Abstract:Until recently, archeological prospection using LiDAR data was based mainly on expertbased and time-consuming visual analyses. Currently, deep learning convolutional neural networks (deep CNN) are showing potential for automatic detection of objects in many fields of application, including cultural heritage. However, these computer-vision based algorithms remain strongly restricted by the large number of samples required to train models and the need to define target classes before using the models. Moreover, t… Show more
“…This process might unintentionally rein- The detection of all archaeological objects of interest within an certain area would require either many different models, a model detecting a multitude of classes or a model that detects a more general class of 'archaeological anomalies'. Recently, attempts at developing the latter have been made (Guyot et al, 2021). However, questions remain how applicable these models are in complex terrain, for example, the Veluwe, where many objects of confusion are present, and how useful such a catch-all category would be in terms of both archaeological research and heritage management (see Trier et al, 2019).…”
Section: Combined Human-computer Strategies For Large-scale Mappingmentioning
confidence: 99%
“…A major advantage of CNNs is the possibility to use transfer‐learning (Razavian et al., 2014), where a CNN is pre‐trained on a large, generic dataset and subsequently is fine‐tuned on a small, specific dataset. In archaeology, transfer‐learning has been successfully implemented on different types of remotely sensed data from Europe (Bonhage et al., 2021; Gallwey et al., 2019; Guyot et al., 2021; Kazimi et al., 2019; Trier et al., 2019; Verschoof‐van der Vaart & Lambers, 2019; Verschoof‐van der Vaart et al., 2020; Verschoof‐van der Vaart & Landauer, 2021; Zingman, 2016; Zingman et al., 2016) and further abroad (Bundzel et al., 2020; Caspari & Crespo, 2019; Somrak et al., 2020; Soroush et al., 2020; Trier et al., 2018, 2021). To date these approaches are generally tested in an (ideal) experimental setting but have not been applied in different contexts or ‘in the wild’, that is, incorporated in archaeological prospection, although the latter is the main aim of most initiatives (see Trier et al., 2019).…”
Within archaeological prospection, Deep Learning algorithms are developed to detect objects within large remotely sensed datasets. These approaches are generally tested in an (ideal) experimental setting but have not been applied in different contexts or 'in the wild', that is, incorporated in archaeological prospection. This research explores the applicability, knowledge discovery-on both a quantitative and qualitative level-and efficiency gain resulting from employing an automated detection tool called WODAN within (Dutch) archaeological practice. WODAN has been used to detect barrows and Celtic fields in LiDAR data from the Dutch Midden-Limburg area, which differs in archaeology, geo-(morpho)logy and land-use from the Veluwe in which it was developed. The results show that WODAN was able to detect potential barrows and Celtic fields, including previously unknown examples, and provided information about the structuring of the landscape in the past. Based on the results, combined human-computer strategies are argued, in which automated detection has a complementary, rather than a substitute role, to manual analysis. This can offset the inherent biases in manual analysis and deal with the problem that current automated detection methods only detect objects similar to the pre-defined target class(es). The incorporation of automated detection into archaeological prospection, in which the results of automated detection are used to highlight areas of interest and to enhance and add detail to existing archaeological predictive maps, seems logical and feasible.
