Abstract: A robot control apparatus includes an actuator; a generator unit; a first detection unit; a first computation unit to compute current positional data of the arm; a second computation unit to compute an input value; a third computation unit to compute an estimation value of a driving torque for driving the actuator; a fourth computation unit to compute a difference between the estimation value of the driving torque and a true value of the driving torque; and a second detection unit to detect a disturbance applied to the arm, wherein the second detection unit includes an update unit to estimate a parameter of a time-series model and updating the time-series model of the first sampling period by applying the parameter, and a determination unit to determine whether a disturbance occurs, by comparing the time-series model of the first sampling period with a time-series model of a second sampling period.

Abstract: A method of confining a robot in a work space includes providing a portable barrier signal transmitting device including a primary emitter emitting a confinement beam primarily along an axis defining a directed barrier. A mobile robot including a detector, a drive motor and a control unit controlling the drive motor is caused to avoid the directed barrier upon detection by the detector on the robot. The detector on the robot has an omnidirectional field of view parallel to the plane of movement of the robot. The detector receives confinement light beams substantially in a plane at the height of the field of view while blocking or rejecting confinement light beams substantially above or substantially below the plane at the height of the field of view.

Abstract: A system and method can provide a command and control paradigm for integrating robotic assets into human teams. By integrating sensor to detect human interaction, movement, physiology, and location, a net-centric system can permit command of a robotic platform without an OCU. By eliminating the OCU and maintaining the advantages of a robotic platform, a robot can be used in the place of a human without fatigue, being immune to physiological effects, capable of non-humanoid tactics, a longer potential of hours per day on-station, capable of rapid and structured information transfer, has a personality-free response, can operate in contaminated areas, and is line-replaceable with identical responses. A system for controlling a robotic platform can comprise at least one perceiver for collecting information from a human or the environment; a reasoner for processing the information from the at least one perceiver and providing a directive; and at least one behavior for executing the directive of the reasoner.

Abstract: In a minimally invasive surgical system, a hand tracking system tracks a location of a sensor element mounted on part of a human hand. A system control parameter is generated based on the location of the part of the human hand. Operation of the minimally invasive surgical system is controlled using the system control parameter. Thus, the minimally invasive surgical system includes a hand tracking system. The hand tracking system tracks a location of part of a human hand. A controller coupled to the hand tracking system converts the location to a system control parameter, and injects into the minimally invasive surgical system a command based on the system control parameter.

Abstract: A robot, a station, system and method therefor is described. The docking system includes, among other items, a robot and a docking station. The robot may have a power storage unit configured to supply power for the robot, a docking terminal group having a first docking terminal and a second docking terminal, and a robot control unit configured to control working state of the robot. The docking station includes a conductive terminal group comprising at least a first conductive terminal and a second conductive terminal. The conductive terminal group is configured to be electrically connected to the docking terminal group respectively. The robot control unit comprises a signal transmission module configured to be electrically connected to the first docking terminal and send a predetermined detection signal, a signal receiving module configured to be electrically connected to the second docking terminal.

Abstract: A control device (1) for a robot arm (8) which, if a person approach detection unit (3) detects approach of a person, performs control according to an impact between the robot arm (8) and the person. The control performed according to the impact is performed through an impact countermeasure motion control unit (4) and by setting individual mechanical impedances for respective joint portions of the robot arm (8) based on a movement of the person detected by a human movement detection unit (2).

Abstract: The different advantageous embodiments may provide an apparatus that may comprise a number of robotic platforms, a wireless communications system, and a computer system. The number of robotic platforms may be configured to move to a number of locations in an assembly area and interact with a number of robotic devices. The wireless communications system may be configured to provide communication with the number of robotic platforms and the number of robotic devices within the assembly area. The computer system may be configured to exchange information with the number of robotic platforms and the number of robotic devices using the wireless communications system.

Abstract: A package having a recessed section, a sensor element arranged in the recessed section and having a piezoelectric material, a lid joined to the package and sealing the recessed section of the package are provided. The package has a first hollow portion which a part of the sensor element fits with, on an inner bottom surface of the recessed section. The lid has a second hollow portion which a part of the sensor element fits with.

