Abstract: Via intuitive interactions with a user, robots may be trained to perform tasks such as visually detecting and identifying physical objects and/or manipulating objects. In some embodiments, training is facilitated by the robot's simulation of task-execution using augmented-reality techniques.

Abstract: A device for programming an handling apparatus, an industrial robot in particular, having an operating unit situated on an arm of the handling apparatus, which is able to be moved by an operator for programming motion sequences together with the arm to different positions, especially processing positions, having input devices on the operating unit for detecting at least positions of the arm, preferably in the form of input keys, the operating unit being connected to a control device for the handling apparatus; and data transmitted via input devices of the operating unit to the control device being displayed to the operator via a monitoring unit. The input devices are additionally used for controlling and operating display menus and input menus stored in the control device, the display menus and the input menus being displayed on the monitoring unit.

Abstract: The present invention relates to a method and a system for controlling a robotic device for inserting or removing rod-like elements into or from a storage frame, the rod-like elements, like smoking bars, serving for storing products, like sausages, each having a sausage-shaped body and a loop for a pendulously storage of the products. The method comprises the steps of moving the storage frame into the operating range of the robotic device, picking up a rod-like element on which a number of sausage like products are hung up by the robotic device, and inserting or removing the rod-like element into or from the storage frame by the robotic device. Moreover, there is provided a storage frame with at least a machine readable label from which information regarding the storage device are read out from the machine readable label, which is attached to the storage device, at least before the storage frame is moved into the operating range of the robotic device.

Abstract: When an operation instruction is input by a first (second) control output instruction input device, locus calculation means calculates a locus of movement of a first (second) therapeutic device on the basis of any one of joint sections, which is instructed to operate. On the basis of a calculation result by the locus calculation means, therapeutic device operation control means controls an operation of the first (second) therapeutic device by a first (second) active mechanism. Thereby, there is provided an endoscope apparatus which can improve the operational efficiency and positional precision of the therapeutic device.

Abstract: Method and system for telematic control of a slave device (402) includes a hand control (101) type control interface which includes a hand grip (102) having an elongated body (202). One or more sensors (208) are provided for sensing a physical displacement of a trigger (212) disposed on the hand grip. An actuator or motor (206) is disposed in the hand grip that is responsive to a control signal from a control system (401) for dynamically controlling a force applied by the trigger to a user of the hand control interface.

Abstract: Methods and systems are provided that may help a robot provide contextual filtering of environmental information, such that the robot may be able to base its actions upon environmental data that is relevant to the device's context.

Abstract: A robot arm system for controlling a motion of a robot arm includes an order determining section for determining an order of teaching information based on at least one or more pieces of perceptual information about circumference environment of the robot arm used by a person to operate the robot arm and change the motion of the robot arm that is sensed by the person, reaction time information as time information from a time when the person receives the perceptual information to a time when the person operates robot arm, and dispersion information about a dispersion level between at least one or more pieces of the teaching information or the perceptual information, and creates motion information about the robot arm based on the teaching information and the order determined by the order determining section.

Abstract: A remote control station that controls a robot through a network. The remote control station transmits a robot control command that includes information to move the robot. The remote control station monitors at least one network parameter and scales the robot control command as a function of the network parameter. For example, the remote control station can monitor network latency and scale the robot control command to slow down the robot with an increase in the latency of the network. Such an approach can reduce the amount of overshoot or overcorrection by a user driving the robot.

Abstract: Continuous change of state directions are graphically provided on a display screen to assist a user in performing necessary action(s) for transitioning between operating modes in a medical robotic system or performing corrective action. A graphical representation of a target state of an element of the medical robotic system is displayed on a display screen viewable by the user. Current states of the element and indications directing the user to manipulate the element towards the target state are continuously determined and graphical representations of the continuously determined current states and indications are displayed on the display screen along with that of the target state.

