To provide a distance and velocity measurement apparatus that can be adopted preferably in a LiDAR or a sensor for a robot, wherein the apparatus can prevent deterioration of SN ratio even in a case where an object in an external environment vibrates. A LiDAR 20 according to the present embodiment includes a first laser apparatus 1a, a second laser apparatus 1b, a polarization-maintaining type optical fiber 2, a WDM filter 6, an optical fiber coupler 3a, an optical amplifier 11, an input/output unit 4, an optical scanner 5, a second optical fiber coupler 3b, a balanced photodetector 7, and a square-law detector 9. Further, a delay line 10 composed of a polarization-maintaining optical fiber is provided on the local port 2b. The first laser apparatus 1a includes a device for generating a first laser light having a first wavelength and a first chirp rate in an interior thereof, and the second laser apparatus 1b includes a device for generating a second laser light having a second wavelength that differs from the first wavelength and a second chirp rate that differs from the first chirp rate.

Daylight visible laser rangefinders and multi-spectral laser rangefinders that emit one or more continuous wave lasers for the purposes of generating a distance measurement are disclosed, along with methods, systems, and devices including laser rangefinders in utility locating and mapping systems and underwater systems.

A light detection and ranging (LIDAR) system performs a method including generating a frequency domain waveform based on a baseband electrical signal in a time domain, wherein the frequency domain waveform includes a spectrum of frequencies and determining a likelihood metric for the spectrum of frequencies of the frequency domain waveform. The method further includes in response to one or more parameters associated with the frequency domain waveform satisfying a condition, modifying the likelihood metric for the spectrum of frequencies based on the one or more parameters associated with the frequency domain waveform to generate a modified likelihood metric for the spectrum of frequencies, selecting a peak frequency from the frequency domain waveform corresponding to a frequency with the highest value for the modified likelihood metric, and determining one or more properties of a target based at least in part on the selected peak frequency.

At least one beam of an optical wave is transmitted along a transmission angle toward a target location from a send aperture of a transmitter. The optical wave comprises at least a first portion, and a second portion having a different characteristic from a characteristic of the first portion. Two or more receivers include at least one receiver comprising: a receive aperture arranged in proximity to at least one of the send aperture or a receive aperture of a different receiver, an optical phased array within the receive aperture, the optical phased array being configured to receive at least a portion of a collected optical wave arriving at the receive aperture along a respective collection angle, and a filter configured to filter the received portion of the collected optical wave according to the characteristic of the first portion of the optical wave.

An electronic device (100) and a method for controlling the electronic device (100) are provided. The electronic device (100) includes a time-of-flight (TOF) module 20, a color camera 30, a monochrome camera (40), and a processor (10). The TOF module (20) is configured to capture a depth image of a subject. The color camera (30) is configured to capture a color image of the subject. The monochrome camera (40) is configured to capture a monochrome image of the subject. The processor (10) is configured to obtain a current brightness of ambient light in real time, and to construct a three-dimensional image of the subject according to the depth image, the color image, and the monochrome image when the current brightness is less than a first threshold.

An electronic device (100) and a method for controlling the electronic device (100) are provided. The electronic device (100) includes a time-of-flight (TOF) module 20, a color camera 30, a monochrome camera (40), and a processor (10). The TOF module (20) is configured to capture a depth image of a subject. The color camera (30) is configured to capture a color image of the subject. The monochrome camera (40) is configured to capture a monochrome image of the subject. The processor (10) is configured to obtain a current brightness of ambient light in real time, and to construct a three-dimensional image of the subject according to the depth image, the color image, and the monochrome image when the current brightness is less than a first threshold.

A 3D sensor for monitoring a monitored zone is provided, wherein the 3D sensor has at least one light receiver for generating a received signal from received light from the monitored zone and has a control and evaluation unit that is configured to detect objects in the monitored zone by evaluating the received signal and to determine the shortest distance of the detected objects from at least one reference volume, and to read at least one distance calculated in advance from the reference value from a memory for the determination of the respective shortest distance of a detected object.

A method for scanning and measuring using a 3D measurement device is provided. The method includes providing the 3D measurement device having a light emitter, a light receiver and a command and evaluation device. The 3D measurement device is further includes a first near-field communication (NFC) device having a first antenna. A second NFC device having a second antenna is positioned adjacent the 3D measurement device. An NFC link is established between the first NFC device and the 3D measurement device. An identifier is transmitted from the second NFC device to the 3D measurement device. It is determined that the second NFC device is authorized to communicate with the 3D measurement device. Commands are transferred to the 3D measurement device from the second NFC device based at least in part on the determination that the second NFC device is authorized to communicate with the 3D measurement device.

A method for scanning and measuring using a 3D measurement device is provided. The method includes providing the 3D measurement device having a light emitter, a light receiver and a command and evaluation device. The 3D measurement device is further includes a first near-field communication (NFC) device having a first antenna. A second NFC device having a second antenna is positioned adjacent the 3D measurement device. An NFC link is established between the first NFC device and the 3D measurement device. An identifier is transmitted from the second NFC device to the 3D measurement device. It is determined that the second NFC device is authorized to communicate with the 3D measurement device. Commands are transferred to the 3D measurement device from the second NFC device based at least in part on the determination that the second NFC device is authorized to communicate with the 3D measurement device.

Provided is a light detection and ranging (LiDAR) device including an illuminance sensor configured to detect illuminance of light received by the LiDAR device, a photodiode array including a plurality of photodiodes that are connected in parallel, the plurality of photodiodes being configured to generate a current based on the light received, and a processor configured to determine a number of photodiodes included in the photodiode array to be activated based on the illuminance and activate the determined number of photodiodes.