Abstract: A solid-state imaging device in which a pixel circuit formed on the first surface side of a semiconductor substrate is shared by a plurality of light reception regions and second surface side of the semiconductor substrate is the light incident side of the light reception regions. The second surface side regions of the light reception regions are arranged at approximately even intervals and the first surface side regions of the light reception regions e are arranged at uneven intervals. Respective second surface side regions and first surface side regions are joined in the semiconductor substrate so that the light reception regions extend from the second surface side to the first surface side of the semiconductor substrate.

Abstract: A pixel includes detection portions which detect transferred charges, a reset portion which resets the plurality of detection portions, a connection/separation control portion which controls connection and separation of the detection portions, and an output portion which outputs a signal corresponding to the potential of a detection portion. In a state where the connection/separation control portion connects the detection portions, the output portion outputs a connection-state reset level signal and a connection-state output signal and, in a state where the connection/separation control portion separates the detection portions, the output portion outputs a separation-state reset level signal and a separation-state output signal. A first pixel signal is generated by a difference between the connection-state reset level signal and the connection-state output signal, and a second pixel signal is generated by a difference between the separation-state reset level signal and the separation-state output signal.

Abstract: A solid state image sensor includes a pixel array, as well as charge-to-voltage converters, reset gates, and amplifiers each shared by a plurality of pixels in the array. The voltage level of the reset gate power supply is set higher than the voltage level of the amplifier power supply. Additionally, charge overflowing from photodetectors in the pixels may be discarded into the charge-to-voltage converters. The image sensor may also include a row scanner configured such that, while scanning a row in the pixel array to read out signals therefrom, the row scanner resets the charge in the photodetectors of the pixels sharing a charge-to-voltage converter with pixels on the readout row. The charge reset is conducted simultaneously with or prior to reading out the signals from the pixels on the readout row.

Abstract: An image sensor includes a photodiode disposed in a first semiconductor material to absorb photons incident on the image sensor and generate image charge. A floating diffusion is disposed in the first semiconductor material and positioned to receive the image charge from the photodiode, and a transfer transistor is coupled between the photodiode and the floating diffusion to transfer the image charge out of the photodiode into floating diffusion in response to a transfer signal. A source follower transistor with a gate terminal is coupled to the floating diffusion to output an amplified signal of the image charge in the floating diffusion. The gate terminal includes a second semiconductor material in contact with the floating diffusion, and a gate oxide is partially disposed between the second semiconductor material and the first semiconductor material. The second semiconductor material extends beyond the lateral bounds of the floating diffusion.

Abstract: Provided is a solid-state image pickup device including: a plurality of pixels, each of which includes a photoelectric conversion portion and a pixel transistor formed in a front surface side of a substrate, wherein a rear surface side of the substrate is set as a light receiving plane of the photoelectric conversion portion; and an element, which becomes a passive element or an active element, which is disposed in the front surface side of the substrate so as to be superimposed on the photoelectric conversion portion.

Abstract: A pixel circuit for use in a high dynamic range (HDR) image sensor includes a photodiode and a floating diffusion is disposed in the first semiconductor wafer. A transfer transistor is disposed in the first semiconductor wafer and is adapted to be switched on to transfer the charge carriers photogenerated in the photodiode to the floating diffusion. An in-pixel capacitor is disposed in a second semiconductor wafer. The first semiconductor wafer is stacked with and coupled to the second semiconductor wafer. A dual floating diffusion (DFD) transistor is disposed in the first semiconductor wafer. The in-pixel capacitor is selectively coupled to the floating diffusion through the DFD transistor. The floating diffusion is set to low conversion gain in response to the in-pixel capacitor being coupled to the floating diffusion, and high conversion gain in response to the in-pixel capacitor being decoupled from the floating diffusion.

Abstract: A solid-state imaging device includes an Si substrate in which a photoelectric conversion unit that photoelectrically converts visible light incident from a back surface side is formed, and a lower substrate provided under the Si substrate and configured to photoelectrically convert infrared light incident from the back surface side.

