Luigi Capozzoli

Archeological crop marks identified from Cosmo-SkyMed time series: the case of Han-Wei capital city, Luoyang, China

ABSTRACT The development of spaceborne Synthetic Aperture Radar (SAR) technology declares that the golden era of SAR remote sensing in archeology is approaching; however, nowadays its methodology framework is still lacking due to the inadequate case studies validated by ground-truths. In this study, we investigated the crop marks using multi-temporal Cosmo-SkyMed data acquired in 2013 by applying a two-step decision-tree classifier in conjunction with a spatial analysis in an area of archeological interest nearby the archeological site of Han-Wei capital city (1900–1500 BP), in Luoyang, China. The time-series backscattering anomalies related to the wheat growth cycle were identified and then further validated in two zones by geophysical investigations (Ground Penetration Radar and electrical measurements) and in a third zone by archeological excavations made after the SAR data acquisition. This study provides a new approach for the relic detection, shallowly buried and covered by the crop vegetation, by temporal crop marks on spaceborne SAR images. We also emphasize the necessity to establish a satellite-to-ground methodology framework for the promotion of remote-sensing technology in archeology.

Integrated Archaeogeophysical Approach for the Study of a Medieval Monastic Settlement in Basilicata

Abstract The paper deals with the results of an archaeo-geophysical approach adopted for the study and the reconstruction of the architectural plan of the medieval monastery of San Pietro a Cellaria in Calvello (Basilicata, Southern Italy). The monastery is a remarkable witness to Benedectine architecture of the 12-13th century in Basilicata, built by monks of the Congregation of S. Maria di Pulsano, who were active mainly in southern Italy. The historical data and the diachronic architectural study, based on the analysis of building techniques, provide evidence for a long and intense history, during which the monastery underwent several architectural changes, including the demolition of buildings and the superposition of other constructional elements. The only preserved medieval remains are a church with a nave; the adjacent structures are more recent. This preliminary data prompted a research project to shed new light on the as yet unknown history of the medieval monastery. Specifically, a remote sensing approach around the monastery including aerial survey by unmanned aerial vehicle (UAV), ground-penetrating radar (GPR) and geomagnetic survey in gradiometric configuration (MAG), was adopted in order to verify the possible existence of buried masonry structures and other possible features of archaeological interest, including channels and aqueducts. The GPR time slices were constructed from closely spaced parallel profiles. The time slices, computed by averaging radar reflections over vertical time windows several nanoseconds thick, are used to map subsoil features associated with the structures, probably of anthropogenic origin. To facilitate the interpretation of the results, a threedimensional image was constructed using closely spaced parallel profiles, which are linearly interpolated. The MAG survey was carried in gradiometer configuration, in order to study magnetic properties of the shallow subsoil. Ground-penetrating radar gives details about archaeological structures in a limited area where survey was possible, while gradiometer survey confirms GPR results and improves archaeological knowledge in the areas where GPR survey was impossible. This multi-sensor remote sensing program revealed a wide variety of archaeological features of interest, which may be targeted accurately with excavations in the future.

Remote Sensing and Geophysics for the Study of the Human Past in the Nasca Drainage

This chapters presents and discusses the results of investigations performed by ITACA Mission of CNR in the Nasca drainage basin, including the ceremonial center of Cahuachi, from 2007 to 2014. The employed approach was based on the multiscale and multisensor integration of remote-sensing methods, including geophysics . Most of the applications have been intended for preventive archaeology, in particular, for providing information on the presence of buried sites and structures by identifying different surface characteristics such as arid bare ground in the Pampas and vegetated areas in the river oases. The operational use of earth-observation technologies has been the occasion to develop ad hoc approaches to data acquisition, processing, and interpretation for the detection of earthen buried structures that is a crucial and challenging issue due to the subtle physical contrast between earthen remains and the surrounding subsoil. This made necessary amassing experience in, and the testing of, various techniques to investigate the subsoil by geophysical and remote methods, working side by side with archaeologists, involved in the interpretation of the results. The obtained results have been the discovery of previously unknown sites in the Nasca drainage basin, the identification of buried ritual offering, the characterization of the stepped structure of Templo Sur, and the mapping of areas of archaeological interest.

