Abstract: A LIDAR includes an emission module, a beam adjustment module and a receiving module, where the beam adjustment module includes a first scanning apparatus and a second scanning apparatus. The emission module is configured to emit a laser beam. The first scanning apparatus is rotated in a first set direction to drive the laser beam to scan along a first direction, and the second scanning apparatus is rotated in a second set direction to drive the laser beam to scan along a second direction. A receiving beam is formed after the laser beam is reflected in the detection region, and the receiving beam is reflected by the second mirror of the second scanning apparatus and then received by the receiving module. The size of the first scanning apparatus can be reduced.

Abstract: Embodiments of this application disclose a point cloud densification method and apparatus, a storage medium, and a LiDAR. The method is applied to the LiDAR, the LiDAR includes an emitter group and a scanning apparatus, and the method includes: obtaining a point cloud densification multiple of a detection field of view at each level; obtaining an interval between scanning lines corresponding to two adjacent emissions based on the point cloud densification multiple of the detection field of view at each level; and performing scanning based on the interval between the scanning lines corresponding to the two adjacent emissions.

Abstract: The present disclosure provides a scanning apparatus placement method, an apparatus and a storage medium. The method includes: establishing a calculation model of a receiving cross section of a second scanning surface; based on the calculation model of a receiving cross section, within a preset rotation range of a first scanning apparatus and an allowable range of a first distance, obtaining a distribution set of sizes of cross sections corresponding to a size of the receiving cross section, an angle of the first scanning apparatus, and a first distance; and selecting a corresponding first distance from the distribution set of sizes of cross sections, when the sizes of the receiving cross sections are symmetrically distributed relative to an angle of the first scanning apparatus.

Abstract: This application discloses a LiDAR, where the LiDAR includes: an emission apparatus, configured to emit a detection laser beam; a scanning apparatus, configured to receive the detection laser beam and emit the detection laser beam to a detection field of view, and to receive an echo laser beam and deflect the echo laser beam to the receiving apparatus; and a receiving apparatus, configured to receive the echo laser beam.

Abstract: This application discloses a point cloud densification method and apparatus, a storage medium, and a LiDAR. The method is applied to the LiDAR, the LiDAR includes an emitter group and a scanning apparatus, and the method includes: obtaining a point cloud densification multiple of a detection field of view at each level; obtaining an interval between scanning lines corresponding to two adjacent emissions based on the point cloud densification multiple of the detection field of view at each level; and performing scanning based on the interval between the scanning lines corresponding to the two adjacent emissions.

Abstract: This application provides a detection method and a LiDAR detection apparatus. The detection method includes: outputting detection laser beams with a preset time delay between two adjacent emissions; receiving the detection laser beam and emitting the detection laser beam to a preset region, scanning the preset region in a preset scanning mode, and further receiving an echo laser beam reflected from the preset region, and outputting the echo laser beam; receiving the echo laser beam and converting the echo laser beam into an electrical signal; and collecting the electrical signal, and processing the electrical signal to obtain detection information of the preset region.

Abstract: This application discloses a LiDAR, where the LiDAR includes: an emission apparatus, configured to emit a detection laser beam; a scanning apparatus, configured to receive the detection laser beam and emit the detection laser beam to a detection field of view, and to receive an echo laser beam and deflect the echo laser beam to the receiving apparatus; and a receiving apparatus, configured to receive the echo laser beam.

Abstract: This application provides a LiDAR including a laser beam emission module and a beam adjustment module. The laser beam emission module includes at least two emitters arranged at intervals, where the emitter is configured to emit the laser beam. The beam adjustment module is configured to adjust the laser beam. A diameter of a light spot formed by the laser beam within a first preset distance is greater than a first preset value, and an angle interval between emission channels of two adjacent emitters that simultaneously emit laser beams is greater than a preset angle.

Abstract: This application discloses a point cloud densification method and apparatus, a storage medium, and a LiDAR. The method is applied to the LiDAR, the LiDAR includes an emitter group and a scanning apparatus, and the method includes: obtaining a point cloud densification multiple of a detection field of view at each level; obtaining an interval between scanning lines corresponding to two adjacent emissions based on the point cloud densification multiple of the detection field of view at each level; and performing scanning based on the interval between the scanning lines corresponding to the two adjacent emissions.

