At least one example embodiment discloses a method of generating an image using a global shutter image sensor. The method includes accumulating a first plurality of charges during a first exposure time from a first plurality of pixels, accumulating a second plurality of charges during a plurality of second exposure times from a second plurality of pixels, the plurality of second exposure times occurring during the first exposure time and being shorter than the first exposure time and generating the image based on the first plurality of charges and the second plurality of charges.

An imaging device includes an imaging element that acquires a first image based on signal charge generated during a first accumulation time, and a second image based on signal charge generated during a second accumulation time relatively longer than the first accumulation time and synchronized with the first image during a synchronization period including the first accumulation time, and a moving image file generating unit that generates a moving image file including a first moving image based on the first image, a second moving image based on the second image, and synchronization information for synchronizing the first moving image and the second moving image frame by frame.

The present technology relates to a solid-state imaging device and an electronic apparatus that enable simultaneous acquisition of a signal for generating a high dynamic range image and a signal for detecting a phase difference.

The solid-state imaging device includes a plurality of pixel sets each including color filters of the same color, for a plurality of colors, each pixel set including a plurality of pixels. Each pixel includes a plurality of photodiodes PD. The present technology can be applied, for example, to a solid-state imaging device that generates a high dynamic range image and detects a phase difference, and the like.

Methods and systems for coded rolling shutter are provided. In accordance with some embodiments, methods and system are provided that control the readout timing and exposure length for each row of a pixel array in an image sensor, thereby flexibly sampling the three-dimensional space-time value of a scene and capturing sub-images that effectively encode motion and dynamic range information within a single captured image.

A high dynamic range imaging pixel may include a photodiode that generates charge in response to incident light. When the generated charge exceeds a first charge level, the charge may overflow through a first transistor to a first storage capacitor. When the generated charge exceeds a second charge level that is higher than the first charge level, the charge may overflow through a second transistor. The charge that overflows through the second transistor may alternately be coupled to a voltage supply and drained or transferred to a second storage capacitor for subsequent readout. Diverting more overflow charge to the voltage supply may increase the dynamic range of the pixel. The amount of charge diverted to the voltage supply may therefore be updated to control the dynamic range of the imaging pixel.

An imaging device includes an image acquisition unit that acquires an original image in which pixels with different exposure periods coexist; a corrected-image generating unit that generates corrected images individually for a plurality of pixel groups formed by classifying the pixels according to the exposure periods, the corrected images being generated by interpolating pixel values and executing exposure correction; and an HDR combining unit that combines the corrected images, wherein, in a case where the difference between the pixel value of a pixel belonging to one of the pixel groups, acquired by exposure, and the pixel value of a pixel belonging to another one of the pixel groups, generated by interpolation at the same position as the aforementioned pixel, is greater than a predetermined threshold, the HDR combining unit increases the combining ratio of the pixel in the corrected image belonging to the one of the pixel group.

In time-delay-and-integrate (TDI) imaging, a charge-couple device (CCD) integrates and transfers charge across its columns. Unfortunately, the limited well depth of the CCD limits the dynamic range of the resulting image. Fortunately, TDI imaging can be implemented with a digital focal plane array (DFPA) that includes a detector, analog-to-digital converter (ADC), and counter in each pixel and transfer circuitry connected adjacent pixels. During each integration period in the TDI scan, each detector in the DFPA generates a photocurrent that the corresponding ADC turns into digital pulses, which the corresponding counter counts. Between integration periods, the DFPA transfers the counts from one column to the next, just like in a TDI CCD. The DFPA also non-destructively transfers some or all of the counts to a separate memory. A processor uses these counts to estimate photon flux and correct any rollovers caused by “saturation” of the counters.

A single-exposure high dynamic range (HDR) image sensor utilizes a charge amplifier having a selectively coupled conversion capacitor to read a single photodiode charge during a multi-phase readout operation. An overflow readout is performed during the photodiode charge integration phase, and utilizes the conversion capacitor to read overflow signals indicating rapidly rising photodiode charges caused by extreme exposure conditions, which also prevents saturation of the photodiode. At the end of the integration phase, the remaining photodiode charge is then measured using two readouts: a high sensitivity readout during which the storage capacitor de-coupled to accurately measure low-light conditions, and a low sensitivity readout during which the remaining photodiode charge is stored on the storage capacitor to provide normal light image data. Final single exposure HDR image data is then calculated by summing the overflow image data with the high-sensitivity and/or the low-sensitivity image data.

A solid-state imaging device includes a pixel array and a pixel value correcting unit. The pixel array includes a plurality of pixels, the plurality of pixels each having one of a different exposure time and a different exposure sensitivity and being disposed according to a predetermined rule. The pixel value correcting unit is configured to correct, among pixel values obtained from the plurality of pixels in the pixel array, a pixel value of a pixel of the plurality of pixels that applies to a preset condition, by using a pixel value of another pixel of the plurality of pixels.

An electronic apparatus includes: an input unit that inputs image data generated by an image capturing unit that has a plurality of imaging regions and that has different imaging conditions for each of the imaging regions and data for the imaging conditions for each of the imaging regions; and a recording control unit that records the image data and the data for the imaging conditions that are inputted from the input unit in a recording unit, wherein the recording control unit records the image data in a recording region of the recording unit which is read after the data for the imaging conditions for each of the image regions.