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.

In accordance with an embodiment of the present disclosure, an image synchronization device includes a light emitting source configured to emit light at intervals of a predetermined time, a sampling phase calibration circuit configured to calibrate a sampling phase of each of the first image sensor and the second image sensor on the basis of a light emitting timing of the light emitting source and a delay calibration circuit configured to generate delay information on the basis of a result of comparison between first image information transmitted from the first image sensor and second image information transmitted from the second image sensor.

An image sensor and a camera are provided. The image sensor includes: a demodulation clock generation circuit configured to generate first to fourth demodulation clock signals respectively having first to fourth phases; a demodulation phase selection circuit configured to generate first to fourth pre-demodulation signals based on the first to fourth demodulation clock signals and a random number that changes for each of a plurality of packets; a delay circuit configured to generate a first delay signals, second delay signals, third delay signals and fourth delay signals by delaying the first to fourth pre-demodulation signals by a plurality of delay phases; and a phase mixer configured to generate first to fourth demodulation signals of which phases are changed based on an address that changes for each of the plurality of packets. The first to fourth phases have a phase difference of 90° from each other.

An image sensor may include a pixel array including a plurality of pixel blocks structured to convert light into electrical signals. Each of the plurality of pixel blocks may include a first light receiving circuit including a plurality of unit pixels which share a first floating diffusion; a second light receiving circuit arranged adjacent to the first light receiving circuit in a second direction, and including a plurality of unit pixels which share a second floating diffusion; a first driving circuit and a second driving circuit positioned between the first light receiving circuit and the second light receiving circuit, and aligned in a first direction crossing the second direction; and an intercoupling circuit configured to electrically couple the first floating diffusion, the second floating diffusion, the first driving circuit and the second driving circuit.

An image sensor includes an array of pixels inside and on top of a substrate. A control circuit is configured to apply voltage potentials to the substrate. During a first phase, the control circuit applies a ground potential to the substrate. During a second phase, the control circuit applies a potential positive with respect to the ground potential to the substrate.

An imaging device includes a controller, a power supply, a regulator, and a switch. The controller is configured to control an imaging unit, on the basis of a command and data that are received from a host in accordance with an I2C/I3C communication protocol. The power supply is configured to supply a voltage to a digital block of the controller. The digital block is configured to be subjected to dynamic voltage frequency scaling within one-frame operation. The regulator and the switch are provided between the digital block and the power supply, and coupled in parallel with each other.

A solid-state imaging device comprising: a pixel array including pixels arranged in a plurality of rows and in a plurality of columns; a first column circuit group; a second column circuit group disposed in the same side with respect to the pixel array as that in which the first column circuit group is disposed; a first counter configured to supply a count signal to the first column circuit group; and a second counter configured to supply a count signal to the second column circuit group, wherein the first column circuit group and the second column circuit group are arranged to be separate from each other in a direction along the columns, wherein the first column circuit group and the second column circuit group are configured to process pixel signals for different colors.

An imaging device includes a light source configured to operate by a light control signal having a first duty ratio; a pixel array in which a plurality of pixels are disposed, each of the plurality of pixels including a photodiode for generating electrical charges in response to a light reception signal output by the light source and reflected from a subject, and a pixel circuit for outputting a pixel signal corresponding to electrical charges of the photodiode; and a logic circuit configured to generate raw data for generating a depth image using the pixel signal, wherein the logic circuit inputs a photo control signal having a second duty ratio to the pixel circuit connected to the photodiode in each of the plurality of pixels, and wherein the first duty ratio is not an integer multiple of the second duty ratio.

An image sensor is provided. The image sensor includes a counting code generator configured to generate a counting code, a pixel array including at least one pixel, a correlated double sampling (CDS) circuit configured to compare a magnitude of a pixel signal output from the at least one pixel with a magnitude of a ramp signal and to output a corresponding comparison signal, a pulse generator configured to generate a pulse signal synchronized with a first clock signal based on the comparison signal, and a counter circuit configured to latch a value of the counting code to correspond to a transition of a level of the comparison signal based on the pulse signal.

An imaging device includes an image sensing circuitry configured to receive image signals from pixels, to convert the received image signals into image data, and to output the image data. The imaging device includes a digital processing circuitry configured to process image data in synchronization with a digital clock. The digital processing circuitry includes a digital clock generator configured to generate the digital clock. The digital clock generator is configured to scatter the digital clock, in response to the image sensing circuitry converting the image signals into the image data.