An imaging device including: a first imaging cell including a first photoelectric converter that generates a first signal; and a second imaging cell including: a second photoelectric converter that generates a second signal; and a capacitor having a first and second terminal, the first terminal electrically coupled to second photoelectric converter. An area of the first photoelectric converter is greater than an area of the second photoelectric converter in a plan view, the first imaging cell has a first number of saturation charges, and the second imaging cell has a second number of saturation charges, the first number of saturation charges is greater than the second number of saturation charges, and the capacitor has capacitance that causes the second number of saturation charges of the second imaging cell to become greater than the first number of saturation charges of the first imaging cell.

An image capturing apparatus includes a plurality of pixels, a signal line connected to the plurality of pixels, and a limiter circuit configured to limit an amplitude of the signal at the signal line. A first pixel in the plurality of pixels sequentially outputs a noise signal, a focus detection signal, and an image capturing signal to the signal line. A second pixel in the plurality of pixels sequentially outputs a noise signal and an image capturing signal to the signal line, and wherein a potential of the signal at the signal line is set to a potential by the limiter circuit during a period after the second pixel outputs the noise signal and before the second pixel outputs the image capturing signal.

The present technique aims to provide a solid-state imaging device that reduces shading and color mixing between pixels. The present invention also provides a method of manufacturing the solid-state imaging device. The present technique further relates to a solid-state imaging device that enables provision of an electronic apparatus that uses the solid-state imaging device, a method of manufacturing the solid-state imaging device, and an electronic apparatus. The solid-state imaging device includes a substrate, pixels each including a photoelectric conversion unit formed in the substrate, and a color filter layer formed on the light incidence surface side of the substrate. The solid-state imaging device also includes a device isolating portion that is formed to divide the color filter layer and the substrate for the respective pixels, and has a lower refractive index than the refractive indexes of the color filter layer and the substrate.

An image sensor includes a function layer including a photoelectric conversion region containing a plurality of semiconductor-type carbon nanotubes; a transparent electrode that collects first electric charges that are positive electric charges or negative electric charges, the positive electric charges or the negative electric charges being generated in the photoelectric conversion region upon entry of light; a first collection electrode that collects second electric charges having a polarity opposite to the first electric charges among the positive electric charges and the negative electric charges; a second collection electrode that collects the second electric charges; a first control electrode that controls movement of the second electric charges toward the first collection electrode; a second control electrode that controls movement of the second electric charges toward the second collection electrode; and an electric charge accumulator in which the second electric charges collected by the first collection electrode are accumulated.

An image sensor includes a pixel array including a plurality of pixels; a row driver configured to control the plurality of pixels; and an analog-to-digital converter configured to digitize a result sensed by the pixel array to generate a first image, wherein the pixel array includes: first pixel groups, wherein each first pixel group of the first pixel groups includes first white pixels and first color pixels among the plurality of pixels; and second pixel groups, wherein each second pixel group of the second pixel groups includes second white pixels and second color pixels among the plurality of pixels, and wherein first pixel data of the first image are generated based on the first white pixels and the first color pixels, and second pixel data of the first image are generated based on the second color pixels.

In a pixel 200, a floating diffusion FD11 and a first capacitor CS11 are selectively connected to each other via a first connection element LG11-Tr, to change the capacitance of the floating diffusion FD11 between a first capacitance and a second capacitance, thereby changing the conversion gain between a first conversion gain (HCG) corresponding to the first capacitance and a second conversion gain (MCG) corresponding to the second capacitance. The floating diffusion FD11 and a second capacitor CS12 are connected together through a second connection element SG11-Tr to change the capacitance of the floating diffusion FD11 to a third capacitance, thereby changing the conversion gain of the source following transistor SF11-Tr to a third conversion gain (LCG) corresponding to the third capacitance

A back-illuminated semiconductor light detecting device includes a light detecting substrate having pixels, and a circuit substrate having signal processing units. For each of the pixels, the light detecting substrate includes avalanche photodiodes respectively having light receiving regions provided in a first main surface side of the semiconductor substrate. In the semiconductor substrate, for each pixel, a trench surrounds at least one region including the light receiving region when viewed from a direction perpendicular to the first main surface. The number of signal processing units is larger than the number of light receiving regions in each pixel, and the number of regions surrounded by the trench in each pixel is equal to or less than the number of light receiving regions in the pixel.

A photoelectric conversion device includes a photoelectric conversion region, a readout circuit, and a counting circuit. The photoelectric conversion region is configured to generate a signal charge. The readout circuit is configured to, when reading out a signal that is based on the signal charge generated at the photoelectric conversion region, selectively perform first readout for reading out the signal using avalanche multiplication that is based on the signal charge and second readout for reading out the signal without causing avalanche multiplication to occur with respect to at least a part of the signal charge. The counting circuit is configured to count a number of occurrences of avalanche current which is caused to occur by avalanche multiplication in the first readout.

An overlight amount detection circuit (1) according to the present disclosure includes a MOS transistor and a high-impedance element (Ca). A source of the MOS transistor (Mn1) is connected to a vertical signal line (VSL) of an image sensor. The high-impedance element (Ca) is connected to a drain of the MOS transistor (Mn1). The overlight amount detection circuit (1) detects a potential fluctuation of the vertical signal line (VSL) based on a potential defined by a gate potential of the MOS transistor (Mn1), and outputs a potential of a contact point between the drain of the MOS transistor (Mn1) and the high-impedance element (Ca) as a signal indicating an overlight amount detection result.

Provided are a method and a device, for processing spectrum data of an image sensor. The method includes obtaining spectrum response signals corresponding to channels of spectrum data of light, the spectrum data being obtained from an object by an image sensor; determining a set of bases corresponding to the obtained spectrum response signals; performing, based on the determined set of bases, a change of basis on at least one basis included in the determined set of bases; and generating, by using a pseudo inverse, reconstructed spectrum data from the spectrum response signals on which the change of basis has been performed.