Abstract: A three-dimensional motion obtaining apparatus includes: a light source; a charge amount obtaining circuit that includes pixels and obtains, for each of the pixels, a first charge amount under a first exposure pattern and a second charge amount under a second exposure pattern having an exposure period that at least partially overlaps an exposure period of the first exposure pattern; and a processor that controls a light emission pattern for the light source, the first exposure pattern, and the second exposure pattern. The processor estimates a distance to a subject for each of the pixels on the basis of the light emission pattern and on the basis of the first charge amount and the second charge amount of each of the pixels obtained by the charge amount obtaining circuit, and estimates an optical flow for each of the pixels on the basis of the first exposure pattern, the second exposure pattern, and the first charge amount and the second charge amount obtained by the charge amount obtaining circuit.

Abstract: A photodetection device includes: a photoelectric converter generating charge; a first channel having first and second ends, the first end being connected to the photoelectric converter, charge being transferred from the first end toward the second end; a second channel diverging from the first channel at a first position of the first channel; a third channel diverging from the first channel at a second position of the first channel; a first accumulator accumulating charge transferred from the first channel through the second channel; a second accumulator accumulating charge transferred from the first channel through the third channel; and at least one first gate electrode switching between transfer/cutoff of charge in the second channel, and switching between transfer/cutoff of charge in the third channel, a width of the first channel at the first end being greater than a width of the first channel at the second end in a plan view.

Abstract: A photodetection device includes: a photoelectric converter generating charge; a first transfer channel having first and second ends, the first end being connected to the photoelectric converter, charge from the photoelectric converter being transferred from the first end toward the second end; a second transfer channel diverging from the first transfer channel at a first position; a third transfer channel diverging from the first transfer channel at a second position, further than the first position from the first end; a first charge accumulator accumulating charge transferred through the second transfer channel; a second charge accumulator accumulating charge transferred through the third transfer channel; a first gate electrode switching between transfer/cutoff of charge in the first transfer channel; and at least one second gate electrode switching between transfer/cutoff of charge in the second and third transfer channels, the third transfer channel being wider than the second transfer channel.

Abstract: A photodetection device includes: a photoelectric converter generating charge; a first diffusion region having a first end connected to the photoelectric converter and a second end and extending in a first direction from the first end toward the second end; a second diffusion region having a third end connected to a first side surface, of the first diffusion region, which is along the first direction and a fourth end and extending in a second direction from the third end toward the fourth end; a first charge accumulator connected to the fourth end; a first gate electrode covering at least part of the first diffusion region; and a second gate electrode covering at least part of the second diffusion region. The second gate electrode covers a first portion of the first diffusion region without the first gate electrode intervention. The first portion is adjacent to the second diffusion region.

Abstract: An imaging device includes a pixel, the pixel including a photoelectric converter which converts light into a signal charge and a charge detection circuit which detects the signal charge. The photoelectric converter includes a photoelectric conversion layer having a first surface and a second surface opposite to the first surface, a pixel electrode on the first surface, a first electrode adjacent to the pixel electrode on the first surface, the first electrode being electrically conductive to the photoelectric conversion layer, and a counter electrode on the second surface, the counter electrode facing the pixel electrode and the first electrode. A shortest distance between the pixel electrode and the first electrode in a plan view is smaller than a shortest distance between the pixel electrode and the first electrode.

Abstract: In one general aspect, the techniques disclosed here feature an imaging device that includes: a semiconductor substrate; a first pixel cell including a first photoelectric converter in the semiconductor substrate, and a first capacitive element one end of which is electrically connected to the first photoelectric converter; and a second pixel cell including a second photoelectric converter in the semiconductor substrate. An area of the second photoelectric converter is larger than an area of the first photoelectric converter in a plan view.

