function D*(s). The use of an effective servo transfer function D*s) is helpful in cases where joint nonlinearities are significant. The effective servo transfer function D*(s) is defined with respect to an ideal joint transfer function G*(s)=1/(Ieffs2+beffs), where Ieff is an effective moment of inertia and beff is an effective damping coefficient.

Abstract: A camera or other sensing unit senses the conditions of articles and mobile entities, including humans within a living space. An article management/operation server manages, within an article database, attribute information about the articles, including operators, according to the information from the sensing unit. The server receives a user's instruction, input through a console unit, and refers to the article database to convert this instruction into a control command, which is then transmitted to a life-support robot.

Abstract: The robot alignment system is used for establishing a predetermined alignment position between a movable robot member and an article that is processed by the robot. The system includes a laser transmitter that emits a focused laser beam and a target against which the focused laser beam is directed. The laser transmitter is preferably supported by the robot and the target is supported by the article that is processed by the robot. A signaling device cooperates with the target to produce a detectable signal when the focused laser beam is received at a predetermined location on the target. The detectable signal signifies establishment of a predetermined alignment position between the robot and the article that is processed by the robot.

Abstract: A camera or other sensing unit senses the conditions of articles and mobile entities, including humans within a living space. An article management/operation server manages, within an article database, attribute information about the articles, including operators, according to the information from the sensing unit. The server receives a user's instruction, input through a console unit, and refers to the article database to convert this instruction into a control command, which is then transmitted to a life-support robot.

Abstract: A camera or other sensing unit senses the conditions of articles and mobile entities, including humans within a living space. An article management/operation server manages, within an article database, attribute information about the articles, including operators, according to the information from the sensing unit. The server receives a user's instruction, input through a console unit, and refers to the article database to convert this instruction into a control command, which is then transmitted to a life-support robot.

Abstract: A camera or other sensing unit senses the conditions of articles and mobile entities, including humans within a living space. An article management/operation server manages, within an article database, attribute information about the articles, including operators, according to the information from the sensing unit. The server receives a user's instruction, input through a console unit, and refers to the article database to convert this instruction into a control command, which is then transmitted to a life-support robot.

Abstract: A camera or other sensing unit senses the conditions of articles and mobile entities, including humans within a living space. An article management/operation server manages, within an article database, attribute information about the articles, including operators, according to the information from the sensing unit. The server receives a user's instruction, input through a console unit, and refers to the article database to convert this instruction into a control command, which is then transmitted to a life-support robot.

Abstract: An internal pressure of a hydropneumatic drive actuator is measured by a pressure measurement device, a displacement amount of a movable mechanism is measured, a desired value and a measurement value of the displacement are inputted so that a position error is compensated by a position error compensation device, a desired value of a pressure difference of the actuator to which antagonistic driving is performed by the desired value is calculated by a desired pressure difference calculation device, outputs from the position error compensation device, the desired pressure difference calculation device, and the pressure measurement device are inputted, and a pressure difference error is compensated by pressure difference error compensation device.

Abstract: A manual-mode operating system for a robot provided with an end-effector.

Abstract: An industrial robot that has uses a simulated force vector to allow a work piece held by the robot end effector to be mated with a work piece whose location and orientation is not precisely known to the robot. When the end effector makes contact with the location and orientation in which the other work piece is held the robot provides a velocity command to minimize the force of the contact and also provides a search pattern in all directions and orientations to cause the end effector to bring the work piece it is holding in contact with the other work piece. The search pattern and the velocity command are continued until the two work pieces mate.

Abstract: An assembling method and an apparatus for carrying out the method capable of efficiently, reliably and easily detecting an insertion and fitting position, for easy automatic assembly. In case a rod-like workpiece is inserted into a hole in an object, an insertable range is determined based an amount of clearance between the workpiece and the hole, an amount of chamfering of the hole, etc. The insertable range is defined as within a range centered at a hole center position 3cp and having a radium of r. A workpiece center position is indicated by 1cp. While the workpiece is moved once throughout a search range (XL-XU) in the X-axis direction, it is moved in the Y-axis direction by an amount equal to or less than an insertable range amount 2r. As shown by a dotted line, the workpiece center 1cp passes without fail through the insertable range during the motion throughout the search range (XL-XU, YL-YU).

