The present invention provides a control method of an image reading device, an image reading device, and a non-transitory computer-readable medium having a program stored thereon, which avoid a reduction in reading resolution. The control method of the image reading device includes: a first step (ST101) of generating N line-shaped images indicating N line-shaped regions (W11) in an imaging target (T1) being conveyed in a conveying direction (X1) by imaging the N line-shaped regions (W11) extending in a direction perpendicular to the conveying direction (X1); a second step (ST102) of performing the same step as the first step (ST101) at a point in time when the imaging target (T1) is conveyed by an amount associated to a width (11a) of N−1 line-shaped regions; and a step (ST103) of generating a read image by arranging the N line-shaped images generated in each of the steps in ascending order.

The invention provides an imaging compensation device, method, and application. The imaging compensation method comprises the steps of: capturing a first image from a predetermined object by a camera; capturing a second image from the predetermined object through a display panel by the camera installed under the display panel; analyzing difference between parameters of the first image and parameters of the second image to construct an imaging compensation algorithm; and using the imaging compensation algorithm to compensate parameters of a last obtained image captured through the display panel by the camera.

Endoscopic systems, non-transitory, machine-readable storage media, and methods for correcting brightness non-uniformity are described. In an embodiment, the endoscopic system includes a light source positioned to emit illumination light onto a scene; a photodetector positioned to receive illumination light reflected off of the scene and configured to generate a scene signal based on the received illumination light; a display; and a controller operatively coupled to the light source, the photodetector, and the display. In an embodiment, the controller including logic that, when executed by the controller, causes the endoscopic system to perform operations including: illuminating the scene with the light source; detecting a scene depth; estimating a scene-specific brightness non-uniformity correction based on the detected scene depth and an endoscopic system brightness non-uniformity profile; and displaying an image of the scene with the display based on the scene signal, the detected scene depth, and the endoscopic system brightness non-uniformity correction.

An imaging system includes: an imaging unit that captures an image of an eye area of a target person by using an image sensor that allows imaging without saturating observed light; an acquisition unit that obtains, from the image, a first information about a first area that does not include reflection of light by an eyeglass lens of the target person, and a second information about a second area that includes the reflection of the light; and a correction unit that corrects the second information so as to reduce an influence of the reflection, on the basis of the first information. According to such an imaging system, it is possible to properly capture the iris image even when the target person is wearing eyeglasses.

An imaging device includes an imaging element and an image processor that receive subject light through an opening in a housing and generate image data, an illuminometer that detects a brightness level in a surrounding environment, an illumination light source that emits illumination light, a switch including a first filter to prevent the illumination light from entering the imaging element and a second filter to allow the illumination light to enter the imaging element to place one of the first filter or the second filter on a front surface of the imaging element based on the brightness level in the surrounding environment detected by the illuminometer, and a setter that sets an amplification factor to be used by the image processor in generating the image data based on the brightness level in the surrounding environment detected by the illuminometer before the image processor starts generating the image data.

Image sensor circuitry comprising an image sensor and method for supporting reduction of laser speckle effects in a digital image. Per each pixel position (x, y) of at least a subregion of the image sensor, the image sensing circuitry: Assigns to said pixel position (x,y) a predefined pixel window (w) comprising said pixel position (x,y) and one or more of its closest neighboring pixel positions. Obtains first pixel values for each pixel located within said predefined pixel window (w), said first pixel values resulting from the same exposure and corresponding to sensed light from this exposure. Combines the obtained first pixel values into a single, second pixel value according to a predefined combination function. The digital image is provided based on the second pixel values.

An image display device includes an imaging unit, a color temperature detection unit, a color temperature sensor, a white balance adjustment unit and a display unit. The imaging unit is configured to capture an image of a rear of a vehicle. The color temperature detection unit is configured to detect a color temperature of a captured image. The color temperature sensor is installed at a front of the vehicle to detect a color temperature of incident light. When a difference between the color temperature of the captured image and the color temperature of the incident light is a color temperature threshold value or greater, the white balance adjustment unit is configured to switch from a first white balance adjustment based on the color temperature of the captured image to a second white balance adjustment based on the color temperature of the incident light.

An image capturing method, a camera assembly, and a mobile terminal are provided. An image sensor includes a two-dimensional (2D) pixel array. The 2D pixel array includes multiple panchromatic pixels and multiple color pixels. The 2D pixel array includes minimum repeating units. Each minimal repeating unit includes multiple sub-units. Each sub-unit includes multiple monochromatic pixels and multiple panchromatic pixels. The image capturing method includes the following. The 2D pixel array is exposed to obtain a panchromatic original image and a color original image. The color original image is processed to obtain a color intermediate image. The panchromatic original image is processed to obtain a panchromatic intermediate image. The color intermediate image and/or the panchromatic intermediate image are processed to obtain a target image.

An observation and designation apparatus includes a first image sensor and a second image sensor that are connected to an electronic image processor circuit connected to a display. The first image sensor and the second image sensor provide fields that are superposed to supply respectively at least a first image and a second image of the same scene. The appliance further includes a laser emitter for emitting a laser beam lying in a predetermined range of wavelengths into a predetermined zone of the field of the second sensor; a region-of-interest filter extending in front of the second sensor. The electronic processor circuit superposes the two images by using the zone of the second image that corresponds to the third region of the filter to register the second image spatially relative to the first image. An observation and designation method makes use of such filtering.

A method for correcting an image includes: orthographically correcting an image; removing a curtain artifact by applying a first filter to the orthographically corrected image; correcting brightness of the image, from which the curtain artifact is removed, by applying a second filter to the image, from which the curtain artifact is removed. The first filter includes a first function and a second function for a first domain and a second domain, which are orthogonal to each other in a frequency region, and the first filter is differentiable and continuous in the first domain and the second domain.