Abstract: A method of navigating an autonomous mobile device to a base station is provided. In the method, when a detector detects a navigating signal sent out by the base station, the mobile device rotates in a first direction until the detector fails to detect the navigating signal, and a first time point is set at this time. Then, the mobile device rotates in a second direction opposite to the first direction until the detector fails to detect the navigating signal, and a second time point is set at this time. Afterward, the mobile device rotates in the first direction by a time computed based on the first and second time points to make the detector face the base station, and then, moves toward a direction pointed by the detector.

Abstract: A method and apparatus for applying sealant. The apparatus may comprise a sealant flow control system. The sealant flow control system may be configured to engage a nozzle of a sealant container to reduce a flow of sealant from the nozzle.

Abstract: A simply-structured initial slippage detection mechanism. When a contact member comes in contact with a contact receiving member via a pressure-sensitive conductive sheet, it is confirmed, on the basis of a change in resistivity of the pressure-sensitive conductive sheet and in response to a detection signal transmitted from the pressure-sensitive conductive sheet, that initial slippage has occurred right before the occurrence of slippage displacement, at a time when a high-frequency waveform component generated right before the occurrence of the slippage displacement of the contact member exceeds a predetermined threshold value. Therefore, it is possible to realize a slippage detection device whose slippage detection section is smaller, more lightweight and thinner.

Abstract: The invention relates to a medical workstation and an operating device (1) for the manual movement of a robot arm (M1-M3). The operating device (1) comprises a controller (5) and at least one manual mechanical input device (E1-E3) coupled to the controller (5). The controller (5) is designed to generate signals for controlling a movement of at least one robot arm (M1-M3) provided for treating a living being (P) based on a manual movement of the input device (E1-E3) such that the robot arm (M1-M3) carries out a movement corresponding to the manual movement. The input device (E1, E2) comprises at least one mechanical damping unit (27, 40), which generates a force and/or torque during a manual movement of the input device (E1, E2) for at least partially suppressing a partial movement resulting from a tremor of the person operating the input device (E1, E2).

Abstract: A shear force detection device for detecting a shear force includes: a support body including an opening defined by a pair of straight parts perpendicular to a detection direction of the shear force and parallel to each other; a support film on the support body and closing the opening, the support film having flexibility; a piezoelectric part on the support film and extending astride an inside and outside of the opening and along at least one of the pair of straight parts of the opening when viewed in a plane in which the support body is seen in a substrate thickness direction, the piezoelectric part being bendable to output an electric signal; and an elastic layer covering the piezoelectric part and the support film.

Abstract: A shear force detection device for detecting a shear force includes: a support body including an opening defined by a pair of straight parts perpendicular to a detection direction of the shear force and parallel to each other; a support film on the support body and closing the opening, the support film having flexibility; a piezoelectric part on the support film and extending astride an inside and outside of the opening and along at least one of the pair of straight parts of the opening when viewed in a plane in which the support body is seen in a substrate thickness direction, the piezoelectric part being bendable to output an electric signal; and an elastic layer covering the piezoelectric part and the support film.

Abstract: This invention provides a device for checking the performance of an image-guided radiation therapy (IGRT) apparatus. The device (referred to here as a phantom) has a central body with detectable markers, rotatably suspended on a ball joint so that the pitch, roll, and yaw may be adjusted. The body is secured against a base plate, which in turn may be positioned laterally, longitudinally, and vertically within the patient treatment area. Thus, the phantom can be adjusted through six degrees of freedom so as to simulate patient positioning. To perform quality control, the phantom is secured at a predetermined offset, and the position is detected by the IGRT apparatus. The robotic couch is then allowed to compensate, a second measurement is made. The measured values are compared with the predetermined offset to assess both the accuracy in detecting the position of the phantom, and the accuracy of the mechanical correction.

