An event-driven sensor including: a pixel array; a column readout circuit coupled to column output lines of the pixel array, the column readout circuit including a plurality of column register cells; and a row readout circuit including a readout memory having a storage location corresponding to each pixel of the pixel array, the readout memory having sets of one or more row lines for writing to rows of memory locations of the readout memory, wherein each row output line of the pixel array is coupled, via a corresponding row line control circuit, to a corresponding one of the sets of one or more row lines of the readout memory.

To generate multiple types of images of the same subject, an electronic apparatus includes a drive control unit that controls the drive of an image sensor, a division unit that divides an image capture region of the image sensor into at least first and second regions, and an image generation unit that generates a first image by capturing an image of the same subject in the first region and generates a second image by capturing an image of the same subject in the second region.

The present disclosure relates to an event-driven sensor comprising: a pixel array (102); a column readout circuit (104) comprising, for each of the column output lines, a column register cell (108) configured to activate a column event output signal (addrx) when it receives a first token while the detection of an event is indicated on the column output line; and a row readout circuit (106) comprising, for each of the row output lines, or for each of a plurality of sub-groups of the row output lines, a row register cell (108) configured to activate a row event output signal (addry) when it receives a second token while an event is indicated on the row output line, or on one of the row output lines of the sub-group.

There is provided a pixel circuit capable of outputting time difference data and image data, and including an image circuit and a difference circuit. The image circuit is used to record and output detected light energy of a first interval as the image data. The difference circuit is used to record and output a variation of detected light energy between the first interval and a second interval as the time difference data. The pixel circuit selects to output at least one of the time difference data and the image data.

There is provided a pixel circuit capable of outputting time difference data and image data, and including an image circuit and a difference circuit. The image circuit is used to record and output detected light energy of a first interval as the image data. The difference circuit is used to record and output a variation of detected light energy between the first interval and a second interval as the time difference data. The pixel circuit selects to output at least one of the time difference data and the image data.

An apparatus according to the present invention in which a first substrate including a photoelectric conversion element and a gate electrode of a transistor, and a second substrate including a peripheral circuit portion are placed upon each other. The first substrate does not include a high-melting-metal compound layer, and the second substrate includes a high-melting-metal compound layer.

Disclosed is an image sensor including first to fourth, fifth to eighth, ninth to 12.sup.th and 13.sup.th to 16.sup.th unit pixel circuits, a first readout line connected to the first and ninth unit pixel circuits, a second readout line connected to the fifth and 13.sup.th unit pixel circuits, a third readout line connected to the second and 10.sup.th unit pixel circuits, a fourth readout line connected to the sixth and 14.sup.th unit pixel circuits, a fifth readout line connected to the third and 11.sup.th unit pixel circuits, a sixth readout line connected to the seventh and 15.sup.th unit pixel circuits, a seventh readout line connected to the fourth and 12.sup.th unit pixel circuits, an eighth readout line connected to the eighth and 16.sup.th unit pixel circuits, first to fourth readout circuits, and a path selector connecting the unit pixel circuits to the readout circuits via the readout lines.

An image sensing device includes a first test block, a second test block, and a readout block. The first test block includes a plurality of first image sensing pixels structured to convert incident light carrying an image into a first pixel signal indicative of the image, and a first heating element structured to transmit heat to the first image sensing pixels. The second test block includes a plurality of second image sensing pixels that each include a light blocking structure to be shielded from receiving incident light to generate a second pixel signal without being directly exposed to the incident light, and a second heating element structured to transmit heat to the second image sensing pixels. The readout block processes the first pixel signal output from the first test block and the second pixel signal output from the second test block.

Provided is a photoelectric conversion device including a pixel array that includes pixels forming columns and is arranged in a substrate, first signal lines each transmitting a signal output from a pixel of a corresponding column, an analog circuit arranged in the substrate and configured to process signals from the pixels, second signal lines transmitting signals from the pixels to the analog circuit on a column basis, a switch configured to change a combination of connections between the first signal lines and the second signal lines, and a shift register arranged in the substrate, including a flip-flop, and configured to control the switch. In a plan view with respect to the substrate, the shift register is arranged between the pixel array and the analog circuit. In the plan view, the switch and the flip-flop are arranged in a direction different from a direction in which the first signal lines extend.

The present disclosure relates to an imaging circuit and an imaging device capable of performing reading at high speed while reducing a circuit scale.

An imaging circuit according to the present disclosure includes a plurality of circuit blocks each including a photoelectric conversion element configured to photoelectrically convert incident light to generate a photocurrent and a current-voltage conversion circuit configured to convert the photocurrent into a voltage signal, a quantizer configured to generate a detection signal of an address event in accordance with a result of comparing the voltage signal supplied from at least one of the plurality of circuit blocks with a threshold, a demultiplexer connected to a subsequent stage of the quantizer, and a plurality of latch circuits connected to different output terminals of the demultiplexer.