Abstract: Robotic posture transfer assist devices for assisting a posture transfer of a patient in a bed may include a device body, a stabilizer coupled with the device body and the bed, and at least one robotic arm having a plurality of degrees of freedom, wherein the robotic arm may be coupled with the device body. Robotic posture transfer assist devices may further include an end-effector removably coupled with the robotic arm, a controller module that provides a control signal to the robotic arm to control a movement of the robotic arm about the plurality of degrees of freedom, and a user input device that provides a command signal to the controller module to command the movement of the robotic arm, wherein the control signal provided by the controller module corresponds with the command signal.

Abstract: A device and method for optimizing a programmed movement path for an industrial robot holding a tool to carry out work along the path during a work cycle. The movement path includes information on positions and orientations for the tool at a plurality of target points on the movement path. The method includes for at least one of the target points: receiving a tolerance interval for the orientation of the tool in the target point, determining movements of the robot between the target point and one or more of the other target points on the path for a plurality of different tool orientations within the tolerance interval, selecting one of the different tool orientations as the tool orientation for the target point based on the determined movements of the robot and with regard to minimizing cycle time, and generating a robot program based on the selected orientation of the tool at the target point.

Abstract: A transfer robot for accommodating and transferring a transferred object has a transfer route storage section, a movement mechanism section, and a security level setting section. The transfer route storage section stores a transfer route having been set up at least on the basis of transfer destination information for the transferred object. The movement mechanism section causes the transfer robot to move toward a transfer destination on the basis of the transfer route. The security level setting section switches a security level of the transfer robot under movement on the basis of a zone level defined beforehand by each region in the transfer route, present position information of the transfer robot, and type information of the transferred object.

Abstract: A remote control unit configured to wirelessly control a mobile robot moving through an environment and having a robot camera. The remote control unit comprises a privacy button operable by a local user and configured to engage a privacy mode of the mobile robot, and a wireless transmitter configured to emit a wireless control signal to the mobile robot based on input from a keypad of the RC unit. The wireless control signal is configured to cause the robot camera to block the field of view of the robot camera such that the environment of the mobile robot is obscured when the privacy mode of the mobile robot is engaged.

Abstract: An approach is provided to move an object across a surface using a grid of vertically-adjustable low friction transfer modules. A first set of transfer modules is selected from the grid, with the first set of modules being underneath the object. Back-side and front-side sets of modules are identified from the selected first set of modules, with the back-side sets being toward the back of the object opposite to the horizontal direction and the front-side sets being toward the front side of the object that faces the horizontal direction. The back-side and front-side sets are vertically adjusted so that the average of the back-side sets of vertical heights is higher than the average of the front-side sets of vertical heights. The vertical adjustment of the transfer modules causes the object to move across the tops of the transfer modules in the horizontal direction.

Abstract: A control method for a balancing lifting gear which includes a lifting motor that can be actuated by a controller and uses a control handle with a force sensor to lift and lower a load-supporting device. In a “Balance” operating mode, the load-supporting device, with or without a picked-up load, is raised or lowered by the controller in response to a force applied by an operator. In order to ensure disturbance-free handling of a load when removing or attaching a load, a “Pick-up” operating mode or an “Assemble” operating mode is selected, in which the load-supporting device is moved independently without the influence of the force of the operator by the controller in the lifting or lowering direction in dependence upon the signals determined by the force sensor. A balancing lifting gear which operates in accordance with the aforementioned control method is also disclosed.

Abstract: The invention relates to a telepresence system (1) with a human-machine interface (2), and with a teleoperator (3) designed to communicate bid sectionally with the human-machine interface (2) via a communications channel (4).

Abstract: Methods, devices (such as computer readable media), and systems (such as computer systems) for performing movements of a tool of a medical robot along a single axis that are achieved by electronically limiting the medical robot's movement to produce movement of the tool along the single axis rather than mechanically restricting the medical robot's movement to produce the single axis movement. The tool's movement will be along the single axis even if a user is moving an input device linked to the medical robot in other axes during the single axis movement. In addition, techniques are disclosed for automating the single axis movement such that it can be programmed to stop at a target location and start at or near a second (e.g.

