Provided are an end effect measuring module and an end effect monitoring apparatus using the same. The end effect measuring module is installed at through holes formed between an Equipment Front End Module (EFEM) equipped with an end effector and a semiconductor processing apparatus for processing a wafer and measuring the position according to the movement path of a target passing the through holes. The measurement target is the end effector, and a sensing unit measures whether or not the end effector is shifted and changed in direction. A light receiving unit of the sensing unit outputs an electrical signal that is higher or lower than a reference value in response to shifting of the end effector, or outputs an electrical signal increasing or decreasing along a time axis in response to a directional change of the end effector.

Provided is a robot control system which can perform force control feedback even when a force sensor has failed. To this end, this robot control system (1) for controlling a robot provided with a force sensor comprises: a force information acquisition unit (11) which acquires force information detected by the force sensor; an electric current information acquisition unit (12) which acquires electric current information from each axial motor of the robot; a force information learning unit (13) which trains a force information estimation model (MF) on the basis of the force information and the electric current information during operation of the robot; a force information estimation unit (15) which estimates force information corresponding to an operation on the basis of the force information estimation model during operation of the robot; and a motor control unit (16) which performs feedback control of each axial motor on the basis of force information acquired by the force information acquisition unit or the force information estimated by the force information estimation unit.

An enhanced exoskeleton system is disclosed comprising an exoskeleton, a base layer comprising at least one sensor, an exoskeleton actuator configured to actuate the exoskeleton, a control subsystem comprising one or more processors, and memory elements including instructions that, when executed, cause the processors to perform operations comprising: receiving sensor data from the sensor, determining a future movement intent of a user of the exoskeleton, determining a command for an exoskeleton actuator based on the future movement intent, and communicating the command to the exoskeleton actuator whereby the exoskeleton is actuated by the exoskeleton actuator. In some embodiments, the sensor data comprises an anticipatory data value from an anticipatory sensor. In some embodiments, the sensor data comprises an anticipatory data value from an electromyography (EMG) sensor.

A transport device has a position detection portion, a holding portion attached to an arm, a driving portion to drive the holding portion and the arm, and a control portion. A control portion controls the position detection portion and the driving portion to perform, as one cycle, a procedure to detect a position of a parcel, select parcels based on a predetermined condition, and set priority for the selected parcels, and a procedure to refer to a result of the detection, and cause the holding portion to take out one or more parcels from the accumulation portion in accordance with the priority to transport the parcels to a predetermined location, and excludes, from parcels to be taken out, a second parcel that is present within a predetermined distance from a first parcel and has priority lower than the priority of the first parcel, during the one cycle.

A machine handling device for handling a sheet-metal workpiece includes a control device that comprises two sensing elements, and a testing station that includes a testing device configured to test functional capability of the control device. The testing device includes a respective electrically conductive testing-contact body for each of the two sensing elements of the control device. The testing station further includes a testing-evaluation device configured to apply a testing voltage between the respective sensing element and the corresponding testing-contact body. The testing-evaluation device includes a testing-measuring unit and a testing-comparing unit. The testing-measuring unit is configured to measure an actual value of a contact-dependent electrical variable that is dependent on a state of an electrically conducting contact between the sensing element and the testing-contact body. The testing-comparing unit is configured to compare the actual value of the contact-dependent electrical variable with a reference value of the contact-dependent electrical variable.

An underwater robotic system includes a frame adapted to be deployed in a body of water and having guide rails and at least one movable rail movably coupled to the guide rails. An actuator module is movably coupled to the at least one movable rail. A control panel disposed proximate the frame and has a plurality of controls thereon. The plurality of controls is operable by an actuator on the actuator module. A position of each of the plurality of controls is known such that motion of the actuator module and the at least one movable rail is remotely controllable to actuate any chosen one of the plurality of controls.

A sensor positioning system, includes an actuation server for communicating with components of the sensor positioning system. The sensor positioning system additionally includes a first actuation system and a second actuation system, wherein each actuation system includes a pulley system for maneuvering an underwater sensor system. The sensor positioning system includes a dual point attachment bracket that connects through a first line to the first actuation system and connecting through a second line to the second actuation system. The underwater sensor system is affixed to the first pulley system, the second pulley system, and the dual attachment bracket through the first line and the second line.

An electromagnetic device for manipulating a magnetic-responsive robotic device, and an electromagnetic apparatus incorporate one or more such electromagnetic device. The electromagnetic device includes a magnetic core 200 having a first portion and a second portion extends from one side of the first portion. The first portion has a first cross section and defining a first central axis. The second portion has a second cross section smaller than the first cross section, and defines a second central axis parallel to the first central axis. A first electromagnetic coil is arranged around the first cylindrical portion. A second electromagnetic coil is arranged around the second cylindrical portion.

An inkjet-type vehicle painting machine capable of keeping temperature elevation of a nozzle head to a certain temperature or less. The painting robot comprises a power supply means for supplying power to drive a piezoelectric substrate of a nozzle head, and a robot arm for moving the nozzle head. The nozzle head is provided in an explosion-proof housing equipped with an explosion-proof construction. A heat dissipation means that dissipates heat generated from the nozzle head within the explosion-proof housing is attached to the nozzle head. A temperature measurement means for measuring the temperature of the heat dissipation means is attached to the heat dissipation means.

User input devices (UIDs) for controlling a surgical robotic system are described. A UID can include one or more tracking sensors to generate respective spatial state signals in accordance with a pose of the UID. At least one of the tracking sensors can be a camera. In the case of multiple tracking sensors, the spatial state signals are processed by a sensor fusion algorithm to generate a more robust, single tracking signal and a quality measure. The tracking signal and the quality measure are then used by a digital control system to control motion of a surgical robotic system actuator that is associated with the UID. Other embodiments are also described and claimed.