Automated Resistivity Profiling (ARP) to Explore Wide Archaeological Areas: The Prehistoric Site of Mont’e Prama, Sardinia, Italy

Piroddi, Luca; Calcina, Sergio Vincenzo; Trogu, Antonio; Ranieri, Gaetano

doi:10.3390/rs12030461

Cited by 20 publications

(5 citation statements)

References 49 publications

(48 reference statements)

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“…To detect what is hidden inside narrow gaps [21] Soil resistivity Detecting changes in the geological structure of the soil that indicate the presence of archaeological remains [22] Magnetometry Detecting buried archaeological materials with iron properties [23] Portable X-ray fluorescence (pXRF)…”

Section: Robotics Applicationmentioning

confidence: 99%

The Role of Modern Techniques in Preservation of Archaeological Sites

Chabuk,

Al-Amiri

2023

Architecture and Urban Planning

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Archaeological sites have always suffered from loss and degradation due to many human and natural hazards. In recent decades, interest in preserving archaeological sites has increased dramatically. Many modern techniques have emerged from the different disciplines that can be used in preservation works, and a large number of the techniques and their capability made it difficult for decision-makers and specialists to determine the appropriate technique that gives the best results in preserving the archaeological site. The research aims to identify the project needed to preserve the archaeological site and then choose the appropriate technique for it, based on the opinions of experts using the analytic hierarchy process (AHP) method, which helps decision-makers and specialists to choose the most appropriate technology. The archaeological site of Babylon was chosen as a case study. As a result of applying the AHP method, the priority weights of preservation stages for the archaeological site of Babylon were determined as follows: (diagnosis and monitoring 30.8 %), (intervention 21.2 %), and (tourism and media 16.6 %), while the appropriate technique was determined as follows: (infrared thermography 29.4 %), (maintenance 49.3 %), and (augmented reality 38.7 %).

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Section: Robotics Applicationmentioning

confidence: 99%

The Role of Modern Techniques in Preservation of Archaeological Sites

Chabuk,

Al-Amiri

2023

Architecture and Urban Planning

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“…Due to the need for physical coupling between the electrodes and the ground, ERT surveys are more troublesome than their electromagnetic counterpart. Hence, for example, in the attempt to speed up the acquisition time of typical ERT surveys and be able to cover larger areas quickly, mobile (pseudo-)ERT systems have been developed and tested [11][12][13]. On the other hand, standard EMI equipment is routinely used to assess (quasi-)3D resistivity distribution of extremely vast areas [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Spreading of Localized Information across an Entire 3D Electrical Resistivity Volume via Constrained EMI Inversion Based on a Realistic Prior Distribution

Zaru,

Rossi,

Vacca

et al. 2023

Remote Sensing

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Frequency-domain electromagnetic induction (EMI) methods are commonly used to map vast areas quickly and with minimum logistical efforts. Unfortunately, they are often characterized by a very limited number of frequencies and severe ill-posedness. On the other hand, electrical resistivity tomography (ERT) approaches are usually considered more reliable; for example, they do not require specific calibration procedures and can be easily inverted in 2D/3D. However, ERT surveys are, by far, more demanding and time consuming, allowing for the deployment of a few acquisition lines per day. Ideally, the optimal would be to have the advantages of both approaches: ease of acquisition while keeping robustness and reliability. The present work raises from the necessity to cope with this issue and from the importance of enforcing realistic constraints to the data inversion without being limited to (over)simplistic spatial constraints (for example, characterizing the smooth and/or sharp regularization). Accordingly, the present research demonstrates, by means of synthetic and field data, how the EMI inversion—based on realistic prior models—can be further enhanced by incorporating additional pre-existing pieces of information. While the proposed scheme is quite general, in the specific examples discussed here, these additional pieces of information are, respectively, a reference model along a line across the survey area, and an ERT section. The field EMI results were verified against extensive ground penetrating radar (GPR) measurements and boreholes.

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“…It has been used to investigate site stratigraphy (Papadopoulos et al ., 2006) and the sedimentological architecture (Yogeshwar et al ., 2019), to detect changes in lithology and geology (Laigre et al ., 2012; Scapozza and Laigre, 2014), depositional targets and buried structures (Papadopoulos et al ., 2007; Tsokas et al ., 2009; Supriyadi et al ., 2019; Cozzolino et al ., 2020), to map remnants of past human occupation (Thacker et al ., 2002; Matias et al ., 2006; Papadopoulos et al ., 2010; Berge and Drahor, 2011a,b; Tsokas et al ., 2018), to reconstruct palaeolandscapes (Papadopoulos et al ., 2014) as well as to detect offshore archaeological features (Sarris et al ., 2014; Tonkov, 2014; Simyrdanis et al ., 2015). ERT is also widely used to choose the most promising areas to excavate (Piroddi et al ., 2020).…”

Section: Introductionmentioning

confidence: 99%

Ground truth validated 3D electrical resistivity imaging of the archaeological deposits at Arma Veirana cave (northern Italy)

Torrese

Zucca

Martini³

et al. 2022

J Quaternary Science

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We present 3D electrical resistivity tomography (ERT) imaging of the archaeological deposits at Arma Veirana cave (northern Italy), to date only partially explored. The archaeological importance of the cave is due to the presence of a rich Mousterian layer, traces of Late Upper Palaeolithic (Epigravettian) temporary occupations and an Early Mesolithic burial of a female newborn. ERT is rarely employed in Palaeolithic cave contexts because Palaeolithic remains are typically disseminated in loose deposits and either do not possess high electrical resistivity contrasts or are too small to be detected. Furthermore, some issues can derive from the confined environment in caves. In this view, our study represents an opportunity to assess the capability of this geophysical method to retrieve subsurface information of Palaeolithic cave deposits and create a framework for the improvement of ERT applications in such a peculiar cave context. The aim of this study was to define the features of the deposits (i.e. geometry, thickness and sediment distribution) and to map the morphology of the underlying bedrock. Results reveal that the thickness of the deposits varies both along the primary axis of the cave and transverse to it. This study allowed the recognition of shallow, meter-sized, fine-grained sediment-filled structures with a longitudinal orientation with respect to the primary axis of the cave, as well as a possible erosional-like structure. The cross-validation of geophysical results with the archaeological evidence (the Early Mesolithic newborn burial and Epigravettian artefacts) confirms that the low-resistivity unit could be the most promising from an archaeological point of view.

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Automated Resistivity Profiling (ARP) to Explore Wide Archaeological Areas: The Prehistoric Site of Mont’e Prama, Sardinia, Italy

Cited by 20 publications

References 49 publications

The Role of Modern Techniques in Preservation of Archaeological Sites

The Role of Modern Techniques in Preservation of Archaeological Sites

Spreading of Localized Information across an Entire 3D Electrical Resistivity Volume via Constrained EMI Inversion Based on a Realistic Prior Distribution

Ground truth validated 3D electrical resistivity imaging of the archaeological deposits at Arma Veirana cave (northern Italy)

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