Abstract: A photodetector includes: a semiconductor substrate including first and second impurity regions; a gate insulating layer located on a region of the semiconductor substrate, the region being between the first and second impurity regions, the gate insulating layer including a photoelectric conversion layer; a gate electrode located on the gate insulating layer and having a light-transmitting property; a first charge transfer channel transferring signal charges corresponding to a current occurring between the first impurity region and the second impurity region depending on a change in a dielectric constant of the photoelectric conversion layer caused by light incidence on the photoelectric conversion layer; a second charge transfer channel diverging from the first charge transfer channel; a first charge storage storing charges, among the signal charges, transferred via the second charge transfer channel; and a first gate switching transfer and shutdown of charges passing through the second charge transfer chann

Abstract: In one general aspect, the techniques disclosed here feature an imaging device that includes: a semiconductor substrate; a first pixel cell including a first photoelectric converter in the semiconductor substrate, and a first capacitive element one end of which is electrically connected to the first photoelectric converter; and a second pixel cell including a second photoelectric converter in the semiconductor substrate. An area of the second photoelectric converter is larger than an area of the first photoelectric converter in a plan view.

Abstract: An imaging device includes a pixel cell including a photoelectric conversion layer having first and second surfaces, a pixel electrode on the first surface, an auxiliary electrode on the first surface, the auxiliary electrode surrounding the pixel electrode and being electrically insulated from the pixel electrode, a counter electrode on the second surface, and a charge detection circuit connected to the pixel electrode; a voltage supply circuit; a first switch switching between electrical connection and disconnection; a first capacitor having one end connected to the auxiliary electrode and the other end held to a predetermined voltage; and a first control circuit connected to the first switch, the first control circuit causing the first switch to switch between electrical connection and disconnection. The voltage supply circuit is connected, through the first switch, to the auxiliary electrode of the first pixel cell and to the one end of the first capacitor.

Abstract: An imaging apparatus includes a unit pixel including a pixel electrode, a charge accumulation region electrically connected to the pixel electrode, and a signal detection circuit electrically connected to the charge accumulation region; a counter electrode facing the pixel electrode; a photoelectric conversion layer disposed between the electrodes; and a voltage supply circuit configured to selectively apply any one of first, second, and third voltages between the electrodes. The photoelectric conversion layer exhibits first and second wavelength sensitivity characteristics in a wavelength range when the voltage supply circuit applies the first and second voltages between the electrodes, respectively, and becomes insensitive to light in the wavelength range when the voltage supply circuit applies the third voltage between the electrodes.

Abstract: An imaging device of the present disclosure includes: an imaging cell including a photoelectric converter including a first electrode, a second electrode, and a photoelectric conversion layer between the first electrode and the second electrode, the photoelectric converter generating signal charge by photoelectric conversion, and a charge detection circuit connected to the first electrode, the charge detection circuit detecting the signal charge; a signal line electrically coupled to the first electrode; and a voltage supply circuit selectively supplying a first voltage and a second voltage different from the first voltage to the signal line.

Abstract: An imaging device of the present disclosure includes: a first and second imaging cells each including a photoelectric converter including a pixel electrode, an opposite electrode, and a photoelectric conversion layer between the pixel electrode and the opposite electrode, the photoelectric converter generating signal charge by photoelectric conversion, and charge detection circuit connected to the pixel electrode, the charge detection circuit detecting the signal charge; and a voltage supply circuit supplying a voltage such that, in a frame period, a potential difference between the pixel electrode and the opposite electrode of the first imaging cell at a start time of a charge accumulation period of the first imaging cell is made different from a potential difference between the pixel electrode and the opposite electrode of the second imaging cell at a start time of a charge accumulation period of the second imaging cell.

Abstract: An imaging apparatus includes a unit pixel including a pixel electrode; a counter electrode facing the pixel electrode; a photoelectric conversion layer disposed between the pixel electrode and the counter electrode; and a computing circuit that acquires a first signal upon a first voltage being applied between the pixel electrode and the counter electrode, the first signal corresponding to an image captured with visible light and infrared light and a second signal upon a second voltage being applied between the pixel electrode and the counter electrode, the second signal corresponding to an image captured with visible light, and generates a third signal by performing a computation using the first signal and the second signal, the third signal corresponding to an image captured with infrared light.

