A method for manufacturing an array substrate and an array substrate are provided. The method includes: providing a base substrate; forming a driving circuit layer at a side of the base substrate; and forming a functional device layer at a side of the driving circuit layer. Forming the driving circuit layer includes forming at least one first lead layer. Forming the first lead layer includes: forming a conductive seed layer at the side of the base substrate; forming a removable pattern-defining layer on a surface of the conductive seed layer, the removable pattern-defining layer being provided with a lead opening exposing a part of the conductive seed layer; forming, in the lead opening, a metal plating layer on the surface of the conductive seed layer; removing the removable pattern-defining layer; and removing a part of the conductive seed layer not covered by the metal plating layer.

An electro-optical device is provided. The electro optical device includes: a light emitting element configured to emit light according to a current flowing between a pixel electrode and a common electrode; a plurality of power-supply wiring lines provided at a side of the pixel electrode and configured to be supplied with a power source potential; a plurality of data lines; a data-signal outputting circuit configured to output a data signal to a data line; a conductive wiring line provided to overlap with the data-signal outputting circuit in plan view and configured to be supplied with the power source potential through a plurality of mounting terminals, in which each of the plurality of power-supply wiring lines is provided between the plurality of data lines in plan view and electrically coupled to the conductive wiring line.

A variety of methods for driving electro-optic displays so as to reduce visible artifacts are described. Such methods include (a) applying a first drive scheme to a non-zero minor proportion of the pixels of the display and a second drive scheme to the remaining pixels, the pixels using the first drive scheme being changed at each transition; (b) using two different drive schemes on different groups of pixels so that pixels in differing groups undergoing the same transition will not experience the same waveform; (c) applying either a balanced pulse pair or a top-off pulse to a pixel undergoing a white-to-white transition and lying adjacent a pixel undergoing a visible transition; (d) driving extra pixels where the boundary between a driven and undriven area would otherwise fall along a straight line; and (e) driving a display with both DC balanced and DC imbalanced drive schemes, maintaining an impulse bank value for the DC imbalance and modifying transitions to reduce the impulse bank value.

Disclosed are a display panel and a display device. The display panel includes a display area and a non-display area surrounding the display area. The display area includes scan lines arranged in a second direction and each extending in a first direction, data lines arranged in the first direction and each extending in the second direction, and pixel driver circuits defined by the scan lines and the data lines intersecting each other, the first direction intersecting the second direction. The non-display area includes a step area and a compensation unit, and the compensation unit is located between the step area and a last row of pixel driver circuits. The compensation unit is connected to a corresponding data line and configured to transmit a leakage current compensation signal to the data line.

The present application provides a method for driving a mini-LED backlight module. The method includes dividing the mini-LED backlight module into a plurality of partitions along an extending direction of a data line, dividing a period of each frame used in the mini-LED backlight module into an adjusting sub-field, and adjusting durations of a bright sub-field or a dark sub-field of the adjusting sub-field corresponding to different partitions based on different gray modes. In such a way, the brightness of each partition falls within a configured brightness threshold range.

A light-emitting substrate and a display device are provided by the present application. The durations of pre-set periods of a plurality of driving circuits decrease along a direction from close to data signal input terminals to away from the data signal input terminals, and/or durations of the pre-set periods of the plurality of driving circuits decrease along a direction from close to first control signal input terminals to away from the first control signal input terminals, which the light-emitting luminance of the light-emitting elements at a near-end and far-end solving a display problem with the display device.

Disclosed are a display substrate, a preparation method thereof, and a display device. The display substrate includes a display region and a bonding region on one side of the display region. The bonding region at least includes a lead area. The display region includes a plurality of data lines and a plurality of data fanout lines. The lead area includes a plurality of lead wires. Orthographic projections of the plurality of data lines and the plurality of data fanout lines on a plane of the display substrate are at least partially overlapped. A first end of at least one data fanout line is connected to the lead wire, and a second end of the at least one data fanout line extends in a direction away from the lead area, to be connected to the data line.

A method may include generating display driver signals that vary between only two levels and applying the display driver signals to opposing electrodes of a display segment within a display device. An intrinsic capacitance of the display device filters the display driver signals to generate different analog signal levels at the display segment of the display device. The method varies the pulse density of the display driver signals to select or de-select the display segment based on an average voltage magnitude across the display segment over a time period. The display segment is activated when the average voltage magnitude exceeds a threshold value.

The present disclosure relates to a display device and a driving method thereof, wherein a refresh rate of pixels is controlled at a reference frame frequency in a normal driving mode, and the refresh rate of the pixels is controlled at a frequency lower than the reference frame frequency in a low speed driving mode. In the low speed driving mode, park data is transmitted to a data driving circuit during at least one vertical blank period.

A display device is disclosed. The display device includes a first display test signal inputting part, configured to input a first display test signal. The display device also includes a first display test signal controlling part, configured to control the input of the first display test signal. The display device also includes a second display test signal inputting part, configured to input a second display test signal. The display device also includes a first test bus, connected to the first display test signal inputting part. The display device also includes a second test bus, connected to the second display test signal inputting part, where the first test bus and the second test bus are connected with each other.