“…This process might unintentionally rein- The detection of all archaeological objects of interest within an certain area would require either many different models, a model detecting a multitude of classes or a model that detects a more general class of 'archaeological anomalies'. Recently, attempts at developing the latter have been made (Guyot et al, 2021). However, questions remain how applicable these models are in complex terrain, for example, the Veluwe, where many objects of confusion are present, and how useful such a catch-all category would be in terms of both archaeological research and heritage management (see Trier et al, 2019).…”
Section: Combined Human-computer Strategies For Large-scale Mappingmentioning
confidence: 99%
“…A major advantage of CNNs is the possibility to use transfer‐learning (Razavian et al., 2014), where a CNN is pre‐trained on a large, generic dataset and subsequently is fine‐tuned on a small, specific dataset. In archaeology, transfer‐learning has been successfully implemented on different types of remotely sensed data from Europe (Bonhage et al., 2021; Gallwey et al., 2019; Guyot et al., 2021; Kazimi et al., 2019; Trier et al., 2019; Verschoof‐van der Vaart & Lambers, 2019; Verschoof‐van der Vaart et al., 2020; Verschoof‐van der Vaart & Landauer, 2021; Zingman, 2016; Zingman et al., 2016) and further abroad (Bundzel et al., 2020; Caspari & Crespo, 2019; Somrak et al., 2020; Soroush et al., 2020; Trier et al., 2018, 2021). To date these approaches are generally tested in an (ideal) experimental setting but have not been applied in different contexts or ‘in the wild’, that is, incorporated in archaeological prospection, although the latter is the main aim of most initiatives (see Trier et al., 2019).…”
Within archaeological prospection, Deep Learning algorithms are developed to detect objects within large remotely sensed datasets. These approaches are generally tested in an (ideal) experimental setting but have not been applied in different contexts or 'in the wild', that is, incorporated in archaeological prospection. This research explores the applicability, knowledge discovery-on both a quantitative and qualitative level-and efficiency gain resulting from employing an automated detection tool called WODAN within (Dutch) archaeological practice. WODAN has been used to detect barrows and Celtic fields in LiDAR data from the Dutch Midden-Limburg area, which differs in archaeology, geo-(morpho)logy and land-use from the Veluwe in which it was developed. The results show that WODAN was able to detect potential barrows and Celtic fields, including previously unknown examples, and provided information about the structuring of the landscape in the past. Based on the results, combined human-computer strategies are argued, in which automated detection has a complementary, rather than a substitute role, to manual analysis. This can offset the inherent biases in manual analysis and deal with the problem that current automated detection methods only detect objects similar to the pre-defined target class(es). The incorporation of automated detection into archaeological prospection, in which the results of automated detection are used to highlight areas of interest and to enhance and add detail to existing archaeological predictive maps, seems logical and feasible.
“…The increasing availability of large-scale lidar, satellite, and aerial imagery on local, regional, and national scales, however, is transforming archaeology around the globe—particularly the searching and mapping of archaeological sites (Figure 2). ML algorithms can be used to process the geospatial data in the search for sites in diverse environments (Bonhage et al 2021; Caspari and Crespo 2019; Davis 2019; Davis, DiNapoli, et al 2020; Davis, Seeber, et al 2020; Evans and Hofer 2019; Guyot et al 2018, 2021; Orengo et al 2020; Soroush et al 2020; Thabeng et al 2019; Trier et al 2018, 2019; Verschoof-van der Vaart and Lambers 2019; Verschoof-van der Vaart et al 2020). FIGURE 2.An illustrative fictional example of how machine learning may be applied to feature identification in geospatial data and the reconstruction of a site.…”
OverviewMachine learning (ML) is rapidly being adopted by archaeologists interested in analyzing a range of geospatial, material cultural, textual, natural, and artistic data. The algorithms are particularly suited toward rapid identification and classification of archaeological features and objects. The results of these new studies include identification of many new sites around the world and improved classification of large archaeological datasets. ML fits well with more traditional methods used in archaeological analysis, and it remains subject to both the benefits and difficulties of those approaches. Small datasets associated with archaeological work make ML vulnerable to hidden complexity, systemic bias, and high validation costs if not managed appropriately. ML's scalability, flexibility, and rapid development, however, make it an essential part of twenty-first-century archaeological practice. This review briefly describes what ML is, how it is being used in archaeology today, and where it might be used in the future for archaeological purposes.
“…It has experimented with geospatial data/images (satellite, aerial, lidar), texts, categorical tableau data, point clouds, and other datasets. For instance, one can consider some indicative examples such as the work that has been done on bone classification [1], remote sensing archaeology [2][3][4][5][6][7][8][9][10][11][12], geophysical prospection [13][14][15][16][17], detection of objects in paintings [18], classification of pottery [19], and the 3D reconstruction of heritage buildings [20]. The main reason behind this growing trend, which has been noticed in the last five years in all scientific domains, underlies the nuisance generated when dealing with multivariate analysis of high-volume datasets, which are challenging to process and interpret.…”
Ground penetrating radar (GPR) is a well-established technique used in archaeological prospection and it requires a number of specialized routines for signal and image processing to enhance the data acquired and lead towards a better interpretation of them. Computer-aided techniques have advanced the interpretation of GPR data, dealing with a wide range of operations aiming towards locating, imaging, and diagnosis/interpretation. This article will discuss the novel and recent applications of machine learning (ML) and deep learning (DL) techniques, under the artificial intelligence umbrella, for processing GPR measurements within archaeological contexts, and their potential, limitations, and possible future prospects.
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