Ground Penetrating Radar for Archeological Sites

Chapter Contents (Back)
Cultural Heritage. Archeological Sites. Archaeological Sites. Heritage. Buried Objects. Ground Penetrating. Radar. GPR.
See also Ground Penetrating Radar, Buried Objects.

Chen, F.[Fulong], Masini, N.[Nicola], Yang, R.X.[Rui-Xia], Milillo, P.[Pietro], Feng, D.[Dexian], Lasaponara, R.[Rosa],
A Space View of Radar Archaeological Marks: First Applications of COSMO-SkyMed X-Band Data,
RS(7), No. 1, 2014, pp. 24-50.
DOI Link 1502
And: Erratum: RS(8), No. 3, 2016, pp. 208.
DOI Link 1604

Stewart, C.[Christopher], Montanaro, R.[Rosanna], Sala, M.[Maura], Riccardi, P.[Paolo],
Feature Extraction in the North Sinai Desert Using Spaceborne Synthetic Aperture Radar: Potential Archaeological Applications,
RS(8), No. 10, 2016, pp. 825.
DOI Link 1609

Stewart, C.[Christopher],
Detection of Archaeological Residues in Vegetated Areas Using Satellite Synthetic Aperture Radar,
RS(9), No. 2, 2017, pp. xx-yy.
DOI Link 1703

Balz, T.[Timo], Caspari, G.[Gino], Fu, B.[Bihong], Liao, M.S.[Ming-Sheng],
Discernibility of Burial Mounds in High-Resolution X-Band SAR Images for Archaeological Prospections in the Altai Mountains,
RS(8), No. 10, 2016, pp. 817.
DOI Link 1609

Urban, T.M.[Thomas M.], Rasic, J.T.[Jeffrey T.], Alix, C.[Claire], Anderson, D.D.[Douglas D.], Manning, S.W.[Sturt W.], Mason, O.K.[Owen K.], Tremayne, A.H.[Andrew H.], Wolff, C.B.[Christopher B.],
Frozen: The Potential and Pitfalls of Ground-Penetrating Radar for Archaeology in the Alaskan Arctic,
RS(8), No. 12, 2016, pp. 1007.
DOI Link 1612

Cerra, D.[Daniele], Agapiou, A.[Athos], Cavalli, R.M.[Rosa Maria], Sarris, A.[Apostolos],
An Objective Assessment of Hyperspectral Indicators for the Detection of Buried Archaeological Relics,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805

Agapiou, A.[Athos], Sarris, A.[Apostolos],
Working with Gaussian Random Noise for Multi-Sensor Archaeological Prospection: Fusion of Ground Penetrating Radar Depth Slices and Ground Spectral Signatures from 0.00 m to 0.60 m below Ground Surface,
RS(11), No. 16, 2019, pp. xx-yy.
DOI Link 1909

Gabler, M.[Manuel], Trinks, I.[Immo], Nau, E.[Erich], Hinterleitner, A.[Alois], Paasche, K.[Knut], Gustavsen, L.[Lars], Kristiansen, M.[Monica], Tonning, C.[Christer], Schneidhofer, P.[Petra], Kucera, M.[Matthias], Neubauer, W.[Wolfgang],
Archaeological Prospection with Motorised Multichannel Ground-Penetrating Radar Arrays on Snow-Covered Areas in Norway,
RS(11), No. 21, 2019, pp. xx-yy.
DOI Link 1911

Catapano, I., Gennarelli, G., Ludeno, G., Soldovieri, F.,
Applying Ground-Penetrating Radar and Microwave Tomography Data Processing in Cultural Heritage: State of the art and future trends,
SPMag(36), No. 4, July 2019, pp. 53-61.
Ground penetrating radar, Inverse problems, Electromagnetic scattering, Data processing, Monitoring BibRef

Ghezzi, A.[Annalisa], Schettino, A.[Antonio], Pierantoni, P.P.[Pietro Paolo], Conyers, L.[Lawrence], Tassi, L.[Luca], Vigliotti, L.[Luigi], Schettino, E.[Erwin], Melfi, M.[Milena], Gorrini, M.E.[Maria Elena], Boila, P.[Paolo],
Reconstruction of a Segment of the UNESCO World Heritage Hadrian's Villa Tunnel Network by Integrated GPR, Magnetic-Paleomagnetic, and Electric Resistivity Prospections,
RS(11), No. 15, 2019, pp. xx-yy.
DOI Link 1908

Gustavsen, L.[Lars], Stamnes, A.A.[Arne Anderson], Fretheim, S.E.[Silje Elisabeth], Gjerpe, L.E.[Lars Erik], Nau, E.[Erich],
The Effectiveness of Large-Scale, High-Resolution Ground-Penetrating Radar Surveys and Trial Trenching for Archaeological Site Evaluations: A Comparative Study from Two Sites in Norway,
RS(12), No. 9, 2020, pp. xx-yy.
DOI Link 2005

