A robot system is provided with a three-dimensional sensor which acquires three-dimensional information of an object, and a robot which includes a gripping device for gripping an object. The robot system uses first three-dimensional information which relates to a state before an object is taken out and second three-dimensional information which relates to a state after an object is taken out as the basis to acquire three-dimensional shape information of an object, and uses the three-dimensional shape information of the object as the basis to calculate a position and posture of the robot when an object is placed at a target site.

Systems and methods for robotic positioning of multiple tools. The system may include one or more robotic devices, multiple tools, and one or more controllers. The one or more robotic devices are each configured to connect to the tools, move the tools to a desired work position, and release the tools at the work position. The tools are able to operate mechanically independently from the robotic devices to perform an operation at the position to which they are delivered. After releasing the tools the robotic devices are able to perform other operations including moving additional tools to different work positions. The one or more controllers oversee the operation of the one or more robotic devices and tools and control the overall operation on a work piece.

An trajectory information generating unit for generating trajectory information defining a trajectory for which a picking hand picks a work at a first position and arranges the work at a second position, an execution control unit for operating a picking apparatus based on trajectory information generated by the trajectory information generating unit, and an execution time estimating unit for estimating a period of time from when the picking apparatus receives an instruction for starting an operation on a work to a time when the operation of the picking apparatus on the work is ended are included. The trajectory information generating unit may adjust an amount of calculation based on an estimation result of the execution time estimating unit.

A machine tool is provided which can execute various works while suppressing increase in cost or size. The machine tool includes a tool spindle device which is a movable member which can move with respect to a mounting surface of the machine tool, and one or more serial-manipulator-type robots attached on the tool spindle device, which can move with the tool spindle device, and which have two or more degrees of freedom, and the robot includes two or more end effectors provided at positions different from each other with one or more joints therebetween.

After a component picked up by a suction nozzle is moved in an XY direction towards target XY coordinates, a waveform of a vibration (vibration waveform) in the Y direction arising in the component after the component has arrived near the target XY coordinates is measured, and control is performed such that the component arrives at a target Z coordinate (value zero) when a displacement y of the component crosses a node of the measured vibration waveform.

A method and system for piece-picking or piece put-away within a logistics facility. The system includes a central server and at least one mobile manipulation robot. The central server is configured to communicate with the robots to send and receive piece-picking data which includes a unique identification for each piece to be picked, a location within the logistics facility of the pieces to be picked, and a route for the robot to take within the logistics facility. The robots can then autonomously navigate and position themselves within the logistics facility by recognition of landmarks by at least one of a plurality of sensors. The sensors also provide signals related to detection, identification, and location of a piece to be picked or put-away, and processors on the robots analyze the sensor information to generate movements of a unique articulated arm and end effector on the robot to pick or put-away the piece.

A system and method for a dynamic robot kitting line that can include: processing a set of order requests and setting a packing fulfillment plan process for a robotic kitting line, wherein robotic kitting line comprises a conveyor system, a set of robotic workcells arranged along the conveyor system, and where each robotic workcell includes at least one robotic pick-and-place machine and a set of item bins; and managing operation of the robotic kitting line according to the packing fulfillment plan, which includes: conveying item totes through the set of robotic workcells, and for each item tote, progressively packing items of an order request assigned to an item tote by incrementally packing items at robotic workcells of the set of robotic workcells.

A semiconductor die pick and place device comprising a handing mechanism comprising a pick arm movable between a placement location and a pick-up location. A reference feature is located on the pick arm, and a light reflecting module is carried by the pick arm. The light reflecting module is operable to reflect an image of the reference feature to an image capturing module such that the reference feature appears to the light reflecting module to be in focus at a virtual position that is equivalent to a position at the pick-up location and/or the placement location.

Devices, systems, and methods for determining whether a container is empty in the context of robotic picking solutions. The system includes a plurality of sensors configured to gather container data regarding a container at a first location, wherein the container data includes at least two of weight data related to the container, depth data related to the container, and color sensor data related to the container, and a processor configured to execute instructions stored on a memory to provide a sensor fusion module configured to process the received container data to determine whether the container is empty.

The article pickup system includes: a camera that is provided in a mobile body capable of moving in an environment where a plurality of articles to be picked up are present and that acquires image data by capturing the plurality of articles; and an article pickup robot that moves in the environment and picks up the plurality of captured articles. The article pickup robot includes: a camera position acquisition unit that detects the camera and then acquires position information of the camera; an article position specification unit that specifies positions of the plurality of articles based on the position information of the camera; a mobile unit that moves to the specified positions; and a pickup unit that picks up the plurality of articles at the positions to which the mobile unit has moved.