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Drone-Mounted Lidar Survey of Maya Settlement and Landscape

Published online by Cambridge University Press:  27 August 2019

Timothy M. Murtha*
Affiliation:
Center for Latin American Studies, University of Florida, 389 Grinter, Gainesville, FL 32611, USA
Eben N. Broadbent
Affiliation:
School of Forest Resources and Conservation, University of Florida, Reed Lab, Gainesville, FL 32611, USA
Charles Golden
Affiliation:
Department of Anthropology, Brandeis University, 415 South Street, Waltham, MA 02454, USA
Andrew Scherer
Affiliation:
Department of Anthropology, Brown University, Box 1921, Providence, RI 02912, USA
Whittaker Schroder
Affiliation:
Department of Anthropology, University of Pennsylvania, 3260 South St., Philadelphia, PA 19104, USA
Ben Wilkinson
Affiliation:
School of Forest Resources and Conservation, University of Florida, Reed Lab, Gainesville, FL 32611, USA
Angélica Almeyda Zambrano
Affiliation:
Department of Tourism, Recreation and Sport Management, University of Florida, 240 Florida Gym, Gainesville, FL 32611, USA
*
([email protected], corresponding author)

Abstract

We conducted unmanned aerial vehicle lidar missions in the Maya Lowlands between June 2017 and June 2018 to develop appropriate methods, procedures, and standards for drone lidar surveys of ancient Maya settlements and landscapes. Three site locations were tested within upper Usumacinta River region using Phoenix Lidar Systems: Piedras Negras, Guatemala, was tested in 2017, and Budsilha and El Infiernito, both in Mexico, were tested in 2018. These sites represent a range of natural and cultural contexts, which make them ideal to evaluate the usefulness of the technology in the field. Results from standard digital elevation and surface models demonstrate the utility of deploying drone lidar in the Maya Lowlands and throughout Latin America. Drone survey can be used to target and efficiently document ancient landscapes and settlement. Such an approach is adaptive to fieldwork and is cost effective but still requires planning and thoughtful evaluation of samples. Future studies will test and evaluate the methods and techniques for filtering and processing these data.

En este trabajo describimos los resultados del uso de tecnología lidar en drones en el área Maya entre junio del 2017 y 2018. Nuestro objetivo es desarrollar métodos, procedimientos y estándares apropiados para el uso de lidar en drones en el mapeo de asentamientos antiguos. Se sobrevolaron tres sitios dentro de la región superior del río Usumacinta: Piedras Negras en Guatemala, Budsilha y El Infiernito en México. Estos sitios representan una gama de contextos naturales y culturales ideales para evaluar las aplicaciones de la tecnología lidar en el campo. Los modelos de elevación digital y de superficie digital muestran la utilidad del uso de drones en el área Maya. Esta tecnología es apropiada y rentable para el trabajo de campo, pero aún requiere de una detallada planificación y evaluación de las muestras. Futuros estudios evaluarán métodos y técnicas para filtrar y procesar estos datos.

Type
Report
Copyright
Copyright © 2019 by the Society for American Archaeology 

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References

References Cited

Chase, Arlen F., Chase, Diane, Awe, Jaime, Weishampel, John, Iannone, Gyles, Moyes, Holley, Yaeger, Jason, and Brown, M. Kathryn 2014a The Use of Lidar in Understanding the Ancient Maya Landscape: Caracol and Western Belize. Advances in Archaeological Practice 2:147160.Google Scholar
Chase, Arlen F., Chase, Diane, Awe, Jaime, Weishampel, John, Iannone, Gyles, Moyes, Holley, Yaeger, Jason, Kathryn Brown, M., Shrestha, Ramesh, Carter, William, and Fernandez-Diaz, Juan 2014b Ancient Maya Regional Settlement and Inter-Site Analysis: The 2013 West-Central Belize Lidar Survey. Remote Sensing 6:86718695.Google Scholar
Chase, Arlen F., Chase, Diane, Weishampel, John, Drake, Jason, Shrestha, Ramesh, Clint Slatton, K., Awe, Jaime, and Carter, William 2011 Airborne Lidar, Archaeology, and the Ancient Maya Landscape at Caracol, Belize. Journal of Archaeological Science 38:387398.Google Scholar
Chase, Arlen, Reese-Taylor, Kathryn, Fernandez-Diaz, Juan, and Chase, Diane 2016 Progression and Issues in the Mesoamerican Geospatial Revolution. Advances in Archaeological Practice 4:219231.Google Scholar
Doneus, Michael, Briese, Christian, Fera, Martin, and Janner, Martin 2008 Archaeological Prospection of Forested Areas Using Full-Waveform Airborne Laser Scanning. Journal of Archaeological Science 35:882893.Google Scholar
Evans, Damian, and Fletcher, Roland 2015 The Landscape of Angkor Wat Redefined. Antiquity 89:14021419.Google Scholar
Fernandez-Diaz, Juan, Carter, William, Shrestha, Ramesh, and Glennie, Craig 2014 Now You See It … Now You Don't: Understanding Airborne Mapping Lidar Data Collection and Data Product Generation for Archaeological Research in Mesoamerica. Remote Sensing 6:9951–10001.Google Scholar
Golden, Charles, Murtha, Timothy, Cook, Bruce, Shaffer, Derek, Schroder, Whittaker, Hermitt, Elijah, Firpi, Omar Alcover, and Scherer, Andrew K. 2016 Reanalyzing Environmental Lidar Data for Archaeology: Mesoamerican Applications and Implications. Journal of Archaeological Science: Reports 9:293308.Google Scholar
Golden, Charles, and Scherer, Andrew 2006 Border Problems: Recent Archaeological Research along the Usumacinta River. PARI Journal 7(2):116.Google Scholar
Golden, Charles, Scherer, Andrew, and Muñoz, A. René 2005 Exploring the Piedras Negras-Yaxchilan Border Zone: Archaeological Investigations in the Sierra del Lacandón, 2004. Mexicon 27:1116.Google Scholar
Hightower, Jessica, Swanson, Christine, and Weishampel, John 2014 Quantifying Ancient Maya Land Use Legacy Effects on Contemporary Rainforest Canopy Structure. Remote Sensing 6:1071610732.Google Scholar
Hutson, Scott 2015 Adapting Lidar Data for Regional Variation in the Tropics: A Case Study from the Northern Maya Lowlands. Journal of Archaeological Science: Reports 4:252263.Google Scholar
Isenburg, Martin 2014 LAStools: Efficient Lidar Processing Software (version 141017, licensed). http://rapidlasso.com/LAStools.Google Scholar
Rosenswig, Robert, López-Torrijos, Ricardo, Antonelli, Caroline, and Mendelsohn, Rebecca 2013 Lidar Mapping and Surface Survey of the Izapa State on the Tropical Piedmont of Chiapas, Mexico. Journal of Archaeological Science 40:14931507.Google Scholar
Scherer, Andrew, and Golden, Charles 2012. Revisiting Maler's Usumacinta: Recent Archaeological Investigation in Chiapas, Mexico. The Pre-Columbian Art Research Institute, San Francisco, California.Google Scholar
von Schwerin, Jennifer, Richards-Rissetto, Heather, Remondino, Fabio, Spera, Maria Grazia, Auer, Michael, Billen, Nicolas, Loos, Lukas, Stelson, Laura, and Reindel, Markus 2016 Airborne Lidar Acquisition, Post-Processing and Accuracy-Checking for a 3D WebGIS of Copan, Honduras. Journal of Archaeological Science: Reports 5:85104.Google Scholar