To suppress voltage variations due to transistor switching noise in a solid-state image sensor including a transistor that initializes a differentiating circuit. A capacitance supplies a charge corresponding to an amount of variation in a predetermined pixel voltage to a predetermined input terminal. A voltage output unit outputs, as an output voltage, a voltage corresponding to an input voltage at the input terminal from a predetermined output terminal. A reset transistor supplies one of a positive charge or a negative charge during a predetermined period to control the output voltage to an initial value in a case where initialization is instructed. A charge supply unit supplies the other of the positive charge or the negative charge when the predetermined period elapses.

A solid-state imaging device includes: a plurality of pixel cells arranged in a matrix. In the solid-state imaging device, each of the plurality of pixel cells includes: a photoelectric converter that generates charge by photoelectric conversion, and holds a potential according to an amount of the charge generated; an initializer that initializes the potential of the photoelectric converter; a comparison section that compares the potential of the photoelectric converter and a predetermined reference signal, and causes the initializer to perform initialization when the potential of the photoelectric converter and the predetermined reference signal match; and a counter that counts a total number of times of initialization performed by the initializer, and outputs a signal corresponding to the total number of times as a first signal indicating an intensity of incident light.

A solid-state imaging device includes: a plurality of pixel cells arranged in a matrix. In the solid-state imaging device, each of the plurality of pixel cells includes: a photoelectric converter that generates charge by photoelectric conversion, and holds a potential according to an amount of the charge generated; an initializer that initializes the potential of the photoelectric converter; a comparison section that compares the potential of the photoelectric converter and a predetermined reference signal, and causes the initializer to perform initialization when the potential of the photoelectric converter and the predetermined reference signal match; and a counter that counts a total number of times of initialization performed by the initializer, and outputs a signal corresponding to the total number of times as a first signal indicating an intensity of incident light.

An image sensor includes: a pixel that generates a pixel signal based upon incident light having entered therein; and a generation unit that includes a first input unit to which the pixel signal is input, a second input unit to which a first reference signal with a shifting voltage is input, and an output unit that outputs an output signal generated based upon the pixel signal and the first reference signal, wherein: the generation unit further includes a first capacitance disposed between the first input unit and the output unit, a second capacitance disposed between the second input unit and the output unit, and a third capacitance connected to either one of the first capacitance and the second capacitance.

An image sensor includes: a pixel that generates a pixel signal based upon incident light having entered therein; and a generation unit that includes a first input unit to which the pixel signal is input, a second input unit to which a first reference signal with a shifting voltage is input, and an output unit that outputs an output signal generated based upon the pixel signal and the first reference signal, wherein: the generation unit further includes a first capacitance disposed between the first input unit and the output unit, a second capacitance disposed between the second input unit and the output unit, and a third capacitance connected to either one of the first capacitance and the second capacitance.

According to the present disclosure, an imaging element may include: a substrate or a well; a pinned photodiode disposed on the substrate; a floating diffusion region disposed on the substrate or the well; a first transfer gate transistor disposed between the pinned photodiode and the floating diffusion region a photodiode signal charge generated by the pinned photodiode to the floating diffusion region; one or more gate-controlled storages disposed on the substrate and storing a signal charge generated by the pinned photodiode as a storage signal charge; a storage-controlling gate electrode disposed adjacent to the gate-controlled storage; an overflow path disposed between the pinned photodiode and the gate-controlled storage and transferring the storage signal charge from the pinned photodiode to the gate-controlled storage; and a detecting node connected to the floating diffusion region, wherein the photodiode signal charge and the storage signal charge can be read at the detecting node.

A photodetection device according to the present disclosure includes: a pixel; a reference signal generation unit; a comparison circuit; and a first switch. The pixel is configured to generate a pixel signal. The reference signal generation unit is configured to generate a reference signal. The comparison circuit includes a first-stage amplifier circuit and a second-stage amplifier circuit that is coupled to the first-stage amplifier circuit through a connection node. The first-stage amplifier circuit is configured to output a first output signal corresponding to a comparison operation based on the pixel signal and the reference signal. The second-stage amplifier circuit is configured to output a second output signal corresponding to the first output signal outputted from the first-stage amplifier circuit through the connection node. The first switch has one end and another end. The one end is coupled to the connection node. The first switch allows impedance and a voltage at the connection node to change.

A photodetection device according to the present disclosure includes: a pixel; a reference signal generation unit; a comparison circuit; and a first switch. The pixel is configured to generate a pixel signal. The reference signal generation unit is configured to generate a reference signal. The comparison circuit includes a first-stage amplifier circuit and a second-stage amplifier circuit that is coupled to the first-stage amplifier circuit through a connection node. The first-stage amplifier circuit is configured to output a first output signal corresponding to a comparison operation based on the pixel signal and the reference signal. The second-stage amplifier circuit is configured to output a second output signal corresponding to the first output signal outputted from the first-stage amplifier circuit through the connection node. The first switch has one end and another end. The one end is coupled to the connection node. The first switch allows impedance and a voltage at the connection node to change.

An imaging device including: a first imaging cell including a first photoelectric converter that generates a first signal; and a second imaging cell including: a second photoelectric converter that generates a second signal; and a capacitor having a first and second terminal, the first terminal electrically coupled to second photoelectric converter. An area of the first photoelectric converter is greater than an area of the second photoelectric converter in a plan view, the first imaging cell has a first number of saturation charges, and the second imaging cell has a second number of saturation charges, the first number of saturation charges is greater than the second number of saturation charges, and the capacitor has capacitance that causes the second number of saturation charges of the second imaging cell to become greater than the first number of saturation charges of the first imaging cell.

In an imaging device, a first digital signal corresponding to a first analog signal read out from a pixel, and a second digital signal corresponding to the amount of charge accumulated during a first exposure period following a period for reading the first analog signal. A difference is acquired between a first difference and a second difference wherein the first difference is a difference between a third digital signal and the second digital signal, the third digital signal is a digital signal corresponding to the amount of charge cumulatively accumulated during the first exposure period and a following second exposure period, and the second difference is a difference between the second digital signal and the first digital signal. At least one of the first exposure period or the second exposure period includes a period during which the first light source is in the on-state.