Abstract: A method is for controlling an imaging device that allows switching of an operation mode between a first mode to perform imaging in a first imaging wavelength band and a second mode to perform imaging in a second imaging wavelength band different from the first imaging wavelength band. The method includes: determining whether ambient light includes near-infrared light based on information obtained in the first mode and information obtained in the second mode; and maintaining or changing the operation mode.

Abstract: An imaging device includes: a pixel array including first and second pixels, each pixel including a photoelectric converter converting light into charge and a detection circuit detecting the charge; a first voltage supply circuit supplying a first voltage to the first pixel such that an electric potential of the first electrode is set to a first electric potential at a point of time at which a charge accumulation period for the first pixel starts; a second voltage supply circuit supplying a second voltage to the second pixel such that an electric potential of the first electrode of the second pixel is set to a second electric potential different from the first electric potential at a point of time at which a charge accumulation period for the second pixel starts; and an addition circuit adding together signals generated in the first and second pixels.

Abstract: An imaging device includes: a first imaging cell including a first photoelectric converter that generates a first signal by photoelectric conversion, and a first signal processing circuit that is electrically connected to the first photoelectric converter and detects the first signal; and a second imaging cell including a second photoelectric converter that generates a second signal by photoelectric conversion, and a second signal processing circuit that is electrically connected to the second photoelectric converter and detects the second signal. Sensitivity of the first imaging cell is higher than sensitivity of the second imaging cell. The first signal processing circuit has a circuit configuration different from the second signal processing circuit. An operation frequency of the first signal processing circuit is different from an operation frequency of the second signal processing circuit.

Abstract: An imaging device includes first and second pixel cells. The first and second pixel cells each include: a photoelectric converter that generates charge; a first charge transfer channel that has a first end electrically connected to the photoelectric converter, and a second end, the charge transfer channel transferring the charge in a direction from the first end toward the second end; a second charge transfer channel that branches from a position of the charge transfer channel, the second charge transfer channel transferring at least a part of the charge; and a charge accumulator that accumulates charge transferred via the second charge transfer channel. Distances from the first end to the position in the direction of the first and second pixel cells are different from each other.

Abstract: An imaging device includes a photoelectric converter that generates charge; a first charge transfer channel having a first end electrically connected to the photoelectric converter and a second end, and transferring the charge in a direction from the first end to the second end; a second charge transfer channel diverging from the first charge transfer channel at a first position and transferring a first part of the charge; a third charge transfer channel diverging from the first charge transfer channel at a second position different from the first position in the direction and transferring a part of the second part of the charge; and first and second charge accumulators that accumulate at least a part of the first and second part of the charge respectively. The imaging device does not include a gate that switches between cutoff and transfer of charge, in the first charge transfer channel.

Abstract: An optical sensor includes: a semiconductor layer including a first region, a second region, and a third region between the first region and the second region; a gate electrode facing to the semiconductor layer; a gate insulating layer between the third region and the gate electrode, the gate insulating layer including a photoelectric conversion layer: a signal detection circuit including a first signal detection transistor, a first input of the first signal detection transistor being electrically connected to the first region; a first transfer transistor connected between the first region and the first input; and a first capacitor having one end electrically connected to the first input. The signal detection circuit detects an electrical signal corresponding to a change of a dielectric constant of the photoelectric conversion layer, the change being caused by incident light.

Abstract: An imaging device includes: first and second pixel cells each including a photoelectric converter and a transistor electrically connected to the photoelectric converter, the transistor having a control terminal; a first buffer circuit having a first input terminal and a first output terminal, the first buffer circuit receiving a signal for controlling the transistor of the first pixel cell; a second buffer circuit having a second input terminal and a second output terminal, the second buffer circuit receiving a signal for controlling the transistor of the second pixel cell; a first control signal line connecting the first output terminal to the control terminal of the first pixel cell; and a second control signal line connecting the second output terminal to the control terminal of the second pixel cell. The first control signal line and the second control signal line are connected to each other.