A method for operating an electronic display includes receiving, using a controller, sensor data related to operational parameters of the electronic display based at least in part on illuminating a sense pixel of at least one row of pixels of the electronic display, wherein a first set of pixels below the at least one row of pixels renders a portion of a first image frame and a second set of pixels above the at least one row of pixels renders a portion of a second image frame. The method also includes adjusting, using the controller, image display on the electronic display based at least in part on the sensor data.

The present technology relates to a solid-state imaging device, a method of manufacturing the same, and an electronic device capable of improving sensitivity in a certain wavelength band and at the same time reducing color mixture of light of other wavelength bands in a photoelectric conversion unit. The solid-state imaging device is provided with a first photoelectric conversion unit which generates a signal charge corresponding to a light amount of light of a first color component on a short wavelength side out of incident light, a second photoelectric conversion unit which generates a signal charge corresponding to a light amount of light of a second color component on a long wavelength side out of the incident light, and a first optical interference film provided between the first photoelectric conversion unit and the second photoelectric conversion unit formed below the first photoelectric conversion unit which transmits the light on the long wavelength side while reflecting the light on the short wavelength side out of the incident light. The present technology may be applied to a CMOS image sensor, for example.

An image sensor may include an organic photo-sensing device configured to selectively sense first visible light and a photo-sensing device array including a first photo-sensing device configured to selectively sense second visible light, a second photo-sensing device configured to selectively sense third visible light, and a third photo-sensing device configured to selectively sense mixed light of the second visible light and the third visible light. The image sensor may include a color filter array including a first color filter configured to selectively transmit the second visible light, a second color filter configured to selectively transmit the third visible light, and a third color filter configured to transmit mixed light of the second visible light and the third visible light. At least the first photo-sensing device and the second photo-sensing device may be at different depths in a substrate and may be laterally offset from each other.

A substrate has a first surface and a second surface facing each other. A photoelectric conversion region includes a plurality of photoelectric conversion devices provided in the substrate. An interlayered insulating layer is provided on the first surface of the substrate. A plurality of wires is provided on the interlayered insulating layer. An inter-wire insulating layer covers the plurality of wires. A plurality of micro lenses is provided on the second surface of the substrate. A grid pattern is provided in at least one of the interlayered insulating layer and the inter-wire insulating layer. The grid pattern, when viewed in a plan view, overlaps a region between two adjacent photoelectric conversion devices of the plurality of photoelectric conversion devices.

A method for operating an electronic display includes receiving, using a controller, sensor data related to operational parameters of the electronic display based at least in part on illuminating a sense pixel of at least one row of pixels of the electronic display, wherein a first set of pixels below the at least one row of pixels renders a portion of a first image frame and a second set of pixels above the at least one row of pixels renders a portion of a second image frame. The method also includes adjusting, using the controller, image display on the electronic display based at least in part on the sensor data.

An imaging apparatus includes a storage portion that stores captured image data obtained by imaging a subject by an imaging element and is incorporated in the imaging element, an output portion that is incorporated in the imaging element, and a plurality of signal processing portions that are disposed outside the imaging element, in which the output portion includes a plurality of output lines each disposed in correspondence with each of the plurality of signal processing portions and outputs each of a plurality of pieces of image data into which the captured image data stored in the storage portion is divided, to a corresponding signal processing portion among the plurality of signal processing portions from the plurality of output lines, and any of the plurality of signal processing portions combines the plurality of pieces of image data.

An imaging apparatus includes a storage portion that stores captured image data obtained by imaging a subject by an imaging element and is incorporated in the imaging element, an output portion that is incorporated in the imaging element, and a plurality of signal processing portions that are disposed outside the imaging element, in which the output portion includes a plurality of output lines each disposed in correspondence with each of the plurality of signal processing portions and outputs each of a plurality of pieces of image data into which the captured image data stored in the storage portion is divided, to a corresponding signal processing portion among the plurality of signal processing portions from the plurality of output lines, and any of the plurality of signal processing portions combines the plurality of pieces of image data.

Provided are an image sensor and an imaging device including the same. The image sensor is configured to generate illuminance data by receiving a light signal including image information of an object and ambient light information and includes a sensing module including a pixel array including a plurality of unit pixels, configured to sense the light signal irradiated to the pixel array and to generate pixel data corresponding to the sensed light signal, and an illuminance data generator configured to generate illuminance data corresponding to ambient light based on the pixel data, wherein the illuminance data generator is configured to generate the illuminance data based on pixel data when the light signal is not focused on the pixel array.

An image capture device, pixel, and method of determining a focus setting for an image capture device are described. The image capture device includes an imaging area and a pixel readout circuit. The imaging area includes a plurality of pixels. The plurality of pixels includes multiple pixels in which each pixel of the multiple pixels includes a two-dimensional array of photodetectors and a microlens. Each photodetector in the array of photodetectors for a pixel is electrically isolated from each other photodetector in the array of photodetectors. A microlens is disposed over the array of photodetectors for the pixel. The pixel readout circuit includes, per pixel, a shared readout circuit associated with the array of photodetectors for the pixel and a set of charge transfer transistors. Each charge transfer transistor is operable to connect a photodetector in the array of photodetectors to the shared readout circuit.

An imaging device includes: a pixel array including pixels including a first pixel and a second pixel, each of the pixels including a photoelectric converter that converts light into charge, the photoelectric converter including a first electrode, a second electrode facing the first electrode, and a photoelectric conversion layer between the first electrode and the second electrode; and an addition circuit that adds together a signal generated in the first pixel and a signal generated in the second pixel.