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Visualisation of LiDAR terrain models for archaeological feature detection

Published online by Cambridge University Press:  02 January 2015

B.J. Devereux ,
G.S. Amable  and
P. Crow
B.J. Devereux
Affiliation:
Unit for Landscape Modelling, University of Cambridge, Sir William Hardy Building, Tennis Court Road, Cambridge CB2 1QB, UK
G.S. Amable
Affiliation:
Unit for Landscape Modelling, University of Cambridge, Sir William Hardy Building, Tennis Court Road, Cambridge CB2 1QB, UK
P. Crow
Affiliation:
Environmental and Human Sciences Division, Forest Research, Alice Holt Lodge, Wrecclesham, Farnham, Surrey, GU10 4LH, UK
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Extract

LiDAR is developing into a formidable instrument of aerial survey. Here the author shows how the LiDAR picture can be enhanced so that features picked up by illumination from different directions can be combined in one comprehensive survey.

Keywords

airborne LiDARairborne laser scanningfeature detectionvegetation removalhill-shadingprincipal components analysislandscape visualisation
Type
Research article
Information
Antiquity , Volume 82 , Issue 316 , June 2008 , pp. 470 - 479
Copyright
Copyright © Antiquity Publications Ltd 2008

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References

Bewley, R. H., Crutchley, S. & Shell, C.. 2005. New light on an ancient landscape: LiDAR survey in the Stonehenge World Heritage Site. Antiquity 79: 636–47.CrossRefGoogle Scholar
Crawford, O.S.G.. & Keiller, A.. 1928. Wessex from the air. Oxford: Clarendon Press.Google Scholar
Davis, J. C. 2002. Statistics and data analysis in geology (3rd edition). New York & Chichester: Wiley.Google Scholar
Devereux, B. J., Amable, G., Crow, P. & Cliff, A.. 2005. The potential of airborne LiDAR for detection of archaeological features under woodland canopies. Antiquity 79:660.CrossRefGoogle Scholar
Doneus, M. & Briese, C.. 2006. Full-waveform, airborne laser scanning as a tool for archaeological reconnaissance, in Campana, S. & Forte, M. (ed.) From space to place: 2nd international conference on remote sensing in archaeology (Proceedings of the 2nd international workshop, CNR, Rome, Italy, December 2-4, 2006) (British Archaeological Reports International Series 1568): 99105. Oxford: Archaeopress.Google Scholar
Mather, P. M. 2004. Computer processing of remotelysensed images: an introduction (3rd edition). Chichester: Wiley.Google Scholar
SAM 31186. 2004. Gloucestershire county council sites and monuments record 2004. Summary Report for Area 5161 (10.19.04).Google Scholar
Sittler, B. 2004. Revealing historical landscapes by using airborne laser scanning, in Thies, M., Koch, B., Spiecker, H. & Weinacker, H. (ed.) Laser scanners for forest and landscape assessment (Proceedings of the ISPRS Working Group 8/2, Freiburg, Germany, October 3-6, 2004; International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences Volume 36, Part 8/W2): 258–61. Freiburg: Institute for Forest Growth, Department of Remote Sensing.Google Scholar
St Joseph, J.K. (ed.) 1977. The uses of air photography (2nd edition). London: John Baker.Google Scholar
Wilson, D. R. 2000. Air photo interpretation for archaeologists (2nd edition). Stroud: Tempus.Google Scholar