Abstract: A robot includes an input detection portion, a motion detection portion, and a control portion. The input detection portion is configured to detect an input given from an operator to a robot body. The motion detection portion is configured to detect a motion by using the input detection portion, the motion being given by the operator. The control portion is configured to execute a motion instruction associated with the motion detected by the motion detection portion.

Abstract: In one embodiment, a method includes by a robotic system: accessing a trajectory plan to be executed by the robotic system, where the trajectory plan includes desired poses at specified times, respectively, for each actuator of the robotic system, executing the trajectory plan for each actuator of the robotic system; monitoring, in real-time for each actuator during execution of the trajectory plan, an actual pose of the respective actuator, determining, based on the monitoring of the actuators, that one or more of the actuators is lagging, where the actual pose of each lagging actuator deviates from the desired pose by more than an error threshold, and adjusting, in real-time responsive to determining that one or more of the actuators is lagging, one or more of the desired poses at one or more specified times, respectively, of the trajectory plan.

Abstract: A controller includes a parameter setting unit that invalidates first mechanism error parameters. The controller includes a measurement control unit that drives a robot with a plurality of orientations at a plurality of positions by using second mechanism error parameters other than the first mechanism error parameters and measures the actual measurement position of the robot by a three-dimensional measuring device. The controller includes a parameter calculation unit that calculates the first mechanism error parameter based on the actual measurement position of the robot and the rotation position of a robot drive motor. The controller includes a correction unit that changes the first mechanism error parameter invalidated by the parameter setting unit to the first mechanism error parameter calculated by the parameter calculation unit.

Abstract: An object can be moved via a robotic system with a combination of force and position control. The control system can include the object to be moved, the robotic system that moves the object, at least one force sensor, at least one position sensor, and a controller. A position control output, a force control output, and a hybrid weighting value can each be determined by the controller based on sensor data and then combined to determine an amount of position control and/or force control to be applied to move the object and/or modify an object in motion's trajectory.

Abstract: A robot control method includes: obtaining force information associated with a left foot and a right foot of the robot; calculating a zero moment point of a COM of a body of the robot based on the force information; updating a motion trajectory of the robot according to the zero moment point of the COM of the body to obtain an updated position of the COM of the body; performing inverse kinematics analysis on the updated position of the COM of the body to obtain joint angles of a left leg and a right leg of the robot; and controlling the robot to move according to the joint angles.

Abstract: One embodiment can provide an apparatus. The apparatus can include a robotic arm, a pair of jaws coupled to the robotic arm configured to grip a fabric piece at a pair of predetermined locations, a force sensor coupled to the jaws and configured to measure a tension force applied to the fabric piece by the jaws, and a control module configured to control movements of at least one jaw based on the measured tension force, thereby allowing the fabric piece to be stretched.

Abstract: An industrial robot motion accuracy compensation method includes: establishing a motion parameter database, wherein the motion parameter database includes a plurality of different reference operating conditions and a motion parameter of the industrial robot corresponding to each reference operating condition, and each reference operating condition is formed by combining each element in each set in a total set of operation conditions; acquiring a current operating condition of the industrial robot; determining whether there is a reference operating condition matched with the current operating condition in the motion parameter database; if yes, taking a motion parameter corresponding to the matched reference operating condition as a motion parameter corresponding to the current operating condition; if no, performing an interpolation on a motion parameter corresponding to the current operating condition, and taking an interpolation result as the motion parameter corresponding to the current operating condition.

Abstract: A robot includes: a base having a plurality of wheels; a body having a bottom portion coupled above the base, and a top portion above the bottom portion, the top portion configured to support food and/or drink; a first camera at the bottom portion, wherein the first camera is oriented to view upward; and a second camera at the top portion, wherein the second camera is configured to view upward.

Abstract: The self-driving robot comprises: a loading box including at least one loading space; a communication circuit configured to transmit or receive a signal; an information collection device configured to detect a surrounding environment; a driving device configured to implement movement of the self-driving robot; and a processor configured to control the loading box, the communication circuit, and the information collection device, wherein the processor performs control so that the self-driving robot identifies delivery authority information and position information of an event operator, in response to detecting a delivery event while moving along a moving path, and the self-driving robot determines whether to open the loading box, on the basis of the delivery authority information and the position information.