Abstract: A robotic storage library is provided for reducing the transition time to reach an operational state following a transition from a power-off to a power-on state. The robotic storage library can generally include a transport unit for moving data cartridges, or other storage elements, between a location in a shelf system and a drive, or data transfer interface, to complete storage operations for a host computer. The library can further include a controller for causing an audit to be performed to create an inventory of the locations. The audit can be stored in nonvolatile memory prior to the power transition. The inventory information can be transmitted to a host computer after the power transition.

Abstract: A robotic system that includes a plurality of robots that are linked to a plurality of remote stations. The robots have an input device and software that allows control of another robot. This allows an operator in close physical proximity to a robot to operate another robot. Each robot can be either a master or slave device.

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

Abstract: A method for remotely monitoring a patient. The method includes generating and transmitting input commands to the robot from a remote station. The remote station may include a personal computer that is operated by a doctor. The input commands can move the robot so that a video image and sounds of the patient can be captured by a robot camera and microphone, respectively, and transmitted back to the remote station. The robot may also have a monitor and a speaker to allow for two-way videoconferencing between the patient and a doctor at the remote station. The robot can move from room to room so that a doctor can make “patient rounds” within a medical facility. The system thus allows a doctor visit patients from a remote location, thereby improving the frequency of visits and the quality of medical care.

Abstract: A robotic system that includes a mobile robot linked to a plurality of remote stations. The robot provides both audio and visual information to the stations. One of the remote stations, a primary station, may control the robot while receiving and providing audio and visual information with the remote controlled robot. The other stations, the secondary stations, may also receive the audio and visual information transmitted between the robot and the primary station. This allows operators of the secondary stations to observe, communicate and be trained through the robot and primary station. Such an approach may reduce the amount of travel required to train personnel.

Abstract: A robotic system that includes a remote controlled robot with at least five degrees of freedom and a teleconferencing function. The robot may include a camera, a monitor and a holonomic platform all attached to a robot housing. The robot may be controlled by a remote control station that also has a camera and a monitor. The remote control station may be linked to a base station that is wirelessly coupled to the robot. The cameras and monitors allow a care giver at the remote location to monitor and care for a patient through the robot. The holonomic platform provides three degrees of freedom to allow the robot to move about a home or facility to locate and/or follow a patient. The robot also has mechanisms to provide at least two degrees of freedom for the camera.

Abstract: A robotic system that allows a consultant to provide remote consulting services through a remotely controlled robot. The robot provides a video image to a remote station that is manned by the consultant. The video image may include a therapist performing a therapeutic routine on a patient. The consultant can view the therapeutic routine and provide consultant information such as instructions to modify or otherwise change the routine. The consultant information is transmitted to the robot and conveyed to the therapist. The system allows a consultant to provide consulting services without have to be physically present at the site of the patient. The remote station also allows the consultant to control movement of the robot so that the video image tracks movement of the therapist and/or patient.

Abstract: There is therefore provided, in accordance with a preferred embodiment of the present invention, a robotic system for systematically moving about an area to be covered. The system includes at least one boundary marker (48) located along the outer edge of the area to be covered, a robot (40) with a navigation system (41) and a sensor unit (43). The navigator system (41) navigates the robot (40) in generally straight, parallel lines from an initial location and turns the robot (40) when the robot (40) encounters one of the boundary markers (48), thereby to systematically move about the area to be covered. The sensor unit (43) senses proximity to one of the at least one boundary marker (48).

Abstract: The problem of editing motion data can be solved by providing a way to specify control points (herein called “handles”) along the path of the motion data and to describe the motion data as a combination of layers of information describing the motion in relationship to these handles. A first layer may describe, for each point in the motion data, the distance of the point between the handles. For example, a path between two handles may be defined. Each point in the motion data is closest to a point along that path. That point along the line has a distance to the two handles. These distances may be defined as a percentage of the length of the path. A second layer may describe the offset of points in the motion data from the line between the two handles.

Abstract: A robot adapted to operate in association with an interface surface having disposed therein or thereon coded data indicative of a plurality of reference points of the interface surface, the robot comprising: movement means to allow the robot to move over the interface surface; a sensing device which senses at least some of the coded data and generates indicating data indicative of a position of the robot on the interface surface; communication means to transmit the indicating data to a computer system running a computer application, and to receive movement instructions from the computer application; and, a marking device adapted to selectively mark the interface surface in response to marking instructions received from the computer application.

