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https://hdl.handle.net/20.500.14279/18328
Title: | Optimal Spatial Resolution for the Detection and Discrimination of Archaeological Proxies in Areas with Spectral Heterogeneity | Authors: | Agapiou, Athos | Major Field of Science: | Engineering and Technology | Field Category: | Civil Engineering | Keywords: | Optimum spatial resolution;Remote sensing archaeology;Archaeological proxies;Simulation data;WorldView-2 | Issue Date: | 1-Jan-2020 | Source: | Remote Sensing, 2020, vol. 12, no.1, articl. no. 136 | Volume: | 12 | Issue: | 1 | Project: | Synergistic Use of Optical and Radar data for cultural heritage applications (PLACES) | Journal: | Remote Sensing | Abstract: | Subsurface targets can be detected from space-borne sensors via archaeological proxies, known in the literature as cropmarks. A topic that has been limited in its investigation in the past is the identification of the optimal spatial resolution of satellite sensors, which can better support image extraction of archaeological proxies, especially in areas with spectral heterogeneity. In this study, we investigated the optimal spatial resolution (OSR) for two different cases studies. OSR refers to the pixel size in which the local variance, of a given area of interest (e.g., archaeological proxy), is minimized, without losing key details necessary for adequate interpretation of the cropmarks. The first case study comprises of a simulated spectral dataset that aims to model a shallow buried archaeological target cultivated on top with barley crops, while the second case study considers an existing site in Cyprus, namely the archaeological site of “Nea Paphos”. The overall methodology adopted in the study is composed of five steps: firstly, we defined the area of interest (Step 1), then we selected the local mean-variance value as the optimization criterion of the OSR (Step 2), while in the next step (Step 3), we spatially aggregated (upscale) the initial spectral datasets for both case studies. In our investigation, the spectral range was limited to the visible and near-infrared part of the spectrum. Based on these findings, we determined the OSR (Step 4), and finally, we verified the results (Step 5). The OSR was estimated for each spectral band, namely the blue, green, red, and near-infrared bands, while the study was expanded to also include vegetation indices, such as the Simple Ratio (SR), the Atmospheric Resistance Vegetation Index (ARVI), and the Normalized Difference Vegetation Index (NDVI). The outcomes indicated that the OSR could minimize the local spectral variance, thus minimizing the spectral noise, and, consequently, better support image processing for the extraction of archaeological proxies in areas with high spectral heterogeneity | Description: | The author would like to acknowledge the “CUT Open Access Author Fund” for covering the open access publication fees of the paper | URI: | https://hdl.handle.net/20.500.14279/18328 | ISSN: | 2072-4292 | DOI: | 10.3390/rs12010136 | Rights: | © by the author. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license | Type: | Article | Affiliation : | Cyprus University of Technology ERATOSTHENES Centre of Excellence |
Funding: | . | Publication Type: | Peer Reviewed |
Appears in Collections: | Publications under the auspices of the EXCELSIOR H2020 Teaming Project/ERATOSTHENES Centre of Excellence |
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