A vertically stacked image sensor with HDR imaging functionality and a method of operating the same are disclosed. The image sensor comprises, a first substrate, a pixel array organized into a plurality of pixel subarrays, of which each pixel comprises a photoelectric element for integrating a photocharge during each one of a plurality of subframe exposures, a transfer gate and a buffered charge-voltage converter. A first charge accumulation element of the charge-voltage converter is operatively connectable to at least one second charge accumulation element through a gain switch. The image sensor comprises control circuitry configured to trigger a partial or a complete transfer of the and to time-interleave at least two rolling shutter control sequences. Separate readout blocks are provided on the second substrate for each pixel subarray, each comprising in a pipelined architecture an A/D conversion unit, a pixel memory logic and a pixel memory unit.

A vertically stacked image sensor with HDR imaging functionality and a method of operating the same are disclosed. The image sensor comprises, a first substrate, a pixel array organized into a plurality of pixel subarrays, of which each pixel comprises a photoelectric element for integrating a photocharge during each one of a plurality of subframe exposures, a transfer gate and a buffered charge-voltage converter. A first charge accumulation element of the charge-voltage converter is operatively connectable to at least one second charge accumulation element through a gain switch. The image sensor comprises control circuitry configured to trigger a partial or a complete transfer of the and to time-interleave at least two rolling shutter control sequences. Separate readout blocks are provided on the second substrate for each pixel subarray, each comprising in a pipelined architecture an A/D conversion unit, a pixel memory logic and a pixel memory unit.

An image sensor generates first digital samples and second digital samples during respective first and second sampling intervals, the first digital samples including at least one digital sample of each pixel of a first plurality of pixels, and the second digital samples including at least one digital sample of each pixel of a second plurality of pixels. A sum of the first digital samples is accumulated within a first counter as the first sampling interval transpires, and a sum of the second digital samples is accumulated within the first counter as the second sampling interval transpires.

One example provides a method of generating a high dynamic range image via a differential TOF pixel comprising an array of pixels each having a first polyfinger and a second polyfinger, the first polyfinger and the second polyfinger being independently controllable to integrate current during an integration period, the method comprising, during the integration period, controlling the first polyfinger for a first exposure time, during the integration period, controlling the second polyfinger for a second exposure time, the second exposure time being shorter than the first exposure time, and for each pixel of the plurality of pixels, comparing a charge collected at the first polyfinger and a charge collected at the second polyfinger to a threshold, and selecting one of the charge collected at the first polyfinger and the charge collected at the second polyfinger for inclusion in the HDR image.

One example provides a method of generating a high dynamic range image via a differential TOF pixel comprising an array of pixels each having a first polyfinger and a second polyfinger, the first polyfinger and the second polyfinger being independently controllable to integrate current during an integration period, the method comprising, during the integration period, controlling the first polyfinger for a first exposure time, during the integration period, controlling the second polyfinger for a second exposure time, the second exposure time being shorter than the first exposure time, and for each pixel of the plurality of pixels, comparing a charge collected at the first polyfinger and a charge collected at the second polyfinger to a threshold, and selecting one of the charge collected at the first polyfinger and the charge collected at the second polyfinger for inclusion in the HDR image.

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.

An image sensor is provided. The image sensor includes: a plurality of pixels provided in a pixel array; a controller configured to control a first pixel group of the plurality of pixels to have a first exposure integration time and a second pixel group of the plurality of pixels to have a second exposure integration time; and a signal processor configured to generate image data based on digital signals corresponding to pixel signals generated by the pixel array, by performing operations on a first value of the digital signals corresponding to the first pixel group and a second value of the digital signals corresponding to the second pixel group. The first exposure integration time of the first pixel group is independent of illuminance of the image data.

A solid-state imaging apparatus includes a first light-shielded pixel region including two or more rows of pixels each including a photoelectric converter which is shielded from light, an aperture pixel region including pixels each including a photoelectric converter which is not shielded from light, and a control unit configured to perform control such that a charge accumulation period for the pixels in the first light-shielded pixel region is longer than a charge accumulation period for the pixels in the aperture pixel region and time to read signals from the pixels in a first row of the first light-shielded pixel region is different from time to read signals from the pixels in a second row different from the first row of the first light-shielded pixel region.

An image pickup apparatus having: an image sensor, having an image pickup plane, configured to photoelectrically convert a subject image formed on the image pickup plane to an image signal; a driving actuator configured to rotatably move the image sensor relative to a rotation axis passing through the image pickup plane; an angular velocity detection sensor configured to detect a rotational angular velocity of the image sensor about the rotation axis; a first shutter configured to control an exposure time of the image sensor; a second shutter configured to control the exposure time of the image sensor; and one or more processors configured to: control the driving actuator to reduce rotational shake around the rotation axis based on the rotational angular velocity; and select one of the first shutter and the second shutter to control the exposure time of the image sensor based on the rotational angular velocity.

Method and apparatus for controlling signal-to-noise ratio (SNR) in high dynamic range automatic exposure control imaging are disclosed. In the method and apparatus, image data is received and a shadow threshold is determined based on the image data. Further, a respective threshold integration ratio is determined for each merge transition of a plurality of exposures having a respective plurality of exposure times. The threshold integration ratio is determined based on a threshold SNR for the merge transition. In the method and apparatus, an integration ratio for each merge transition is determined based on the shadow threshold and the threshold integration ratios. An output image is generated based on the determined integration ratios for each merge transition.