Abstract: A conveying device capable of sequentially and efficiently picking up a plurality of randomly located rods, and conveying the picked up rod to a predetermined place, without using a complicated mechanism. A sucking unit has a nozzle attached to a robot hand, and is configured to move the nozzle close to an end of a first cylindrical portion of a rod to be picked. The nozzle is configured to hold the rod by being lifted while sucking the first portion within the nozzle.

Abstract: The present invention relates to a system and method for information process and motor control using artificially constructed apparatus. More specially, the present invention provides a system and method that can process nature language and other informational input including visual, audio and other sensory inputs and respond intelligently.

Abstract: In a coupled control mode, the surgeon directly controls movement of an associated slave manipulator with an input device while indirectly controlling movement of one or more non-associated slave manipulators, in response to commanded motion of the directly controlled slave manipulator, to achieve a secondary objective. By automatically performing secondary tasks through coupled control modes, the system's usability is enhanced by reducing the surgeon's need to switch to another direct mode to manually achieve the desired secondary objective. Thus, coupled control modes allow the surgeon to better focus on performing medical procedures and to pay less attention to managing the system.

Abstract: In accordance with various embodiments, a user-guidable robot appendage provides haptic feedback to the user.

Abstract: Robots may manipulate objects based on sensor input about the objects and/or the environment in conjunction with data structures representing primitive tasks and, in some embodiments, objects and/or locations associated therewith. The data structures may be created by instantiating respective prototypes during training by a human trainer.

Abstract: A robot cleaner and a method for controlling a robot cleaner are provided. The method may include sensing a stored value of a pulse width modulation (PWM) duty ratio based on a voltage of a battery; comparing a measured value of the PWM duty ratio with the stored value to calculate a difference between the measured value and the stored value; upon determining that the difference between the measured value and the stored value is equal to or greater than a first set value, calculating a distributed value of acceleration on a substantially vertically extending axis of the robot cleaner; and, upon determining that the distributed value of acceleration deviates from a range of a second set values, increasing a force to suction foreign matter.

Abstract: A supporting head is provided with binaural artificial ears. Each binaural artificial ear comprises an auricle-shaped structure and a microphone. In order to enhance auditory localization cues, at least an upper part of the head is provided with an acoustically dampening surface.

Abstract: The invention is related to methods and apparatus that use a visual sensor and dead reckoning sensors to process Simultaneous Localization and Mapping (SLAM). These techniques can be used in robot navigation. Advantageously, such visual techniques can be used to autonomously generate and update a map. Unlike with laser rangefinders, the visual techniques are economically practical in a wide range of applications and can be used in relatively dynamic environments, such as environments in which people move. One embodiment further advantageously uses multiple particles to maintain multiple hypotheses with respect to localization and mapping. Further advantageously, one embodiment maintains the particles in a relatively computationally-efficient manner, thereby permitting the SLAM processes to be performed in software using relatively inexpensive microprocessor-based computer systems.

Abstract: A robotic claw includes a sleeve, a rod, a plurality of balls and a plunger. The sleeve comprises a mounting portion and a clamping portion. A mounting hole defined at an end of the mounting portion. A plurality of receiving through holes defined in the clamping portion, and an assembling hole communicating with the receiving through hole, and is defined at an end of the clamping portion. The balls are movably received in the receiving through holes correspondingly. The rod comprises an urging portion movably received in the sleeve to push the balls toward the receiving through holes. The plunger seals the assembling hole to prevent the balls from dropping out of the receiving through holes, and the balls can be mounted in the receiving through holes through the assembling hole.

Abstract: The systems and methods are directed to mechanical arms and manipulators, and more particularly, to optical distance sensors in use for approach, grasping and manipulation. The system may include a manipulator having an arm and a multi fingered end-effector coupled to the distal end of the arm. The end-effector may include an optical proximity sensor configured to detect the distance to an object prior to contact with the object. The end-effector may include an optical proximity sensor configured detect a measurement of force applied to the object by the manipulator post contact with the object. The measurement of force may be a range of force measurements including a minimum, a maximum and a measurement between or within the minimum and the maximum.

