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.

Disclosed is a method of synchronising an image sensor with a PWM driver operable to drive an arrangement associated with the image sensor, wherein at least one synchronisation signal produced by the image sensor is used to reset the PWM driver and the at least one synchronisation signal is delayed before being used to reset the PWM driver such that the switching on or off of the at least one synchronisation signal occurs at a defined time in relation to a sensitive period of the image sensor's operation.

A semiconductor device in which a plurality of substrates including a first substrate and a second substrate are stacked, wherein the first substrate includes a pixel unit in which a plurality of pixels are arranged, the second substrate includes a control circuit configured to control the semiconductor device, and the first substrate further includes a detection circuit configured to detect a connection state of a connection portion between the first substrate and the second substrate.

An image sensor includes: a first substrate including a plurality of pixels; and a second substrate including a clock signal generator configured to generate a first clock signal, at least one buffer configured to receive the first clock signal from the clock signal generator and generate a buffered clock signal, a ramp signal generator configured to receive the buffered clock signal and generate a ramp signal based on the buffered clock signal, wherein a time length of an on-duty period of the first clock signal is different from a time length of an on-duty period of the buffered clock signal.

Certain embodiments provide an image processing apparatus including an image processing circuit configured to perform image processing on continuously captured image data frame by frame, a failure diagnosis processing circuit configured to diagnose a failure of the image processing circuit, and a failure diagnosis control circuit configured to control whether to perform failure diagnosis at an arbitrary frame.

A sensor chip includes: a pixel array unit that has a rectangular-shaped area in which a plurality of sensor elements are arranged in an array pattern; and a global control circuit, in which driving elements simultaneously driving the sensor elements are arranged in one direction, and each of the driving elements is connected to a control line disposed for each one column of the sensor elements, that is arranged to have a longitudinal direction to be along a long side of the pixel array unit. For example, the present technology can be applied to ToF sensor.

An imaging-displaying apparatus includes an imaging unit outputting an imaging signal; an image processing unit generating an image signal based on the imaging signal, and writing the signal in a VRAM; an image signal output unit outputting the image signal from the VRAM, and outputting the signal to the display unit; and a timing control unit generating an imaging vertical synchronizing signal for driving the imaging unit, generating a display vertical synchronizing signal obtained by delaying the imaging vertical synchronizing signal at least by a predetermined time which is necessary for a generation of an image signal, and supplying the signal to the display unit, and controlling an image signal output unit so that the image signal is read from the VRAM by being delayed by a phase difference between the imaging vertical synchronizing signal and the display vertical synchronizing signal, after outputting the imaging signal from the imaging unit.

An image capturing device includes: a plurality of first pixels that have a plurality of color components, and that generate first signals by photoelectrically converting incident light; a plurality of second pixels that generate second signals by photoelectrically converting light that has passed through the first pixels; and a drive unit that reads out the first signals from the first pixels, and that reads out the second signals from the second pixels at timings that are different from timings of reading out the first signals.

A solid-state image sensor and an image capture apparatus are provided that can realize image acquisition and distance measurement while restraining the circuit scale from increasing. The solid-state image sensor includes a plurality of pixels each including a sensor unit that generates a pulse with a frequency that is based on a reception frequency of a photon, and a counter that can operate in a first mode of counting the number of pulses of a signal generated by the sensor unit, and a second mode of counting the number of pulses of a predetermined signal that is based on an elapsed time from a timing at which light is emitted from a light emitting unit.

A solid-state image sensor is provided with a pixel array including a measuring pixel and an imaging pixel, a compression circuit that applies compression processing to a signal obtained by the measuring pixel, and an output circuit that outputs the signal obtained by the measuring pixel and a signal obtained by the imaging pixel. The solid-state image sensor is configured to operate in a first mode in which a signal that is obtained by the measuring pixel and then applied the compression processing is output, and in a second mode in which a signal that is obtained by the imaging pixel and then not applied the compression processing is output.