Cornett, R.L.[Reagan L.], Ernenwein, E.G.[Eileen G.],
Object-Based Image Analysis of Ground-Penetrating Radar Data for Archaic Hearths,
RS(12), No. 16, 2020, pp. xx-yy.
DOI Link 2008

Capozzoli, L.[Luigi], Catapano, I.[Ilaria], de Martino, G.[Gregory], Gennarelli, G.[Gianluca], Ludeno, G.[Giovanni], Rizzo, E.[Enzo], Soldovieri, F.[Francesco], Scelza, F.U.[Francesco Uliano], Zuchtriegel, G.[Gabriel],
The Discovery of a Buried Temple in Paestum: The Advantages of the Geophysical Multi-Sensor Application,
RS(12), No. 17, 2020, pp. xx-yy.
DOI Link 2009

Bellanova, J.[Jessica], Calamita, G.[Giuseppe], Catapano, I.[Ilaria], Ciucci, A.[Alessandro], Cornacchia, C.[Carmela], Gennarelli, G.[Gianluca], Giocoli, A.[Alessandro], Fisangher, F.[Federico], Ludeno, G.[Giovanni], Morelli, G.[Gianfranco], Perrone, A.[Angela], Piscitelli, S.[Sabatino], Soldovieri, F.[Francesco], Lapenna, V.[Vincenzo],
GPR and ERT Investigations in Urban Areas: the Case-Study of Matera (Southern Italy),
RS(12), No. 11, 2020, pp. xx-yy.
DOI Link 2006

Chen, F.[Fen], Zhou, R.[Rui], van de Voorde, T.[Tim], Chen, X.Z.[Xing-Zhuang], Bourgeois, J.[Jean], Gheyle, W.[Wouter], Goossens, R.[Rudi], Yang, J.[Jian], Xu, W.B.[Wen-Bo],
Automatic detection of burial mounds (kurgans) in the Altai Mountains,
PandRS(177), 2021, pp. 217-237.
Elsevier DOI 2106
Kurgans, Stone mounds, Altai Mountains, Remote sensing archaeology, Object detection BibRef

Zhao, W.[Wenke], Yuan, L.[Lin], Forte, E.[Emanuele], Lu, G.[Guoze], Tian, G.[Gang], Pipan, M.[Michele],
Multi-Frequency GPR Data Fusion with Genetic Algorithms for Archaeological Prospection,
RS(13), No. 14, 2021, pp. xx-yy.
DOI Link 2107

Sanchez, G.M.[Gabriel M.], Grone, M.A.[Michael A.], Apodaca, A.J.[Alec J.], Byram, R.S.[R. Scott], Lopez, V.[Valentin], Jewett, R.A.[Roberta A.],
Sensing the Past: Perspectives on Collaborative Archaeology and Ground Penetrating Radar Techniques from Coastal California,
RS(13), No. 2, 2021, pp. xx-yy.
DOI Link 2101

Haridim, M.[Motti], Zemach, R.[Reuven],
Stochastic Processes Approach in GPR Applications,
GeoRS(60), 2022, pp. 1-10.
Stochastic processes, Correlation, Tools, Scattering, Q measurement, Solid modeling, Radar antennas, A-scan, B-scan, time ensemble (TE) correlation functions (TECFs) BibRef

Byram, S.[Scott], Sunseri, J.U.[Jun Ueno],
Principles and Practice of Investigating Buried Adobe Features with Ground-Penetrating Radar,
RS(13), No. 24, 2021, pp. xx-yy.
DOI Link 2112

El-Behaedi, R.[Raghda],
Detection and 3D Modeling of Potential Buried Archaeological Structures Using WorldView-3 Satellite Imagery,
RS(14), No. 1, 2022, pp. xx-yy.
DOI Link 2201

Shao, J.Z.[Ji-Zhong], Liu, G.[Guan], Yuan, H.[Hong], Song, Q.[Qize], Yang, M.G.[Min-Ge], Luo, D.[Dan], Zhang, X.S.[Xiao-Si], Tan, Y.R.[Yan-Ran], Zhang, Y.X.[Yu-Xin],
Evaluation and Scale Forecast of Underground Space Resources of Historical and Cultural Cities in China,
IJGI(11), No. 1, 2022, pp. xx-yy.
DOI Link 2201

Chias, P., Abad, T., Echeverria, E.,
Terrestrial and Aerial Ground-Penetrating Radar in Use for the Architectural Researches: Ancient 16th Century Water Supply and Drainage at the Monastery of El Escorial (Madrid, Spain),
HTML Version. 1311

Acar, U., Bayram, B., Cetin, H.I.,
An Approach to Find Localization of Non-Existent Historical Buildings By Terrestrial Photogrammetry,
DOI Link 1209

Chapter on Cartography, Aerial Images, Buildings, Roads, Terrain, