A photosensitive sensor is capable of operating in a global shutter mode and in a rolling shutter mode. The sensor includes at least one pixel with a photosensitive region configured to photogenerate charges. A first transfer gate is configured to transfer photogenerated charges from the photosensitive region to a transfer node. A source-follower transistor is configured to transmit a reading signal to a read node, in the global shutter mode, in a manner controlled by a potential of the photogenerated charges on the transfer node. A second transfer gate is configured to transfer the photogenerated charges from the photosensitive region to the read node in the rolling shutter mode.

A dynamic vision sensor may include a pixel array including at least a first photoreceptor and a second photoreceptor, the first photoreceptor and the second photoreceptor including at least one first pixel and at least one second pixel, respectively, the at least one first pixel and the at least one second pixel configured to generate at least one first photocurrent and at least one second photocurrent in response to an incident light, respectively, and the first photoreceptor and the second photoreceptor configured to a first and second log voltages based on the at least one first photocurrent and the at least one second photocurrent, respectively, processing circuitry configured to, amplify the first and second log voltages, detect a change in intensity of the light based on the amplified first log voltage, the amplified second log voltage, and a reference voltage, and output an event signal corresponding to the detected value.

A dynamic vision sensor may include a pixel array including at least a first photoreceptor and a second photoreceptor, the first photoreceptor and the second photoreceptor including at least one first pixel and at least one second pixel, respectively, the at least one first pixel and the at least one second pixel configured to generate at least one first photocurrent and at least one second photocurrent in response to an incident light, respectively, and the first photoreceptor and the second photoreceptor configured to a first and second log voltages based on the at least one first photocurrent and the at least one second photocurrent, respectively, processing circuitry configured to, amplify the first and second log voltages, detect a change in intensity of the light based on the amplified first log voltage, the amplified second log voltage, and a reference voltage, and output an event signal corresponding to the detected value.

An image sensor comprises a row driver, a first row line which is connected to the row driver, first to fourth pixels connected to the first row line, first to fourth column lines connected to the first to fourth pixels and configured to receive respective first to fourth output signals from the first to fourth pixels, a boosting circuit connected to the first to fourth column lines, a second row line connected to the boosting circuit, first and second boosting drivers connected, respectively, to first and second terminals of the second row line. The boosting circuit may adjust voltage of the first and second output signals based on a first boosting enable signal received from the first boosting driver and may adjust a voltage of the third and fourth output signals based on a second boosting enable signal received from the second boosting driver.

Provided is a reception apparatus that includes an information processing section configured to generate an image at least either in a first mode for reading out a whole captured region or in a second mode for reading out a partial region in the captured region. At the time of readout in the second mode, the image processing section varies a readout rate depending on the region.

An image sensor comprises a plurality of pixels. Pixels are capable of detecting a change in an amount of light intensity and pixels are capable of detecting an amount of light intensity. In a first mode the sensor outputs data from the first one or more of the pixels. In a second mode the sensor outputs data from the second one or more of the pixels. At least one of the first mode and the second mode is selected by a processor based on at least one of a result of processing data output in the first mode and a result of processing data output in the second mode.

An image sensor includes a pixel array including a first pixel and a second pixel which are connected to a same column line, the first pixel including 2N sub-pixels sharing a first floating diffusion node and the second pixel including 2N sub-pixels sharing a second floating diffusion node, wherein N is a positive integer greater than or equal to two, a timing generator configured to change a reset order and a readout order of 4N sub-pixels included in the first pixel and the second pixel, according to an exposure time setting value, and output a row address according to the changed orders, and a row driver configured to drive the pixel array based on the row address.

An image recognition device (image recognition system 100) according to the present disclosure includes an imaging unit (10) and a recognition unit (14). The imaging unit (10) captures a plurality of images at the same exposure start timing in one frame period by using imaging pixels having different sensitivities to generate image data. The recognition unit (14) recognizes a subject from each of the image data. The imaging unit (10) includes a pixel array in which a plurality of imaging pixels having different exposure times, different light transmittances of color filters, or different light receiving areas are two-dimensionally arranged.

An image capturing circuit that can be applied to an image capturing apparatus, including a pixel array having photoelectric conversion elements arranged in a matrix, a row selection circuit capable of reading out still image data with a first resolution and LV moving image data with a second resolution lower than the first resolution from the pixel array, an image memory for storing the read still image data and the read LV moving image data, and a reduction circuit that converts the still image data to reduced image data with a third resolution lower than the first resolution. The still image data is read out from the memory and output after converted to the reduced still image data, and the still image data is also output without being converted. The LV moving image data is read out from the memory and output without being converted.

An image capturing circuit that can be applied to an image capturing apparatus, including a pixel array having photoelectric conversion elements arranged in a matrix, a row selection circuit capable of reading out still image data with a first resolution and LV moving image data with a second resolution lower than the first resolution from the pixel array, an image memory for storing the read still image data and the read LV moving image data, and a reduction circuit that converts the still image data to reduced image data with a third resolution lower than the first resolution. The still image data is read out from the memory and output after converted to the reduced still image data, and the still image data is also output without being converted. The LV moving image data is read out from the memory and output without being converted.