Described herein are techniques that improve the collection and readout of charge carriers in an integrated circuit. Some aspects of the present disclosure relate to integrated circuits having pixels with a plurality of charge storage regions. Some aspects of the present disclosure relate to integrated circuits configured to substantially simultaneously collect and read out charge carriers, at least in part. Some aspects of the present disclosure relate to integrated circuits having a plurality of pixels configured to transfer charge carriers between charge storage regions within each pixel substantially at the same time. Some aspects of the present disclosure relate to integrated circuits having three or more sequentially coupled charge storage regions. Some aspects of the present disclosure relate to integrated circuits capable of increased charge transfer rates. Some aspects of the present disclosure relate to techniques for manufacturing and operating integrated circuits according to the other techniques described herein.

A time of flight sensor includes at least one demodulation pixel. Each demodulation pixel includes a semiconductor substrate; a charge generation region in the semiconductor substrate, the charge generation region having a lateral extent, the charge generation region being configured to convert light into charge carriers; a light directing element in the charge generation region of the semiconductor substrate, the light directing element being configured to direct light through at least a portion of the lateral extent of the charge generation region; a collection region in the semiconductor substrate, the collection region being configured to collect the charge carriers generated in at least a portion of the lateral extent of the charge generation region, and a readout component in electrical communication with the collection region, the readout component being operable to control an electrical coupling between the charge generation region and the collection region.

A solid-state imaging device includes a pixel array where pixels are arranged in a matrix. Each of the pixels includes a photoelectric conversion unit configured to generate a signal charge based on incident light, and an element isolation layer having light-shielding properties and surrounding a periphery of the photoelectric conversion unit. The element isolation layers of adjacent ones of the pixels in a row direction and a column direction are isolated from each other. A charge storage layer and a charge trapping layer are provided in each of regions between the element isolation layers of the adjacent ones of the pixels in the row direction and the column direction. The charge storage layer stores the signal charge. The charge trapping layer reduces incidence of light on the charge storage layer.

The present disclosure relates to an imaging device and an electronic device that make it possible to obtain a better pixel signal. A photoelectric conversion part that converts received light into a charge; a holding part that holds a charge transferred from the photoelectric conversion part; and a light shielding part that shields light between the photoelectric conversion part and the holding part are provided. The photoelectric conversion part, the holding part, and the light shielding part are formed in a semiconductor substrate. The light shielding part of a transfer region that transfers the charge from the photoelectric conversion part to the holding part is formed as a non-penetrating light shielding part that does not penetrate the semiconductor substrate. The light shielding part other than the transfer region is formed as a penetrating light shielding part that penetrates the semiconductor substrate. The present technology is applicable to an imaging device.

A socket includes a first base member that includes a module mount unit allowing a module including an imaging device and an object to be placed thereon and an electric connector that electrically connects the imaging device to an external apparatus, a second base member having an opening, and an engagement unit that causes the first base member to be engaged with the second base member under a condition that the module placed on the module mount unit is sandwiched by the first and second base members. When the first base member is engaged with the second base member by the engagement unit under a condition that the module placed on the module mount unit is sandwiched by the first base member and the second base member, the electric connector is electrically connected to the imaging device, and the object receives illumination light from a light source through the opening.

A back-illuminated solid-state imaging device includes a semiconductor substrate, a shift register, and a light-shielding film. The semiconductor substrate includes a light incident surface on the back side and a light receiving portion generating a charge in accordance with light incidence. The shift register is disposed on the side of a light-detective surface opposite to the light incident surface of the semiconductor substrate. The light-shielding film is disposed on the side of the light-detective surface of the semiconductor substrate. The light-shielding film includes an uneven surface opposing the light-detective surface.

A circuit may include an array of single photon avalanche diode (SPAD) cells, each SPAD cell configured to be selectively enabled by an activation signal. The circuit may include a control circuit configured to selectively enable a subset of the array of SPAD cells based on a measured count rate of the array of SPAD cells.

A solid state imaging device that includes a phase difference detection pixel which is a pixel for phase difference detection; a first imaging pixel which is a pixel for imaging and is adjacent to the phase difference detection pixel; and a second imaging pixel which is a pixel for imaging other than the first imaging pixel. An area of a color filter of the first imaging pixel is smaller than an area of a color filter of the second imaging pixel.

A solid state imaging device has: a photosensitive part containing a plurality of charge transfer parts that transfer, in column units, the signal charges of a plurality of photoelectric conversion elements disposed in a matrix; a conversion/output unit that converts, to an electrical signal, the signal charges forwarded by the charge transfer parts; a peripheral circuit part that performs a predetermined process with respect to the electrical signals from the conversion/output part; a relay part that relays the forwarding to the peripheral circuit part of the electrical signal from the conversion/output part; a first substrate where a photosensitive part and the conversion/output part are formed; and a second substrate where the peripheral circuit part is formed. The first and second substrates are stacked together, and the relay part electrically connects the conversion/output part formed at the first substrate to the peripheral circuit part formed at the second substrate.

A Single-Photon Avalanche Diode (SPAD) device an active region configured to detect incident radiation, a first radiation blocking ring surrounding the active region, and a radiation blocking cover configured to shield part of the active region from the incident radiation. The radiation blocking cover is configured to define a second radiation blocking ring vertically spaced apart from the first radiation blocking ring. The SPAD device may include radiation blocking vias extending between the first and second radiation blocking rings.