A bridge device for measuring the thickness of mainly flat panels to be placed in a panel production line includes a frame having feet for fixing the bridge device to the floor; a plurality of supports that support measuring contact systems, which are slidable perpendicularly to the conveying direction of the panels so to adjust their positions for a transversal measure of the panels; a plurality of measuring contact systems, of which is one is for each longitudinal side of the panels; a photocell detecting the position of the panels and their lengths; blocking knobs for blocking the supports; and a device transmitting the information concerning the actual thickness of each panel to a machine for treating one of the main surfaces of the panel.

According to an aspect, a manufacturing method of a display device includes: obtaining a first reference position on a surface of a holding substrate based on positions of a plurality of first alignment marks of the holding substrate; and aligning the holding substrate with a transfer destination substrate such that the first reference position on the holding substrate and a second reference position on a surface of the transfer destination substrate coincide. The holding substrate is sectioned into a plurality of first sections and a plurality of second sections when viewed from one direction. Each of the first sections is provided in a part of a gap between the second sections when viewed from the one direction, has a light transmission rate higher than a light transmission rate of the second sections, and forms the first alignment mark through which light passes when viewed from the one direction.

An apparatus for contactless transportation of a device in a vacuum processing system is described. The apparatus includes: a magnetic transportation arrangement for providing a magnetic levitation force (F.sub.L) for levitating the device, the magnetic transportation arrangement comprising one or more active magnetic units; a sensor for monitoring a motion of the device, and a controller configured for controlling the one or more active magnetic units based on a signal provided by the sensor.

A semiconductor manufacturing apparatus according to an embodiment includes: a stage to have a plurality of pins to hold a semiconductor substrate having a first surface on which a film to be etched is formed and a second surface positioned on an opposite side to the first surface; a nozzle to eject a liquid chemical toward the first surface of the semiconductor substrate from above the stage; and an optical measurer to radiate light toward the second surface of the semiconductor substrate from a side of the stage during ejection of the liquid chemical, and to measure a displacement amount of the semiconductor substrate based on a state of reception of light reflected on the second surface.

The present application discloses a collision prevention system of automated overhead hoist, including: a traveling track; overhead hoists movably mounted on the traveling track; photoelectric sensing apparatuses, arranged below the traveling track, and configured to form protection areas below the traveling track and output a feedback signal when detecting that an unexpected object enters the protection areas; and a control system, connected to the overhead hoists and the photoelectric sensing apparatuses, and configured to control at least one of the overhead hoists to stop moving upon receiving the feedback signal.

The present disclosure relates to a wafer processing apparatus and a wafer transfer method. The wafer processing apparatus includes: a first machine; a second machine, including a manipulator, the manipulator transfers a wafer to the machine through a connection port; the connection port is provided between the first machine and the second machine; door panels, provided on the first machine and used to close the connection port; a detector, for detecting a current position of the door panel; a driver, connected to the door panel, for driving the door panel to move to open or close the connection port; and a controller, connected to the detector, the driver and the manipulator, for controlling the door panel to move according to the current position of the door panel to open or close the connection port, and control the manipulator to transfer the wafer.

A reactor system with stuck lift pin detection. The system includes a reaction chamber, a susceptor for supporting wafers in an interior space of the reaction chamber, and an elevator for raising and lowering the susceptor in the interior space. Further, the system includes a lift pin supported by and extending vertically through the susceptor to travel between an up and a down position with movements of the susceptor by the elevator, and a landing pad is provided in the system for receiving a base of the lift pin when the lift pin is in the down position. Significantly, the system also includes a sensor assembly with a sensor positioned at least partially within the interior space of the reaction chamber. An output signal of the sensor is indicative of whether the lift pin is sticking or seizing during travel through the susceptor.

A conveyance abnormality prediction system includes an estimation unit that has a learned model having machine learned a relationship between a data set including sensor data outputted, at a time of substrate transport in the past, from each of a plurality of sensors provided on a substrate transport unit and a degree of conveyance abnormality at the time of the substrate transport, estimates a degree of conveyance abnormality at a time of new substrate transport by using, as an input, a data set including sensor data outputted from each of the plurality of sensors at the time of the new substrate transport, and outputs the estimated degree of conveyance abnormality.

A component mounting system for mounting a component on a substrate, the mounting system comprising a component supplying unit configured to supply the component; a substrate holding unit configured to hold the substrate in an orientation such that a mounting face for mounting the component on the substrate is facing vertically downward; a head configured to hold the component from vertically below; and a head drive unit that, by causing vertically upward movement of the head holding the component, causes the head to approach the substrate holding unit to mount the component on the mounting face of the substrate.

A method for adjusting a chip mounting position, an apparatus, a medium, and an electronic device are provided. The adjustment method includes: obtaining offsets of actual mounting positions of individual chips in a first group of chips; obtaining an average offset for the actual mounting positions of the individual chips in the first group of chips according to the offsets of the actual mounting positions of the individual chips in the first group of chips; and adjusting the chip mounting position according to the average offset for the actual mounting positions of the individual chips in the first group of chips.