An imaging system includes a plurality of pixel circuits each having a photodiode, a biasing circuit and a charge-to-voltage converter. The photodiode is configured to generate charges in response to light or radiation. The biasing circuit is configured to provide a constant bias voltage across the photodiode so as to drain the charges generated by the photodiode. The charge-to-voltage converter is configured to accumulate the charges drained by the biasing circuit and convert the accumulated charges into a corresponding output voltage.

An embodiment provides an imaging device including a pixel that includes a first photoelectric conversion portion, a second photoelectric conversion portion, a first transfer transistor, a second transfer transistor, and a floating diffusion portion. The first transfer transistor transfers a signal charge in the first photoelectric conversion portion to the floating diffusion portion. The second transfer transistor transfers a signal charge in the second photoelectric conversion portion to the floating diffusion portion. A potential at the first photoelectric conversion portion for the signal charge is higher than a potential at the second photoelectric conversion portion for the signal charge.

An image pickup apparatus outputs a picked-up image signal based on a difference between an electric charge signal and a noise signal generated by a photoelectric converter. The apparatus has a generating unit that generates a difference image that is based on a difference between a first image picked up under a first image pickup condition and a second image picked up under a second image pickup condition in which an exposure amount of the photoelectric converter is smaller than the exposure amount of the photo electric converter in the first image pickup condition, a detector that detects a black spot area on the basis of the difference image generated by the generating unit, and a voltage controller that controls a clip voltage that is set to limit a voltage of the noise signal, on the basis of the detected black spot area.

The present invention relates to a device for signal compensation in medical X-ray images. The device (100) comprises a generation module (10) configured to generate an X-ray ghosting image based on an X-ray detector read-out subsequent to a last X- ray exposure of a plurality of X-ray exposures; a scaling module (20) configured to scale the X-ray ghosting image into a scaled X-ray ghosting image; and a subtraction module (30) configured to subtract the scaled X-ray ghosting image from any subsequent X-ray image recorded during a respective subsequent X-ray exposure of the plurality of X-ray exposures.

A solid state image sensor includes a pixel array, as well as charge-to-voltage converters, reset gates, and amplifiers each shared by a plurality of pixels in the array. The voltage level of the reset gate power supply is set higher than the voltage level of the amplifier power supply. Additionally, charge overflowing from photodetectors in the pixels may be discarded into the charge-to-voltage converters. The image sensor may also include a row scanner configured such that, while scanning a row in the pixel array to read out signals therefrom, the row scanner resets the charge in the photodetectors of the pixels sharing a charge-to-voltage converter with pixels on the readout row. The charge reset is conducted simultaneously with or prior to reading out the signals from the pixels on the readout row.

A solid-state imaging apparatus includes: an overflow element group that accumulates a signal charge that overflows from a photodiode; and a floating diffusion layer that selectively holds a signal charge transferred from the photodiode and a signal charge transferred from the overflow element group. The overflow element group includes m groups (m≥2) connected in series in stages, each group including an overflow element and a storage capacitive element. An overflow element among the groups transfers, to the storage capacitive element included in the same group as the overflow element, a signal charge that overflows from the photodiode or a signal charge from an upstream storage capacitive element among the groups.

An image pickup element including an image pickup unit including an array of a plurality of unit pixels, each of the plurality of unit pixels including a plurality of pixels; a saturation detection unit configured to detect a saturated pixel based on a plurality of pixel signals of a subject image output from the plurality of pixels of each of the plurality of unit pixels; a first image signal generation unit configured to generate a first image signal of the subject image by combining the plurality of pixel signals output from each of ones of the plurality of pixels; and an output unit configured to output information indicating a result of detection of the saturated pixel conducted by the saturation detection unit and the first image signal.

An image sensor which operates in a global shutter mode is provided. The image sensor includes a pixel array comprising a plurality of pixels arranged in a plurality of rows and columns, a timing generator configured to generate row driver control signals which controls an integration period of a pixel of the plurality of pixels to include at least two sub integration periods, and a row driver configured to generate a plurality of row control signals which controls each of the rows in the pixel array based on the row driver control signals, wherein the timing generator is further configured to control a single image frame to include the integration period and a readout period of the pixel, based on the row driver control signals.

Imagers and associated devices and systems are disclosed herein. In one embodiment, an imager includes a pixel array and control circuitry operably coupled to the pixel array. The pixel array includes an imaging pixel configured to produce a reset signal and a non-imaging pixel configured to produce a nominal reset signal. The control circuitry is configured to produce an output signal based at least in part on one of (a) the nominal reset signal when distortion at the imaging pixel exceeds a threshold and (b) the reset signal when distortion does not exceed the threshold.

An imaging device includes a pixel region in which a plurality of pixels and a plurality of charge-to-voltage conversion circuits are arranged in matrix. The pixels include photoelectric conversion elements that output charges in accordance with intensity of received light. The charge-to-voltage conversion circuits convert the charges output from the pixels into voltage signals. The pixel region includes an isolated region including isolated shaded pixels covered with a first shading metal of the same layer as a layer of wiring metals of the charge-to-voltage conversion circuits, and an isolated pixel that is not covered with the metal. All the pixels surrounding the isolated pixel in the isolated region are the isolated shaded pixels.