Abstract: A method and system to optimize underwater operations utilizing a radio frequency identification (RFID) arrangement. The RFID arrangement includes a plurality of RFID tags positioned on an underwater surface, with each of the plurality of tags coded with unique information related to each tag's location on the underwater surface. The RFID system also includes an RFID reader/interrogator attached to an underwater explorer. When the underwater explorer is within a reading range of a tag, the reader/interrogator reads the unique tag information. The tag information is used to optimize underwater operations performed by the explorer, which may be a diver or a water vessel.

Abstract: A method of navigating a medical device through a body of a patient includes providing a topography of at least a portion of the body, accepting user input defining a navigation path, robotically navigating the medical device to a starting point on the path, and robotically navigating the medical device along the navigation path to an endpoint. Waypoints defining the navigation path may be input on a graphical representation of the topography using a user interface such as a pointing device or touchscreen. The navigation path may also be defined by tracing a substantially continuous path on the graphical representation. A therapy may be administered while robotically navigating the medical device along the navigation path, either forward or in reverse, or while navigating the medical device along a return path defined by a plurality of virtual breadcrumbs generated as the medical device traverses the navigation path.

Abstract: A semi-automatic, interactive robotic system for performing and/or simulating a multi-step task includes a user interface system, a recognition system adapted to communicate with the user interface system, a control system adapted to communicate with the recognition system, and a sensor-actuator system adapted to communicate with the control system. The recognition system is configured to recognize actions taken by a user while the user operates the user interface system and to selectively instruct the control system to cause the sensor-actuator system to perform, and/or simulate, one of an automatic step, a semi-automatic step or direct step of the multi-step task based on the recognized actions and a task model of the multi-step task.

Abstract: A humanoid robot equipped with an interface for natural dialog with an interlocutor is provided. Previously, the modalities of dialog between humanoid robots equipped moreover with evolved displacement functionalities and human beings are limited notably by the capabilities for voice and visual recognition processing that can be embedded onboard said robots. The present disclosure provides robots are presently equipped with capabilities to resolve doubt on a several modalities of communication of the messages that they receive and for combining these various modalities which make it possible to greatly improve the quality and the natural character of dialogs with the robots' interlocutors. This affords simple and user-friendly means for carrying out the programming of the functions making it possible to ensure the fluidity of these multimodal dialogs.

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

Abstract: A robotic system has a plurality of user selectable operating modes. To select one of the operating modes, a user performs a distinguishing action which uniquely identifies a desired operating mode among the plurality of user selectable operating modes. A method implemented by a processor in the robotic system identifies the distinguishing action and places the robotic system in the user selected operating mode.

Abstract: A desired joint torque output limiting unit limits operations of a desired joint torque output unit and a limit cancellation unit cancels the limitation by the output limiting unit. An actuator of a joint of a robot is controlled in accordance with modified desired joint torque outputted from the output limiting unit, so that the robot can be controlled even upon switching between dynamics parameters.

Abstract: A method for positioning a welding head or welding torch of a robot welding system over a workpiece sends microwaves as a measuring signal from a transmitter arranged on the welding head to the workpiece. The microwaves reflected on the workpiece are received by at least one receiver arranged on the welding head, and the received microwaves are evaluated by an evaluation module for determining the position of a workpiece edge. The microwaves are sent from at least one transmitter in different positions on the welding head, and the reflected microwaves are received, with a change of polarization, by the at least one receiver, having a polarization plane arranged at an angle to the polarization plane of the transmitter. The position of the edge is determined by the evaluation module at least on the basis of a phase change of the respective microwaves reflected on the different positions.

