In a vehicle-mounted camera system, an appropriate white balance correction processing according to a situation is executed to a long exposure time image and a short exposure time image shot in variously changing illumination environments. A vehicle-mounted camera system includes a vehicle-mounted camera that performs relatively long exposure time shooting and short exposure time shooting, a signal processing device (signal processing device) that executes a white balance correction processing for each of a long exposure time image and a short exposure time image, composes these images after the white balance correction processing, and generates a high dynamic range image, and a system control part (processing switch device) that obtains an illumination environment in which the vehicle is placed, and switches the white balance correction processing for the long exposure time image and the white balance correction processing for the short exposure time image according to the illumination environment.

A spectrum-inspection device includes a substrate including a first photodiode and a second photodiode. The spectrum-inspection device also includes an interference-type filter disposed over the first and second photodiodes. The interference-type filter allows a first light beam with wavelength of a multi-band to pass through. The multi-band includes a first waveband, a second waveband, a third waveband, and a fourth waveband. The spectrum-inspection device also includes a first absorption-type filter disposed over the first and second photodiodes. The first absorption-type filter allows a second light beam with wavelength of a first region to pass through. The spectrum-inspection device further includes a second absorption-type filter disposed over the second photodiode. The second absorption-type filter is disposed over the first absorption-type filter and allows a third light beam with wavelength of a second region to pass through, wherein the second region overlaps the first region.

An image sensor according to some example embodiments includes a pixel array unit including a plurality of transmission signal lines and a plurality of output signal lines, and a plurality of pixels connected to the plurality of transmission signal lines and the plurality of output signal lines. Each of the plurality of pixels includes a plurality of photoelectric conversion elements, which are configured to detect and photoelectrically convert incident light. The plurality of pixels include at least one autofocusing pixel and at least one normal pixel.

An image sensor is provided. The image sensor includes: a plurality of photoelectric elements for receiving an incident light. The photoelectric elements are arranged into a plurality of unit cells, and each of the unit cells includes a first photoelectric element and a second photoelectric element. The first photoelectric element in each of the unit cells captures a first pixel in a first phase, and the second photoelectric element in each of the unit cells captures a second pixel in a second phase, wherein the first phase is different from the second phase.

The present invention provides a full-color three-dimensional optical sectioning microscopic imaging system and method based on structured illumination, includes an illumination source, a dichroic prism positioned at the illumination optical path, a structured light generator positioned at the reflected optical path of the dichroic prism, a lens positioned at the transmitted optical path of the dichroic prism, a beam splitter positioned at the optical path of the lens, an objective lens and a sample stage positioned at the upper optical path of the beam splitter, a reflector mirror and a tube lens positioned at the lower optical path of the beam splitter and a CCD camera positioned behind the tube lens. The illumination source is an incoherent monochrome LED or a white light LED The structured light generator is a DMD (Digital Micro-mirror Device).

Provided is an image sensor including a pixel array which provides a plurality of pixels arranged in rows and columns. The plurality of pixels include: a plurality of image sensing pixels each including a plurality of image sensing sub pixels that include the same color filter; and a plurality of phase detection pixels each including at least one phase detection sub pixel which generates a phase signal for calculating a phase difference between images, wherein the plurality of image sensing sub pixels included in the same image sensing pixel are connected to one selection signal line and receive the same selection signal.

An image sensor includes a sensing layer for sensing a light beam and a number of pixel groups. Each of the pixel groups includes a yellow filter unit allowing a green light component and a red light component of the light beam to pass through, a green filter unit allowing the green light component of the light beam to pass through, and a blue filter unit allowing a blue light component of the light beam to pass through.

Provided are an image sensor and an image capturing apparatus including the image sensor. The image sensor includes a pixel array including: multiple sensing pixels outputting image signals respectively corresponding to intensities of incident light; and at least one pair of focusing pixels that are adjacent each other, and each outputting a phase difference of the incident light as a focusing signal; wherein each focusing pixel includes: a semiconductor layer including a photodetecting device accumulating electric charges generated according to absorbed light from among the incident light; a wiring layer formed on a first surface of the semiconductor layer and including wirings; a planarization layer having a first surface on a second surface of the semiconductor layer; a shielding layer formed in the planarization layer to block some of the incident light to be incident to the photodetecting device; and a color filter layer and a micro lens layer.

The present disclosure relates to a method for multi-color fluorescence imaging under a single exposure, an imaging method and system. The imaging system includes: a fluorescence microscope, configured to obtain a real image of the sample; a spatial mask, disposed behind the fluorescence microscope, and configured to perform mask modulation on the real image of the sample; a 4f system, disposed behind the spatial mask, in which the real image of the sample passes through the spatial mask to the 4f system; an optical granting, disposed on a Fourier plane in middle of the 4f system, and configured to split the real image of the sample to obtain a split real image; and an image sensor, configured to obtain the split real image to obtain an image of the sample. The present disclosure advantages of improving imaging rate in multi-spectrum fluorescence microscopy.

The present disclosure relates to a signal processing device, a signal processing method, and a signal processing program which can more accurately perform color reproduction to an image captured by using visible light and infrared light. A plurality of pixel signals, output by a color-difference sequential system from an image sensor on which light having passed through a color filter array including a plurality of complementary color filters is incident, are acquired. With respect to the plurality of pixel signals, a parameter to eliminate a term corresponding to a predetermined infrared wavelength in an equation to calculate a color-difference signal from the plurality of pixel signals, is set using the plurality of pixel signals. Thereafter, a luminance signal obtained by performing an addition process of the plurality of pixel signals and a color-difference signal obtained by performing a subtraction process between the plurality of pixel signals are calculated using the parameter.