CN210119572U - Narrow linewidth filtering laser radar - Google Patents

Narrow linewidth filtering laser radar Download PDF

Info

Publication number
CN210119572U
CN210119572U CN201920528317.0U CN201920528317U CN210119572U CN 210119572 U CN210119572 U CN 210119572U CN 201920528317 U CN201920528317 U CN 201920528317U CN 210119572 U CN210119572 U CN 210119572U
Authority
CN
China
Prior art keywords
filtering
narrow
laser
filter element
filter
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
CN201920528317.0U
Other languages
Chinese (zh)
Inventor
梁伟
杨昆云
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Suzhou Radium Intelligence Sensing Technology Co Ltd
Original Assignee
Suzhou Radium Intelligence Sensing Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Suzhou Radium Intelligence Sensing Technology Co Ltd filed Critical Suzhou Radium Intelligence Sensing Technology Co Ltd
Priority to CN201920528317.0U priority Critical patent/CN210119572U/en
Application granted granted Critical
Publication of CN210119572U publication Critical patent/CN210119572U/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Optical Radar Systems And Details Thereof (AREA)

Abstract

The utility model relates to a narrow linewidth filtering laser radar presses narrow laser linewidth through the mode that adopts the exocoel feedback, and with the frequency or the wavelength locking of emergent laser in the selected within range of exocoel feedback component, reduce the influence of ambient temperature change to the laser signal wavelength, on this basis, further use narrow linewidth filtering component to carry out filtering process to echo signal to filtering background light noise by a wide margin improves laser radar's detectivity and detection distance, and simultaneously, the cooperation has the filtering component of difference filtering parameter or has the arc structure, has improved the uniformity of filtering component filtering effect under different echo incident angles, makes the utility model discloses a narrow linewidth filtering laser radar has sensitivity and detection reliability basically the same in whole field angle.

