An organic light emitting device includes: a substrate; a thin film transistor disposed on the substrate; an organic light emitting element connected to the thin film transistor and receiving a data voltage; a plurality of encapsulation thin films disposed on the organic light emitting element, and encapsulating the thin film transistor and the organic light emitting element; a planarization layer disposed on the encapsulation thin film; and a touch sensor disposed on the planarization layer.

An organic light emitting device includes: a substrate; a thin film transistor disposed on the substrate; an organic light emitting element connected to the thin film transistor and receiving a data voltage; a plurality of encapsulation thin films disposed on the organic light emitting element, and encapsulating the thin film transistor and the organic light emitting element; a planarization layer disposed on the encapsulation thin film; and a touch sensor disposed on the planarization layer.

A touch panel assembly adapted to reduce electromagnetic interference is disclosed. An electronic display is provided within a housing for an instrument panel of a vehicle. A resistive touch panel includes first and second independently operable, seamless grid sections and touch input receivers placed adjacent to the grid sections. A first input/output device in electronic communication with the display and associated with the first grid section and a second input/output device in electronic communication with the display and associated with the second grid section extends through at least one electromagnetically shielded channel that extends from within said housing to outside of said housing.

A touch panel assembly adapted to reduce electromagnetic interference is disclosed. An electronic display is provided within a housing for an instrument panel of a vehicle. A resistive touch panel includes first and second independently operable, seamless grid sections and touch input receivers placed adjacent to the grid sections. A first input/output device in electronic communication with the display and associated with the first grid section and a second input/output device in electronic communication with the display and associated with the second grid section extends through at least one electromagnetically shielded channel that extends from within said housing to outside of said housing.

Apparatus, systems, and methods for display panel power savings during stylus usage are disclosed. An example apparatus includes interface circuitry to receive touch event location data indicative of touch events by a user on a display screen of an electronic device; and processor circuitry to perform operations to instantiate display mapping circuitry to identify an area of the display screen covered by a portion of a body of the user based on a shape of the portion; and pixel identification circuitry to identify respective ones of pixels of the display screen in the area of the display screen; and cause a property of the respective ones of the pixels to be adjusted.

Apparatus and methods of impedance sensing are described. One method includes performing a first digital conversion of an attribute of a sensor electrode and performing a second digital conversion of the attribute of the sensor electrode. The second digital conversion differs by at least one characteristic from the first digital conversion. The method further includes calculating a resistance of the sensor electrode from a first and second digital value of the first and second digital conversions, respectively; and calculating a capacitance of the sensor electrode from the first and second digital value of the first and second digital conversions, respectively.

Apparatus and methods of impedance sensing are described. One method includes performing a first digital conversion of an attribute of a sensor electrode and performing a second digital conversion of the attribute of the sensor electrode. The second digital conversion differs by at least one characteristic from the first digital conversion. The method further includes calculating a resistance of the sensor electrode from a first and second digital value of the first and second digital conversions, respectively; and calculating a capacitance of the sensor electrode from the first and second digital value of the first and second digital conversions, respectively.

A touch display and an anti-interference method thereof are provided. The touch display has a display panel, a touch panel, a touch chip, and a compensation circuit. A compensation signal line is led out from a common electrode layer of the display panel. A sensing signal line is led out from a touch layer of the touch panel. An input terminal of the compensation circuit is connected to the compensation signal line and the sensing signal line, and a compensated sensing signal is output to the touch chip from the output terminal. An ability of the touch screen to resist noise interference is improved.

A touch display and an anti-interference method thereof are provided. The touch display has a display panel, a touch panel, a touch chip, and a compensation circuit. A compensation signal line is led out from a common electrode layer of the display panel. A sensing signal line is led out from a touch layer of the touch panel. An input terminal of the compensation circuit is connected to the compensation signal line and the sensing signal line, and a compensated sensing signal is output to the touch chip from the output terminal. An ability of the touch screen to resist noise interference is improved.

A touch screen sensor includes a visible light transparent substrate and an electrically conductive micropattern disposed on or in the visible light transparent substrate. The micropattern includes a first region micropattern within a touch sensing area and a second region micropattern. The first region micropattern has a first sheet resistance value in a first direction, is visible light transparent, and has at least 90% open area. The second region micropattern has a second sheet resistance value in the first direction. The first sheet resistance value is different from the second sheet resistance value.