Abstract: An apparatus and method for a low dark current floating diffusion is discussed. An example method includes coupling a photodiode to a floating diffusion through a transfer gate where a gate terminal of the transfer gate is provided a first voltage, resetting the floating diffusion, repetitively sampling image charge on the photodiode a plurality of times, where the sampled image charge is coupled to the floating diffusion, and where the gate terminal of the transfer gate is provided a second voltage less than the first voltage during each sampling of the image charge, while repetitively sampling the image charge, coupling an additional capacitance to the floating diffusion, where a first capacitance voltage is applied to the additional capacitance during the sampling, and performing correlated double sampling of the sampled image charge.

Abstract: An imaging device includes a pixel region in which light sensing pixels are grouped into pixel-units that each include multiple pixels, each column including pixels from at least two of the pixel-units. Each of the pixel-units is connected, via a corresponding readout line, to a corresponding readout unit configured to perform analog-to-digital conversion on pixel signals output thereto. A scanning unit that extends in a column direction is configured to select pixels for readout by applying row scanning pulses to scan lines connected to rows. A scanning unit that extends in a row direction for applying readout-enabling scan pulses to lines connected to columns is omitted. Those pixels that are selected for readout by one of the row scanning pulses are read out independently of any enabling pulses applied to lines connected to columns.

Abstract: An image sensor includes a pixel array having plurality of pixel cells arranged into a plurality of rows and a plurality of columns of pixel cells in a first semiconductor die. A plurality of pixel support circuits are arranged in a second semiconductor die that is stacked and coupled together with the first semiconductor die. A plurality of interconnect lines are coupled between the first and second semiconductor dies, and each one of the plurality of pixel cells is coupled to a corresponding one of the plurality of pixel support circuits through a corresponding one plurality of interconnect lines. A plurality of shield bumps are disposed proximate to corners of the pixel cells in the pixel array and between the first and second semiconductor dies such that each one of the plurality of shield bumps is disposed between adjacent interconnect lines along a diagonal of the pixel array.

Abstract: Provided is a solid-state image pickup device including: a plurality of pixels, each of which includes a photoelectric conversion portion and a pixel transistor formed in a front surface side of a substrate, wherein a rear surface side of the substrate is set as a light receiving plane of the photoelectric conversion portion; and an element, which becomes a passive element or an active element, which is disposed in the front surface side of the substrate so as to be superimposed on the photoelectric conversion portion.

Abstract: An image sensor for detecting light-emitting diode (LED) without flickering includes a pixel array with pixels. Each pixel including subpixels including a first and a second subpixel, dual floating diffusion (DFD) transistor, and a capacitor coupled to the DFD transistor. First subpixel includes a first photosensitive element to acquire a first image charge, and a first transfer gate transistor to selectively transfer the first image charge from the first photosensitive element to a first floating diffusion (FD) node. Second subpixel includes a second photosensitive element to acquire a second image charge, and a second transfer gate transistor to selectively transfer the second image charge from the second photosensitive element to a second FD node. DFD transistor coupled to the first and the second FD nodes. Other embodiments are also described.

Abstract: An electronic apparatus includes: a pixel array section in which pixels including photoelectric conversion sections that generate signal charges corresponding to amounts of light, charge accumulation sections that receive the signal charges from the corresponding photoelectric conversion sections and that are shared thereby, and pixel transistors that read out the signal charges generated by the corresponding photoelectric conversion sections and that are shared thereby are two-dimensionally arranged in a matrix; a solid-state image capture device including a scanner that can drive the pixels so that exposure periods of all of the pixels are simultaneously started, that can drive the pixels so that the exposure periods of all of the pixels are simultaneously ended, and that sequentially selects and scans the pixels in readout periods; and a mechanical shutter that determines an end of the exposure periods for still-image shooting.