Description

Narrow linewidth filtering laser radar
Technical Field
The utility model relates to a laser radar, concretely relates to compression laser linewidth to utilize narrow band filter to restrain the laser radar that the background light disturbed in order to improve detection precision, detection distance and detection reliability.
Background
In order to obtain high vertical resolution, two types of solutions exist for the existing multiline pulse time of flight tof (time of flight) lidar. The first type is represented by velodyne (US8767190), which uses multiple laser arrays and photo-detector arrays to achieve high vertical resolution. However, in this kind of scheme, the assembly and debugging of the laser array and the detector array are extremely complicated, and along with the improvement of the resolution requirement, the assembly and debugging difficulty will rise exponentially, and in addition, the reliability of this kind of laser radar is also lower. In another type of solution, a single laser and PD detection unit is used to perform one or two dimensional scanning within the field of view angle (FOV) by means of a coaxial scanning mechanism such as a MEMS or galvo galvanometer, which acts as both a reflection unit for the outgoing laser and echo signals. The scheme can greatly simplify the laser radar structure and reduce the assembly and debugging cost. However, there is a contradiction in this type of scheme that is difficult to reconcile. That is, in order to obtain a high resolution, the scanning mechanism is required to have a small device size, so that stable and rapid rotation can be performed, and the single scanning time is shortened; to obtain a clear and reliable echo signal, or to obtain a high detection sensitivity or a sufficiently long detection distance, the galvanometer used to reflect the echo signal is required to have a large size to reflect a sufficient number of echo photons to the detector.
In the prior art, there are attempts to solve the contradiction of the second solution, such as using a high-sensitivity detector, such as avalanche diode APD or single photon avalanche diode SPAD, SiPM, etc., to obtain higher detection sensitivity. However, these devices have extremely high detection sensitivity close to single photons, and are easily interfered by background light, so that the detection sensitivity and detection distance are greatly limited.
Because the main application scene of the vehicle-mounted laser radar is outdoors, the background light of the vehicle-mounted laser radar is mainly sunlight. While the laser wavelength is narrower compared to sunlight. Based on this characteristic, a popular method for suppressing background light noise in the prior art is to use a filter.
Generally, as shown in fig. 1, the spectral width of a commonly used pulse semiconductor laser is about 10nm, and the center of the spectrum shifts by about 0.3nm/K with the change of the ambient temperature. For the vehicle-mounted laser radar, the environmental temperature of the actual application scene of the laser radar may generate a variation amplitude of about 100K due to seasonal variation, usage scene change and other factors. Therefore, prior art filters typically have a line width of at least 40nm to account for spectral center shifts caused by changes in ambient temperature. Obviously, the filter plate line width margin reserved by the measure still allows a large amount of background light to transmit, and the filtering effect which can be actually generated is limited.
Disclosure of Invention
In order to solve the technical problem, the utility model provides a narrow linewidth filtering laser radar, it can increase substantially filtering background light noise, improves laser radar's detectivity and detection distance.
Specifically, the narrow-linewidth filtering lidar comprises conventional lidar components such as a laser, a collimating lens, a scanning mechanism, a converging lens, a detection unit, a signal processing circuit and the like, and further comprises a narrow-linewidth filtering element. The filter element carries out filtering processing on the echo laser signal, selectively allows light with wavelength within the line width range to penetrate through, and filters noise outside the line width range. The detection unit is preferably a high sensitivity detector.
An aspect of the utility model provides a laser frequency stabilization subassembly for with the laser frequency locking in a less variation range. The frequency stabilizing component can be a passive frequency stabilizing component such as a temperature adjusting and frequency stabilizing component, such as a semiconductor temperature control element, and is used for controlling the laser to work in a stable temperature range so as to counteract the influence caused by the change of the ambient temperature. Or an active frequency stabilization component, such as an external cavity feedback element like a diffraction grating or a VBG bulk grating, disposed in the external cavity of the laser and configured to feed back the laser light to the cavity of the laser to narrow the linewidth of the pulsed laser light and lock the frequency or wavelength of the laser light within a predetermined range of the external cavity feedback element to suppress temperature drift of the laser wavelength.
Another aspect of the present invention provides a narrow linewidth filter element, which may be a filter disposed in front of a detector or a coated film on the surface of a detector element. The narrow linewidth filter element is matched with the frequency stabilized narrow linewidth laser by the frequency stabilizing component to allow the narrow linewidth laser to pass through.
The utility model discloses a narrow linewidth filtering scheme can be used to coaxial or non-coaxial laser radar. When used in a coaxial lidar, the lidar further includes a mirror or a PBS and 1/4 slide combination element; the narrow-band filter element is arranged between the converging lens (or receiving lens) and the mirror, which filter element should have the same filter parameters throughout.
For use with non-coaxial lidar, it is preferable to provide an arrayed detector unit to enable the lidar to achieve larger field angles and higher angular resolution. The filter element is arranged between the converging lens and the PD array, and the overall size of the filter element should cover the line connecting each PD detector in the PD array and the edge of the converging lens, in other words, the size of the filter element should be able to cover all the converging lens-converged echo beams that can impinge on the PD array.
Because the central frequency and the spectrum width of the narrow-band filter depend on the incident angle of incident light, and echo beams have different incident angles when irradiating the PD detectors at different positions in the PD array, the flat narrow-band filter with the uniform coating film cannot realize the same filtering effect, and even the situation that one of the central area and the edge area of the filter does not allow the echo beams to penetrate appears. Although the line width of the filter plate is increased to ensure that echo light beams irradiated to different areas of the filter plate can pass through, obviously, the suppression effect on background light noise is seriously reduced.
