A method of projecting a likeness of an item onto a surface is disclosed. A determination that a user is interested in an item is made. A schematic corresponding to the item is identified based on information about the item. The user is provided with an option to project a likeness of the item onto a surface. Based on an accepting of the option by the user, a device of the user is instructed to project the likeness of the item onto the surface based on the schematic.

A hydraulic tool for use with a clamp connector where a first clamping element and a second clamping element of the clamp connector are pivotable towards each other into a closed position by exerting a pulling force on an operating shaft and a pushing force on a spacer sleeve, and where said first and second clamping elements are lockable in said closed position by tightening a locking nut against a shoulder on the spacer sleeve. The tool includes a pulling element; a hydraulic power unit for moving the pulling element in relation to the spacer sleeve and thereby allow the hydraulic tool to exert a pulling force on the operating shaft and a pushing force on the spacer sleeve; a rotatable actuating member with a socket engageable with the locking nut; and a drive motor for rotating the actuating member to allow the actuating member to rotate the locking nut.

The projection type display device includes a projection display unit that includes light sources, a light modulation element that spatially modulates light emitted from the light sources, and a projection unit that projects light spatially modulated by the light modulation element onto a projection surface; a sight line detection unit that detects a line of sight; and a system controller that stops projection of the projection light onto the projection surface by the projection display unit in a state where the line of sight detected by the sight line detection unit is out of the projection surface and restarts the projection of the projection light onto the projection surface by the projection display unit after a first time elapses after a timing of moment when the line of sight is determined to move from an outside of the projection surface to an inside of the projection surface.

A sign-monitoring system includes at least one electronic sign and a controller comprising a processor and memory. The electronic sign includes a pixel array, the pixel array including a plurality of pixels. The electronic sign further includes an embedded controller coupled to the at least one electronic sign. The embedded controller develops diagnostic information for the at least one electronic sign, the diagnostic information including information related to a number of malfunctioning pixels in the plurality of pixels. The controller is communicably coupled to the embedded controller and receives at least a portion of the diagnostic information from the embedded controller. In addition, the controller assesses the at least a portion of the diagnostic information to develop health information. The assessment involves evaluating the information related to the number of malfunctioning pixels.

The invention relates to an articulated apparatus for guiding a relative movement of components into a target position, which may be the operating position of a micromanipulator arrangement. The articulated apparatus has multiple parts, which are movable with respect to each other. Two stop devices are used which, in combination, imitate the latching-in of a conventional latching device, but offer a considerably greater level of precision. A combined stop position is settable as said target position in which the first stop position and the second stop position are both present. The invention uses two stop devices in order to imitate the leaving of the latched target position in two directions as in the case of latching. Such articulated apparatus may be typically used with a micromanipulator arrangement of a cytobiological or microbiological workstation.

A fault detection system is provided for a display system including an AMLCD. A video processor embeds encoded fault detection data within the digital video stream that is sent directly to the AMLCD. The fault detection data is embedded in such a manner that it is not displayed by the AMLCD. The fault detection data in the digital video stream received by the AMLCD is detected by the AMLCD and is then sent back to the video processor. The video processor compares what was sent with what is received to determine whether there is a difference which may be indicative of a fault in the AMLCD or the path of the digital video stream. As an additional check, the AMLCD may send timing error data to the video processor indicating whether the AMLCD is working properly. The video processor generates and outputs a fault flag to initiate a corrective action if a fault is detected in the AMLCD and/or the path of the digital video stream.

A touch substrate is provided, comprising a touch region. The touch region includes a first electrode layer and a second electrode layer which are provided on a base substrate (1) and are insulated from each other; the first electrode layer includes a plurality of sensing electrodes (4) provided along rows and columns and a first connection portion (8); the second electrode layer includes a second connection portion (2); adjacent sensing electrodes (4) in a same row are connected with each other by the first connection portion (8); adjacent sensing electrodes (4) in a same column are connected with each other by the second connection portion (2); the first connection portion (8) and the second connection portion (2) cross with each other and insulate from each other; a side of the first electrode layer away from the second electrode layer is provided with connection wires (7) connected with the sensing electrodes (4), and the connection wires (7) are configured to transmit a touch drive signal or a touch detection signal; and the connection wires (7) are led out from a same side of the touch substrate. A fabrication method of the touch substrate and a display apparatus are provided to realize a non-frame or narrow-frame design.

The invention provides a Mura compensation method for display panel, which extracts the luminance information of a grayscale b other than the lowest grayscale from the inputted image through an image console, generates a Mura value index table for 0 to the lowest grayscale; uses linearly interpolation calculate the Mura values for the remaining grayscales; determines the inputted data signal; for low grayscale image smaller than the lowest grayscale, searches the index table for Mura value to perform Mura compensation to make the compensated grayscale larger than the lowest grayscale; for dynamic image, uses linear interpolation to calculate the Mura value corresponding to the inputted data signal; and for static image, uses non-linear interpolation to calculate the Mura value corresponding to the inputted data signal. As such, the Mura compensation effect is improved for static and low grayscale images; moreover, the memory speed requirement is reduced.