A photoelectric conversion device includes a circuit provided between an avalanche photodiode and a power source, a counter configured to count an output signal output from the avalanche photodiode, and a memory into which time information indicating that a count value of the counter has reached a threshold value within a predetermined exposure period shorter than an exposure time is written, wherein a clock signal is configured to be input to the circuit in the exposure period.

In an example embodiment, an image processing device includes a pixel array including pixels two-dimensionally arranged and configured to capture an image, each of the pixels including a plurality of photoelectric conversion elements and an image data processing circuit configured to generate image data from pixel signals output from the pixels. The image processing device further includes a color data processing circuit configured to extract color data from the image data and output extracted color data. The image processing device further includes a depth data extraction circuit configured to extract depth data from the image data and output extracted depth data. The image processing device further includes an output control circuit configured to control the output of the color data and the depth data.

A control method in an imaging device is provided. The imaging device includes a pixel-cell array including a plurality of photosensitive pixel-units, each photosensitive pixel-unit of the photosensitive pixel-units includes at least two exposure pixels including at least one medium-exposure pixel. The method includes determining an ambient brightness level of a photographing environment; adjusting a first ratio to be a first value, in response to a brightness level of the photographing environment belonging to a high-level or a low-level, wherein the first ratio indicates a ratio of the at least one medium-exposure pixel in the each photosensitive pixel-unit; and adjusting the first ratio to be a second value, in response to the brightness level of the photographing environment belonging to a medium-level, wherein the low-level, the medium-level, and the high-level are in an ascending order, and the first value is greater than the second value.

A method that can detect targets is described. The method includes setting an integration time for each of a plurality of readout circuits based on a speed of the target. The readout circuits are configured to read pixels in an image detector. The pixels have a pitch of less than ten micrometers. The integration time is not more than five hundred microseconds and corresponds to a subframe of a fast frame image. The method also includes performing integrations of each readout circuit based on the integration time. Thus, a plurality of subframes are provided. A number of the subframes are averaged to provide the fast frame image.

An image sensor is disclosed. The image sensor includes a plurality of pixels arranged in a plurality of rows and a plurality of columns, each of the pixels including: a photodiode; a floating diffusion node configured to accumulate photocharges generated from the photodiode; a first capacitor configured to store charges according to a voltage of the floating diffusion node which is reset; a second capacitor configured to store charges according to a voltage of the floating diffusion node in which the photocharges are accumulated; a first sampling transistor connected to a first output node and configured to sample charges to the first capacitor; a second sampling transistor connected to the first output node and configured to sample charges to the second capacitor; and at least one precharge select transistor connected to the first output node and configured to reset the first output node.

An image capturing system includes an image capturing unit including an image capturing surface on which pixel blocks each including a plurality of pixels are two-dimensionally arranged, exposure parameters being separately settable for the pixel blocks, a determination unit configured to determine a first exposure parameter and a second exposure parameter so that a difference between the first exposure parameter and the second exposure parameter is greater than or equal to a predetermined value, an exposure control unit configured to set the first exposure parameter determined by the determination unit and the second exposure parameter determined by the determination unit alternately as the exposure parameters for the pixel blocks and configured to control image capturing by the image capturing unit, and a display unit configured to display an image captured by the image capturing unit.

A device includes a pixel unit, a selection unit, and a first generation unit. The pixel unit has a plurality of pixels arranged in a plurality of rows. Each pixel includes a quenching circuit configured to receive a signal for determining start and end of an exposure period and a photodiode coupled to the quenching circuit. The selection unit is configured to simultaneously receive a plurality of clock signals of different periods and select a clock signal to be outputted from the plurality of clock signals. The first generation unit is configured to generate the signal by using the outputted clock.

A device includes a pixel unit, a selection unit, and a first generation unit. The pixel unit has a plurality of pixels arranged in a plurality of rows. Each pixel includes a quenching circuit configured to receive a signal for determining start and end of an exposure period and a photodiode coupled to the quenching circuit. The selection unit is configured to simultaneously receive a plurality of clock signals of different periods and select a clock signal to be outputted from the plurality of clock signals. The first generation unit is configured to generate the signal by using the outputted clock.

This disclosure describes devices, systems, and methods that relate to obtaining image frames with variable resolutions in synchronization with a clock source. An example device may include an image sensor, a clock input, and a controller. The controller includes at least one processor and a memory. The at least one processor is operable to execute program instructions stored in the memory so as to carry out operations. The operations include receiving, by the clock input, a clock signal. The clock signal is a periodic signal defining at least one scan interval. The operations also include during the scan interval, causing the image sensor to capture a full resolution image frame. The operations yet further include during the scan interval, causing the image sensor to capture at least one reduced resolution image frame.

Imaging devices are disclosed. In one example, an imaging device includes a pixel array with light-receiving pixels that are separated pixel lines, and that accumulating electric charge in an accumulation period. An exposure controller sets time lengths of the accumulation such that the time lengths repeat in predetermined order. The accumulation period includes a first accumulation period and a second accumulation period each having a first time length, and a third accumulation period and a fourth accumulation period each having a second time length. A processor generates image data by adding pixel values based on the accumulation result in a first pixel line in the first accumulation period, the accumulation result in a second pixel line in the second accumulation period, the accumulation result in the first pixel line in the third accumulation period, and the accumulation result in the second pixel line in the fourth accumulation period.