Abstract: A method for constructing a real-geographic-space scene in real time based on a panoramic-video technique is provided. By using a measuring robot and the attitude sensors, accurately determining the geographic coordinates and the attitudes of the cameras, where the cameras may be installed in a fixed or stringing manner, where in the fixing type a plurality of neighboring videos at the same moment undergo orthographic correction and splicing, and in the stringing type the cameras are installed to a guiding device and may locally, independently and quickly move and shoot, and the videos of the neighboring cameras are spliced in real time; and fusing the videos, the geographic coordinates and the environment sounds that satisfy the delay time, to form a scene video streaming.

Abstract: mechanical arm type measuring robot device and an application method, and relates to the technical field of intelligent coal mine mining. The mechanical arm type measuring robot device comprises an automatic leveling total station, a protection mechanism, a pitch adjusting mechanism, a yaw adjusting mechanism, a vertical rotating mechanism, a controller, a mounting base and a mobile terminal. Based on a preset pitch angle and a preset yaw angle, the measuring robot starts from an initial position, and performs extension and retraction actions in a plurality of degrees of freedom in the pitch adjusting mechanism and the yaw adjusting mechanism to move the total station to a preset working position.

Abstract: A method for constructing a real-geographic-space scene in real time based on a panoramic-video technique is provided. By using a measuring robot and the attitude sensors, accurately determining the geographic coordinates and the attitudes of the cameras, where the cameras may be installed in a fixed or stringing manner, where in the fixing type a plurality of neighboring videos at the same moment undergo orthographic correction and splicing, and in the stringing type the cameras are installed to a guiding device and may locally, independently and quickly move and shoot, and the videos of the neighboring cameras are spliced in real time; and fusing the videos, the geographic coordinates and the environment sounds that satisfy the delay time, to form a scene video streaming.

Abstract: An opto-mechanical system is provided. The opto-mechanical system includes a light emission assembly, a light receiving assembly, and a light scanning assembly. The light emission assembly is configured to emit an emission light signal to a target object. The light receiving assembly is configured to receive an echo light signal reflected by the target object. The light scanning assembly includes a first light scanning element and a second light scanning element. The emission light signal emitted by the light emission assembly is sequentially transmitted by the first light scanning element and the second light scanning element to the target object, and the echo light signal reflected by the target object is sequentially transmitted by the second light scanning element and the first light scanning element to the light receiving assembly.

Abstract: A topological bulk laser includes a topological photonic crystal (32) having an energy band inversion between dipole mode and quadrupole mode near the center of Brillouin zone and a trivial photonic crystal (31) not having band inversion for splicing to each other. The reflection and confinement of an optical field occurs at the interface; and the interface encloses to form a closed contour, thereby forming a laser cavity with an effective cavity feedback for lasing at the interior of the interface. This band-inversion-induced reflection mechanism induces single-mode lasing with directional vertical emission. At room temperature, the topological bulk laser can achieve low threshold, narrow linewidth, and a high side-mode suppression ratio, reduce the fabrication difficulty and costs, and improve heat dissipation and electrical injection efficiency, hence improving lifetime and stability of devices.

Abstract: A measuring-robot device for fully mechanized coal mining faces and an automatic measuring system are provided. The measuring robot includes a suspension cage, a total station, a prism and an industrial computer. Firstly, the suspension cage with automatic leveling function is fixed on the top beam of a hydraulic support, then the total station and the industrial computer are fixed in the suspension cage, and finally the prism with a plug connector is installed under the base of the total station, forming a measuring-robot device. According to the fluctuations of the fully mechanized coal mining face, several measuring robots will be deployed along the fully mechanized coal mining face, and the adjacent measuring robots are line of sight to each other, forming the automatic measuring system covering the fully mechanized coal mining.

Abstract: A measuring-robot device for fully mechanized coal mining faces and an automatic measuring system are provided. The measuring robot includes a suspension cage, a total station, a prism and an industrial computer. Firstly, the suspension cage with automatic leveling function is fixed on the top beam of a hydraulic support, then the total station and the industrial computer are fixed in the suspension cage, and finally the prism with a plug connector is installed under the base of the total station, forming a measuring-robot device. According to the fluctuations of the fully mechanized coal mining face, several measuring robots will be deployed along the fully mechanized coal mining face, and the adjacent measuring robots are line of sight to each other, forming the automatic measuring system covering the fully mechanized coal mining.