Abstract: A sensor relay control device generates feedback data based on sensor data including a plurality of components and being output by an external sensor installed at a portion of a joint of a robot and is connected to a robot control device that executes feedback control of the robot based on the feedback data. The sensor relay control device includes: a generating unit that imports sensor data output by the external sensor and performs coordinate conversion; a synchronizing unit that synchronizes the control data of each axis of the motors with a control cycle of the robot control device; and an outputting unit that outputs the control data of each axis of the motors synchronized with the control cycle of the robot control device to the robot control device as the feedback data.

Abstract: A piezoelectric debris sensor and associated signal processor responsive to debris strikes enable an autonomous or non-autonomous cleaning device to detect the presence of debris and in response, to select a behavioral mode, operational condition or pattern of movement, such as spot coverage or the like. Multiple sensor channels (e.g., left and right) can be used to enable the detection or generation of differential left/right debris signals and thereby enable an autonomous device to steer in the direction of debris.

Abstract: A method of generating a 3D complex octree map. A plurality of points each having 3D location information are detected from a range image. A space having the detected plurality of points is represented using grids. If points in a grid forms a plane, the grid is not subdivided and planar information about the plane is stored. A space not forming a plane is subdivided, thereby enhancing the storage efficiency.

Abstract: A computer program product and an apparatus for preparing a moving program for controlling the operation of a working robot which can move a known working apparatus relative to a workpiece and which can perform desired work on the workpiece. Movement information of the working apparatus may be input to a text entry screen on a character basis. Movement information of the working apparatus may also be input via a figure entry screen as a path on a two-dimensional plane in correlation with height information. The movement information that is input on the text entry screen is output in real time as the path on the two-dimensional plane and the height information thereof on the figure entry screen. The movement information that is input on the figure entry screen is output in real time to the text entry screen on the character basis.

Abstract: Provided is an apparatus for executing a robot task using a robot model definition. A task execution apparatus include: a storage unit to store at least one robot model, at least one robot behavior, and at least one robot task; and a task execution unit to generate at least one execution object from the stored at least one robot model, at least one robot behavior, and at least one robot task, and to execute a task of a robot from a corresponding execution object among the generated at least one execution object in response to an execution command input from a user.

Abstract: An apparatus in an example comprises a manipulator, a force sensor, a signal modulator, and a visual indicator. The manipulator is employed by a user. The force sensor determines a force signal from a force applied by the manipulator on a part of an environment of the user. The signal modulator is adjustable by the user to select a switch point for the visual indicator based on relative fragility of the part of the environment. The signal modulator employs the force signal and the switch point to control the visual indicator for the user.

Abstract: A robotic system includes: a detection unit that detects at least one of a voice, light and an image of a content outputted by a content output device; a decision unit that assesses information detected by the detection unit on the basis of reference data so as to assess the content outputted by the content output device; and a control unit that controls a behavior or a state of the robotic system on the basis of the assessment made by the decision unit.

Abstract: A brain-based device (BBD) for moving in a real-world environment has sensors that provide data about the environment, actuators to move the BBD, and a hybrid controller which includes a neural controller having a simulated nervous system being a model of selected areas of the human brain and a non-neural controller based on a computational algorithmic network. The neural controller and non-neural controller interact with one another to control movement of the BBD.

Abstract: A surgical robotic system is provided including at least one robotic unit that is mechanically self-contained such that the robotic unit is movable on a bodily surface inside a patient's body independently of any structure positioned outside of the patient's body, and a control device positioned remotely from the at least one robotic unit, wherein said control device transmits commands that manipulate the at least one robotic unit inside the patient's body. A method of performing a robotically assisted medical procedure is also provided, including positioning at least one robotic unit inside a patient's body, moving the robotic unit on a bodily surface inside the patient's body by transmitting commands thereto via a control device that is positioned remotely from the at least one robotic unit, and actuating at least one medical tool positioned on the robotic unit via the control device.

