A method for detecting at least one characteristic parameter of a closure element (12) closing an opening. By means of a handling device (10), a movement is imposed on the closure element (12), wherein at least the interacting force between the closure element and the handing device during the movement is determined by means of a first sensor (20) integrated in the handling device, and position changes of the closure element during the movement sequence are detected by means of a second sensor (26).

Embodiments of present disclosure relates to an apparatus and a method for calibrating a laser displacement sensor for use with a robot. The apparatus comprises an auxiliary object arranged in a work space of the robot or held by the robot and comprising a planar surface adapted to be detected by the laser displacement sensor; and a controller configured to: determine a characteristic point on the planar surface of the auxiliary object based on a detection result from the laser displacement sensor; cause the laser displacement sensor to point at the characteristic point for plural times with the same angle and different distances to obtain an orientation of the laser displacement sensor; and cause the laser displacement sensor to point at the characteristic point for plural times with different angles and the same distance to obtain a relative position relationship between the laser displacement sensor and the robot.

A construction robot for mounting a member with a changeable height on a body at a predetermined height includes: a manipulator; an end effector provided at a distal end of the manipulator; a recognizing unit configured to recognize positions of the member and the body; and a measuring unit configured to measure a positional relation between the member and the body. The end effector includes a holding unit configured to hold the member in a releasable manner, and a height adjusting unit configured to adjust a height of the member by moving the member in contact with the body in a direction moving closer to or in a direction moving away from the body.

A robot control system includes: a mobile robot that controls movement of an object; an estimation unit that estimates a position of the object based on detection information of the object acquired by first sensors installed on base portions of the mobile robot; and a control unit that controls an end effector of the mobile robot. The control unit moves the end effector to the position estimated by the estimation unit, and controls the movement of the object using the end effector when a distance between the object and the second sensor acquired by the second sensor is equal to or less than a distance threshold value.

A device for ensuring safe operation of a robot used for cosmetics applications, including the retrofitting of robots not originally design for such applications. In some embodiments, the robot is used for the automatic placement of eyelash extensions onto the natural eyelashes of a subject. In some embodiments, a safety barrier is provided by a physical barrier or light curtain. In other embodiments, readily deformable end effectors are used.

A modular movable robot includes a lower plate provided with a traveling unit, an upper plate spaced above the lower plate, a plurality of lower supporting frames vertically elongated between the lower plate and the upper plate, a top plate spaced above the upper plate, a plurality of upper supporting frames vertically elongated between the upper plate and the top plate, and a housing surrounding edges of the lower plate, the upper plate, and the top plate. A longitudinal length of the housing is longer than a horizontal width of the housing.

A shoe upper having a plurality of arms that expand the shoe opening when the topline of the upper is compressed toward the sole portion of the shoe.

A human-robot system and method for performing an agricultural task, the system including: a robotic manipulator with an agricultural tool coupled to an end effector thereof; an imaging device adapted to capture imagery of a target, the imaging device mechanically coupled to the end effector; a laser distance sensor adapted to measure a distance between the manipulator and the target, the laser distance sensor mechanically coupled to the end effector and collocated with the imaging device; and a control unit including: a processing unit, a monitor and a human-machine interface (HMI), wherein the processing unit is configured to display the imagery on the monitor and to receive markings from the HMI and calculate a trajectory for the manipulator to perform the agricultural task with the tool.

An intelligent robot control method is provided for an intelligent robot. The method includes obtaining a first position at which the intelligent robot is currently located and a target position to be reached, and determining a movement path from the first position to the target position. The movement path has a particular roadblock. The method also includes transmitting a removal request when the intelligent robot moves from the first position to a second position, and a distance between the second position and a third position at which the particular roadblock is located and that is to be reached reaches a target distance. The removal request is used for requesting a removal instruction to be transmitted to the particular roadblock, and the removal instruction is used for, based on a roadblock type of the particular roadblock, instructing to remove the particular roadblock before the intelligent robot arrives.

The present disclosure relates to a method for sensing the depth of an object by considering external light and a device implementing the same, and a method for sensing the depth of an object by considering external light according to an embodiment of the present disclosure comprises the steps of: storing, in a storage unit, first depth information of an object, which is sensed at a first time point by a depth camera unit of a depth sensing module; storing, in the storage unit, second depth information of the object, which is sensed at a second time point by the depth camera unit; comparing, by a sensing data filtering unit of the depth sensing module, the generated first and second depth information to identify a filtering target region from the second depth information; and adjusting, by a control unit of the depth sensing module, the depth value of the region filtered from the second depth information.