Abstract: The present disclosure relates to a robot teaching system, which moves a robot according to an external force applied from the outside so that the robot has a location and posture intended for teaching and then teaches a location and posture of the moved robot, and the robot teaching system comprises: an arm including a plurality of articular shafts and a plurality of links connected by the plurality of articular shafts; a plurality of strain gauges respectively coupled to frames of the plurality of links to measure a deformation value of the link that is deformed by the external force; and a calculating device configured to estimate the external force from the deformation value of the link obtained by the plurality of strain gauges, calculate a teaching force from the external force and move the robot by an operation corresponding to the teaching force.

Abstract: A robot including: a robot body that includes an arm having a longitudinal axis, and at least one joint; and a proximity sensor unit that detects an object approaching the arm of the robot body. The proximity sensor unit includes: a support member that is fixed to the arm of the robot body and that is disposed, at such a position as to extend across the joint of the robot body, so as to be away from a surface of the arm in a direction perpendicular to the longitudinal axis of the arm; and a plurality of proximity sensors that are attached to the support member.

Abstract: A control method for a robot system having a robot arm and executing an operation mode of the robot arm having an execution mode in which a motion program is executed and a teaching mode in which the motion program is taught, includes setting an upper limit velocity of a motion velocity of the robot arm to a first velocity when the operation mode is the execution mode, and setting the upper limit velocity to a second velocity lower than the first velocity when the operation mode is the teaching mode.

Abstract: An industrial robot system includes: a robot that includes a torque sensor on at least one rotary shaft; and a controller that controls the robot. The controller includes a moment output unit that outputs a value of moment from a posture of the robot or the posture and a motion of the robot, a program storage unit that stores a motion program, a drive control unit that causes each of component parts of the robot to perform a rotating motion around the rotary shaft in accordance with the motion program, and an output calibration unit that associates a torque detection value detected by the torque sensor with the value of moment output from the moment output unit in the rotating motion of each of the component parts around the rotary shaft performed by the drive control unit.

Abstract: A robot apparatus is provided on a stand and includes a control apparatus that controls the robot apparatus. The control apparatus calculates vibration generated on the stand based on model data of the stand and trajectory data of an operation of the robot apparatus and corrects the trajectory data based on the vibration.

Abstract: The present disclosure discloses a dispatching method and device, and a non-transitory readable storage medium, and relates to the field of computer technology. The method of the present disclosure includes: obtaining path condition information within a warehouse; calculating pickup time of each candidate robot of a plurality of candidate robots according to a location of the candidate robot and the path condition information; dispatching a target robot to perform a pickup task according to the pickup time of each candidate robot.

Abstract: Devices, systems, and methods related to incentives for complying with suggested driving operations can include determining suggested driving operations, determining a desirability of the suggested driving operations, communicating the desirability of the suggested driving operations, and optionally monitoring compliance with the suggested driving operations.

Abstract: A conveyance robot system according to the present disclosure includes an intrusion detection sensor that detects an intrusion of an object into the arm opening, and a distance sensor that measures a clearance distance indicating a distance between an arm entry/exit surface and a shelf, the arm entry/exit surface being a surface of the conveyance robot in which the arm opening is provided from among surfaces of the conveyance robot 1 constituting the safety cover, and the object being stored in the shelf. The distance sensor is disposed at a fixed height of the shelf in a horizontal direction and at a height of the shelf corresponding to a part to be measured.

Abstract: An interactive autonomous robot is configured for deployment within a social environment. The disclosed robot includes a show subsystem configured to select between different in-character behaviors depending on robot status, thereby allowing the robot to appear in-character despite technical failures. The disclosed robot further includes a safety subsystem configured to intervene with in-character behavior when necessary to enforce safety protocols. The disclosed robot is also configured with a social subsystem that interprets social behaviors of humans and then initiates specific behavior sequences in response.

Abstract: According to some embodiments, a tactile information estimation apparatus may include one or more memories and one or more processors. The one or more processors are configured to input at least first visual information of an object acquired by a visual sensor to a model. The model is generated based on visual information and tactile information linked to the visual information. The one or more processors are configured to extract, based on the model, a feature amount relating to tactile information of the object.

Abstract: The present disclosure provides a grip manipulator used in a robot to eliminate an inefficient and power consumable operation caused by the use of multiple manipulators when gripping an object or handling the gripped object. The grip manipulator includes a manipulator body, a support rod of a first group and a support rod of a second group provided to protrude from the manipulator body in a direction, a longitudinal drive unit configured to discharge or introduce the support rod of the first group or the support rod of the second group in the protruding direction, and a transverse drive unit configured to spread or gather the support rod of the first support group or the support rod of the second group in a direction perpendicular to the protruding direction.