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Procedure to evaluate the accuracy of laser-scanning systems using a linear precision electro-mechanical actuator

Procedure to evaluate the accuracy of laser-scanning systems using a linear precision electro-mechanical actuator

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Published

Deformation monitoring is critical for the inspection of civil engineering structures. Three-dimensional laser-scanning systems can provide the ability to control unexpected deformations that cannot be monitored with traditional topographic instruments, such as total stations or levels. Technical datasheets provided by laser manufacturers typically give the accuracy of single-point measurements, but these specifications can be improved using surface-fitting of the data points. In this study, a procedure is used to detect the true accuracy that can be achieved using surface-fitting techniques. The procedure uses a precision actuator that moves an aluminium plate whose shift can be measured by the geodetic instrumentation. Accuracy is calculated as the difference between the values given by the actuator and the values from the geodetic instruments. The procedure is tested using a laser scanner, Riegl LMS Z390i and a total station, Leica TCR 1102. Similar results are obtained in both cases and accuracies are less than 1 mm. The results confirm that this Riegl system can be used to detect small deformations and can be applied to monitor civil engineering structures. The single point measurements confirm the data provided by the laser scanner manufacturer with an accuracy of approximately 6 mm.

Inspec keywords: electromechanical actuators; condition monitoring; measurement by laser beam; deformation; spatial variables measurement; optical scanners

Other keywords: Leica TCR 1102; true accuracy; Riegl LMS Z390i; linear precision electromechanical actuator; single point measurements; precision actuator; total station; geodetic instrumentation; laser scanner; surface fitting technique; laser scanning systems; laser manufacturers; civil engineering structures; deformation monitoring; aluminium plate

Subjects: Metrological applications of lasers; Other optical system components; Metrological applications of lasers; Spatial variables measurement; Spatial variables measurement; Control gear and apparatus; Optical shutters, windows, diaphragms, deflectors, choppers, and scanners; Instrumentation; Maintenance and reliability; Control technology and theory (production); Measurement

References

    1. 1)
      • S. Soudarissanane , R. Lindenbergh , B. Gorte . Reducing the error in terrestrial laser scanning by optimizing the measurement set-up. Int. Arch. Photogramm. Remote Sens. Spatial Info. Sci , 615 - 620
    2. 2)
    3. 3)
      • ISO 17123–4: ‘Optics and optical instruments. Field procedures for testing geodetic and surveying instruments. Part 4. Electro-optical distance meters (EDM instruments)’, 2001.
    4. 4)
      • W. Kenneth , A. Jeffrey . Continuous GPS monitoring of structural deformation at Pacoima dam. California Seimol. Res. Lett. , 299 - 308
    5. 5)
      • T. Nuttens , A. De Wulf , L. Bral . High resolution terrestrial laser scanning for tunnel deformation measurements. FIG Congress , 1 - 15
    6. 6)
    7. 7)
      • H.–M. Zogg , H. Ingensand . Terrestrial laser scanning for deformation monitoring – load tests on the Felsenau viaduct. Int. Arch. Photogramm. Remote Sens. Spatial Info. Sci , 555 - 561
    8. 8)
      • J. Armesto , J. Roca-Pardiñas , H. Lorenzo , P. Arias . Modelingmasonry arches shape using terrestrial laser scanning data and nonparametric methods. Eng. Struct. , 607 - 615
    9. 9)
    10. 10)
    11. 11)
    12. 12)
      • Alba, M., Fregonese, L., Prandi, F., Scaioni, M., Valgoi, P.: `Structural monitoring of a large dam by terrestrial laser scanning', Proc. ISPRS Commission V Symp., 2006.
    13. 13)
    14. 14)
      • T. Lovas , A. Barsi , A. Detrekoi . Terrestrial laser scanning deformation measurements of structures. Int. Arch. Photogramm. Remote Sens. Spatial Info. Sci , 527 - 531
    15. 15)
    16. 16)
      • M. Tsakiri , D. Lichti , N. Pfeifer . (2006) Terrestrial laser scanning for deformation monitoring’.
    17. 17)
      • D.D. Lichti , M.G. Licht . Experiences with terrestrial laser scanner modeling and accuracy assessment. IAPRS Dresden , 5 , 155 - 160
    18. 18)
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