To this end, the utility model provides two kinds of solutions. One is to use non-uniform filter elements, i.e. filter elements with different filter parameters in different regions. The filtering parameters are preferably distributed on the filtering plate in a concentric ring shape, namely a plurality of concentric rings exist in the direction from the center to the edge of the filtering plate, the filtering plate areas corresponding to the same concentric ring have the same filtering parameters, and the concentric rings are preferably circular rings. The filter element with non-uniform filter parameters can be realized by performing annular coating for multiple times on an integral filter plate; or may be a circular array of several filter units arranged in concentric rings. The filter units in the circular array may have a ring structure corresponding to the annular array, or a fan structure obtained by further subdividing the ring structure. Wherein, the filters on different concentric rings have different filter parameters, and the filters on the same concentric ring have the same filter parameters.
Another solution provided by the present invention is to employ a uniform filter element, but the filter element is an arc protruding towards the PD array. Wherein the arc-shaped filter element is such that a line connecting each PD detector in the PD array to the center of the focusing lens is substantially perpendicular to the surface of the filter element, such that the focused echo beams, when directed to each of the PD detectors, form substantially the same angle of incidence at the surface of the filter element. By substantially perpendicular is meant that the line connecting the PD detector to the centre of the converging lens forms an angle theta with the surface of the filter element of between 80 and 90 degrees inclusive.
The arc-shaped filter element can be an integral filter plate or an array consisting of a plurality of small filter units which are arranged in an arc shape in the above manner. Wherein, each small-sized filter unit can be an arc-shaped filter plate or a flat plate filter plate with the curvature identical to that of the integral filter element. When a flat plate filter array is used, it should have a size small enough to meet the above-mentioned substantially vertical requirement. When the arc-shaped filter element adopts an array structure, the filter unit can also adopt an annular or fan-shaped structure in the flat filter element array.
The filter parameter setting of the flat plate type element and the angle setting of the arc-shaped filter element relative convergence echo need to meet a premise, namely, the converged echo light beams can penetrate through the filter element when being emitted to the PD detector, and the filter element can play a basically same actual filtering effect after filtering the penetrated light beams. The substantially same actual filtering effect means that the difference of background light noise included in the filtered transmitted light is less than or equal to 20%.
The utility model discloses compare in prior art and can play following beneficial effect at least: utilize outer chamber feedback elements such as feedback grating to narrow laser linewidth, and lock the frequency and the wavelength of outgoing laser, the background light noise is cut down by a wide margin to cooperation narrowband filter element, improves the sensitivity and the detection distance that laser radar surveyed, simultaneously, the cooperation has differentiated filtering parameter or has the filter element of arc structure, has improved the uniformity of filter element filtering effect under different echo incident angles, makes the utility model discloses a narrow linewidth filtering laser radar has sensitivity and the detection reliability basically the same in whole visual field angle.
Drawings
FIG. 1 is a spectrum diagram of a 905nm wavelength pulsed semiconductor laser in the prior art;
fig. 2 is a schematic diagram of the narrow linewidth filtering laser radar of the coaxial arrangement of the present invention;
FIG. 3 is a schematic representation of a PBS and 1/4 wave plate combination;
FIG. 4 is a schematic diagram of a non-coaxial narrow linewidth filter lidar employing a plate filter element;
FIG. 5 is an enlarged partial view of a non-coaxial narrow linewidth filtered lidar employing a plate filter element;
FIG. 6 shows three construction modes of the flat panel filter element;
FIG. 7 is a schematic diagram of a non-coaxial narrow linewidth filtered lidar employing an arcuate filtering element;
fig. 8 is a close-up view of a non-coaxial narrow linewidth filtered lidar employing an arcuate filtering element.
In the figure: the device comprises a pulse laser 1, a collimating lens 2, a feedback grating 3, a reflecting mirror 4, a scanning mechanism 5, a narrow-band filter 6, a converging lens 7, a PD detector 8, emergent light 9, feedback light 10, an echo 11, a PD array 12, a flat plate type filter element 13, an arc-shaped filter element 14, a detection target 15, a signal processing circuit 30, an annular filter unit 131a, a fan-shaped filter unit 131b and a flat plate filter unit 141 of the arc-shaped filter element.
Detailed Description
Example 1.
As shown in fig. 2, the narrow linewidth filtering lidar adopts a laser emission optical path and a laser detection optical path which are coaxially arranged, and comprises a pulse laser 1, a collimating lens 2, a feedback grating 3, a reflecting mirror 4, a scanning mechanism 5, a narrow-band filter 6, a converging lens 7, a PD detector 8 and a signal processing circuit. The above components are arranged so that the light pulses emitted by the pulse laser 1 are collimated by the collimating lens 2 and the feedback grating 14 partially reflects the narrow band of wavelengths of the feedback light 10 back into the laser cavity as determined by the grating structure, forcing the laser wavelength to lock onto the narrow range of wavelengths selected for the grating. The outgoing light 9 is directed in a different direction by the scanning mechanism 5 via the mirror 4. The echo 11 is reflected by the reflector 4 and passes through the narrow-band filter 6, and the converging lens 7 converges on the PD detector 8. The PD signal is processed by a signal processing circuit to calculate the flight time and the distance.
The laser wavelength locked by the feedback grating 3 is matched with the narrow-band filter 6, and the feedback grating 3 and the narrow-band filter 6 have the same temperature drift coefficient, so that the same wavelength matching is ensured under different environmental temperatures.
The mirror 4 may be a partial mirror or a mirror with a hole in the middle for the transmission of the radiation beam. Or a combination of polarizing beam splitter PBS and 1/4 wave plates as shown in fig. 3.
In this embodiment, firstly, on the coaxial laser radar system, the line width of the emergent light 9 is compressed to be less than or equal to 2nm by using the feedback grating 3; accordingly, a narrow-band filter 6 having a line width of 5nm is used, and allows the wavelength of the laser light to be transmitted to match the wavelength of the outgoing light 9 to be locked.
