Abstract: An object correcting method includes disposing multiple sample objects at different positions on a display screen, the sample objects having respective attributes characteristic thereof; obtaining the position of a point on the display screen specified by a user; changing the attribute of a target object by calculating an interpolated value of the attributes of the sample objects based on the positions at which the sample objects are disposed and the position of the point and replacing the value of at least one of the parameters of the attribute of the target object with the calculated interpolated value; and correcting the target object based on the changed attribute thereof.

Abstract: In one embodiment a method to determine a center of gravity of a three dimensional object comprises positioning the object on a test platform in a first orientation, determining a position of the center of gravity along a first axis and a second axis when the object is in the first orientation, rotating the object with respect to a third axis which is orthogonal to the first axis and the second axis, determining a position of the center of gravity along at least one of the first axis or the second axis when the object is in the second orientation, and using a change in the position of the center of gravity along the at least one of the first axis or the second axis when the object is in the second orientation to determine a position of the center of gravity along the third axis. Other embodiments may be described.

Abstract: A method of training a robot to autonomously execute a robotic task includes moving an end effector through multiple states of a predetermined robotic task to demonstrate the task to the robot in a set of n training demonstrations. The method includes measuring training data, including at least the linear force and the torque via a force-torque sensor while moving the end effector through the multiple states. Key features are extracted from the training data, which is segmented into a time sequence of control primitives. Transitions between adjacent segments of the time sequence are identified. During autonomous execution of the same task, a controller detects the transitions and automatically switches between control modes. A robotic system includes a robot, force-torque sensor, and a controller programmed to execute the method.

Abstract: A surgical robot system and a control method thereof include a slave device and a master device to control motion of the slave device. The surgical robot system further includes a monitoring device that inspects a signal transmitted within the system in real time to stop motion of the slave device if an abnormal signal is detected.

Abstract: A teleoperated surgical system includes a surgical instrument with an end effector and a master input device. A servomechanism may be operatively coupled to the end effector to apply a force to the end effector, and at least one processor may operatively couple the servomechanism to the master input device to apply a grip force with the first and second gripping elements in response to input at the master input device. The applied grip force may be based at least in part on a mechanical advantage of the surgical instrument end effector.

Abstract: A grip apparatus includes a robot hand including plural fingers and pressure sensitive conductive rubber provided to the finger and configured to output a detection signal equivalent to acting force. The pressure sensitive conductive rubber is covered by a cover member. The grip apparatus also includes a control unit configured to cause the plural fingers to perform an opening or closing operation and compare a detection value based on the detection signal from the pressure sensitive conductive rubber with a threshold to determine whether the robot hand grips the work or releases the work. During a period from a time when the closing operation is started until a time when the fingers contacts the work, the control unit samples the detection signal of the pressure sensitive conductive rubber and sets the threshold as a value higher than a detection value at a time of this sampling.

Abstract: Devices, systems, and methods for providing increased range of movement of the end effector of a manipulator arm having a plurality of joints with redundant degrees of freedom. Methods include defining a position-based constraint within a joint space defined by the at least one joint, determining a movement of the joints along the constraint within a null-space and driving the joints according to a calculated movement to effect the commanded movement while providing an increased end effector range of movement, particularly as one or more joints approach a respective joint limit within the joint space.

Abstract: A method of designing and manufacturing an acoustic sensor having a high degree of directivity is disclosed. The sensor includes a rotatable plate that is attached to a substrate with mounts. In one aspect the mounts are freely rotatable and the torque on the plate is measured using detectors disposed on springs that provide a resistance to rotation of the plate. In another aspect the plate is mounted to the substrate with mounts that torsionally deform during rotation of the plate. These detectors measure the torque on the plate according to the torsional deformation of the mounts. Methods of improving the signal to noise ratio of acoustic sensors having multiple detectors are also disclosed.