Abstract: The present technology relates to an imaging device that can reduce the size thereof, and to an electronic apparatus. An upper substrate and a lower substrate are stacked. A pixel and a comparing unit that compares the voltage of a signal from the pixel with the ramp voltage are provided on the upper substrate, the ramp voltage varying with time. A storage unit that stores a code value obtained at a time when a comparison result from the comparing unit is inverted is provided on the lower substrate. The comparing unit is formed with a transistor that receives the voltage of the signal from the pixel at the gate, receives the ramp voltage at the source, and outputs a drain voltage. Accordingly, the imaging device can be made smaller in size. The present technology can be applied to image sensors.

Abstract: A solid-state imaging device in which a pixel circuit formed on the first surface side of a semiconductor substrate is shared by a plurality of light reception regions and second surface side of the semiconductor substrate is the light incident side of the light reception regions. The second surface side regions of the light reception regions are arranged at approximately even intervals and the first surface side regions of the light reception regions e are arranged at uneven intervals. Respective second surface side regions and first surface side regions are joined in the semiconductor substrate so that the light reception regions extend from the second surface side to the first surface side of the semiconductor substrate.

Abstract: A method of backside illuminated image sensor fabrication includes forming a plurality of photodiodes in a semiconductor material, where the plurality of photodiodes are disposed to receive image light through a backside of the backside illuminated image sensor. The method further includes forming a transfer gate coupled to extract image charge from a photodiode in the plurality of photodiodes, and forming a storage gate coupled to the transfer gate to receive the image charge. Forming the storage gate includes forming an optical shield in the semiconductor material; depositing a gate electrode proximate to a frontside of the semiconductor material; and implanting a storage node in the semiconductor material, where the storage node is disposed in the semiconductor material between the optical shield and the gate electrode.

Abstract: Provided is a solid-state image pickup device including: a plurality of pixels, each of which includes a photoelectric conversion portion and a pixel transistor formed in a front surface side of a substrate, wherein a rear surface side of the substrate is set as a light receiving plane of the photoelectric conversion portion; and an element, which becomes a passive element or an active element, which is disposed in the front surface side of the substrate so as to be superimposed on the photoelectric conversion portion.

Abstract: There is provided an imaging device that includes photovoltaic type pixels that have photoelectric conversion regions generating photovoltaic power for each pixel depending on irradiation light; and an element isolation region that is provided between the photoelectric conversion regions of adjacent pixels and in a state of substantially surrounding the photoelectric conversion region.

Abstract: The present technology relates to a conversion apparatus, an imaging apparatus, an electronic apparatus, and a conversion method that are capable of reducing the scale of a circuit. The conversion apparatus includes: a comparison unit that compares an input voltage of an input signal and a ramp voltage of a ramp signal that varies with time; and a storage unit that holds a code value when a comparison result from the comparison unit is inverted, the holding of the code value by the storage unit being repeated a plurality of times, to generate a digital signal having a predetermined bit number. The predetermined bit number is divided into high-order bits and low-order bits, the low-order bits are acquired earlier than the high-order bits, and the acquired low-order bits and the high-order bits are combined with each other, to generate the digital signal having the predetermined bit number. The present technology can be applied to a portion of an image sensor, in which AD conversion is performed.

Abstract: A pixel circuit for use in an image sensor includes an unpinned photodiode disposed in a semiconductor material. The unpinned photodiode adapted to photogenerate charge carriers in response to incident light. A floating diffusion is disposed in the semiconductor and coupled to receive the charge carriers photogenerated in the unpinned photodiode. A transfer transistor is disposed in the semiconductor material and coupled between the unpinned photodiode and the floating diffusion. The transfer transistor is adapted to be switched on to transfer the charge carriers photogenerated in the unpinned photodiode to the floating diffusion. A boost capacitor is disposed over a surface of the semiconductor material proximate to the unpinned photodiode. The boost capacitor is coupled to receive a photodiode boost signal while the transfer transistor is switched on to further drive the charge carriers photogenerated in the unpinned photodiode to the floating diffusion.