Compared with a laser radar which does not use the feedback grating 3 and the narrow-band filter 6, the coaxial laser radar which adopts the feedback grating 3 to be matched with the narrow-band filter with the bandwidth of 5nm has the advantages that the background light noise is reduced by about 8 times, and the measuring distance is increased by 2.8 times.
Example 2
Unlike embodiment 1, this embodiment employs a non-coaxial lidar arrangement and thus does not include the structure of the mirror 4. In particular, the detector is a PD array 12. As shown in fig. 4 to 5, the narrow-band filter 6 is a flat plate type filter element 13, and is disposed between the PD array 12 and the condenser lens 7. The flat plate filter elements are of sufficient size to ensure that the echoes directed to the PD array 12 are all filtered.
The light pulse emitted by the pulse laser 1 is collimated by the collimating lens 2, and the feedback grating 3 partially reflects the feedback light 10 with the narrow band of wavelength determined by the grating structure back into the laser cavity, so that the laser wavelength is locked in the narrow wavelength range selected by the grating. The outgoing light 9 is directed in different directions via the scanning mechanism 5. The echo 11 is converged by the converging lens 7 and then emitted to the PD array 12 through the flat plate filter element 13. The PD signal is processed by a signal processing circuit to calculate the flight time and the distance.
Example 3
As shown in fig. 6A, the flat plate type filter element 13 may be an integral plate filter covering all PD detectors 8 in the PD array 12. What is different from embodiment 2 is that the filter sheet of the whole sheet has a plurality of filter regions distributed in concentric circular rings, and the circular rings are adjacent to each other. The filtering regions corresponding to the same circular ring have the same filtering parameters, and the filtering regions corresponding to different circular rings have different filtering parameters, so as to match the different incident angles formed by the echo light beams converged by the converging lens 7 in different regions of the flat plate type filtering element 13. The above-mentioned filtering parameters should be set so that the echoes 11 irradiated in different regions of the flat plate filter element 13 can all pass through the flat plate filter element 13, and preferably, each region can have the same actual filtering effect.
The flat plate filter element 13 having different filter parameters in different filter regions can be prepared by a differential coating method, for example, by coating the regions corresponding to the concentric rings by adhering a cover for multiple times.
Example 4
As shown in fig. 6B, different from embodiment 3, the flat plate type filter element 13 may be composed of an array of several ring filter units 131a, such as B1, B2, B3, B4, B5 in fig. 6B; wherein b1 is a circular filter unit. The annular filter units 131a themselves have uniform filter parameters, but the filter parameters are different between different annular filter units 131 a. The filter parameters were set in the manner described in example 3. The filtering units are preferably connected seamlessly, such as by using adhesive, ultrasonic welding, etc., to form an array.
Example 5
As shown in fig. 6C, unlike embodiment 4, the ring filter unit 131a may be further divided into several fan-shaped filter units 131b, such as b41, b42, b43, b44 … b4n in fig. 6C; they are connected with each other seamlessly to form a filtering ring b 4; in this manner, for example, 4 filter rings are formed, and the 4 filter rings and the central circular filter unit b1 are connected to each other without a gap, thereby forming the flat plate type filter element 13. The fan-shaped filtering units 131b on the same ring have the same filtering parameters, and the filtering parameters of the filtering areas corresponding to different rings are different. The filter parameters were set in the manner described in example 3.
Although fig. 6A-6C each illustrate only 5 concentric rings, this does not represent that only 5 concentric rings or preferably 5 concentric rings can be used, and fig. 6A-6C are merely simplified examples to facilitate the understanding of the inventive concept.
Example 6
In contrast to embodiment 2, as shown in fig. 7, the narrow-band filter 6 of this embodiment is an arc-shaped filter element 14, and the arc-shaped filter element 14 is arranged to protrude toward the PD array 12, so that when the echo light beam from the focusing lens 7 is emitted to any PD detector 8 in the PD array 12, the light beam is directed to be substantially perpendicular to the surface of the arc-shaped filter element 14, thereby avoiding the difference in filtering effect caused by the fact that the laser light beam has different light incident angles when irradiating different positions of the filter element. In other words, the surface of the narrow band filter 6 is substantially perpendicular to the rays directed from the center of the converging lens to the center of any one of the PD detectors 8. By substantially perpendicular is meant that the above-mentioned rays make an angle of not less than 80 degrees with the surface of the narrow band filtering element.
Specifically, the arc-shaped filter element 14 may be a monolithic filter segment that is arc-shaped as a whole, or may be an array of filter units that are arranged in an arc shape. The arrangement of the filter unit can refer to the arrangement in embodiments 4 to 5. I.e. the filter unit may be circular or sector shaped. Except that the filter units in the embodiments 4 to 5 are all of a flat plate structure. The filtering unit applied in this embodiment may be a flat plate structure (e.g. the flat plate unit 141 in fig. 8) or an arc structure with a certain curvature, and the area is preferably the same as the curvature of the arc filtering element 14, so as to form an arc filtering surface with the same curvature. Both forms of filter unit described above satisfy that the direction from the center of the converging lens 7 to any one PD detector 8 in the PD array 12 is substantially perpendicular to the surface of the curved filter element 14, i.e. it forms an angle θ between 80 and 90 degrees.
Further, unlike embodiments 4 to 5, the filter units in the present embodiment have substantially the same filter characteristics therebetween.
Considering that the uniform film coating is difficult to control in the manufacturing process of the large-size filter and the installation and debugging of the arrayed filter are complicated, the filter array is preferably adopted in the embodiment, and the number of the filters is less than that of the PD detectors, so that the uniform film coating problem required to be faced in manufacturing the large-size filter is avoided, and meanwhile, the assembly and debugging difficulty of the arc-shaped filter array is controlled.
The filter parameters described herein include only line width and filter range; the filter characteristics include a temperature drift coefficient parameter and the like in addition to the above parameters.
It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. The present invention is not limited to the above-mentioned specific embodiments, and other embodiments that can be obtained by means of conventional replacement, readjustment, simple deformation, etc. by those skilled in the art do not depart from the concept of the present invention.