Abstract: Manipulator systems and methods are provided in which there is at least one slave manipulator assembly and at least one controller assembly in communication with the slave manipulator assembly. The controller assembly is configured to remotely operate the slave manipulator assembly, and the slave manipulator assembly provides feedback information to the controller assembly. The feedback information may include a measure of an amount of resistance or movement on the slave manipulator assembly. The systems and methods may be configured to automatically switch between at least two modes of operation when an amount of resistance or movement on the slave manipulator assembly fluctuates above and below a threshold amount of resistance or movement on the slave manipulator assembly.

Abstract: Example systems and methods for self-righting a robotic device are provided. An example method may include determining an orientation of a bottom surface of a legged robotic device with respect to a ground surface. The method may also include determining that the robotic device is in an unstable position, based on the determined orientation. The method may also include performing a first action configured to return the robotic device to a stable position. The method may also include performing a first action configured to return the legged robotic device to the stable position. The method may also include performing a second action configured to return the legged robotic device to the stable position, if the legged robotic device is in the unstable position after the first action.

Abstract: A robotic device for providing assistance in manipulation, including a base having a movable segment mounted thereon in association with a motor-drive mechanism connected to a control unit. The segment having an end portion provided with a member for holding an element to be manipulated and a handle for enabling the end portion to be manipulated by an operator. The control unit is connected to a detection mechanism for detecting an external force applied on the end portion and arranged to control the motor-drive mechanism as a function of an amplification factor for amplifying the detected force and servo-control gains. The control unit is connected to a pressure sensor mounted on the handle to detect the force with which the operator grips the handle and is arranged to modify the amplification factor and the servo-control gains as a function of the detected grip force.

Abstract: The invention relates to collaborative robotic equipment comprising a supporting structure supporting an arm that can be moved along at least one axis and the end of which is equipped with a tool, wherein the arm comprises a first horizontal portion, movable on a vertical axis and connected to the supporting structure by a first pivot, a second pivot providing the rotary connection of a second horizontal portion to the first portion, an end fitting providing connection between the second portion and a motorized tool-holding linear actuator which is fitted with a manual-control stick collaborating with a main force sensor to control the vertical movement of the tool and amplify the manual effort.

Abstract: A system including a memory having instructions causing a processor to perform operations, for planning a grasping-device approach to an object by a grasping device, a pre-grasp device position, and a pre-grasp device pose. The operations comprise obtaining input data including grasping-device data, object data, and environmental-constraint data, determining, based on the grasping-device data, a grasp volume model, determining a test approach vector, and determining, using the vector, the constraint data, and the model, whether approach vector modification is needed. The operations also include modifying, if modification is needed, the test approach, yielding a resulting approach vector, and determining, if modification is not needed, that the test approach is the resulting approach vector.

Abstract: A method of improving sensitivity of a robot which includes: a calculation step, an induction step and a conversion step. The calculation step calculates angular velocities of joints of a robot. The induction step determines induced accelerations at the end of the robot by converting the angular velocities of the joints into a velocity at the end of the robot, using a Jacobian matrix, and by differentiating the velocity. The conversion step determines forces at a middle portion of the robot by multiplying the induced accelerations at the middle portion of the robot by a weight of the robot, multiplies the forces by an enhancement ratio, and then converts results of the multiplication into necessary torque at the joints, using a Jacobian matrix.

Abstract: A walking robot having joints which move using a torque servo, a posture of the robot being stably controlled, and a method of controlling a posture of the robot. It is possible to maintain a stable angle of the upper body while keeping an erect posture and balance using the COG of the robot and the inclination and the direction of the upper body and the pelvis of the robot, even in an external variation including external force or an inclination angle of the ground. Even in a state in which terrain information is not known in advance, the robot may keep an erect posture in a direction of gravity. Even when a plane where the robot stands is gradually inclined, the postures of the upper body and the legs of the robot may be kept while actively changing the angle of the ankle joint.

Abstract: A method and apparatus for haptic hard surface emulation using a dynamic physical constraint are provided. The movement and position of the dynamic physical constraint is actively controlled in order to emulate a hard surface. The dynamic physical constraint may be controlled by a computer. In another aspect of the invention, the dynamic physical constraint limits the motion of a manipulator joint in space. The position at any time of the dynamic physical constraint is dependent on the position in space of the manipulator's end effector.

