An image sensing device includes an image sensor suitable for correcting depth information based on a control signal, and for generating image data according to the depth information, and a controller suitable for analyzing an error of the depth information, and for generating the control signal, based on first and second cycle signals provided from the image sensor.

An image sensing device includes an image sensor suitable for correcting depth information based on a control signal, and for generating image data according to the depth information, and a controller suitable for analyzing an error of the depth information, and for generating the control signal, based on first and second cycle signals provided from the image sensor.

An array of photodiodes is provided, the array including a plurality of photodiodes arranged in groups, each group including at least a first photodiode, a second photodiode and a third photodiode; and a shutter for controlling integration time of each of the first, second and third photodiodes in the groups, facilitating detection of light by the first photodiode during a first timeslot, detection of light by the second photodiode during a second timeslot, and detection of light by the third photodiode during a third timeslot. The first, second and third timeslots are independently controlled allowing thereby detecting various portions of light radiation.

An image sensing device is provided to include a pixel array including unit pixel blocks that are arranged in a first direction and a second direction crossing the first direction, each unit pixel block configured to generate pixel signals in response to incident light reflected from a target object. The unit pixel block includes normal first pixel configured to receive a portion of the incident light at a first arrival time and generate a first pixel signal in response to the incident light, and a second pixel configured to receive another portion of the incident light at a second arrival time and generate a second pixel signal in response to the incident light. The second arrival time is later than the first arrival time.

A depth sensor and an image detecting system including the same are provided. The depth sensor includes a pixel that generates an image signal based on a sensed light. The pixel includes a first photo transistor that integrates first charges based on a first photo gate signal toggling during an integration period, a second photo transistor that integrates second charges based on a second photo gate signal toggling during the integration period, a first transfer transistor that transfers the first charges to a first floating diffusion node based on a first transfer gate signal, a second transfer transistor that transfers the second charges to a second floating diffusion node based on the first transfer gate signal, and a switch that is connected with the first photo transistor, the second photo transistor, the first transfer transistor, and the second transfer transistor.

[Object] Provided are a light receiving device and a light receiving circuit that are capable of performing highly accurate ranging with an increased field of view (FOV).

[Solving Means] A light receiving device according to the present disclosure includes a light detector array including a plurality of pixels each configured to output a pulse in response to a reaction of a light detector with a photon, a counter circuit configured to count the pulse outputted from at least one of the pixels of the light detector array, and a control circuit configured to select, from the light detector array, one of the pixels to be enabled and one of the pixels to be disabled, on the basis of the number of counts of the pulse from the counter circuit.

An image sensor for distance measurement and an image sensor module including the image sensor are provided. The image sensor includes: a pixel array including a plurality of pixels including a plurality of first pixels arranged on a first line and a plurality of second pixels arranged on a second line, wherein the plurality of first pixels and the plurality of second pixels are arranged to be staggered from each other, and each of the plurality of first pixels and the plurality of second pixels includes a plurality of modulation gates for receiving a plurality of modulated signals during a photocharge collection period; a row decoder that provides control signals and the plurality of modulated signals to the pixel array; and an analog-to-digital conversion circuit that receives a plurality of sensing signals from the pixel array and converts the plurality of sensing signals into a plurality of digital signals.

A light receiving element array includes one or more unit element blocks. Each of the unit element blocks includes different light receiving elements with different element structures.

A pixel circuit for background light suppression includes: a 2-tap pixel circuit including first and second pixel capacitors, first and second storage switches, and first and second transfer switches; an in-pixel sigma delta circuit including a plurality of switching switches and a storage capacitor for storing charge transferred from the first and second pixel capacitors; an adaptive sigma delta controller configured to determine switching states of the plurality of switching switches according to a first state of the first pixel capacitor, or a second state of the second pixel capacitor, or both; and a chopping controller configured to instruct the storage switches and the transfer switches of the 2-tap pixel circuit to be selectively switched according to an output of the adaptive sigma delta controller.

Provided is a measurement device that includes a pixel including a light receiver, a plurality of storage sections, and an electric charge supplying section. The light receiver generates received-light electric charge by performing photoelectric conversion on the basis of light. The plurality of storage sections stores the received-light electric charge and the plurality of storage sections includes a first storage section and a second storage section. The electric charge supplying section selectively supplies the received-light electric charge generated by the light receiver to the plurality of storage sections. The measurement device includes a processor that generates a first detection value on the basis of an electric charge amount of the received-light electric charge stored in the first storage section, and generates a second detection value on the basis of an electric charge amount of the received-light electric charge stored in the second storage section. The processor generates a first pixel value on the basis of a difference between the first detection value and the second detection value.