Provided are a touch display panel and a detection method thereof, and a touch display apparatus. The touch display panel includes a display structure layer, a touch structure layer, a touch detection circuit and a detection signal line. The display structure layer includes a plurality of data lines, and the touch structure layer includes a plurality of touch signal lines. A timing of the touch display panel includes a detection stage. The touch detection circuit is connected with touch signal lines, data lines and the detection signal line, and is configured to provide, in the detection stage, a signal of the touch signal line to a data line under a control of a detection signal of the detection signal line, to detect the touch signal line according to a light emission state of pixel units to which the data line is connected.

An object is to reduce the number of false detections of defects in a screen display test. A third control section includes: a first data acquiring section; a second data acquiring section; a comparing section configured to carry out a comparison between the first data and the second data; a searching section configured such that, in a case where there is a mismatch frame, the searching section carry out a search as to whether or not any of frame images matches up with the base image; and a third display control section configured such that, in a case where none of the frame images in the predetermined number of frames matches up with the base image, the display control section controls an output section to make an output indicating that there is a defect in the second data.

Apparatuses, systems, methods, and computer program products are presented for multi-platform testing automation. A method includes electrically triggering, with a rotate command, at least one mechanical actuator to rotate a frame to successively present different faces of the frame to a camera of a mobile hardware device. A method includes simulating one or more touch input events on a mobile hardware device for each successively presented different face of a frame. At least one mechanical actuator and a mobile hardware device are disposed within an enclosure that comprises a light source. A method includes receiving data associated with simulated one or more touch input events and a camera of a mobile hardware device from the mobile hardware device over a data network.

An enclosure for testing performance of an application contains one or more devices. A first device being tested presents output using a display or a speaker. A camera or microphone, which may be associated with a second device in the enclosure, acquires information regarding the output, such as by acquiring data representing the display output of the first device using a camera. An interface presenting information regarding the performance of the application includes information determined using the camera or microphone, which may be useful when the first device is unable to directly capture the output that is presented. In other cases, a second device in the enclosure may provide a display output or an audio output, and the first device may receive the output using a camera or microphone, enabling the performance of the application relating to receipt of input by the first device to be tested.

A display apparatus according to an example embodiment may include: a substrate including a display area and a non-display area outside the display area; a plurality of pixels in the display area; a plurality of touch electrodes overlapping with the pixels in the display area; a gate driving circuit in the non-display area and connected to the touch electrodes via at least one gate driving line; and a touch inspection circuit in the non-display area and connected to the touch electrodes through at least one touch line, the touch inspection circuit including at least one touch inspection switch and a touch inspection control switch.

Hardware monitors which can be used by a formal verification tool to exhaustively verify a hardware design for a memory unit. The hardware monitors include detection logic to monitor one or more control signals and/or data signals of an instantiation of the memory unit to detect symbolic writes and symbolic reads. In some examples a symbolic write is a write of symbolic data to a symbolic address; and in other examples a symbolic write is a write of any data to a symbolic address. A symbolic read is a read of the symbolic address. The hardware monitors also include assertion verification logic that verifies an assertion that read data corresponding to a symbolic reads matches write data associated with one or more symbolic writes preceding the read.

A touch screen testing platform may be used to engage a dynamically positioned target feature being displayed on a touch screen enabled device during a testing protocol. The platform may record imagery displayed by the touch screen device and then analyze the imagery to locate the target feature within a reference coordinate system. The platform may recognize that the target feature is missing from the imagery and respond by causing the touch screen device to scroll through a command menu and/or toggle through virtual screens. Once located, the platform may instruct a robotic device tester to select the target feature by contacting the touch screen at the identified location using a conductive tip designed to simulate a user's fingertip. Prior to running a test, the camera may be focused to a point that is offset from the display screen of the touch screen device.

A display panel and a testing method thereof, the display panel including a product region and a cutting region, and the product region including a display sub-region and a non-display sub-region. The display panel includes a flexible substrate, a thin film transistor layer, an organic light-emitting layer, a encapsulation layer, and a touch layer. The touch layer includes touch electrodes and touch leads. An end of each of the touch leads is connected to a corresponding touch electrode, the other end of each of the touch leads extends from the non-display sub-region to the cutting region, and a density of the touch leads in the cutting region is less than a density of the touch leads in the non-display sub-region.

An apparatus can include a calibration circuit to determine a backlight status of a display device based on a detected difference in a noise level corresponding to the display device. The calibration circuit can perform an operation to calibrate a touchscreen coupleable to the display device based on the determined backlight status.

A complex programmable logic device includes a SGPIO analyzing circuit, a I.sup.2C analyzing circuit and a first multiplexer. The SGPIO analyzing circuit has a plurality of port analyzing circuits, a detecting circuit and a processing circuit. Each port analyzing circuit receives an input signal and outputs a first data. The detecting circuit detects the input signal of the first port analyzing circuit to output a detecting signal. The processing circuit captures port information of the first data outputted by at least part of the port analyzing circuits as a first control signal according to the detecting signal. The I.sup.2C analyzing circuit analyzes a data flow for outputting a second control signal according to an address command related to an address message, a control command and an input data. The first multiplexer selects the first control signal or the second control to be outputted according to a testing signal.