Geomorphometric Methods for Burial Mound Recognition and Extraction from High Resolution LiDAR DEMs

Niculiţă, Mihai

doi:10.20944/preprints202002.0074.v1

Cited by 6 publications

(1 citation statement)

References 25 publications

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“…Different researchers have already focused on archaeological evidence detection at a raster/2D level (Figure 1), adopting machine learning (Freeland et al, 2016;Guyot et al, 2018;Niculiță, 2020;Rom et al, 2020) and deep learning (Albrecht et al, 2019;Trier et al, 2021) strategies, whereas only a few studies aimed at automatic filtering/segmenting point clouds (Hu and Yuan, 2016;Geveart et al, 2018;Bulatov et al, 2021). Generalisation and transferability capabilities are also evaluated.…”

Section: Related Workmentioning

confidence: 99%

Seeing Among Foliage With Lidar and Machine Learning: Towards a Transferable Archaeological Pipeline

Mazzacca

Grilli

Cirigliano

et al. 2022

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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Abstract. Airborne LiDAR technology has become an essential tool in archaeology during the last two decades since it allows archaeologists to measure and map items or structures that would otherwise be hidden under vegetation. In order to detect and characterise the archaeological evidence, it is a common practice to extract accurate digital terrain models (DTM) by filtering out the vegetation from Airborne Laser Scanning (ALS) datasets. Although previous approaches have performed well in ALS filtration, they are still subject to several variables (flight height, forest cover, type of sensors utilised, etc.) and are frequently integrated into expensive commercial software or customised for specific locations. This study presents a workflow for treating ALS archaeological datasets using machine learning algorithms for both filtering the vegetation and detecting hidden structures. The workflow is applied to two different archaeological environments (in terms of structures, vegetation, landscape, point density), and results demonstrate that the pipeline is rapid and accurate, and the prediction model is transferable.

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Section: Related Workmentioning

confidence: 99%

Seeing Among Foliage With Lidar and Machine Learning: Towards a Transferable Archaeological Pipeline

Mazzacca

Grilli

Cirigliano

et al. 2022

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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Documentation of Archaeology-Specific Workflow for Airborne LiDAR Data Processing

Lozić

Štular

2021

Geosciences

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Airborne LiDAR is a widely accepted tool for archaeological prospection. Over the last decade an archaeology-specific data processing workflow has been evolving, ranging from raw data acquisition and processing, point cloud processing and product derivation to archaeological interpretation, dissemination and archiving. Currently, though, there is no agreement on the specific steps or terminology. This workflow is an interpretative knowledge production process that must be documented as such to ensure the intellectual transparency and accountability required for evidence-based archaeological interpretation. However, this is rarely the case, and there are no accepted schemas, let alone standards, to do so. As a result, there is a risk that the data processing steps of the workflow will be accepted as a black box process and its results as “hard data”. The first step in documenting a scientific process is to define it. Therefore, this paper provides a critical review of existing archaeology-specific workflows for airborne LiDAR-derived topographic data processing, resulting in an 18-step workflow with consistent terminology. Its novelty and significance lies in the fact that the existing comprehensive studies are outdated and the newer ones focus on selected aspects of the workflow. Based on the updated workflow, a good practice example for its documentation is presented.

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Detection, Morphometric Analysis and Digital Surveying of Archaeological Mounds in Southern Iraq with CartoSat-1 and COSMO-SkyMed DEMs

Tapete

Cigna

2022

Land

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In Near and Middle Eastern archaeology, satellite-derived digital elevation models (DEM) of medium spatial resolution (≥30 m) are mostly used to locate and map archaeological mounds (namely ‘tells’), whereas high resolution DEMs (≤10 m) are still poorly exploited. To fill this gap, the 5 m resolution CartoSat-1 Euro-Maps 3D Digital Surface Model (DSM) is assessed vs. the 30 m Shuttle Radar Topography Mission (SRTM) global DEM, the Advanced Land Observing Satellite (ALOS) World 3D–30 m (AW3D30) and a 10 m COSMO-SkyMed DEM, on a test area in Wasit, southern Iraq, where the high density of tells is yet to be exhaustively documented. A total of 344 sites was mapped, with one order of magnitude improvement compared to previous mapping exercises, existing databases and historical maps. The morphometric analysis not only highlights the reliability of CartoSat-1 DSM height and volume estimates, but also suggests that, in the test area, the volume of a tell can robustly be calculated based on the simple knowledge of its basal area, following a quadratic function. Morphology and elevation of at least 53% irregularly shaped tells were impacted by anthropogenic disturbances. Morphometric indices (e.g., Topographic Position Index, DEViation from mean elevation) are a viable automated method to ease tells detection. When integrated with other satellite datasets (e.g., CORONA, Google Earth, Sentinel-2 imagery), the CartoSat-1 DSM can unveil morphological changes and support condition assessment. In Wasit, agriculture and modern development are among the major threats for tells preservation, alongside looting.

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Geomorphometric Methods for Burial Mound Recognition and Extraction from High Resolution LiDAR DEMs

Cited by 6 publications

References 25 publications

Seeing Among Foliage With Lidar and Machine Learning: Towards a Transferable Archaeological Pipeline

Seeing Among Foliage With Lidar and Machine Learning: Towards a Transferable Archaeological Pipeline

Documentation of Archaeology-Specific Workflow for Airborne LiDAR Data Processing

Detection, Morphometric Analysis and Digital Surveying of Archaeological Mounds in Southern Iraq with CartoSat-1 and COSMO-SkyMed DEMs

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