Abstract: A robot control system includes a start position storage that stores a start position or orientation in a manual operation, a redundancy trajectory storage that successively stores a position or orientation of optimized redundancy during the manual operation, and a reverse movement controller which performs movement control for changing the position or orientation of a robot hand, which have been changed by the manual operation, in a reverse direction from the current position or orientation to the start position or orientation. The reverse movement controller also performs movement control for reversely changing the position or orientation of the redundancy by following the position or orientation of the redundancy that have been successively stored in the redundancy trajectory storage.

Abstract: A control apparatus for a master-slave robot includes a force correction section detecting unit that detects a section at which force information from at least one of force information and speed information is corrected, and a force correcting unit that corrects the force information at a section detected as a force correction section by the force correction section detecting unit. A small external force applied to a slave manipulator is magnified and transmitted to a master manipulator, or an excessive manipulation force applied to the master manipulator is reduced and transmitted to the slave manipulator.

Abstract: Improved robotic surgical systems, devices, and methods include selectably associatable master/slave pairs, often having more manipulator arms than will be moved simultaneously by the two hands of a surgeon. Four manipulator arms can support an image capture device, a left hand tissue manipulation tool, a right hand tissue manipulation tool, and a fourth surgical instrument, particularly for stabilizing, retracting, tool change, or other functions benefiting from intermittent movement. The four or more arms may sequentially be controlled by left and right master input control devices. The fourth arm may be used to support another image capture device, and control of some or all of the arms may be transferred back-and-forth between the operator and an assistant. Two or more robotic systems each having master controls and slave manipulators may be coupled to enable cooperative surgery between two or more operators.

Abstract: A robotic apparatus that interacts with a user and a personal computer (PC) receives inputs from a user and from the PC and reacts and interacts. The interactive apparatus includes a USB interface with the PC to receive power and data such as key strokes, key combinations, email notifications, and web cam events, for example. The interactive apparatus also includes microphones and a phototransistor to detect sounds and movement. The interactive apparatus includes an eye assembly attached to a body and leg, which is responsive to inputs and interactions with the user and PC.

Abstract: A robotic hand assembly comprising: a hand section comprising: at least one digit provided with at least one actuatable joint; and a control section comprising: at least one actuation device, the at least one actuation device comprising: a sensing module configured to sense a force applied to a tendon coupled at a first end to the at least one actuatable joint; and an actuation module configured to actuate the at least one actuatable joint.

Abstract: A robotic system includes a robot adapted for moving a payload in proportional response to an input force from an operator, sensors adapted for measuring a predetermined set of operator input values, including the input force, and a controller. The controller determines a changing stiffness value of the operator using set of operator input values, and automatically adjusts a level of control sensitivity over the robot using the stiffness value. The input values include the input force, a muscle activation level of the operator, and a position of the operator. A method of controlling the robot includes measuring the operator input values using the plurality of sensors, processing the input values using the controller to thereby calculate the stiffness value, and automatically adjusting the level of control sensitivity over the robot using the stiffness value. A specific operator may be identified, with control sensitivity being adjusted based on the identity.

Abstract: The present invention provides a robot system including a robot having a plurality of move axes and a safeguard apparatus provided independently of a control system of the robot and adapted for limiting a movable range of the robot. The safeguard apparatus includes at least two individual-axis-detection external sensors configured to be respectively turned ON/OFF in response to a rotational position or a transfer position of respective at least two move axes among the plurality of move axes of the robot, and an apparatus body configured to limit a move of the robot based on a combination of ON/OFF conditions of at least two output signals obtained from the at least two individual-axis-detection external sensors.

Abstract: A coordinated action robotic system may include a plurality of robotic vehicles, each including a platform and at least one manipulator movable relative thereto. The robotic system may also include a remote operator control station that may include a respective controller for each manipulator. The remote operator control station may also include a mapping module to map movement of each manipulator relative to its platform. Operation of the controllers for manipulator movement in a given direction produces corresponding movement of the respective manipulators in the given direction such that the robotic vehicles may be controlled as if they were one robotic vehicle. The coordinated movement may result in increased operational efficiency, increased operational dexterity, and increased ease of controlling the robotic vehicles.

