An imaging apparatus according to the present invention includes an imaging unit configured to capture an image of an arbitrary object and output a plurality of image signals with different exposures and a focus detection signal, and a composition unit configured to compose the plurality of image signals with different exposures output from the imaging unit and output the composed image signal. In a case of time-sequentially capturing images in succession, the imaging unit outputs the focus detection signal instead of the plurality of image signals at a predetermined timing. The composition unit composes image signals by using image signals in a time-sequentially adjacent different timing instead of image signals missing at the predetermined timing.

In an image capturing apparatus that comprises a pixel area of pixels arranged in a matrix, output circuits apply preset processing to signals read out in parallel from divided areas obtained by dividing the pixel area in a column direction and output the processed signals, a controller performs control to execute first driving for reading out signals corresponding to a predetermined voltage to the output circuits, and second driving for reading out image signals from the pixel area, and a correction circuit generates gain data based on the predetermined voltage for correcting differences between the signals for correction of different columns output for each of the divide areas, and corrects the image signals of the divided areas using the gain data generated for the corresponding divided areas.

An image color retention method includes displaying a first preview image on a preview interface, where an image of a first region in the first preview image is displayed in color, and an image of a second region in the first preview image is an image obtained after processing is performed according to a target processing mode, determining a second individual object as a target object in response to a first operation of a user, and displaying a second preview image on the preview interface, where an image of a third region in the second preview image is displayed in color, and an image of a fourth region in the second preview image is an image obtained after processing is performed according to the target processing mode.

A method for processing image data may include: obtaining a first image and a second image that capture a same scene in different views, from a first camera and a second camera, respectively; spatially aligning the first image with the second image; obtaining a color transformation matrix that maps the first image to the second image based on color values of the first image and the second image; obtaining an estimated illuminant color from an output of a neural network by inputting the color transformation matrix to the neural network, wherein the neural network is trained based on a pair of reference images of a same reference scene with a color rendition chart that are captured by different cameras having different spectral sensitivities; and performing a white balance correction on the first image based on the estimated illuminant color to output a corrected first image.

A semiconductor measurement device may include an illumination apparatus having a polarizer on a propagation path of light output from a light source; an optical assembly including an objective lens configured to allow light passing through the polarizer to be incident on a sample and a beam splitter configured to transmit light reflected from the sample to first and second sensors; and a controller. The controller may be configured to determine an alignment state of patterns in a first region of the sample using a first original image output by the first sensor and an alignment state of patterns in a second region of the sample using a second original image output by the second sensor. The first sensor includes a first image sensor and a self-interference generator in a path along which light is incident on the first image sensor. The second sensor includes a second image sensor.

A semiconductor measurement device may include an illumination apparatus having a polarizer on a propagation path of light output from a light source; an optical assembly including an objective lens configured to allow light passing through the polarizer to be incident on a sample and a beam splitter configured to transmit light reflected from the sample to first and second sensors; and a controller. The controller may be configured to determine an alignment state of patterns in a first region of the sample using a first original image output by the first sensor and an alignment state of patterns in a second region of the sample using a second original image output by the second sensor. The first sensor includes a first image sensor and a self-interference generator in a path along which light is incident on the first image sensor. The second sensor includes a second image sensor.

An image sensor includes a pixel array including a plurality of unit pixels arranged along a plurality of rows and a plurality of columns. Each of the unit pixels includes a photoelectric conversion element generating and accumulating photocharges, a charge detection node receiving the photocharges accumulated in the photoelectric conversion element, a readout circuit converting the photocharges accumulated in and output from the charge detection node into an electrical pixel signal, the readout circuit outputting the electrical pixel signal, a capacitive element, and a switching element controlling connection between the charge detection node and the capacitive element. Each of the rows of the pixel array includes first pixels connected to a first conversion gain control line and second pixels connected to a second conversion gain control line.

An image sensor includes a pixel array including a plurality of unit pixels arranged along a plurality of rows and a plurality of columns. Each of the unit pixels includes a photoelectric conversion element generating and accumulating photocharges, a charge detection node receiving the photocharges accumulated in the photoelectric conversion element, a readout circuit converting the photocharges accumulated in and output from the charge detection node into an electrical pixel signal, the readout circuit outputting the electrical pixel signal, a capacitive element, and a switching element controlling connection between the charge detection node and the capacitive element. Each of the rows of the pixel array includes first pixels connected to a first conversion gain control line and second pixels connected to a second conversion gain control line.

An image sensor includes a pixel array, wherein the pixel array includes a first unit pixel including first sensing pixels adjacent along a column direction and second sensing pixels adjacent along the column direction, the first sensing pixels and the second sensing pixels being adjacent along a row direction, and a same color filter overlapping first and second sensing pixels. The first sensing pixels share a first floating diffusion node. The second sensing pixels share a second floating diffusion node.

An image sensor includes a pixel array, wherein the pixel array includes a first unit pixel including first sensing pixels adjacent along a column direction and second sensing pixels adjacent along the column direction, the first sensing pixels and the second sensing pixels being adjacent along a row direction, and a same color filter overlapping first and second sensing pixels. The first sensing pixels share a first floating diffusion node. The second sensing pixels share a second floating diffusion node.