Noise is reduced in a solid-state image capturing element provided with an ADC for each column. An analog-to-digital converter increases or decreases an analog signal using an analog gain selected from among a plurality of analog gains, and converts the increased or decreased analog signal to a digital signal. An input switching section inputs, as the analog signal, one of a test signal having a predetermined level and a pixel signal to the analog-to-digital converter. In a case where a test signal is inputted, a correction value calculation section obtains, from the analog signal and the digital signal, a correction value for correcting an error in the selected analog gain, and outputs the correction value. A correction section, when inputted with the pixel signal after the correction value is outputted, corrects the digital signal using the correction value.

A photoelectric conversion device includes: pixels forming columns and each configured to output a pixel signal; and comparator units provided to respective columns and each configured to receive the pixel signal from the pixels on a corresponding column and the reference signal. Each comparator unit includes a comparator having a first input node that receives the pixel signal and a second input node that receives the reference signal, a first capacitor that connects a reference signal line and the second input node, a second capacitor whose one electrode is connected to the second input node, and a select unit that connects the other electrode of the second capacitor to either the reference signal line or a reference voltage line. The other electrode of the second capacitor is connected to the reference signal line during first mode AD conversion and connected to the reference voltage line during second mode AD conversion.

An image sensor has an image sensor array and circuit design employing a method of black level compensation to address image shading related to global exposure image capture and rolling row by row readout schemes. An image sensor including the invented black level compensation pixel array and method may be incorporated within a digital camera.

A method of removing fixed pattern noise, comprising: S01: performing a single-frame segmented exposure on a pixel array; S02: reading a signal of the pixel array, comprising: S021: performing a soft reset, so as to set the reset signal of the pixel unit to an intermediate voltage, and reading a differential reset signal; S022: performing a hard reset so as to set the reset signal of the pixel unit to a high voltage; S023: turning on a transmission MOS transistor to enable an exposure signal of the photodiode to be transmitted to the floating diffusion area, and reading a differential pixel transmission signal; S03: subtracting the differential reset signal from the differential pixel transmission signal to obtain an exposure signal with fixed pattern noise removed. Another method of removing fixed pattern noise and an image sensor are further provided.

An image sensor supporting a full resolution mode and a crop mode, the image sensor including: a pixel array including a plurality of pixels configured to generate a pixel signal by sensing an object; an analog-to-digital converter configured to convert the pixel signal into a digital signal and including a plurality of metal lines; a bias generator configured to apply a bias voltage to the plurality of metal lines; and a bias controller including: a first transistor configured to activate all of the plurality of metal lines based on a first control signal; and a second transistor configured to activate a first metal line for the crop mode among the plurality of metal lines based on a second control signal.

The present disclosure relates to a solid-state imaging device, a manufacturing method thereof, and an electronic apparatus, in which both oblique light characteristics and sensitivity can be improved. The solid-state imaging device includes pixel array unit in which a plurality of pixels is two-dimensionally arranged in a matrix and multi-stage light shielding walls are provided between the pixels. The present disclosure is applicable to, for example, a back-illuminated type solid-state imaging device and the like.

An image sensor may include an array of image pixels arranged in rows and columns. Each column of pixels may be coupled to current source transistors and a threshold voltage mitigation circuit. The threshold voltage mitigation circuit may include a long p-channel device for producing a reference current for the current source transistors. The mitigation circuit also includes an autozero transistor and a sampling transistor for passing a global control voltage to the current source transistors. The global control voltage may be generated using a control voltage generator that includes current mirroring circuits and a replica of the current source transistors and the threshold voltage mitigation circuit.

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 circuity 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.

A CMOS optical sensor comprises spare readout channels to replace readout channels found defective at the end of the manufacturing process. These spare readout channels are dispatched over the width of the optical sensor (corresponding to the row direction) in the form of spare groups G.sub.m1, G.sub.m2, Gm.sub.3 of m spare readout channels each, m integer at least equal to 1. Each spare group is inserted between two successive default groups Gn.sub.1 and Gn.sub.2 of n default readout channels each and coupling means SW1 are configured to replace a defective default readout channel in a default group as well as any default readout channels of the group between the defective one and the spare group next to the default group of concern. Advantageously, for a row Row.sub.i being currently selected for CDS reading each pixel in the row, a row noise level V.sub.RN.sub.i is obtained from the A spare readout channels that are not used in the implemented repairing scheme, by sampling an analogic DC reference signal by each of the A spare readout channels and averaging the A values Sp.sub.k obtained. The row reference value V.sub.RN.sub.i is then subtracted from each of the pixel digital signal S.sub.i,j outputs for the current selected row, to finally obtain a signal value d.sub.i,j with row noise suppression.

A gain adjustment unit calculates a total sum of analog gains on a way from photoelectric conversion output of an image pickup device to input of an analog/digital conversion circuit with use of picked-up images provided from the analog/digital conversion circuit, the analog/digital conversion circuit being configured to convert an output of an analog processing section into a digital signal, the analog processing section being configured to transmit and amplify an image pickup signal from the image pickup device, the image pickup device being provided at an insertion portion of an endoscope, and determines, as an adjustment gain, a difference between a target value of a total sum of gains and the total sum of the analog gains, and output information.