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

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

Abstract: A robot controller for teaching a robot with high efficiency. The robot controller including command storage unit (21) where a movement command and a work command are stored, command identifying unit (24) for discriminating between the movement and work commands, unit (22) for making/editing a series of work programs or discrete work programs by a combination of the commands, work program storage units (23) where the work programs are stored so as to control the robot according to the stored program, further including a work section identifying unit (25) for identifying a work section of the work program by way of the command identification unit (24) and work section automatic stopping unit (27) for automatically stopping or suspending the execution of the work program at the work section in a standby state when the work section identifying unit (25) identifies the work section during the execution of the work program.

Abstract: A system for wafer handling employing a complex numerical method for calculating a path of wafer travel that controls wafer acceleration and jerk, and results in maximum safe speed of wafer movement from a first point to a second point. Motion is begun along a straight line segment while accelerating to a first path velocity. During this acceleration, the system computer calculates a series of straight line segments and interconnecting sinusiodally shaped paths over which the wafer is to be guided to the second point. The straight line segments and sinusiodally shaped paths are calculated so as to minimize total path length and the time required to move the wafer from the first point to the second point. The system computes the point of entrance and exit to and from each straight and sinusoidal path.

Abstract: A gap welding process (10) for manipulating a movable robotic welder (30) for making a weld between two or more substantially immovable work pieces (51) using a higher level programming language (20). The gap welding process (10) performs a data transfer routine which takes spreadsheet data (18) representing expected variables, runs a data conversion program (20) that creates weld program data including point position, user frames (34 and 36), weld schedule, seam tracking schedule, weave schedule, azimuth orientation, travel speed, wait time, weave type and number of digital output control data. The gap welding process (10) also performs a gap-sensing routine (28) for actual weld gap measuring by using the robotic welder (30) to touch specific locations on pieces forming the gap or fixturing to produce weld variance data.

Abstract: A teleoperator system with telepresence is shown which includes right and left hand controllers (72R and 72L) for control of right and left manipulators (24R and 24L) through use of a servomechanism that includes computer (42). Cameras (46R and 46L) view workspace (30) from different angles for production of stereoscopic signal outputs at lines (48R and 48L). In response to the camera outputs a 3-dimensional top-to-bottom inverted image (30I) is produced which, is reflected by mirror (66) toward the eyes of operator (18). A virtual image (30V) is produced adjacent control arms (76R and 76L) which is viewed by operator (18) looking in the direction of the control arms. Use of the teleoperator system for surgical procedures also is disclosed.

Abstract: A robot (1) is provided which includes a situated behaviors layer (SBL) (58). This SBL (58) is formed in the form of a tree structure in which a plurality of schemata (behavior modules) is connected hierarchically in such a matter that the schemata are highly independent of each other for each of them to behave uniquely. A patent schema can define a pattern in which child schemata are connected, such as an OR type pattern in which the child schemata are caused to behave uniquely, AND type pattern in which the plurality of child schemata are caused to behave simultaneously or a SEQUENCE type pattern indicating a sequence in which the plurality of child schemata should behave, thereby permitting to select a behavior pattern of the robot (1). Also, a new child schema can additionally be included in the SBL (58) without having to rewrite the schemata connection in the tree structure, whereby a new behavior or function can be added to the robot (1).

Abstract: An apparatus that controls the action of a pet robot. The apparatus includes a portable terminal (3) having an electrode that may contact a user (2). When the user touches the electrode provided on the head of the robot (1), the user ID stored in the memory section of the portable terminal (3) is transmitted to the robot (1) through the user (2). The robot (1) retrieves the information associated with the user ID it has received, thereby identifying the user (2). The robot (1) may determine that the user (2) touched it in the past. In this case, the robot (1) performs an action in accordance with the information about what the user (2) did to it in the past.

Abstract: A method of processing objects using a bilateral architecture. The method comprises the steps of: arranging a plurality of instruments around a bi-directional conveyance device, the instruments spaced at fixed pitch intervals along the conveyor device; assigning dedicated movers to each of the instruments, the dedicated movers for loading and unloading of the objects to and from the instruments and the conveyance device; and controlling the operation of the conveyance device to have an interrupted motion, the interrupted motion for co-ordinating the loading and unloading of the objects; wherein the dedicated movers are positioned such that adjacent movers operate independently of one another. The method can be operated on an automated robotic system having a modular architecture.