Abstract: A robot and a method of controlling the same are disclosed. The robot derives a maximum dynamic performance capability using a specification of an actuator of the robot. The control method includes forming a first bell-shaped velocity profile in response to a start time and an end time of a motion of the robot, calculating a value of an objective function having a limited condition according to the bell-shaped velocity profile, and driving a joint in response to a second bell-shaped velocity profile that minimizes the objective function having the limited condition.

Abstract: A robotic arm is mounted on a personal mobility device, such as a wheelchair, scooter or the like, and is controlled with a user input interface, also mounted on the personal mobility device. The user input interface has a grip operable by the user to move in a plurality of orthogonal directions, both spatially and angularly, having articulating arms supporting a housing with a pivot member.

Abstract: A first finger portion and a second finger portion of an end effector are brought close to each other, and when the first finger portion is brought into contact with an object to be grasped, an arm is moved in a direction where the first finger portion is provided while the contact between the first finger portion and the object to be grasped is kept.

Abstract: A robot controller includes a force control unit that outputs a correction value of a target track of a robot based on a detected sensor value acquired from a force sensor, a target value output unit that obtains a target value by performing correction processing on the target track based on the correction value and outputs the obtained target value, and a robot control unit that performs feedback control of the robot based on the target value. The force control unit includes an impedance processor that obtains a solution of a differential equation in force control as the correction value before the conversion processing, and a nonlinear convertor that obtains the correction value after the conversion processing by performing nonlinear conversion processing on the correction value before the conversion processing acquired from the impedance processor and outputs the obtained correction value after the conversion processing.

Abstract: A bend sensor is used to determine force applied to a robotic arm. The force may be an external force applied to the arm, an internal actuation force, or both. In some aspects, a stiffening element is used to restore the arm to a minimum kinematic energy state. In other aspects, the stiffening element is eliminated, and the arm is fully actuated.

Abstract: In one embodiment of the invention, a control system for a robotic surgical instrument is provided including a torque saturation limiter, a torque to current converter coupled to the torque saturation limiter, and a motor coupled to the torque to current converter. The torque saturation limiter receives a desired torque signal for one or more end effectors and limits the desired torque to a range between an upper torque limit and a lower torque limit generating a bounded torque signal. The torque to current converter transforms a torque signal into a current signal. The motor drives an end effector of one or more end effectors to the bounded torque signal in response to the first current signal.

Abstract: Method and system for telematic control of a slave device. Displacement of a user interface control is sensed with respect to a control direction. A first directional translation is performed to convert data specifying the control direction to data specifying a slave direction. The slave direction will generally be different from the control direction and defines a direction that the slave device should move in response to the physical displacement of the user interface. A second directional translation is performed to convert data specifying haptic sensor data to a haptic feedback direction. The haptic feedback direction will generally be different from the sensed direction and can define a direction of force to be generated by at least one component of the user interface. The first and second directional translation are determined based on a point-of-view of an imaging sensor.

Abstract: In one embodiment of the invention, a control system for a robotic surgical instrument is provided including a torque saturation limiter, a torque to current converter coupled to the torque saturation limiter, and a motor coupled to the torque to current converter. The torque saturation limiter receives a desired torque signal for one or more end effectors and limits the desired torque to a range between an upper torque limit and a lower torque limit generating a bounded torque signal. The torque to current converter transforms a torque signal into a current signal. The motor drives an end effector of one or more end effectors to the bounded torque signal in response to the first current signal.