Abstract: A robot cleaner that travels straight through alignment of drive wheels to move the robot cleaner and a method of controlling travel of the same. Information related to a movement angle of the robot cleaner is detected from angle information of a caster wheel rotating depending upon a state of a floor, such as a carpet in a state in which texture of the carpet occurs in one direction, and, when the movement angle of the robot cleaner deviates due to slippages of the drive wheels, rates of rotation of the drive wheels are adjusted to correct the slippages of the drive wheels such that the robot cleaner easily travels straight.

Abstract: The present disclosure is related to an exemplary robot manipulator system having a robot manipulator with a kinematic chain of stiff robot manipulator segments, which are linked together by hinged joints. A robot controller controls execution of a robot program. At least one temperature sensor provides measured temperature values. At least one heatable cover is attached onto at least one manipulator segment for applying heat energy thereon, with an amount of heat energy being controlled dependent on measured temperature values of the at least one temperature sensor.

Abstract: Awareness of a device, such as a robot, to proximate humans (or other moving object) is manifested by a visual signal aligned with—i.e., aimed at—the human. For example, an illumination system may take the form of a closed or partial ring around which lighting elements may be selectively activated.

Abstract: Described embodiments include a system and an apparatus. A described mobile robotic device includes a mobile chassis configured to travel on a transmission line of a power transmission system. The mobile robotic device includes an inspection module physically associated with the mobile chassis and configured to automatically inspect a structure associated with the power transmission system. The mobile robotic device includes a risk-assessment module physically associated with the mobile chassis and configured to assess a potential risk to the power transmission system in response to inspection data provided by the inspection module. The mobile robotic device includes a communication module physically associated with the mobile chassis and configured to output data indicative of the assessed potential risk.

Abstract: A robot includes: an arm; a driving source that pivots the arm; an angle sensor that detects a pivot angle and outputs pivot angle information; an inertia sensor that is attached to the arm and outputs inertial force information; a control command generating unit that outputs a control command defining rotational operation of the arm; a control conversion determining unit that determines whether the inertial force information is used when the driving source is controlled; and an arm operation control unit that performs a first control based on the control command, the pivot angle information, and the inertial force information, if the control conversion determining unit determines that the inertial force information should be used, and performs a second control based on the control command and the pivot angle information, if the control conversion determining unit determines that the inertial force information should not be used.

Abstract: A method for training a robot to execute a robotic task in a work environment includes moving the robot across its configuration space through multiple states of the task and recording motor schema describing a sequence of behavior of the robot. Sensory data describing performance and state values of the robot is recorded while moving the robot. The method includes detecting perceptual features of objects located in the environment, assigning virtual deictic markers to the detected perceptual features, and using the assigned markers and the recorded motor schema to subsequently control the robot in an automated execution of another robotic task. Markers may be combined to produce a generalized marker. A system includes the robot, a sensor array for detecting the performance and state values, a perceptual sensor for imaging objects in the environment, and an electronic control unit that executes the present method.

Abstract: A robot includes: an arm driven by a motor; an angle sensor that detects a pivoting angle of the motor; an inertia sensor that detects an inertial force acting on the arm; a noise detecting unit that detects a noise frequency of the inertia sensor from both an output of the angle sensor and an output of the inertia sensor; a filter-constant determining unit that determines a characteristic of a filter from information of the noise detecting unit; and the filter that removes noise of the inertia sensor on the basis of the filter-constant determining unit.

Abstract: A clamp replacing apparatus includes a robot arm, a clamp and a connecting assembly configured for detachably connecting the clamp to the robot arm. The connecting assembly includes a first rotator and a second rotator. The first rotator is fixed to the robot arm and comprises a number of first locking portions each defining a receiving groove. The second rotator is fixed to the clamp and comprises a number of second locking portions corresponding to the first locking portions and each defining a bolt portion. The bolt portion can be received in the corresponding receiving groove or escaped from the receiving groove.

