The laser radar includes a clock generator, a projection unit configured to project pulse laser light in synchronization with a clock signal, a light reception unit configured to receive reflected light, a counter configured to count a counter value which is the number of clock signals generated from a projection timing until a light reception timing, a delay circuit in which a plurality of stages of delay units are connected and to which the clock signal is successively input, and a time calculation unit configured to calculate a round trip time of the pulse laser light on the basis of the counter value and the number of hops which is the number of stages of the delay units to which a head of the clock signal is transmitted in a period of the clock signal including the light reception timing.

The laser radar includes a clock generator, a projection unit configured to project pulse laser light in synchronization with a clock signal, a light reception unit configured to receive reflected light, a counter configured to count a counter value which is the number of clock signals generated from a projection timing until a light reception timing, a delay circuit in which a plurality of stages of delay units are connected and to which the clock signal is successively input, and a time calculation unit configured to calculate a round trip time of the pulse laser light on the basis of the counter value and the number of hops which is the number of stages of the delay units to which a head of the clock signal is transmitted in a period of the clock signal including the light reception timing.

Systems, methods, and computer-readable media are disclosed for a systems and methods for intra-shot dynamic LIDAR detector gain. One example method my include emitting, by an optical ranging system at a first time, a first light pulse. The example method may also include increasing, after the first time, a sensitivity of a photodetector of the optical ranging system from a first sensitivity at the first time to a second sensitivity at a second time. The example method may also include decreasing the sensitivity of the photodetector of the optical ranging system from the second sensitivity at third time to the first sensitivity at a fourth time, wherein the fourth time is after the photodetector receives return light based on the first light pulse. The example method may also include emitting, by the optical ranging system at the fourth time, a second light pulse.

Systems, methods, and computer-readable media are disclosed for a systems and methods for intra-shot dynamic LIDAR detector gain. One example method my include emitting, by an optical ranging system at a first time, a first light pulse. The example method may also include increasing, after the first time, a sensitivity of a photodetector of the optical ranging system from a first sensitivity at the first time to a second sensitivity at a second time. The example method may also include decreasing the sensitivity of the photodetector of the optical ranging system from the second sensitivity at third time to the first sensitivity at a fourth time, wherein the fourth time is after the photodetector receives return light based on the first light pulse. The example method may also include emitting, by the optical ranging system at the fourth time, a second light pulse.

A sensor includes an avalanche photodiode (APD), a first resistor, a second resistor, and a rectification element. The first resistor is connected between a current output terminal of the APD and a first output terminal. The second resistor and the rectification element are connected in series between the current output terminal and a second output terminal. The rectification element is connected between the second resistor and the second output terminal.

A method of a sensing device, comprising steps of emitting, by a light source of the sensing device, a light pulse in each of n cycles; measuring, by a single photon avalanche diodes array of the sensing device, a time-of-flight value with a resolution of m in each of the n cycles to generate n raw data frames based on a reflected light of the light pulse; performing, by a pre-processing circuit of the sensing device, a pre-processing operation to n raw data frames to generate k pre-processed data frames, wherein m, n and k are natural numbers, and k is smaller than n; and generating, by post-processor of the sensing device, a histogram according to the k pre-processed data frames and analyzing the histogram to output a depth result.

A lidar system may include a programmable configuration memory, configured to receive configuration values for controlling histogramming operations performed by the lidar system. The lidar system may also include an array controller, configured or programmed or set to read the configuration values and send control signals according to the configuration values in the programmable configuration memory. The lidar system may also include a sensor array, where the sensor array includes a plurality of pixels. Each pixel in the plurality of pixels may include a photosensor, summation circuitry, and a memory device. Each of the plurality of pixels may be configured to generate histogram data by collecting photon counts during a plurality of time bins for each of a plurality of laser cycles.

A lidar system may include a programmable configuration memory, configured to receive configuration values for controlling histogramming operations performed by the lidar system. The lidar system may also include an array controller, configured or programmed or set to read the configuration values and send control signals according to the configuration values in the programmable configuration memory. The lidar system may also include a sensor array, where the sensor array includes a plurality of pixels. Each pixel in the plurality of pixels may include a photosensor, summation circuitry, and a memory device. Each of the plurality of pixels may be configured to generate histogram data by collecting photon counts during a plurality of time bins for each of a plurality of laser cycles.

A distance measurement apparatus comprises a light emitter that emits light toward a scene, a light receiver that includes at least one light-receiving element and detects reflected light from the scene produced by the emission of light with the at least one light-receiving element, and a signal processing circuit that generates and outputs, for each frame, output data including measurement data indicating the positions or distances of a plurality of points in the scene on the basis of a signal outputted by the light receiver. The output data includes reference time data indicating a reference time determined for each frame and time difference data determined for each point, the time difference data indicating the difference from the reference time.

An echo signal processing method includes receiving echo signals, in different directions, including a first echo signal and a second echo signal, and the first echo signal and the second echo signal are received, determining a first inflection point from the first echo signal, determining a second inflection point from the second echo signal, determining whether a time difference between a first moment at which the first inflection point is received from the first echo signal and a second moment at which the second inflection point is received from the second echo signal is less than a preset threshold, and combining the first echo signal and the second echo signal when the time difference is less than the preset threshold.