Abstract: A CPU of a robot control device calculates load torque based on the inertia force, centrifugal force or Coriolis force, gravity force, friction torque, and actuator inertia torque applied to a joint axis of each link, each time an orientation parameter indicative of the link position and orientation allowed by a redundant degree of freedom is sequentially changed, under a constraint of end-effector position and orientation as target values. The CPU obtains the link position and orientation at which the ratio of the load torque to the rated torque of a rotary actuator provided for each joint is minimized, while the orientation parameter is being changed, and provides a feed-forward value that gives rise to each load torque obtained when the ratio of the load torque to the rated torque of the rotary actuator is minimized, to a control command generated to the rotary actuator of each joint axis for achieving the end-effector position and orientation as target values.

Abstract: A computer-assisted surgery system may have a robotic arm including a surgical tool and a processor communicatively connected to the robotic arm. The processor may be configured to receive, from a neural monitor, a signal indicative of a distance between the surgical tool and a portion of a patient's anatomy including nervous tissue. The processor may be further configured to generate a command for altering a degree to which the robotic arm resists movement based on the signal received from the neural monitor; and send the command to the robotic arm.

Abstract: A robot mechanism for controlling the position of a machine tool in a large-scale manufacturing assembly includes six rotary axes and one linear axis. Secondary feedback systems are included on at least several of the axes. A controller receives secondary feedback information and uses it to control the position of the machine tool within an accuracy of ±0.3 mm.

Abstract: A device for reducing damage to an electric vehicle powered by a trailing cable, the device including an electric sensor for determining the mobile equipment's position relative to a hazard, and an electric controller responsive to the electrical means for operating a motor to change the operation of the electric vehicle to reduce the likelihood of adverse effects to the trailing cable if the electric vehicle's position is near the hazard.

Abstract: A leg assist device having an abnormality management procedure which appropriately adapts to an abnormal situation is provided. The leg assist device is provided with a leg attachment and a controller. The leg attachment comprises upper and a lower links connected with a rotary joint, and an actuator. The upper link is to be attached to the upper leg of the user. The lower link is to be attached to the lower leg of the user. The actuator swings the lower link relative to the upper link. The controller outputs the commands so that the swing angle of the lower link follows a target trajectory. Further, the controller executes a first abnormality management process in which the controller shuts off torque transmission from the actuator to the user when the controller detects an abnormality before outputting the commands to the actuator.

Abstract: A robot system according to the embodiments includes a robot that includes a hand including a gripping mechanism that grips a thin plate-shaped work and an arm that moves the hand, and a robot control apparatus that controls the robot. The robot control apparatus, when causing the robot to transfer the work at a predetermined work transfer position by controlling the robot, performs a presence/absence confirmation of the work by operating the gripping mechanism while causing the hand to retract after the hand reaches the work transfer position.

Abstract: A cooperative-control robot includes a base component, a mobile platform arranged proximate the base component, a translation assembly operatively connected to the base component and the mobile platform and configured to move the mobile platform with translational degrees of freedom substantially without rotation with respect to said the component, a tool assembly connected to the mobile platform, and a control system configured to communicate with the translation assembly to control motion of the mobile platform in response to forces by a user applied to at least a portion of the cooperative-control robot. The translation assembly includes at least three independently operable actuator arms, each connected to a separate position of the mobile platform. A robotic system includes two or more the cooperative-control robots.

Abstract: A master console includes handles configured to control robotic surgical instruments of a slave robot, force/torque detectors configured to detect forces applied to the handles by an operator, a force compensator configured to generate force control signals that cancel out the forces applied to the handles by the operator, and a master controller configured to drive at least one joint of each of the handles in order to control motion of the handles based on motion control signals and the generated force control signals.

Abstract: The invention relates to a method for mounting a component, which comprises an insertion part and a holding part, in an opening in a workpiece by means of an industrial robot, which has an end effector, which guides the component on the holding part thereof. The method according to the invention is implemented by causing the insertion part of the component to approach the opening by moving the industrial robot; increasing the process forces by means of the industrial robot, once the insertion part of the component has made contact with the workpiece, until a process force threshold is reached, wherein the process forces are stored particularly in the form of material stresses; increasing the flexibility of the industrial robot when the process force threshold is reached; and executing a passive centering movement of the industrial robot based upon the process forces that are released by a relaxation of the material.

