Test station to characterize the emission of a LiDAR

被引：0

作者：

Cunha, N. F. ^{[1
]}

Rodrigues, Manuel j. l. f. ^{[2
]}

Ferreira, F. ^{[1
]}

Viana-gomes, J. ^{[2
]}

Linhares, J. M. M. ^{[2
]}

Franco, S. ^{[2
]}

Oliveira, F. ^{[2
]}

Soares, N. ^{[3
]}

Vasilevskiy, M. I. ^{[2
]}

Rebouta, L. ^{[1
]}

机构：

[1] Univ Minho, Phys Ctr Minho & Porto Univ, P-4800058 Azurem, Guimarãe, Portugal

[2] Univ Minho, Phys Ctr Minho & Porto Univ, P-4710057 Braga, Portugal

[3] Bosch Car Multimedia Portugal SA, P-4701970 Braga, Portugal

来源：

APPLIED OPTICS | 2024年 / 63卷 / 01期

关键词：

BEAM-PROPAGATION;

D O I：

10.1364/AO.505749

中图分类号：

O43 [光学];

学科分类号：

070207 ; 0803 ;

摘要：

A test station setup devised to measure the emission characteristics and beam propagation parameters of a light detection and ranging (LiDAR) system is presented. The main blocks of the station to measure the accessible emission, wavelength peak and FWHM, pulse duration, pulse repetition rate, horizontal and vertical angular resolution, field of view, beam propagation factor M2, beam waist size, waist location, and divergence are described. The performance of this test station was demonstrated using a commercial spinning LiDAR, a Velodyne VLP-16, which successfully enables these measurements for a laser beam with a wavelength of 913 nm. (c) 2023 Optica Publishing Group

引用

页码：17 / 29

页数：13

共 50 条

[1] Mobile Lidar Station
Titov, Semen, V
Nikolashkin, Semyen, V
26TH INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS, ATMOSPHERIC PHYSICS, 2020, 11560
[2] New approach using lidar measurements to characterize spatiotemporal aerosol mass distribution in an underground railway station in Paris
Raut, J. -C.
Chazette, R.
Fortain, A.
ATMOSPHERIC ENVIRONMENT, 2009, 43 (03) : 575 - 583
[3] Design and realization of conducted spurious emission test for base station
Wang, W
Yao, DP
ICEMI 2005: CONFERENCE PROCEEDINGS OF THE SEVENTH INTERNATIONAL CONFERENCE ON ELECTRONIC MEASUREMENT & INSTRUMENTS, VOL 4, 2005, : 66 - 70
[4] Using LiDAR to characterize logjams in lowland rivers
Abalharth, Mandi
Hassan, Marvvan A.
Klinkenberg, Brian
Leung, Vivian
McCleary, Richard
GEOMORPHOLOGY, 2015, 246 : 531 - 541
[5] LIDAR MONITORING OF STRATOSPHERIC AEROSOL AND OZONE AT THE SIBERIAN LIDAR STATION
Nevzorov, A. A.
Dolgii, S. I.
Nevzorov, A. V.
Makeev, A. P.
Bazhenov, O. E.
Gridnev, Yu V.
Romanovskii, O. A.
23RD INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS: ATMOSPHERIC PHYSICS, 2017, 10466
[6] Lidar complex for measuring the atmospheric temperature at the Siberian lidar station
Bobrovnikov, S. M.
Gorlov, E., V
Zharkov, V., I
Trifonov, D. A.
25TH INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS: ATMOSPHERIC PHYSICS, 2019, 11208
[7] Lidar complex of small lidar station of IAO SB RAS
Marichev, V. N.
Bochkovskii, D. A.
27TH INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS, ATMOSPHERIC PHYSICS, 2021, 11916
[8] Measurement complex Siberian Lidar Station
Nevzorov, A., V
Dolgii, S., I
Nevzorov, A. A.
Makeev, A. P.
Kharchenko, O., V
26TH INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS, ATMOSPHERIC PHYSICS, 2020, 11560
[9] SIBERIAN LIDAR STATION: INTSTRUMENTS AND RESULTS
Matvienko, G. G.
Balin, Yu. S.
Bobrovnikov, S. M.
Romanovskii, O. A.
Kokhanenko, G. P.
Samoilova, S., V
Penner, I. E.
Gorlov, E., V
Zharkov, V., I
Sadovnikov, S. A.
Kharchenko, O., V
Yakovlev, S., V
Bazhenov, O. E.
Burlakov, V. D.
Dolgii, S., I
Makeev, A. P.
Nevzorov, A. A.
Nevzorov, A., V
22ND INTERNATIONAL SYMPOSIUM ON ATMOSPHERIC AND OCEAN OPTICS: ATMOSPHERIC PHYSICS, 2016, 10035
[10] Fluorescent channel of the Siberian Lidar Station
Grishaev, Mike V.
Zuev, Vladimir V.
Kharchenko, Olga V.
15TH SYMPOSIUM ON HIGH-RESOLUTION MOLECULAR SPECTROSCOPY, 2006, 6580

← 1 2 3 4 5 →