The invention relates to a photoplethysmography (PPG) sensing device comprising —a pulsed light source, —at least one pixel to create photo-generated electrons, synchronized with said pulsed light source. It is mainly characterized in that each pixel comprises: —a pinned photodiode (PPD) having two electronic connection nodes, —a sense node (SN), to convert the photo-generated electrons into a voltage, and —a Transfer Gate (TGtransfer) transistor, having its source electronically connected to one electronic connection node of said pinned photodiode (PPD), and being configured to act as a transfer gate (TG) between said pinned photodiode (PPD) and said sense node (SN), allowing the photo-generated electrons to sink when the light is pulsed-off, the photo-generated electrons integration when the light is pulsed-on and the transfer of at least part of the integrated photo-generated electrons to said sense node for a read-out.

A color filter array includes a plurality of pixel filters arranged in a predetermined pattern composed of 2×2 pixel filters including two infrared filters and two visible filters. The two infrared filters in the predetermined pattern are disposed along one diagonal, and the two visible filters in the predetermined pattern are disposed along another diagonal.

An image sensor includes: a pixel array including a plurality of pixels divided into a plurality of binning areas; a readout circuit configured to, from the plurality of binning areas, receive a plurality of pixel signals including a first sensing signal of first pixels and a second sensing signal of second pixels during a single frame period and output a first pixel value corresponding to the first pixels and a second pixel value corresponding to the second pixels based on the plurality of pixel signals; and an image signal processor configured to generate first image data based on a plurality of first pixel values corresponding to the plurality of binning areas, generate second image data based on a plurality of second pixel values corresponding to the plurality of binning areas, and generate output image data by merging the first image data with the second image data.

An image sensing device may include one or more pixel groups arranged in rows and columns in an array, each pixel group being arranged at an intersection between a row and a column of the array, wherein each pixel group comprises one or more floating diffusion regions, and one or more groups of an odd number photoelectric conversion units structured to convert incident light to generate electrical charge, each group of the odd number of photoelectric conversion units electrically connected in common to one of the floating diffusion regions for receiving the generated electrical charge.

In some embodiments, a method for processing inspection data associated with cargo irradiated by a plurality N of pulses of inspection is provided. The method includes obtaining the inspection data, the inspection data being representative of intensity values of pixels of an inspection image of the including data associated with a higher energy mode, and data associated with a lower energy mode; generating a histogram having, as a first axis, bins corresponding to pixel intensity values HM associated with the higher energy mode and, as a second axis, bins corresponding to pixel intensity values LM associated with the lower energy mode; selecting a bin corresponding to a most frequent bin of the pixel intensity values HM; and generating a transformation table by mapping each bin of the pixel intensity values LM with the selected bin of the pixel intensity values HM.

In some embodiments, a method for processing inspection data associated with cargo irradiated by a plurality N of pulses of inspection is provided. The method includes obtaining the inspection data, the inspection data being representative of intensity values of pixels of an inspection image of the including data associated with a higher energy mode, and data associated with a lower energy mode; generating a histogram having, as a first axis, bins corresponding to pixel intensity values HM associated with the higher energy mode and, as a second axis, bins corresponding to pixel intensity values LM associated with the lower energy mode; selecting a bin corresponding to a most frequent bin of the pixel intensity values HM; and generating a transformation table by mapping each bin of the pixel intensity values LM with the selected bin of the pixel intensity values HM.

The present disclosure relates to a solid-state imaging device that makes it possible to suppress deterioration of phase difference information, and an electronic device.

There is provided a solid-state imaging device including a pixel array unit in which a plurality of pixels is two-dimensionally arrayed. The plurality of pixels includes a phase difference pixel for phase difference detection, the pixel array unit has an array pattern in which pixel units including neighboring pixels of a same color are regularly arrayed, and the phase difference pixel is partially not added when horizontal/vertical addition is performed on a pixel signal of a predetermined pixel in a horizontal direction and a pixel signal of a predetermined pixel in a vertical direction, in reading the plurality of pixels. The present disclosure can be applied to, for example, a CMOS image sensor having a phase difference pixel.

Provided is an imaging device capable of adaptively acquiring a captured image according to an imaging condition. An imaging device (1) according to an embodiment includes: an imaging unit (10) that includes a pixel array (110) including a plurality of pixel groups each including N×N pixels (100) (N is an integer of 2 or more), and outputs a pixel signal read from each pixel; and a switching unit (14) that switches a reading mode in which the pixel signal is read from each of the pixels by the imaging unit, in which the switching unit switches the reading mode between an addition mode in which the pixel signals read from the N×N pixels included in the pixel group are added to form one pixel signal and an individual mode in which each of the pixel signals read from the N×N pixels included in the pixel group is individually output.

In some embodiments, a method is performed at a device with a processor, non-transitory memory, and an event camera including pixel sensors distributed across an area. The method includes converting an event stream from a pixel sensor over a first time period into event frames by dividing the first time period into sub-periods, and binning pixel events of the event stream, where each of the sub-periods is associated with a frame sub-period identifier. The method further includes addressing the pixel sensors by sub-dividing the area into tiles, where each of the tiles includes a grouping of the pixel sensors, and a tile address of a particular pixel sensor is a combination of a tile identifier and a position locator of the particular pixel sensor. The method further includes encoding the pixel events as a function of a tile address, a frame sub-period identifier, and a brightness indicator value.

In some embodiments, a method is performed at a device with a processor, non-transitory memory, and an event camera including pixel sensors distributed across an area. The method includes converting an event stream from a pixel sensor over a first time period into event frames by dividing the first time period into sub-periods, and binning pixel events of the event stream, where each of the sub-periods is associated with a frame sub-period identifier. The method further includes addressing the pixel sensors by sub-dividing the area into tiles, where each of the tiles includes a grouping of the pixel sensors, and a tile address of a particular pixel sensor is a combination of a tile identifier and a position locator of the particular pixel sensor. The method further includes encoding the pixel events as a function of a tile address, a frame sub-period identifier, and a brightness indicator value.