Abstract: Method and system for telematic control of a slave device. Displacement of a user interface control is sensed with respect to a control direction. A first directional translation is performed to convert data specifying the control direction to data specifying a slave direction. The slave direction will generally be different from the control direction and defines a direction that the slave device should move in response to the physical displacement of the user interface. A second directional translation is performed to convert data specifying haptic sensor data to a haptic feedback direction. The haptic feedback direction will generally be different from the sensed direction and can define a direction of force to be generated by at least one component of the user interface. The first and second directional translation are determined based on a point-of-view of an imaging sensor.

Abstract: A force sensor includes a base unit, an elastic supporting unit, an action unit supported by the elastic supporting unit, and a detection unit that detects at least one of an external force acting on the action unit and a moment acting on the action unit. The detection unit includes a light source, a diffraction grating, a photodetector array that receives an interference image formed by light that has been emitted from the light source and diffracted by the diffraction grating and outputs signals having different phases, and a calculation unit that calculates a displacement of the action unit with respect to the base unit on the basis of the signals and calculates at least one of the external force and the moment acting on the action unit on the basis of the displacement.

Abstract: A robot apparatus includes a gripping unit configured to grip a first component, a force sensor configured to detect, as detection values, a force and a moment acting on the gripping unit, a storing unit having stored therein contact states of the first component and a second component and transition information in association with each other, a selecting unit configured to discriminate, on the basis of the detection values, a contact state of the first component and the second component and select, on the basis of a result of the discrimination, the transition state stored in the storing unit, and a control unit configured to control the gripping unit on the basis of the transition information selected by the selecting unit.

Abstract: A robot control system includes a force control unit configured to output a correction value of a target track of a robot on the basis of sensor information acquired from a force sensor, a target-value output unit configured to apply correction processing based on the correction value to the target track to calculate a target value and output the calculated target value, and a robot control unit configured to perform feedback control of the robot on the basis of the target value. The force control unit includes a digital filter unit. The force control unit applies digital filter processing by the digital filter unit to the sensor information to calculate a solution of an ordinary differential equation in force control and outputs the correction value on the basis of the calculated solution.

Abstract: System (100) and methods (500) for remotely controlling a slave device (102). The methods involve: using a Hybrid Hand Controller (“HHC”) as a full haptic controller to control the slave device when the HHC (406) is coupled to a docking station (460); detecting when the HHC is or is being physically de-coupled from the docking station; automatically and seamlessly transitioning an operational mode of at least the HHC from a full haptic control mode to a gestural control mode, in response to a detection that the HHC is or is being de-coupled from the docking station; and using at least the HHC as a portable gestural controller to control the slave device when the HHC is de-coupled from the docking station.

Abstract: Method for controlling the action of a robotic arm which comprises the following stages: a) moving the robotic arm by means of an action programmed in a controller; b) measuring the force which the robotic arm applies at specific points in the movement in stage a); c) comparing the force applied at each of the points in stage b) with force profile data stored in the controller; d) as a result of the comparison in paragraph c), generating an alarm signal if the force measured in stage b) is outside the limits defined in the force profile and carrying out stage a) if the force measured in stage b) is within the limits defined in the force profile.

Abstract: The present invention is in the field of soybean variety OW1012750 breeding and development. The present invention particularly relates to the soybean variety OW1012750 and its progeny, and methods of making OW1012750.

Abstract: A force feedback system and method are provided. The force feedback system includes a communication module, a processor and a motor drive module. The processor is for receiving and processing mechanical arm signals corresponding to a movement of the plurality of mechanical arms and the motor drive module is for activating the plurality of actuators. The method involves providing an interface between a controller and a plurality of mechanical arms, receiving and processing mechanical arm signals corresponding to movement of the mechanical arms activating a plurality of actuators and generating a force feedback.

Abstract: A force information correcting unit generates force information in accordance with magnification percentage information acquired by a display information acquiring unit. The force information matches a picture watched by an operator to manipulation of the operator with no sense of incongruity. A force information presentation unit presents the generated force information to the operator, so that work efficiency is improved.

