Title

Terrestrial laser scanning in monitoring of anthropogenic objects

Journal title

Geodesy and Cartography

Yearbook

2017

Volume

vol. 66

Numer

No 2

Authors

Janina Zaczek-Peplinska ; Kowalska, Maria

Divisions of PAS

Nauki Techniczne

Publisher

Commitee on Geodesy PAS

Date

2017

Identifier

ISSN 2080-6736

References

Lichti (2004), Error Propagation in Directly Georeferenced Terrestrial Laser Scanner Point Clouds for Cultural Heritage Recording of FIG Working Week, Proc, 22. ; Kaspar (2004), Laser in Surveying Editorship spol s ro Republic s ISBN, Scanning Civil Engineering, 110. ; Zaczek (null), Metodyka wykonania oceny stanu powierzchni masywnej konstrukcji betonowej na podstawie klasyfi kacji obszarów jednorodnych chmur punktów in Red Eksploatacja budowli piętrzących - diagnostyka i zapobieganie zagrożeniom ss Instytut Meteorologii i Gospodarki, null, 2015. ; Pesci (2008), Effects of surface irregularities on intensity data from laser scanning : an experimental approach of, Annals Geophysics, 51, 839. ; Crutchley (2009), Using LiDAR in archaeological contexts the English heritage experience and lessons learned Laser Scanning for the Environmental Heritage Large WileyBlackwell, Sciences, 180. ; Voegtle (2009), Effects on the measurements of the terrestrial laser scanner HDS Leica caused by different object materials Proceedings of, Work, 6000. ; Bucksch (2007), Error budget of terrestrial laser scanning : Influence of the intensity remission of the scan quality NordOst, Proceedings, 1. ; Zaczek (null), a Potential of image processing methods based on intensity values captured by TLS for surface condition assessment Digital Proceedings of, null, 2015. ; Rees (2013), Physical Principles of Remote Sensing Third Edition Institute University of University pages, Polar Research, 441. ; Kilian (2007), metody diagnostyki masywnych konstrukcji betonowych i ekologia terenów wiejskich, null, 4, 77. ; Milan (2009), Terrestrial laser scan - derived topographic and roughness data for hydraulic modelling of gravel - bed rivers Chapter in Laser Scanning for the Environmental Heritage Large pages, Sciences, 133. ; Alberti (2013), - based approach for a multi - purpose characterization of Alpine forests : an Italian case study iForest, Biogeosciences Forestry, 6, 156, doi.org/10.3832/ifor0876-006 ; Zaczek (2014), Analysis of the possibility for using the results of terrestrial laser scanning measurements and classifi cation algorithms of images for the engineering structure surface condition assessment Proceedings of the first Vertical Geology Conference University, null, 227. ; Soudarissanane (2007), Error budget of terrestrial laser scanning : infl uence of the incidence angle on the scan quality NordOst pages, Proceedings, 1. ; Zaczek (2012), Możliwości wykorzystania intensywności odbicia promienia laserowego do oceny stanu powierzchni betonowego obiektu hydrotechnicznego Chapter in Zapory - bezpieczeństwo i kierunki rozwoju Meteorologii i Gospodarki Wodnej pages, null, 20, 204. ; Kaasalainen (2011), Analysis of Incidence Angle and Distance Effects on Terrestrial Laser Scanner Intensity for Correction Remote Sensing, Search Methods, 3, doi.org/10.3390/rs3102207 ; Osińska (2007), korekcji radiometrycznej w procesie przetwarzania zdjęć satelitarnych i i, null, 17. ; Hancock (2012), Detecting Fire Damaged Concrete Using Laser Scanning Proceedings of FIG Working Week Roma https www fig net resources proceedings fig proceedings fig Accessed st, null, 1. ; Lerma García (2008), Risk Mapping Theory and Practice on Terrestrial Laser Scanning Training Material Based on Practical Applications Universidad Politecnica de, null. ; Valzano (2005), Realistic Representations of Cultural Heritage Sites and Objects Through Laser Scanner Information National Research Council of Ottawa pages, null, 1. ; Owerko (2013), Geomorphometric monitoring of active slopes and their impact on post - glacier lake in the Tatra mountains th International Multidisciplinary Conference International, Proceedings Multidisciplinary, 13, 16, doi.org/10.5593/SGEM2013/BB2.V2/S09.032 ; Jaboyedoff (2012), Use of LiDAR in landslide investigations a, review Natural Hazards, 5, doi.org/10.1007/s11069-010-9634-2 ; Pętlicki (2016), Calving of Fuerza Glacier Greenwich Island observed with terrestrial laser scanning and continuous video monitoring of, Journal Glaciology, 235, doi.org/10.1017/jog.2016.72 ; Pfeifer (2007), Investigating Terrestrial Laser Scanning Intensity Data : Quality and Functional Relations Proceedings of VIII International Conference on Optical Techniques pages, Measurement, 328. ; Zaczek (null), Selection of reference fi elds for statistical analysis of point clouds in a process of technical condition assessment of concrete water dam Digital Proceedings of ICOCEE, null, 2015. ; Wróbel (2010), a pomiarach inwentarskich obiektów budowlanych rozprawa habilitacyjna, null, 209. ; Mleczko (2012), teoretyczne i przegląd metod oraz algorytmów korekcji radiometryczno - topografi cznej radarowych obrazów satelitarnych i i, null, 23, 303. ; Rutkowska (2013), Problemy strat ciepła w istniejących budynkach jednorodzinnych w kontekście błędów wykonawczych Annual Set The Environment Protection, null, 2625.

DOI

10.1515/geocart-2017-0011