A camera device includes multiple sensors with each sensor including an integrated multi-element filter. Because of the use of different filters in different sensors, a wide variety of filter patterns can be supported in a single camera device without the need for moveable or otherwise changeable filters. While multiple optical chains and sensors are included which sensors are used during a given time period are determined based on the whether a power save mode of operation is active and/or the image capture mode being used. Fewer optical chains are used during power save mode for capturing images corresponding to the image mode in use, e.g., color, IR, or monochrome. While the camera device may include a large number of optical modules, e.g., 4, 10 or more, in some embodiments sensors of optical chains not selected for use during a given time period are intentionally powered down to conserve power.

A solid-state image sensor and an imaging system with a two-dimensional pixel array, and a plurality of types of filters that are arranged facing a pixel region of the two-dimensional pixel array, the filters each including a spectrum function and a periodic fine pattern shorter than a wavelength to be detected, wherein each of the filters forms a unit which is larger than the photoelectric conversion device of each pixel on the two-dimensional pixel array, where one type of filter is arranged for a plurality of adjacent photoelectric conversion device groups, wherein the plurality of types of filters are arranged for adjacent unit groups to form a filter bank, and wherein the filter banks are arranged in a unit of N?M, where N and M are integers of one or more, facing the pixel region of the two-dimensional pixel array.

There is provided an image processing apparatus. A calculation unit calculates a difference in a signal level, for each area, between a first image obtained by shooting a subject under a first shooting condition and a second image obtained by shooting the subject under a second shooting condition in which high-frequency components of an optical image of the subject are reduced compared to the first shooting condition. A mixing unit mixes a signal level of the first image and a signal level of the second image at a ratio based on the difference, so as to generate a third image. The mixing unit sets a ratio of the second image when the difference is a first value, to be larger than a ratio of the second image when the difference is a second value that is smaller than the first value.

An endoscope apparatus includes an imager that outputs an imaging signal and an image processor that generates an emphasis image signal and a non-emphasis image signal based on the imaging signal. The emphasis image signal corresponds to emphasis narrow band light included in an emphasis wavelength range that includes at least one of a maximum wavelength that takes a maximum value of an optical absorption spectrum and a color-range largest wavelength that takes a largest value of the optical absorption spectrum. The non-emphasis image signal corresponds to non-emphasis narrow band light included in a non-emphasis wavelength range that excludes the emphasis wavelength range from three color ranges and that is included in a color range that does not include the emphasis narrow band light.

An image processing apparatus interpolates a signal of a missing color component based on first, second, and third color signals respectively generated by first, second, and third pixels of an image sensor, to generate color signals. These pixels are arranged in a matrix. The first pixels generate the first color signal of a first luminance component of white light. The second pixels generate the second color signal of a second luminance component of narrow band light. Density of the first pixels being higher than density of the second pixels and density of the third pixels. The apparatus extracts a specific frequency component signal from a color signal of the first luminance component among the color signals generated by interpolation, and adds the specific frequency component signal to a color signal of a color component different from the first luminance component depending on white light imaging or narrow band imaging.

An image processing apparatus having a plurality of Bayer arrays each including 4 pixels sharing a common electrode connected to a vertical signal line wherein: each of the pixels has a pixel electrode connected to a horizontal signal line; and the location of each of the horizontal signal lines and the location of each of the pixel electrodes each connected to one of the horizontal signal lines are determined so that the locations in a neighboring Bayer array are a mirror image of counterpart locations in another Bayer array adjacent to the neighboring Bayer array.

An image sensor includes a substrate, a first set of sensor pixels formed on the substrate, and a second set of sensor pixels formed on the substrate. The sensor pixels of the first set are arranged in rows and columns and are configured to detect light within a first range of wavelengths (e.g., white light). The sensor pixels of the second set are arranged in rows and columns and are each configured to detect light within one of a set of ranges of wavelengths (e.g., red, green, and blue). Each range of wavelengths of the set of ranges of wavelengths is a subrange of said first range of wavelengths, and each pixel of the second set of pixels is smaller than each pixel of the first set of pixels.

Systems and methods are provided for imaging a target as for example a multiwell plate. A plurality of regions of interest are selected on the target at a system control. The selected plurality of regions of interest are simultaneously imaged to provide an image with the plurality of regions of interest selectively magnified by a microlens array (30) and the regions that are not of interest are rejected by means of a mirrored aperture array, a mask, or selective illumination of the regions of interest of the target.

A plurality of adjacent pixels is provided adjacently in a plurality of directions to a first pixel. A direction with a highest correlation is derived from signals of the plurality of pixels, and the direction with the highest correlation is reflected to interpolation processing to be performed on the signal of first pixel.

An image capturing apparatus includes: photoelectric converting elements having a light reception sensitivity to light in a wavelength band from 600 to 2500 nm, and receiving an object light flux to output pixel signals; n types of wavelength filters (n>4) allowing passage therethrough of light included in the flux and is in wavelength bands being respectively different, each including the wavelength band; and an image data generator generating image data using the output from an element among those having received the flux passed through one of m types of the wavelength filters (3?m<n) a combination determined based on a predetermined condition being determined such that among the respective wavelength bands of the m types of filters, a shortest-wavelength side wavelength band and a longest-wavelength side wavelength band overlap, and each filter among the m types allowing passage therethrough of light in the wavelength band including a predetermined effective wavelength band.