Abstract: Methods and systems for robotic command and operation are provided. In some examples, a robot may be configured to receive a short-form command input that is comprised of an action verb and an object/target, and to analyze contextual/situational data for event outcomes from which the robot can determine an action of a plurality of possible actions to execute. The determination and analyses functions may be performed, in whole or part, through use of a cloud computing system.

Abstract: Continuous change of state directions are graphically provided on a display screen to assist a user in performing necessary action(s) for transitioning between operating modes in a medical robotic system or performing corrective action. A graphical representation of a target state of an element of the medical robotic system is displayed on a display screen viewable by the user. Current states of the element and indications directing the user to manipulate the element towards the target state are continuously determined and graphical representations of the continuously determined current states and indications are displayed on the display screen along with that of the target state.

Abstract: A service providing system according to an embodiment includes a robot unit, an interface that receives input of order input information, and a control unit that is connected to the robot unit and the interface, and causes the robot unit to execute an operation based on the order input information input with the interface. Furthermore, the service providing system receives input of the order input information with the interface, causes the robot unit to execute the processing operation based on the order input information input with the interface, and provides a product on which the processing operation has been performed by the robot unit.

Abstract: A system for calibrating a robotic tool includes a housing including an aperture for receiving the robotic tool, an image generating device disposed in the housing and positioned to generate an image of the robotic tool received through the aperture of the housing, wherein the image generating device generates an image signal representing the image of the robotic tool, a light source disposed in the housing to backlight the robotic tool received through the aperture of the housing, and a processor responsive to the image signal for calculating and monitoring a configuration of the robotic tool.

Abstract: A robot arm provided with a body unit shifting mechanism that connects a base unit and a body unit so as to be relatively shifted, and joint lock mechanisms that are capable of mechanically securing respective joints is disposed on the body unit, and a robot operation control unit controls to switch between a robot arm operation mode in which the robot arm is operated with one of the joints of the robot arm brought into a free state, and a body unit shift mode in which the body unit is shifted with the joint being brought into a locked state.

Abstract: A system and method for ensuring that a large number of connectors, such as fiber-optic cable-connectors, which are plugged-into connector-receptacles arrayed across a connector-panel, are not intentionally disconnected by an un-authorized user with malicious intent, or accidentally unplugged by an authorized technician who may be trying to manually pull-out a specific connector for testing or other purposes but, inadvertently, could otherwise unplug a neighboring connector because of not being able to clearly see which plug is actually being removed due to the large number of cables that are connected to the panel. The connectors are locked in place by restraining arms which are controlled by solenoids or motors. Each restraining arm can be commanded to release its respective connector, but only when the correct command from a computer is received. The same system and method can be applied to connector-receptacles arrayed on one or both sides of the panel.

Abstract: A child-care robot for use in a nursery school associates child behavior patterns with corresponding robot action patterns, and acquires a child behavior pattern when a child behaves in a specified pattern. The robot selects one of the robot action patterns, which is associated with the acquired child behavior pattern, and performs the selected robot action pattern. Additionally, the robot associates child identifiers with parent identifiers, and receives an inquiry message from a remote terminal indicating a parent identifier. The robot detects one of the child identifiers, which is associated with the parent identifier of the inquiry message, acquires an image or a voice of a child identified by the detected child identifier, and transmits the acquired image or voice to the remote terminal. The robot further moves in search of a child, measures the temperature of the child, and associates the temperature with time of day at which it was measured.

Abstract: The present invention relates to a feeding assistant robot, which assists in feeding patients or the elderly and infirm who have difficulty in moving their arms and thus have difficulty in feeding themselves. The feeding assistant robot includes: a picking arm including a gripper for picking up food placed on a tray; a feeding arm, including a spoon on which the food picked up by the picking arm is placed, for moving the spoon to the mouth of a user; an input device enabling the user to direct the movements of the picking arm and of the feeding arm; and a control unit electrically connected to the picking arm, the feeding arm, and the manipulation part to control the movements of the picking arm and the feeding arm according to the commands from the input device.

