The present technology relates to an image sensor, an imaging device, and a ranging device capable of performing imaging so that noise is reduced. A photoelectric conversion unit configured to perform photoelectric conversion; a charge accumulation unit configured to accumulate charges obtained by the photoelectric conversion unit; a transfer unit configured to transfer the charges from the photoelectric conversion unit to the charge accumulation unit; a reset unit configured to reset the charge accumulation unit; a reset voltage control unit configured to control a voltage to be applied to the reset unit; and an additional control unit configured to control addition of capacitance to the charge accumulation unit are included. The charge accumulation unit includes a plurality of regions. The present technology can be applied to, for example, an imaging device that captures an image and a ranging device that performs ranging.

An imaging device includes pixels. Each of the pixels includes a first electrode, a second electrode, a photoelectric conversion layer that is located between the first electrode and the second electrode, that contains a donor semiconductor material and an acceptor semiconductor material, and that generates a pair of an electron and a hole, a first charge blocking layer located between the first electrode and the photoelectric conversion layer, a second charge blocking layer located between the second electrode and the photoelectric conversion layer, and a charge storage region that is electrically connected to the second electrode and that stores the hole. The difference between the electron affinity of the acceptor semiconductor material and the electron affinity of the first charge blocking layer is larger than the difference between the ionization potential of the donor semiconductor material and the ionization potential of the second charge blocking layer.

Disclosed is a SPAD pixel for a backside illuminated image sensor. More particularly, the SPAD pixel may improve sensitivity to long wavelengths by maximizing the depth of a PN junction in an epitaxial layer in the SPAD substrate.

A backside illuminated image sensor, including a semiconductor layer, a first gate structure, and a light sensing device, is provided. The semiconductor layer has a first surface and a second surface opposite to each other. The first gate structure is disposed on the second surface. The light sensing device is located in the semiconductor layer. The light sensing device extends from the first surface to the second surface.

A photo sensor, a manufacturing method thereof, and a display panel are disclosed. By an ion implantation method forming an N-type region and a P-type region on a surface of polycrystalline silicon in a same layer respectively, compatibility with an ion implantation process is ensured, while covering a layer of an amorphous silicon photosensitive layer on the polycrystalline silicon enhances light absorption ability and can increase photo-generated electron-hole pairs. Furthermore, built-in electric fields exist on a horizontal direction and a vertical direction, which can more effectively separate the electron-hole pairs to enhance photo-generated electric current to improve accuracy of fingerprint recognition.

A photoelectric conversion apparatus includes pixels having adjacent first and second pixels. The pixels each include, in a semiconductor layer of a substrate, a photoelectric conversion portion that generates charges, a charge holding portion that holds the charges, and a floating diffusion layer that converts the charges into a voltage. At least parts of the charge holding portion in the first pixel and the floating diffusion layer in the second pixel, parts of the charge holding portion in the first pixel and the charge holding portion in the second pixel, and/or parts of the floating diffusion layer in the first pixel and the floating diffusion layer in the second pixel overlap each other without physically touching each other in a depth direction of the substrate in a state where a region for separating the at least parts of the charge holding portions and the floating diffusion layers is provided therebetween.

The disclosure relates to a demodulator including a pinned photodiode; at least one storage node; at least one transfer gate connected between the storage node and the pinned photodiode. The pinned photodiode includes a p-doped epitaxial semiconductor layer; a n-doped semiconductor region formed within the epitaxial semiconductor layer; a p+ pinning layer formed on top of said semiconductor region. The pinning layer is split into at least two separate regions spaced apart by electrical insulating element, each region being arranged for being biased independently by a respective biasing signal for creating a gradient of potential within the semiconductor region.

A dynamic vision sensor (DVS) or change detection sensor reacts to changes in light intensity and in this way monitors how a scene changes. This disclosure covers both single pixel and array architectures. The DVS may contain one pixel or 2-dimensional or 1-dimensional array of pixels. The change of intensities registered by pixels are compared, and pixel addresses where the change is positive or negative are recorded and processed. Analyzing frames based on just three values for pixels, increase, decrease or unchanged, the proposed DVS can process visual information much faster than traditional computer vision systems, which correlate multi-bit color or gray level pixel values between successive frames.

Some embodiments relate to an imaging system including an active pixel and an analog-to-digital conversion (ADC) circuit including comparator. The comparator may be operatively coupled to the active pixel and configured to receive an output of the active pixel. The back-end ADC and memory circuit may be operatively coupled to the active pixel. The back-end ADC and memory circuit may include a write control circuit, an ADC memory operatively coupled to a read/write data bus and to the write control circuit, and a state latch operatively coupled to the write control circuit.

Provided is a semiconductor device capable of achieving high detection efficiency and low jitter without depending on an increase in thickness of a substrate. A semiconductor device is provided with a plurality of pixels in each of which an avalanche photodiode element that photoelectrically converts incident light is formed, and each of the plurality of pixels is provided with a substrate including a first semiconductor material, and a stacked portion stacked on a surface on a light incident side of the substrate and including a second semiconductor material different from the first semiconductor material.