A display apparatus is provided, which includes a display module, a biosensor, an ambient-light sensor, and a display controller. The ambient-light sensor is configured to detect ambient-light brightness and an ambient-light color temperature of the display apparatus. The display controller is configured to receive a video signal from a host, and displays the video signal on the display module. When the biosensor detects that a user is located in front of the display apparatus, the biosensor transmits an image-adjustment control signal to the display controller to control the display apparatus to enter an image-adjustment mode. When the display apparatus is in the image-adjustment mode, the display controller adjusts screen brightness and a screen color temperature of the image signal displayed on the display module according to the ambient-light brightness and the ambient-light color temperature.

A method for driving electro-optic displays including electro-optic material disposed between a common electrode and a backplane. The backplane includes an array of pixel electrodes, each coupled to a transistor. A display controller applies waveforms to the pixel electrodes. The method includes applying first measurement waveforms to a first portion of the pixel electrodes. During each frame of the first measurement waveforms, the same time-dependent voltages are applied to each pixel electrode of the first portion of pixel electrodes. The method includes determining the impedance of the electro-optic material in proximity to the first portion of pixel electrodes based on a measurement of the current flowing through a current measurement circuit and the time-dependent voltages applied to each pixel electrode during the first measurement waveforms, and selecting driving waveforms based on the impedance of the electro-optic material in proximity to the first portion of pixel electrodes.

The present disclosure discloses a display device and a driving method of the display device. The display device includes a display panel for displaying an image, a driver for driving the display panel, a controller for controlling the driver, and a duty cycle controller for defining an unknown area in which vertical resolution information is not known and a known area in which the vertical resolution information is known within one frame when a driving frequency of the display panel is changed, and varying a duty cycle for driving the known area.

A display device configured to communicate with at least one other display device connected to a network is disclosed. The display device includes communication circuitry configured to receive unique information and a service set identifier (SSID) from each of the at least one other display device, the unique information for use in identification of each of the at least one other display device, and a controller configured to change an SSID based on a comparison between unique information of the display device and at least one piece of the received unique information.

An electronic device includes a display including at least one pixel and at least a partial area of which is transparent. The electronic device also has a fingerprint sensor disposed in an area under the display, on which a screen is displayed, to collect light, a direction of which is changed by an object approaching the display and acquire image information related to fingerprint authentication. In addition, the electronic device has a processor adapted to acquire image information of the fingerprint sensor.

An electronic device may include a first display pipeline that may output image data via an output path. The electronic device may include first frame merge circuitry coupled to the output path. The electronic device may also include a first multiplexer coupled to the first frame merge circuitry and to the output path. The first multiplexer may transmit the image data from the output path to an electronic display, and, in response to a first control signal associated with the first frame merge circuitry generating a merged output, the first multiplexer transmits the merged output to the electronic display.

An electronic device may include: a memory, a display, a haptic module comprising haptic circuitry, a sound module comprising audio circuitry, and a processor. The processor may be configured to: detect an event for an output of vibration and sound, delay the output of the vibration, change a sound output mode from a first mode to a second mode for fast output while the output of the vibration is delayed, output the sound using the sound module in the second mode, and output the delayed vibration through the haptic module to be synchronized with the output of the sound. As the sound output mode is changed to the second mode, a sound output path may be opened. The sound output path may be changed from the first path for non-fast output to the second path for fast output.

Some embodiments of the invention provide a map application with novel map exploration tools. In some embodiments, the map application executes on a mobile device (e.g., a handheld smartphone, a tablet, etc.) with a touch sensitive screen. The map application of some embodiments has a first display area to display a map of a region, and second and third display areas to display information about items displayed on the map in the first display area. In some embodiments, the second display area slides over the first display area to overlap at least a portion of the first display area. After the second display area slides over the first display area, the third display area in some embodiments slides over the first display area to overlap at least a portion of the first display area. In some embodiments, the second and third display areas slide over the first display area from one side of the first display area. This side is the bottom of the first display area in some embodiments. In some embodiments, the bottom side is expected to be closer to a position for resting the mobile device in a hand of a user than a top side of the first display area. Accordingly, in some embodiments, the second and third display areas slide up from the bottom side of the first display area so that information and/or controls that are provided in these display areas are more accessible for one handed operations (e.g., thumb-based touch operations) of the user as the user hold and interacts with the device with one hand.

Apparatuses, systems, methods, and computer program products are disclosed for adjusting brightness settings based on proximity and context data. A proximity module determines a proximity of a first information handling device to a second information handling device. A context module determines context data associated with one or more of the second information handling device and a user of the second information handling device. An adjustment module adjusts a brightness setting of the first information handling device based on the determined proximity and the context data.

A method, system and computer program product applying an application profile to a display configuration of a device, which overrides the default ambient light setting (ALS) data associated with a display. The method includes detecting initiation of an application. The method further includes searching at least one database for an application profile associated with the application. The application profile includes application-specific ALS data, which establishes an application-specific configuration of the display while the application is open on the display. In response to locating the application profile within the at least one database, the application profile is applied to the display, with the application-specific ALS data replacing/overriding the default ALS data.