A high dynamic range sensing device is disclosed. The device includes an array of Bayer pattern units. Each of the Bayer pattern units comprises a plurality of pixels and each of the plurality of pixels comprises a plurality of photodiodes. At least one of the plurality of photodiodes in each pixel is configured to detect near infrared (NIR) light and at least one of the plurality of photodiodes in each of the plurality of pixels is configured to detect visible light.

The resolution of narrow band imaging is improved, while color reproducibility is improved when performing white-light observation. Provided is an endoscope system including an image pickup device having three types of color filters, said types being blue, green, and magenta, and also including an image processor that generates an image by processing a signal acquired by the image pickup device. The image processor includes a ratio calculator that calculates the ratio between a blue signal and a magenta signal, and also includes a red-signal generator that generates a red signal based on the ratio calculated by the ratio calculator.

An image processing device (10) is provided with: an estimation unit (11) for estimating, by using image data and a spectral sensitivity characteristic of a color image sensor in a wavelength range from visible light to near-infrared light, a spectral distribution characteristic of an incident light incident on the color image sensor, based on a model expressing the spectral distribution characteristic of the incident light, the image data including one or more color channels and acquired by capturing, using the color image sensor, the incident light including visible light and near-infrared light; and a generation unit (12) for generating, using the estimated spectral distribution characteristic of the incident light and the spectral sensitivity characteristic of the color image sensor, visible light image data configured only from information representing the visible light and near-infrared light image data configured only from information representing the near-infrared light.

An input signal for each of three primary color components is converted into a luminance signal and a color signal by a color space conversion part 11. A gain setting part 12 sets a gain for the color signal obtained by color space conversion according to a signal level of a setting reference signal generated on the basis of the input signal, for example, the luminance signal. A gain adjustment part 14 performs gain adjustment of the color signal with the gain set by the gain setting part 12, and in a case where the luminance signal is larger than a threshold set according to a dynamic range for each color component, the gain adjustment part 14 makes the subject achromatic so that, even in a case where a light amount of the subject is high, influence of a difference in the dynamic range is little.

An image sensor device includes a plurality of color filter units arranged in an array, each of the color filter units comprising an array of n*m color filters, and n and m are integers equal to or greater than 3. The plurality of color filter units includes a plurality of first color filter units, a plurality of second color filter units, and a plurality of third color filter units. The color filters of the first color filter units are transmissive to light beams within a first wavelength range, the color filters of the second color filter units are transmissive to light beams within a second wavelength range, and the color filters of the third color filter units are transmissive to light beams within a third wavelength range.

Provided herein is an image-sensing device and a method for auto white balance. An image signal processor is used to perform the method. In the method, an RGBIr photo sensor receives an image with data over red, green and blue channels. The image data over the red, green and blue channel is firstly restored. A series of weights are calculated according to the image data over an infrared channel. The weights are allocated to the image data so as to adjust the infrared ratios over the red, green and blue channels for reducing infrared effect on auto white balance. After that, an infrared weighting calculation is performed for adjusting the infrared values over the red, green and blue channels of the image. A set of white balance gains are obtained. An auto white balance is performed for obtaining a new image with infrared crosstalk compensation.

An image capturing device includes: an image capturing element having a first image capturing region that captures an image of a photographic subject and outputs a first signal, and a second image capturing region that captures an image of the photographic subject and outputs a second signal; a setting unit that sets an image capture condition for the first image capturing region to an image capture condition that is different from an image capture condition for the second image capturing region; a correction unit that performs correction upon the second signal, for employment in interpolation of the first signal; and a generation unit that generates an image of the photographic subject that has been captured by the first image capturing region by employing a signal generated by interpolating the first signal according to the second signal as corrected by the correction unit.

The present disclosure relates to an imaging apparatus and an imaging method as well as a program that make it possible to apply light having an optimum wavelength to capture an image without a user taking heed of a type of an imaging object. A wavelength of light optimum for analysis of a target is specified as an effective wavelength from a multispectral image of the target on which white light is applied, and light of the effective wavelength is applied upon the target. The target in this state is captured as a multispectral image, and the target is analyzed on a basis of a spectral image of an effective wavelength. The present disclosure can be applied to an endoscope device.

A display control apparatus according to an embodiment of the present disclosure includes a display controller that performs enhancement on a region where resolution is changed in response to changing of lowpass characteristics or a region where false color is generated or changed in response to changing of the lowpass characteristics in image data generated on the basis of light incident via a lowpass filter.

A solid-state image sensor including a semiconductor layer having a light incident side, a support substrate positioned on an opposite side of the light incident side of the semiconductor layer, photoelectric conversion elements formed two-dimensionally in the semiconductor layer, light reflection structures formed on a surface of the support substrate which faces toward the semiconductor layer, and positioned such that the light reflection structures face the photoelectric conversion elements, respectively, and an interlayer insulating layer formed between adjacent ones of the light reflection structures. The light reflection structures include a light transmission layer and a reflective metal that covers a surface of the light transmission layer opposite to a surface facing the semiconductor layer, and the reflective metal has a concave curved surface facing the photoelectric conversion elements.