An optical device is provided. The optical device includes a time-of-flight (TOF) sensor array, a photon conversion thin film, and a light source. The photon conversion thin film is disposed above the time-of-flight sensor array. The light source emits light with a first wavelength towards the photon conversion thin film to be converted into light with a second wavelength received by the time-of-flight sensor array. The second wavelength is longer than the first wavelength.

A phased array lidar includes: a laser generator (100) configured to generate original laser; an optical transmitting medium (400); an optical splitting apparatus (200) coupled to the laser generator (100) through the optical transmitting medium (400); the optical splitting apparatus (200) including a device configured to receive the original laser; and Z radiation units (300), each being respectively coupled to the optical splitting apparatus (200), where Z is a natural number greater than 1. The optical splitting apparatus (200) is configured to split the original laser into Z first optical signals, and send each of the Z first optical signals respectively to the radiation units (300), so that electromagnetic waves radiated by all of the radiation units (300) are combined into a beam of radar waves. The laser generator (100), the device, and the optical transmitting medium (400) are made of a material capable of transmitting laser having power greater than a set power value.

A phased array lidar includes: a laser generator (100) configured to generate original laser; an optical transmitting medium (400); an optical splitting apparatus (200) coupled to the laser generator (100) through the optical transmitting medium (400); the optical splitting apparatus (200) including a device configured to receive the original laser; and Z radiation units (300), each being respectively coupled to the optical splitting apparatus (200), where Z is a natural number greater than 1. The optical splitting apparatus (200) is configured to split the original laser into Z first optical signals, and send each of the Z first optical signals respectively to the radiation units (300), so that electromagnetic waves radiated by all of the radiation units (300) are combined into a beam of radar waves. The laser generator (100), the device, and the optical transmitting medium (400) are made of a material capable of transmitting laser having power greater than a set power value.

A time-of-flight (ToF) image sensor system includes a pixel array, where each pixel of the pixel array is configured to receive a reflected modulated light signal and to demodulate the reflected modulated light signal to generate an electrical signal; a plurality of analog-to-digital converters (ADCs), where each ADC is coupled to at least one assigned pixel of the pixel array and is configured to convert a corresponding electrical signal generated by the at least one assigned pixel into an actual pixel value; and a binning circuit coupled to the plurality of ADCs and configured to generate at least one interpolated pixel, where the binning circuit is configured to generate each of the at least one interpolated pixel based on actual pixel values corresponding to a different pair of adjacent pixels of the pixel array, each of the at least one interpolated pixel having a virtual pixel value.

Systems and methods are disclosed for phase unwrapping for time-of-flight imaging. A method is provided for phase unwrapping that includes measuring a plurality of wrapped depths at a respective plurality of frequencies, wherein each of the plurality of wrapped depths corresponds to a respective phase, generating a plurality of unwrapped phases based on a probability distribution function, by unwrapping each of the plurality of wrapped depths, and identifying a Voronoi cell.

Systems and methods are disclosed for phase unwrapping for time-of-flight imaging. A method is provided for phase unwrapping that includes measuring a plurality of wrapped depths at a respective plurality of frequencies, wherein each of the plurality of wrapped depths corresponds to a respective phase, generating a plurality of unwrapped phases based on a probability distribution function, by unwrapping each of the plurality of wrapped depths, and identifying a Voronoi cell.

A time-of-flight (TOF) sensor device includes: an illumination component that emitting a light beam toward a viewing space; a receiving lens element receiving reflected light and directing the reflected light to a photo-receiver array; and a processor. The processor is configured to generate distance information for a pixel corresponding to an object in the viewing space based on time-of-flight analysis of the reflected light; record a variation of an intensity of the reflected light from the object over time to yield intensity variation information; record a variation of the distance information for the pixel corresponding to the object over time to yield distance variation information; and apply a correction factor to the distance information in response to a determination that the intensity variation information and the distance variation information do not conform to an inverse-square relationship.

A time-of-flight (TOF) sensor device includes: an illumination component that emitting a light beam toward a viewing space; a receiving lens element receiving reflected light and directing the reflected light to a photo-receiver array; and a processor. The processor is configured to generate distance information for a pixel corresponding to an object in the viewing space based on time-of-flight analysis of the reflected light; record a variation of an intensity of the reflected light from the object over time to yield intensity variation information; record a variation of the distance information for the pixel corresponding to the object over time to yield distance variation information; and apply a correction factor to the distance information in response to a determination that the intensity variation information and the distance variation information do not conform to an inverse-square relationship.

An image sensor, employed in a time-of-flight (TOF) sensing system, includes a pixel array including a plurality of pixels arranged in plural rows and plural columns, each pixel generating an amount of charge in response to an incident light, and first driving circuitry configured to supply a driving control signal to each pixel via the plural columns. The first driving circuitry is configured to supply the driving control signal via one of odd and even columns.

A ranging processing device includes: a four-phase ranging operation unit that performs an operation to calculate depth indicating a distance to an object by using all eight detection signals two of which are detected for each of irradiated light of first to fourth phases; a two-phase ranging operation unit that performs the operation to calculate the depth indicating the distance to the object by alternately using four detection signals based on the irradiated light of the first phase and the irradiated light of the second phase and four detection signals based on the irradiated light of the third phase and the irradiated light of the fourth phase among the eight detection signals; and a condition determination unit that makes condition determination based on the detection signals and switch between the four-phase ranging operation unit and the two-phase ranging operation unit to be used.