In a pixel array unit 11, pixels that generate pixel signals are arranged in a matrix. A control unit 17 performs reading of pixel signals in a first mode in which reading of the pixel signals is performed by thinning out lines from the pixel array unit 11, and reading of pixel signals in a second mode in which reading of the pixel signals is performed by including the lines thinned out in the first mode after the reading in the first mode. A signal processing unit 16 uses a pixel signal read in the first mode and a pixel signal read in the second mode, to set an amount of correction for a pixel of the lines thinned out in the first mode, on the basis of the pixel signal read in the second mode from a pixel in which reading of the pixel signal is performed in the first mode and the second mode, and corrects the pixel signal read in the second mode from the pixel of the lines thinned out in the first mode with the set amount of correction to reduce an influence of leakage light.

Provided is an image sensor including a first pixel including a first floating diffusion region and a second floating diffusion region, a second pixel including a first floating diffusion region, a second floating diffusion region, and a third floating diffusion region, a third pixel including a first floating diffusion region and a second floating diffusion region, and a fourth pixel including a first floating diffusion region, a second floating diffusion region, and a third floating diffusion region, wherein the second floating diffusion region of the first pixel and the second floating diffusion region of the second pixel are connected through a first metal line, and wherein the third floating diffusion region of the second pixel and the third floating diffusion region of the third pixel are connected through a second metal.

Methods for capturing and transmitting images by an in-vivo device comprise operating a pixel array in a superpixel readout mode to capture probe image, for example, according to a time interval. Concurrently to capturing of each probe image, the probe image is evaluated alone or in conjunction with other probe image(s), and if it is determined that no event of interest is detected by the last probe image, or by the last few probe images, the pixel array is operated in the superpixel readout mode and a subsequent probe image is captured. However, if it is determined that the last probe image, or the last few probe images, detected an event of interest, the pixel array is operated in a single pixel readout mode and a single normal image, or a series of normal image, is captured and transmitted, for example, to an external receiver.

An imaging system for low-power and low data-rate applications is provided. The imaging system comprises a pixel array having a plurality of photosensitive elements (pixels) divided into a plurality of groups of photosensitive elements (super pixels). An image processor is operably connected to the pixel array and configured to selectively operate each group of photosensitive elements in either (i) a high resolution mode in which the pixel array outputs readout voltages corresponding to all of the photosensitive elements in the respective group of photosensitive elements or (ii) a low resolution mode in which the pixel array outputs readout voltages corresponding to only a subset of the photosensitive elements in the respective group of photosensitive elements. Groups of photosensitive elements corresponding to detected motion in each image frame are operated in the high resolution mode, while the remaining groups of photosensitive elements are operated in the low resolution mode.

A solid-state imaging device according to an embodiment of the present disclosure includes a light-receiving surface and a plurality of pixels arranged to face the light-receiving surface. Each of the pixels includes a photoelectric conversion section that photoelectrically converts light incident via the light-receiving surface, a charge-holding section that holds charges transferred from the photoelectric conversion section, a first potential barrier provided between the photoelectric conversion section and the charge-holding section, and a second potential barrier provided around a region including the photoelectric conversion section, the charge-holding section, and a first impurity semiconductor region. The first potential barrier is lower than the second potential barrier.

The present disclosure relates to an imaging device and an imaging method capable of shortening an imaging interval in high-speed continuous imaging. A temporary memory, which temporarily stores image data transferred from an image sensor and then transfers the image data to a main memory, in a case where high-speed continuous imaging is instructed, sequentially stores a plurality of pieces of the image data transferred from the image sensor at a predetermined speed in a state where the transfer of the image data to the main memory is stopped, and then sequentially transfers the plurality of pieces of stored image data to the main memory at a speed lower than the predetermined speed. The present disclosure can be applied to an imaging device.

An image capturing apparatus comprising: an actuator that actuates an image sensor; a storage; an image processor that processes the image signal read out from the image sensor; and a controller that controls the actuator, the storage and the image processor by selectively using a plurality of operation modes. The plurality of operation modes includes a first operation mode of performing, at a predetermined first cycle, a first operation in which a first image signal is read out from the image sensor and processed by the image processor, and selectively performing a second operation in which a second image signal is read out from the image sensor and stored in the storage or a third operation in which the stored second image signal is read out from the storage and processed by the image processor.

An imaging device includes a first pixel. The first pixel includes a first photoelectric conversion region, and first and second transistors coupled to the first photoelectric conversion region to transfer charge generated by the first photoelectric conversion region. The imaging device includes a first driving circuit and a second driving circuit to drive the first pixel in a first mode and a second mode, the first mode being a mode in which the first driving circuit applies a first set of transfer signals to the first and second transfer transistors, the second mode being a mode in which the second driving circuit applies a transfer signal to only one of the first and second transfer transistors.

An untethered apparatus for performing inside-out device tracking based on visual-inertial simultaneous location and mapping (SLAM) includes a dynamic vision sensor (DVS) configured to output an asynchronous stream of sensor event data, an inertial measurement unit (IMU) sensor configured to collect IMU data associated with motion of the apparatus at a predetermined interval, a processor and a memory. The memory contains instructions, which when executed by the processor, cause the apparatus to accumulate DVS sensor output over a sliding time window, the sliding time window including the predetermined interval, apply a motion correction to the accumulated DVS sensor output, the motion correction based on the IMU data collected over the predetermined interval, generate an event-frame histogram of DVS sensor events based on the motion correction, and provide the event-frame histogram of the DVS sensor events and the IMU data to a visual inertial SLAM pipeline.

An imaging element includes a reading circuit, a memory that is capable of storing read captured image data, and an output circuit that outputs output image data based on the captured image data to an outside, in which the reading circuit reads out the captured image data using a first reading method or a second reading method having a smaller read data amount than the first reading method, in a case of the first reading method, a first frame rate corresponds to a second frame rate, in a case of the second reading method, the first frame rate is a frame rate lower than in the case of the first reading method, and the first and second reading methods are switched in accordance with a motion of a subject.