According to an embodiment, an object handling device includes a base, a manipulator, a first camera, a sensor, a manipulator control unit and a calibration unit. The manipulator is arranged on the base, and includes a movable part and an effector that is arranged on the movable part and acts on an object. The first camera and the sensor are arranged on the manipulator. The manipulator control unit controls the manipulator so that the movable part is moved to a position corresponding to a directed value. The calibration processing unit acquires a first error in a first direction based on an image photographed by the first camera, acquire a second error in a second direction intersecting with the first direction based on a detection result obtained by the sensor, and acquire a directed calibration value with respect to the directed value based on the first error and the second error.

A medical manipulator includes an insertion portion, an arm portion, a light irradiation section irradiating a luminous flux having an optical axis parallel to an arm axial line, an imaging section imaging a locus of an optical image, a rotational movement portion rotating the arm portion around a reference axial line, and an initialization control unit performing initialization control to aligning the arm portion with the reference axial line, in which the initialization control unit includes: a locus acquisition control section controlling the light irradiation section, the rotational movement portion, and the imaging section to acquire a locus of the luminous flux, a convergence determination section computing a diameter of the locus and determines whether or not the diameter of the locus has converged, a driving amount correction section obtaining a driving amount of the first redundant joint and performs driving, and a convergence operation control section.

Provided is a calibration system for a horizontal articulated robot, the system including: an installation surface on which a base of the horizontal articulated robot is installed; two reference surfaces that are provided on the base, that intersect with the installation surface, and that intersect with each other; and a positioning jig that is attached to a distal end of the horizontal articulated robot and that has three positioning surfaces, which respectively and simultaneously come into contact with the installation surface and the two reference surfaces.

A method of calibrating a manipulator of an industrial robot, the method including providing a primary manipulator having one or more primary joints and a primary mounting interface; providing a secondary manipulator having one or more secondary joints and a secondary mounting interface, where the primary mounting interface is substantially rigidly connected to the secondary mounting interface; providing a load sensor between the primary mounting interface and the secondary mounting interface, the load sensor being configured to provide load data indicative of loads between the primary mounting interface and the secondary mounting interface; controlling the primary manipulator to adopt at least one calibration state; for each calibration state, recording a primary joint position of at least one primary joint; and calibrating the secondary manipulator based on the at least one recorded primary joint position; wherein the primary manipulator is controlled to adopt the at least one calibration state based on the load data; and/or wherein the calibration of the secondary manipulator is additionally made based on the load data.

According to an embodiment, an object handling device includes a base, a manipulator, a first camera, a sensor, a manipulator control unit and a calibration unit. The manipulator is arranged on the base, and includes a movable part and an effector that is arranged on the movable part and acts on an object. The first camera and the sensor are arranged on the manipulator. The manipulator control unit controls the manipulator so that the movable part is moved to a position corresponding to a directed value. The calibration processing unit acquires a first error in a first direction based on an image photographed by the first camera, acquire a second error in a second direction intersecting with the first direction based on a detection result obtained by the sensor, and acquire a directed calibration value with respect to the directed value based on the first error and the second error.

A mechanism-parametric-calibration method for a robotic arm system is provided, including: controlling the robotic arm to perform a plurality of actions so that one end of the robotic arm moves toward corresponding predictive positioning-points; determining a predictive relative-displacement between each two of the predictive positioning-points; after each of the actions is performed, sensing three-dimensional positioning information of the end of the robotic arm; determining, according to the three-dimensional positioning information, a measured relative-displacement moved by the end of the robotic-arm when each two of the actions are performed; deriving an equation corresponding to the robotic arm from the predictive relative-displacements and the measured relative-displacements; and utilizing a feasible algorithm to find the solution of the equation. When an ambient temperature changes or a stress variation on the robotic arm exceeds a predetermined range, re-obtaining the set of mechanism parametric deviations corresponds to a current robot configuration.