An image sensor processor implemented method for retaining pixel intensity, comprising: receiving, by the image processor, a numerical value indicative of a corresponding pixel intensity; determining, by the image processor, whether a least significant portion of the received numerical value is equal to a predetermined numerical value; and responsive to determining the least significant portion of the received numerical value is equal to the predetermined numerical value, rounding, by the image processor, the received numerical value of the corresponding pixel intensity to a higher or lower value depending on a bit sequence, and if the least significant portion of the received numerical value is not equal to the predetermined value, rounding the received numerical value to the higher or lower value based on the received numerical value; and binning the rounded value.

An image sensor processor implemented method for retaining pixel intensity, comprising: receiving, by the image processor, a numerical value indicative of a corresponding pixel intensity; determining, by the image processor, whether a least significant portion of the received numerical value is equal to a predetermined numerical value; and responsive to determining the least significant portion of the received numerical value is equal to the predetermined numerical value, rounding, by the image processor, the received numerical value of the corresponding pixel intensity to a higher or lower value depending on a bit sequence, and if the least significant portion of the received numerical value is not equal to the predetermined value, rounding the received numerical value to the higher or lower value based on the received numerical value; and binning the rounded value.

An image capturing apparatus comprises: an image sensor including a pixel region including a plurality of pixel units, arranged in a matrix, each having first and second photoelectric conversion units, and a storage unit provided for each column; and a driving unit configured to drive the image sensor by, for each pixel unit to be read of the plurality of pixel units, exclusively selecting an operation of combining a signal of the first photoelectric conversion unit and a signal of the second photoelectric conversion unit for each pixel unit and outputting the combined signal to the storage unit, an operation of reading a signal from the first photoelectric conversion unit of each pixel unit to the storage unit, or an operation of reading a signal from the second photoelectric conversion unit of each pixel unit to the storage unit.

An imaging apparatus includes a reading unit, a display unit, and a control unit. The reading unit reads pixel signals from imaging pixels and focus detection pixels. The display unit displays an image. When both exposure/reading of the imaging pixels and the focus detection pixels are achievable within time corresponding to a display frame rate of the display unit, the control unit controls to alternate the exposure/reading of the imaging pixels and the exposure/reading of the focus detection pixels. When both the exposure/reading of imaging pixels and the focus detection pixels are not achievable within the time, the control unit controls to perform the exposure of the imaging pixels and the focus detection pixels at the same time and read the pixel signals of the imaging pixels and the focus detection pixels after the end of the exposure of the imaging pixels and the focus detection pixels.

An image sensor (IS) includes a plurality of pixel blocks (PB) to which colors different from each other are assigned. Each of the plurality of pixel blocks (PB) includes a plurality of pixels (PX). The plurality of pixels PX provided in at least one pixel block (PB) among the plurality of pixel blocks (PB) includes one or more anomalous pixels (UPX). The anomalous pixel (UPX) detects light of one or more colors assigned to the other one or more pixel blocks (PB).

An image sensor (IS) includes a plurality of pixel blocks (PB) to which colors different from each other are assigned. Each of the plurality of pixel blocks (PB) includes a plurality of pixels (PX). The plurality of pixels PX provided in at least one pixel block (PB) among the plurality of pixel blocks (PB) includes one or more anomalous pixels (UPX). The anomalous pixel (UPX) detects light of one or more colors assigned to the other one or more pixel blocks (PB).

The present disclosure relates to a solid-state imaging device and an electronic device that can be provided with phase difference pixels with a lower degree of difficulty in manufacturing.

Provided is a solid-state imaging device including a pixel array unit in which a plurality of pixels is two-dimensionally arrayed, in which the pixel array unit has an array pattern in which a plurality of pixel groups each including neighboring pixels of an identical color is regularly arrayed, and among the plurality of pixel groups arrayed in the array pattern, pixels configuring a light-shielded pixel group are shielded in an identical direction side from light, the light-shielded pixel group being a pixel group including pixels each being shielded in a part of a light incident side from the light. The present technology can be applied to, for example, a CMOS image sensor including pixels for phase difference detection.

A solid-state imaging device including: a pixel array unit in which a plurality of pixels outputting an analog pixel signal are arranged in a two-dimensional matrix form; a ramp signal generation unit configured to generate and output a ramp wave; a clock generation unit configured to generate and output multiphase clocks; and a signal-processing unit, wherein the signal-processing unit including: a plurality of analog-to-digital conversion circuits, and a plurality of repeater circuits, wherein each of the plurality of analog-to-digital conversion circuits includes: a comparison unit, and a latch unit, wherein each of the plurality of the analog-to-digital conversion circuits outputs the digital value according to the state of the phase held by each latch circuit, and wherein each of the plurality of the repeater circuits corresponding to the same set are arranged side by side, and the repeater circuits are connected in series.

In one embodiment, an X-ray CT apparatus includes: an X-ray detector equipped with a plurality of detection elements each of which is configured to output an X-ray signal in accordance with X-rays passing through an object; and a scan controller configured to acquire X-ray signals in each of a first mode and a second mode in one scan by switching between the first mode and the second mode, the first mode being a mode of acquiring high-resolution data which are respective X-ray signals outputted from the plurality of detection elements, the second mode being a mode of acquiring normal-resolution data in which X-ray signals outputted from some of the plurality of detection elements are integrated.

A stereoscopic image capture device includes a first image sensor, a second image sensor, a first frame timer, and a second frame timer. The first and second frame timers are different frame timers. The first image sensor includes a first plurality of rows of pixels. The second image sensor includes a second plurality of rows of pixels. The first and second image sensors can be separate devices or different areas of a sensor region in an integrated circuit. The first frame timer is coupled to the first image sensor to provide image capture timing signals to the first image sensor. The second frame timer coupled to the second image sensor to provide image capture timing signals to the second image sensor.