Claims (10)

1. The utility model provides a narrow linewidth filtering laser radar, includes pulse laser, collimating lens, scanning mechanism, convergent lens, detecting element and signal processing circuit, its characterized in that: the laser device further comprises an external cavity feedback element and a narrow-band filter element, wherein the external cavity feedback element is arranged to reflect part of laser light to a resonant cavity of the laser device so as to lock emergent laser light within a preset laser line width range of the feedback element, and the preset laser line width range is matched with the narrow-band filter element, so that an echo signal of the emergent laser light can penetrate through the narrow-band filter element and can achieve substantially the same actual filtering effect after being filtered by the narrow-band filter element.
2. The narrow linewidth filtered lidar of claim 1, wherein: the external cavity feedback element is one of a VBG body grating, a Bragg grating or a diffraction grating.
3. The narrow linewidth filtered lidar of claim 1, wherein: the preset laser line width range is less than or equal to 2nm, and the line width of the narrow line width filter is less than or equal to 5 nm.
4. The narrow linewidth filtered lidar of claim 1, wherein: the laser radar also comprises a reflector, and a light path of emergent laser and an echo light path are coaxially arranged.
5. The narrow linewidth filtered lidar of claim 1, wherein: the light path of the emergent laser and the echo light path are not coaxially arranged, the detection unit is a PD array, and each PD detector in the PD array is covered by the narrow-band filtering element on the echo light path.
6. The narrow linewidth filtered lidar of claim 5, wherein: the narrow-band filter element is an integral flat plate type filter element, and a plurality of concentric rings with different filter parameters are formed from the center to the outer direction of the narrow-band filter element in a mode of multiple coating and the like; the filter element regions corresponding to the same circular ring have the same filter parameters.
7. The narrow linewidth filtered lidar of claim 5, wherein: the narrow-band filter element is a flat-plate filter element formed by an array of a plurality of circular ring-shaped or sector-shaped filter units, and the center of the narrow-band filter element is a circular filter unit; the filtering units on the same ring have the same filtering parameters, and the filtering units on different rings have different filtering parameters.
8. The narrow linewidth filtered lidar of claim 5, wherein: the narrow-band filter element is a one-piece arc-shaped filter element, the arc-shaped filter element protrudes towards one side of the PD array, and the arc shape is set to enable the echo light beams converged by the convergent lens to be basically vertical to the surface of the narrow-band filter element when being directed to any PD detector in the PD array.
9. The narrow linewidth filtered lidar of claim 5, wherein: the narrow-band filtering element is an arc-shaped filtering element formed by an array of a plurality of circular ring-shaped or fan-shaped filtering units, the center of the narrow-band filtering element is a circular filtering unit, each filtering unit has basically the same filtering characteristic, and the filtering units can be flat plate structures or arc-shaped structures with the same curvature as the arc-shaped filtering elements.
10. The narrow linewidth filtered lidar of claim 7 or 9, wherein: and seamless connection is adopted among a plurality of filtering units forming the array.
CN201920528317.0U 2019-04-18 2019-04-18 Narrow linewidth filtering laser radar Expired - Fee Related CN210119572U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201920528317.0U CN210119572U (en) 2019-04-18 2019-04-18 Narrow linewidth filtering laser radar

