Abstract: In one embodiment, an image sensor includes a pixel array including a plurality of pixels, an analog-to-digital converter configured to convert analog pixel signals output from the pixels into digital signals, a first cluster configured to store a first group of digital signals among the digital signals and to output first image data, a second cluster configured to store a second group of digital signals among the digital signals and to output second image data, and at least one cluster switch connected to the first cluster and the second cluster, a first channel, and a second channel. The image sensor is configured to transmit at least one among the first image data and the second image data to at least one among the first channel and the second channel based on an operation mode.

Abstract: A pixel array includes pixels arranged in a grid, with separate readout paths configured to readout image data from different subsets of the pixels in the array. An image sensor may employ image data from one subset of pixels, which may include fewer pixels than another subset of pixels in the array, to quickly form an image.

Abstract: An image sensor includes a pixel array, a column signal processor, and a column mismatch compensator. The pixel array outputs a pixel signal from each column line during a pixel measuring time, and outputs a reference signal during a reference measuring time. The column signal processor performs correlated double sampling (CDS) on the reference signal to generate a reference CDS signal, and performs CDS on the pixel signal to generate a pixel CDS signal. The column mismatch compensator compensates the pixel CDS signal based on the reference CDS signal.

Abstract: A temperature sensor includes a band gap reference (BGR) circuit, a voltage generation unit and a digital CDS circuit. The band gap reference (BGR) circuit generates a reference voltage proportional to a temperature. The voltage generation unit generates a first voltage and a second voltage based on the reference voltage, where the first voltage and the second voltage are proportional to the temperature. The digital CDS circuit generates a digital signal corresponding to the temperature by performing a digital correlated double sampling (CDS) operation on the first voltage and the second voltage. The temperature sensor is able to detect a temperature accurately.

Abstract: A temperature sensor includes a band gap reference (BGR) circuit, a voltage generation unit and a digital CDS circuit. The band gap reference (BGR) circuit generates a reference voltage proportional to a temperature. The voltage generation unit generates a first voltage and a second voltage based on the reference voltage, where the first voltage and the second voltage are proportional to the temperature. The digital CDS circuit generates a digital signal corresponding to the temperature by performing a digital correlated double sampling (CDS) operation on the first voltage and the second voltage. The temperature sensor is able to detect a temperature accurately.

Abstract: In one embodiment, the boost circuit includes a boost unit configured to perform a charge pumping operation based on a control signal. A controller is configured to control the boost unit such that the boost unit performs a lesser charge pumping operation from an initial time when power is supplied to the boost circuit until a desired time than after the desired time.

Abstract: In one embodiment, the boost circuit includes a boost unit configured to perform a charge pumping operation based on a control signal. A controller is configured to control the boost unit such that the boost unit performs a lesser charge pumping operation from an initial time when power is supplied to the boost circuit until a desired time than after the desired time.

Abstract: Am image sensor includes an active pixel array, an optical black pixel array, and a reset level compensation unit. The active pixel array includes a plurality of active pixels. The optical black pixel array includes a plurality of optical black pixels. The reset level compensation unit compensates for the active reset signal levels output form the active pixels, according to the average value of the optical black reset signal levels output from the optical black pixels. An active reset signal having a stable level is output regardless of the distribution of the optical black pixels and the active pixels.