Electrical and electromagnetic techniques applied to an archaeological framework reconstructed in laboratory

Ground penetrating radar (GPR) and electrical resistivity tomography (ERT) are typical geophysical techniques applied into archaeological context thanks to their capability to study variations of physical attributes of buried objects in the soil causing electric and electromagnetic contrasts compared to the behaviour of the surrounding environment. Unfortunately sometimes these contrasts are difficult to define for several reasons including strong attenuation of signals introduced into the soil, limited depth and low resolution of investigation related to instrumentation characteristics. Great efforts are required to understand the complexity of the relationship between archaeological features and their geophysical response and give an effective interpretation of resulting data. For this reason an experimental activity has been performed at the Hydrogeosite laboratory focused on the assessment of the capability of geophysical techniques to detect archaeological remains placed in humid or saturated subsoil.

Archaeogeophysical-Based Approach for Inca Archaeology: Overview and one operational application

Even if, in recent decades, the use of remote sensing technologies (from satellite, aerial and ground) for archaeology is stepping into its golden age, in Southern America geophysics for preventive archaeology is more recent and less used than in Europe, Central America and Middle East. In this paper, we provide a brief overview and show the preliminary results obtained from the investigations conducted in Chachabamba (Peru). The archaeological area is located on a strategic terrace overlooking three Inca roads, which served the most important ceremonial centres (including Machu Picchu) of the Urubamba Valley also known as the Sacred Valley. In particular, Chachabamba investigations were conducted with two principal aims: (1) to give new impetus to archaeological research with targeted investigations aimed at improving and completing the site’s knowledge framework; (2) to experiment and validate an archaeogeophysical approach to be reapplied in other sites of the Urubamba valley, including Machu Picchu, having similar characteristics as those found in Chachabamba.

Geophysical techniques applied to investigate underwater structures

The need to investigate underwater structures leads to study the capability of geophysical methods to analyze the physical behavior of the subsoil in water saturated conditions. Ground penetrating radar and electrical resistivity methods are well suited to localize and identify underwater structures but these methods are affected by some limitations that are analyzed in laboratory where an underwater archaeological site was simulated. GPR and ERT are applied and the results with the two techniques are compared and discussed.

Cave-surface Electrical Resistivity Tomography in “Castello di Lepre” Karst System (Marsico Nuovo, Southern Italy)

Summary Several geophysical methods, electrical resistivity tomography (ERT), gravimetric prospecting (G), Ground Penetrating Radar (GPR) and seismic methods (S), are commonly applied to characterize karst cave ( Beres et al., 2001 ; Martinez-Moreno et al., 2015 ; Bermejo et al., 2016 ; and references therein). In detail, the geophysical approach provides information on cave geometry and subsurface geological structure. Several karst areas have a complex deep system, but the geophysical methods, such as geoelectrical ones, offer partial deep information due to a low-resolution. Therefore, this work would like to introduce a new 2D and 3D geoelectrical approach, that we call “cave-surface” ERT, which define an improvement of the deep resolution comparing to surface ERT. Finally, an application of this new methodology in the karst cave Castello di Lepre (Marsico Nuovo, Basilicata region, Italy) is described.

Puquios : New Insights from the Integration of Remote Sensing, GIS-Based Analyses and Geophysical Investigations

The investigations conducted previously on the Nasca puquios, with particular reference to those systematically performed by Schreiber and Lancho Rojas (1995), Schreiber and Lancho Rojas (Los puquios de Nasca: un sistema de galerias filtrantes. Editorial Los Pinos, Lima, 1998), Schreiber and Lancho Rojas (Aguas en el Desierto. Los puquios de Nasca. Fondo Editorial, Lima, Peru, 2006), have had the merit of placing the theme of Nasca water management in the center of debate on the ancient Nasca world. Water has become the crossroads of all the other research lines focused on the influence of environment and climate on the Nasca culture, as well as on the geoglyphs, ceremonial architecture, and settlements. In this cultural framework, some studies based on multitemporal, multiscale, and multisensor analyses have been performed in the Rio Grande de Nasca drainage in order to investigate the interaction between the puquios and environmental conditions, as well as to improve knowledge of the local environmental settings. Herein we present and discuss the investigations, based on the integration of remote sensing, GIS -based analyses, and geophysical prospecting, in the framework of the ITACA mission of the Italian CNR. Outputs from satellite-based investigations, along with all the information already available from previous studies, were the input data used in the statistical spatial analyses and geophysical prospecting. The main findings provided information useful to: (i) improve the current knowledge on the puquios at both intra-site and inter-site levels and their relationship with environmental and human settings, (ii) identify unknown puquios, (iii) and support planning for subsequent archaeological excavations. As a whole, the investigations based on the adopted integrated approach provided new insights into this hyper-arid area which has been the homeland for numerous civilizations, despite the extreme physical environment that presents serious obstacles to human occupation.