A solid-state image pickup device is provided which can inhibit degradation of image quality which may occur when a global electronic shutter operation is performed. A gate drive line for a first transistor of gate drive lines for pixel transistors is positioned in proximity to a converting unit.

A pixel cell includes a photodiode disposed in a semiconductor material layer to accumulate image charge photogenerated in the photodiode in response to incident light. A storage transistor is coupled to the photodiode to store the image charge photogenerated in the photodiode. The storage transistor includes a storage gate disposed proximate a first surface of the semiconductor material layer. The storage gate includes a pair of vertical transfer gate (VTG) portions. Each one of the pair of VTG portions extends a first distance into the semiconductor material layer through the first surface of the semiconductor material layer. A storage node is disposed below the first surface of the semiconductor material layer and between the pair of VTG portions of the storage gate to store the image charge transferred from the photodiode in response to a storage signal.

The present disclosure relates to an imaging device, a driving method, and an electronic apparatus that can capture an image with a higher dynamic range. The imaging device includes a pixel region in which pixels are arranged, the pixels each including a photoelectric conversion unit that converts incident light into electric charges through electric conversion and stores the electric charges, and two or more charge storage units that store the electric charges transferred from the photoelectric conversion unit; and a drive unit that drives the pixels. The drive unit drives each pixel to cause the photoelectric conversion unit to repeatedly transfer electric charges with different exposure times to the two or more charge storage units during the light reception period of one frame. The present technology can be applied to an imaging device capable of capturing an HDR image, for example.

A solid-state imaging device includes: pixels arranged in a matrix on a semiconductor substrate. Each of the pixels includes: a photoelectric converter that converts received light into a signal charge; at least one read gate that reads the signal charge from the photoelectric converter; charge accumulators that each accumulate the signal charge read by the at least one read gate; and a charge holder that receives, from one of the charge accumulators, transfer of the signal charge accumulated in the charge accumulator, holds the signal charge, and transfers, to one of the charge accumulators, the signal charge held, each of the charge accumulators includes a part of a transfer channel and a part of a transfer electrode overlapping with the part of the transfer channel in a planar view of the semiconductor substrate, and the transfer channel per one pixel comprises transfer channels.

A solid-state imaging device includes: a plurality of pixels arranged in a matrix on a semiconductor substrate, wherein each of the plurality of pixels includes: a photoelectric converter that converts received light into a signal charge; a plurality of read gates that each read the signal charge from the photoelectric converter; a plurality of charge accumulators that each accumulate the signal charge read by any one of the plurality of read gates; and a charge holder that receives, from one of the plurality of charge accumulators, transfer of the signal charge accumulated in the charge accumulator, holds the signal charge, and transfers, to one of the plurality of charge accumulators, the signal charge held.

A solid-state image pickup device is provided which can inhibit degradation of image quality which may occur when a global electronic shutter operation is performed. A gate drive line for a first transistor of gate drive lines for pixel transistors is positioned in proximity to a converting unit.

The present disclosure relates to an imaging device, a driving method, and an electronic apparatus that can capture an image with a higher dynamic range. The imaging device includes a pixel region in which pixels are arranged, the pixels each including a photoelectric conversion unit that converts incident light into electric charges through electric conversion and stores the electric charges, and two or more charge storage units that store the electric charges transferred from the photoelectric conversion unit, and a drive unit that drives the pixels. The drive unit drives each pixel to cause the photoelectric conversion unit to repeatedly transfer electric charges with different exposure times to the two or more charge storage units during the light reception period of one frame. The present technology can be applied to an imaging device capable of capturing an HDR image, for example.

A photoelectric conversion device includes a plurality of pixels each of which includes a photoelectric converter that generates charges by photoelectric conversion, a first transfer unit that transfers charges in the photoelectric converter to a first holding portion, a second transfer unit that transfers charges in the first holding portion to a second holding portion, an amplifier unit that outputs a signal based on charges held in the second holding portion, and a third transfer unit that transfers charges of the photoelectric converter to a drain portion; and a control unit that, in an exposure period in which signal charges are accumulated in the photoelectric converter, changes a potential barrier formed by the third transfer unit with respect to the signal charges accumulated in the photoelectric converter from a first level to a second level that is higher than the first level.

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.

A pixel includes: a photoelectric conversion unit; a charge holding unit; a transfer unit which transfers a charge of the photoelectric conversion unit to the charge holding unit in an on-state; and an overflow control unit which discharges a charge of the photoelectric conversion unit in an on-state. There is a period in which both the transfer unit and the overflow control unit are in an off-state and the photoelectric conversion unit and the charge holding unit respectively hold a charge of a different frame. In a first mode, a first potential barrier is formed, the first potential barrier being lower than a potential barrier formed between the photoelectric conversion unit and the charge holding unit by the transfer unit in an off-state. In a second mode, a second potential barrier that is even lower than the first potential barrier is formed.