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201920528317.0U CN210119572U (en) 2019-04-18 2019-04-18 Narrow linewidth filtering laser radar

Publications (1)

Publication Number Publication Date
CN210119572U true CN210119572U (en) 2020-02-28

Family

ID=69612977

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201920528317.0U Expired - Fee Related CN210119572U (en) 2019-04-18 2019-04-18 Narrow linewidth filtering laser radar

Country Status (1)

Country Link
CN (1) CN210119572U (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114325649A (en) * 2021-12-30 2022-04-12 中国科学院光电技术研究所 Photon counting laser radar working in strong noise environment
WO2023077801A1 (en) * 2021-11-05 2023-05-11 上海禾赛科技有限公司 Laser radar

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2023077801A1 (en) * 2021-11-05 2023-05-11 上海禾赛科技有限公司 Laser radar
CN114325649A (en) * 2021-12-30 2022-04-12 中国科学院光电技术研究所 Photon counting laser radar working in strong noise environment

Similar Documents

Publication Publication Date Title
CN110780283B (en) Receiving system, laser radar comprising same and echo receiving method
CN109477896B (en) Optical system for sensing scan field
US11644546B2 (en) Lidar systems based on tunable optical metasurfaces
CN110333511B (en) Transmit-receive synchronous laser radar optical system
CN111856508A (en) Narrow linewidth filtering laser radar
WO2019099166A1 (en) Scanning lidar system and method with spatial filtering for reduction of ambient light
CN210015229U (en) Distance detection device
CN109001747B (en) Non-blind area laser radar system
WO2021051723A1 (en) Laser transceiving module and lidar
CN210119572U (en) Narrow linewidth filtering laser radar
CN108008371B (en) Lidar sensor for detecting objects
WO2021258707A1 (en) Planar array dispersive spectral photosensitive assembly, receive end, and laser radar system
CN110235025B (en) Distance detecting device
CN111090082A (en) Laser radar and method for detecting using the same
CN112219130B (en) Distance measuring device
US11585901B2 (en) Scanning lidar system and method with spatial filtering for reduction of ambient light
US20230341525A1 (en) Detection apparatus, laser radar system, and terminal
US20230145710A1 (en) Laser receiving device, lidar, and intelligent induction apparatus
CN111580123B (en) Photoelectric sensor and method for detecting object
CN113296079B (en) Remote photoelectric detection system
WO2021258708A1 (en) Dispersion spectrum photosensitive assembly, receiving end, and lidar system
US11454708B2 (en) Lidar device
WO2021258709A1 (en) Dispersion spectrum lidar system and measurement method
US20220260677A1 (en) Laser radar and method for performing detection by using the same
CN216083083U (en) Coaxial optical system for laser ranging

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20200228

Termination date: 20210418

CF01 Termination of patent right due to non-payment of annual fee