Methods for driving an electro-optic display having a plurality of display pixels and each of the plurality of display pixels is associated with a display transistor, the method includes applying a first voltage to a transistor associated with a display pixel for a first duration of time to drain remnant voltages from the display pixel, applying a second voltage to the transistor for a second duration of time to stop the draining of remnant voltages from the display pixel, and applying a third voltage to the transistor for a third duration of time to drain remnant voltages from the display pixel.

According to the array substrate provided by this disclosure, in a row of sub-pixels, sub-pixels in the odd columns and even columns are separately coupled to different gate lines, i.e., making the sub-pixels coupled to the same gate line are not adjacent to each other. In this way, during row scanning drive, an up-down twist charging may be implemented, and the sub-pixels cause no interference to each other.

A system reads a desired circuit parameter from a pixel circuit that includes a light emitting device, a drive device to provide a programmable drive current to the light emitting device, a programming input, and a storage device to store a programming signal. One embodiment of the extraction system turns off the drive device and supplies a predetermined voltage from an external source to the light emitting device, discharges the light emitting device until the light emitting device turns off, and then reads the voltage on the light emitting device while that device is turned off. The voltages on the light emitting devices in a plurality of pixel circuits may be read via the same external line, at different times. In-pixel, charge-based compensation schemes are also discussed, which can be used with the external parameter extraction implementations.

This disclosure provides apparatuses and methods of manufacturing apparatuses including thin film transistors (TFTs) and storage capacitors. An apparatus can include a substrate, a TFT, a storage capacitor adjacent to the TFT, and a common electrode. The storage capacitor can be substantially transparent to increase aperture ratio of a display device. The storage capacitor can include an insulating layer between a first transparent electrode and a second transparent electrode. The TFT can include a gate electrode, a gate insulating layer, an oxide semiconductor, source and drain electrodes, and a dielectric layer. The oxide semiconductor can be formed out of the same layer as the first transparent electrode, and the common electrode can be formed out of the same layer as the oxide semiconductor or the source and drain electrodes.

Provided is a driving device of a display medium, including an application unit that applies a voltage with a pulse width corresponding to a density of a color to be displayed to each of plural pixels of a display medium in which plural kinds of particle groups having different movement starting voltages for movement between a pair of substrates according to an electric field and different colors are enclosed, and a controller that controls the application unit so that a first voltage with a pulse width corresponding to a density of a color of a first particle group finishes being applied to each of the plural pixels, and then a second voltage with a pulse width corresponding to a density of a color of a second particle group is applied thereto.

The present disclosure provides LED drivers and methods for driving LED matrixes in response to display signals. According to one exemplary embodiment, an LED driver is provided. The LED driver includes a two-dimensional pulse profile engine that receives display signals and timing signals, and produces a pulse profile defining signal amplitudes at various times during a driving pulse to produce a desired LED output that accounts for artifacts of the LED matrix and other driver circuitry. The LED driver further includes current forming circuitry and driver circuitry. The current forming circuitry can be configured to form a driving pulse to reflect the pulse profile. The driver circuitry can be coupled to the two-dimensional pulse profile engine and the current forming circuitry for forming a current pulse to one or more LEDs in the matrix.

A display panel includes a plurality of sub-pixels. At least one sub-pixel of the plurality of sub-pixels includes a first electrode, a light modulation structure disposed on a side of the first electrode, and a second electrode disposed at a side of the light modulation structure away from the first electrode. The light modulation structure includes a refractive index adjustment layer, and a light modulation layer disposed between the refractive index adjustment layer and the first electrode. A refractive index of the refractive index adjustment layer is changed under action of an electric field between the first electrode and the second electrode. The light modulation layer is in contact with the refractive index adjustment layer, and at least a part of a surface of the light modulation layer that is in contact with the refractive index adjustment layer is a curved face.

A display device includes a display panel including pixels, a data driver configured to provide a data signal and an emission voltage to the pixels through the data lines, a scan driver configured to provide a scan signal to the pixels through the scan lines, a power voltage provider configured to provide a high power voltage to the pixels through a high power voltage line and to provide a low power voltage to the pixels through a low power voltage line, and a timing controller configured to generate control signals that control the data driver and the scan driver. The display panel includes a power controller that determines whether the data line is coupled to the high power voltage line or to the low power voltage line.

New reflective display architecture embodiments are disclosed to create specular or paper-like reflectance comprising a transparent outer sheet with an optional light diffusing layer, a rear backplane electrode, a perforated continuous reflective or non-reflective film with a thin conductive reflective or transparent layer acting as a front electrode facing the transparent outward sheet placed between the transparent outward sheet and rear backplane electrode. Other variations include semi-retroreflective or sintered TiO.sub.2 layers atop the front electrode. Light is modulated by reflectance or absorbance of the light rays that pass through the transparent outward sheet by movement of light absorbing electrophoretically mobile particles within an optically transparent liquid or air medium. A voltage bias is applied across the medium by a voltage source to move the electrophoretically mobile particles.

A display device includes a support and first and second conductive electrical power supply elements, the first conductive element being arranged on the support. The display device also includes LED modules, each including at least one LED and two electrical power supply pads that are arranged on two opposite faces, respectively, of the LED module, one of which corresponds to an emissive face of the LED. The electrical power supply pads of each LED module are connected to the first and second conductive electrical power supply elements, respectively, and the connection area of an electrical power supply pad of an LED module for connection with the first conductive electrical power supply element is smaller than a receiving area of the first conductive element corresponding to the area of the first conductive element in a parallel plane to the connection areas of the power supply pads of the LED modules.