An image capturing apparatus includes a plurality of pixels, a signal line connected to the plurality of pixels, and a limiter circuit configured to limit an amplitude of the signal at the signal line. A first pixel in the plurality of pixels sequentially outputs a noise signal, a focus detection signal, and an image capturing signal to the signal line. A second pixel in the plurality of pixels sequentially outputs a noise signal and an image capturing signal to the signal line, and wherein a potential of the signal at the signal line is set to a potential by the limiter circuit during a period after the second pixel outputs the noise signal and before the second pixel outputs the image capturing signal.

An imaging pixel (2) to mitigate cross-talk effects comprises a voltage supply node (VN) to receive a supply voltage (VDD), and an output node (ON) to provide a pixel output signal. The imaging pixel (2) further comprises a photosensitive element (10), and a source follower transistor (31) having a control node coupled to the photosensitive element (10). The source follower transistor (31) is interposed between the voltage supply node (VN) and the output node (ON). The imaging pixel (2) comprises a clamping circuit (20) being interposed between the voltage supply node (VN) and the output node (ON).

A photoelectric converter includes pixels, vertical output lines to which a signal is outputted from the pixels, clippers configured to limit a potential of the output lines and a controller. Each of the clippers includes a first circuit configured to output an amplification signal according to a predetermined potential and the potential of the output line and a second circuit configured to supply a current according to the amplification signal to the output line. The controller controls each of the clippers to a state selected from states including a first state in which a range in which the potential of the output line can change is limited using the first and second circuits, and a second state in which the range in which the potential of the vertical output line can change is limited with an output of the second circuit deactivated.

A readout integrated circuit configured to read out sensing signals from an optical sensing panel including a sensor array for fingerprint sensing is provided. The readout integrated circuit includes a plurality of input terminals, a comparator circuit and a control circuit. The plurality of input terminals are configured to be coupled to a plurality of output terminals of the optical sensing panel. The comparator circuit is configured to receive an output voltage from an output terminal of the plurality of output terminals of the optical sensing panel and at least one reference voltage, compare the output voltage to the at least one reference voltage and output a comparison result. The control circuit is coupled to the comparator circuit. The control circuit is configured to receive the comparison result and determine a supplementary charge amount to be charged to or discharged from the output terminal according to the comparison result.

An overlight amount detection circuit (1) according to the present disclosure includes a MOS transistor and a high-impedance element (Ca). A source of the MOS transistor (Mn1) is connected to a vertical signal line (VSL) of an image sensor. The high-impedance element (Ca) is connected to a drain of the MOS transistor (Mn1). The overlight amount detection circuit (1) detects a potential fluctuation of the vertical signal line (VSL) based on a potential defined by a gate potential of the MOS transistor (Mn1), and outputs a potential of a contact point between the drain of the MOS transistor (Mn1) and the high-impedance element (Ca) as a signal indicating an overlight amount detection result.

An imaging device according to the present disclosure includes an imaging unit, a connector, and a converter. The imaging unit includes a first signal line, a first pixel, a second signal line, and a second pixel. The first pixel outputs a first pixel voltage to the first signal line. The first pixel voltage corresponds to an amount of received light. The second pixel outputs a second pixel voltage to the second signal line. The second pixel voltage corresponds to the amount of received light. The connector includes a connection line, a first connection switch, a first control circuit, a second connection switch, and a second control circuit. The converter is coupled to the first signal line and the second signal line. The converter performs AD conversion on the basis of each of the first pixel voltage and the second pixel voltage.

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.

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.

A light detecting device includes: one or more switch transistors, a first pixel including a first floating diffusion region coupled to a first photoelectric converter through a first transfer transistor, and a first amplification transistor coupled to the first floating diffusion region, a second pixel including a second floating diffusion region coupled to a second photoelectric converter through a second transfer transistor, and a second amplification transistor coupled to the second floating diffusion region, and a third pixel including a third floating diffusion region coupled to a third photoelectric converter through a third transfer transistor, and a third amplification transistor coupled to the third floating diffusion region. A pixel signal is differentially amplified by the first and third amplification transistors. The first and second floating diffusion regions are selectively connected to each other via one of the one or more switch transistors.

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.