Abstract: The present invention relates to a control method and device for position-based impedance controlled industrial robot, and more particularly, a control method and device for position-based impedance controlled industrial robot able to improve contact stabilization with regard to an environment with a variety of stiffness. According to a control method and device for position-based impedance controlled industrial robot in accordance with the present invention, a robust contact stabilization for a position-based impedance controlled industrial robot contacting and interacting with an uncertain actual environment may be guaranteed.

Abstract: In a 6-axis robot, as an example, an inter-axis offset can be measured and calibrated. A light emitting diode is installed on an end effector, and the end effector is located on a plurality of target positions of movement on the axis X (Xb) of a robot coordinate. Then, the position of the light emitting diode is measured by a three-dimensional gauge, and an inter-axis offset F is detected based on an error between the target positions of movement and actually moved positions. For the inter-axis offset F, DH parameters are calibrated.

Abstract: Method and system for telematic control of a slave device. Displacement of a user interface control is sensed with respect to a control direction. A first directional translation is performed to convert data specifying the control direction to data specifying a slave direction. The slave direction will generally be different from the control direction and defines a direction that the slave device should move in response to the physical displacement of the user interface. A second directional translation is performed to convert data specifying haptic sensor data to a haptic feedback direction. The haptic feedback direction will generally be different from the sensed direction and can define a direction of force to be generated by at least one component of the user interface. The first and second directional translation are determined based on a point-of-view of an imaging sensor.

Abstract: A bend sensor is used to determine force applied to a robotic arm. The force may be an external force applied to the arm, an internal actuation force, or both. In some aspects, a stiffening element is used to restore the arm to a minimum kinematic energy state. In other aspects, the stiffening element is eliminated, and the arm is fully actuated.

Abstract: Disclosed herein is a method of controlling a robot hand similar to a hand of a human being such that the robot hand naturally and safely grasps an object. The robot hand, including fingers and a palm, is capable of naturally and safely grasping an object, by the tip of each finger performing impedance control while following the optimal path on a Cartesian coordinate system, although the robot hand cannot reach a position ideal to grasp the object due to sensor errors or shape information of the object to be grasped is not correctly recognized. Also, the robot hand is capable of stably grasping the object even when moving or manipulating the object.

Abstract: A robot hand has a plurality of fingers including a contact sensing finger that senses contact with an object. A base provided with the fingers detects a resultant reaction force that is the combination of reaction forces from the fingers. When no resultant reaction force is detected, the plurality of fingers are moved toward the object, and when the contact sensing finger comes into contact with the object, a force that drives the fingers is switched to a force corresponding to a grasp force. When the contact sensing finger has not come into contact with the object but a resultant reaction force is detected, the driving of the fingers is terminated and the position of the base is corrected by moving the base in a direction in which the resultant reaction force having acted thereon is not detected any more.

Abstract: A robot controller (11) which moves either a tool (4) or a workpiece (W) relative to another one with a hand unit, controls the force acting between the tool and the workpiece, comprising a force detector unit (3) for detecting a force in one axial direction and moments about the axes in two axial directions that are at right angles with the one axis and are, further, at right angles with each other; a force-presuming point setting unit (12) for setting a force-presuming point at where a force acting between the tool and the workpiece is presumed; and a force-presuming unit (13) for presuming forces in the two axial directions and a moment about the one axis based upon the force in the one axial direction and the moments about the axes in the two axial directions, and upon the position of the force-presuming point.

Abstract: Disclosed is a method of absorbing an impact generated when a foot of a walking robot lands on the ground to perform the walking of the walking robot. When the foot of the walking robot lands on the ground, an F/T sensor installed on the sole or the ankle of the foot measures external force and the posture of the sole of the foot is adjusted in a direction of complying with the external force, and thus an impact transmitted to the walking robot in landing is absorbed. Further, the posture adjusting speed of the sole of the foot is adjusted according to walking speeds (stopped, walking, running).