Abstract: An automatic veering structure for a floor cleaning apparatus comprises a driving wheel set to control moving direction of the floor cleaning apparatus, an auxiliary wheel set and a buffer module. It also has a detection module to detect whether the auxiliary wheel set is suspended in the air and whether the buffer module bumps into an obstacle, then output a first detection signal and a second detection signal to a control module to determine whether to trigger the driving wheel set to drive the floor cleaning apparatus to veer to prevent the floor cleaning apparatus from suspending and falling, or stopping moving when encounters the obstacle. Thus the lifespan of the floor cleaning apparatus is lengthened and cleaning efficiency improves.

Abstract: A system is employed for defining a position (location) of a receiving element inside an area surrounded by a wire loop, along the perimeter (a perimeter wire loop), of a work area or other bounded area. In particular, the system can determine whether the receiver is inside or outside the loop, and evaluate its distance from the perimeter wire.

Abstract: Methods and systems for representing information associated with an object in an area are provided. An example method includes determining a high-resolution representation of information associated with an area in which a robotic device is configured to operate. The high-resolution representation of information may include data associated with an object in the area and an indication of an occurrence of an update to the data. The method may further include determining a proximity of the robotic device to the object in the area. According to the method, when the proximity is less than a proximity threshold or the occurrence of the update is greater than an age threshold, a low-resolution representation of information associated with the area may be determined and provided to the robotic device.

Abstract: A mobile robot including a robot body, a drive system supporting the robot body, and a controller in communication with the drive system. The robot also includes an actuator moving a portion of the robot body through a volume of space adjacent the mobile robot and a sensor pod in communication with the controller. The sensor pod includes a collar rotatably supported and having a curved wall formed at least partially as a surface of revolution about a vertical axis. The sensor pod also includes a volumetric point cloud sensor housed by the collar and observing the volume of space adjacent the robot from within the collar along an observation axis extending through the curved wall. A collar actuator rotates the collar and the volumetric point cloud sensor together about the collar axis.

Abstract: A navigational control system for altering movement activity of a robotic device operating in a defined working area, comprising a transmitting subsystem integrated in combination with the robotic device, the transmitting subsystem comprising means for emitting a number of directed beams, each directed beam having a predetermined emission pattern, and a receiving subsystem functioning as a base station that includes a navigation control algorithm that defines a predetermined triggering event for the navigational control system and a set of detection units positioned within the defined working area in a known spaced-apart relationship, the set of detection units being configured and operative to detect one or more of the directed beams emitted by the transmitting system; and wherein the receiving subsystem is configured and operative to process the one or more detected directed beams under the control of the navigational control algorithm to determine whether the predetermined triggering event has occurred, an

Abstract: A system for controlling a human-controlled proxy robot surrogate is presented. The system includes a plurality of motion capture sensors for monitoring and capturing all movements of a human handler such that each change in joint angle, body posture or position; wherein the motion capture sensors are similar in operation to sensors utilized in motion picture animation, suitably modified to track critical handler movements in near real time. A plurality of controls attached to the proxy robot surrogate is also presented that relays the monitored and captured movements of the human handler as “follow me” data to the proxy robot surrogate in which the plurality of controls are configured such that the proxy robot surrogate emulates the movements of the human handler.

Abstract: The inventive concept of the metrology system (the system) actively determines the 6 Degree of Freedom (6-DOF) pose of a motion device such as, but not limited to, an industrial robot employing an end of arm tool (EOAT). A concept of the system includes using laser pointing devices without any inherent ranging capability in conjunction with the EOAT-mounted targets to actively determine the pose of the EOAT at distinct work positions of at least one motion device.

Abstract: A wearable robot may be worn by a user to record or teach a motion, including a motion such as sign language. The wearable robot includes a mode to record sign language data in a system by a sign language expert wearing the wearable robot and a mode to teach the sign language data recorded in the system to a sign language learner wearing the wearable robot. A user who wishes to learn sign language may easily learn sign language. In particular, a disabled person, who has poor eyesight and is unable to watch a video that teaches sign language, may learn sign language very intuitively using the wearable robot. Further, a user who has normal eyesight may also learn sign language more easily than from using a video which teaches sign language or from a sign language expert.