Abstract: The invention relates to methods and appropriate devices for safely, unequivocally and exclusively, temporarily assigning the command authority of an operator (1) to a controllable technical system (60) using a mobile control device (2) which is technically suitable for periodically controlling a plurality of controllable technical systems (60), which is equipped as standard with safety switch elements (38, 39) such as an emergency stop switch, ok key and operating mode selection switches and for a data coupling with the controllable technical system (60) in spite of having only normal transmission means (6) or network technologies without any particular features specific to safety function.

Abstract: A remote control station that controls a robot through a network. The remote control station transmits a robot control command that includes information to move the robot. The remote control station monitors at least one network parameter and scales the robot control command as a function of the network parameter. For example, the remote control station can monitor network latency and scale the robot control command to slow down the robot with an increase in the latency of the network. Such an approach can reduce the amount of overshoot or overcorrection by a user driving the robot.

Abstract: The invention relates to a control system for a surgical navigation system, wherein the navigation system is associated with a detection unit for detecting system control inputs made by a user, and wherein the navigation system is controlled in accordance with the control inputs and the detection unit comprises a gesture detection for detecting user gestures. The invention also relates to a method for controlling a surgical navigation system, wherein a detection unit for detecting system control inputs made by a user is associated with the surgical navigation system, the navigation system is controlled in accordance with the control inputs, and user gestures are used as said control inputs.

Abstract: A remote-controlled mobile machine has a pair of flexible shafts (10) formed by inserting torque transmission driving wires (11) into tubes (12). One ends of the flexible shafts (10) are respectively connected to power sources (2), and the other ends thereof are respectively connected to a pair of left and right crawler mechanisms (102). The crawler mechanisms (102) are driven/controlled by remote control via the flexible shafts (10) to make the mobile machine travel.

Abstract: A robotic hand controller, having 8 Degrees of Freedom, with force feedback mechanisms in one or more and preferably all available degrees of freedom is provided. The hand controller is used with a plurality of end effectors such as forceps and scissors. The plurality of robotic arms and the plurality of end effectors are controlled by a surgeon working on a robotic console. The robotic console includes the robotic hand controller which allows the surgeon to perform motion in 8 Degrees of Freedom using the end effectors.

Abstract: A system for providing autonomous capabilities to a radio-controlled robot, comprises two communication boxes, one connected to the robot and the other connected to an operator control unit (OCU). Each communication box comprises two radios that are interoperable with preexisting data radios in the robot; a microprocessor unit; and bidirectional attenuators. The system further comprises a software application that runs on the microprocessor unit of each communications box, to integrate data into existing transmission data stream between the robot and OCU, via preexisting data radios. The system enables the issuance of additional commands besides those issued by the OCU, using the original OCU.

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: This invention realizes a speech communication system and method, and a robot apparatus capable of significantly improving entertainment property. A speech communication system with a function to make conversation with a conversation partner is provided with a speech recognition means for recognizing speech of the conversation partner, a conversation control means for controlling conversation with the conversation partner based on the recognition result of the speech recognition means, an image recognition means for recognizing the face of the conversation partner, and a tracking control means for tracing the existence of the conversation partner based on one or both of the recognition result of the image recognition means and the recognition result of the speech recognition means. The conversation control means controls conversation so as to continue depending on tracking of the tracking control means.

Abstract: Continuous change of state directions are graphically provided on a display screen to assist a user in performing necessary action(s) for transitioning between operating modes in a medical robotic system or performing corrective action. A graphical representation of a target state of an element of the medical robotic system is displayed on a display screen viewable by the user. Current states of the element and indications directing the user to manipulate the element towards the target state are continuously determined and graphical representations of the continuously determined current states and indications are displayed on the display screen along with that of the target state.