There is provided a solid-state imaging device including an imaging unit (211) that captures a first captured image, a light emission controlling unit (271) that controls emission of light from the light emitting unit, a decision unit (2331) that decides whether or not the emission of light is detected from within the first captured image, and a transmission controlling unit (2333) that controls, when the emission of light is detected, transmission of a second captured image or data based on the second captured image.

An imaging device of the present disclosure includes: a pixel array section in which pixels including light receiving elements are arranged; a first pixel control section that performs control to read out signals of all the pixels in the pixel array section at a first frame rate; a second pixel control section that performs control to read out signals of the pixels in a specific region in the pixel array section at a second frame rate higher than the first frame rate; and an analog-to-digital conversion section that performs an analog-to-digital conversion on a pixel signal read out by the control performed by the first pixel control section or the second pixel control section.

A time-of-flight (TOF) camera device including an optical transmitter configured to transmit light to a subject, an optical receiver configured to receive light reflected from the subject, and an actuator configured to adjust either one or both of an optical scanning direction and field of luminance (FOL) of the optical transmitter.

In a solid-state imaging element that measures a distance, miniaturization of pixels is facilitated. The solid-state imaging element includes a pixel array unit and a photon number detection unit. In the solid-state imaging element including the pixel array unit and the photon number detection unit, the pixel array unit is provided with a plurality of pixels that generates a predetermined analog signal depending on incidence of a photon and a signal line to which the plurality of pixels is connected in common. Furthermore, in the solid-state imaging element, the photon number detection unit detects the number of photons incident, on the basis of the analog signal transmitted via the signal line.

A depth sensor for measuring a distance to an object and an image signal processor configured to change a binning mode based on ambient light are provided. A method for operating a depth sensor for measuring a distance to an object includes outputting a pixel signal from at least one depth pixel included in a pixel array, generating ambient light information based on an intensity of ambient light outside the depth sensor, the intensity of the ambient light being measured using the pixel signal, and setting a binning mode of the depth sensor to an analog binning mode or a digital binning mode based on the ambient light parameter value.

An electronic apparatus includes an imaging element having a plurality of image capture regions, each of the image capture regions having a plurality of pixels for generating an image signal; a setting unit that sets different image capture conditions for the plurality of image capture regions; and a control unit that corrects a portion of an image signal of a photographic subject captured under first image capture conditions in an image capture region among the plurality of image capture regions so that it is as if the portion of the image signal was captured under second image capture conditions.

An imaging device that smoothly transfers electric charges from a photoelectric converter to a transfer destination is provided. This imaging device includes: a semiconductor layer; a photoelectric converter that generates electric charges corresponding to a received light amount; and a transfer section that includes a first trench gate and a second trench gate and transfers the electric charges from the photoelectric converter to a single transfer destination via the first trench gate and the second trench gate, the first trench gate and the second trench gate each extending from the front surface to the back surface of the semiconductor layer into the photoelectric converter. The first trench gate has a first length from the front surface to the photoelectric converter, and the second trench gate has a second length from the front surface to the photoelectric converter, the second length being shorter than the first length.

An imaging device includes a pixel array including pixel circuits arranged into rows and columns. Each bitline of a plurality of bitlines is coupled to a respective column of pixel circuits of the pixel array. The plurality of bitlines is grouped into pairs of bitlines. A plurality of binning circuits is coupled to the plurality of bitlines. Each binning circuit is coupled to a respective pair of bitlines and is responsive to a multi-mode select signal. Each binning circuit is configured to output a binned signal responsive to the first and second bitlines of the respective bitline pair in a first mode. Each binning circuit is configured to output a first signal from a first bitline of the respective bitline pair in a second mode. Each binning circuit is configured to output a second signal from the second bitline of the respective bitline pair in a third mode.

A transfer control device includes a difference identifying section which identifies, for a first and second images sequentially captured by synchronous scanning, a difference region of the second image, on the basis of an event signal indicating a change in intensity of light generated in one or a plurality of pixels of each of the first and second images during a time period from capturing of the first image to capturing of the second image; and a transfer control section which executes data transfer different between the difference region and regions other than the difference region, for the second image.

The disclosure relates to a filter array and to a method for processing image data in a camera. The camera is configured to receive light and generate image data using an image sensor having an associated filter array. The image sensor includes an array of pixels, each of which corresponds to a filter element in the filter array, so that each pixel has a spectral response at least partly defined by a corresponding filter element. The filter array includes a pattern of wideband filter elements and at least two types of narrowband filter elements. The method includes the step of generating a luminance image comprising a wideband filter element value that is calculated for each pixel of the image sensor.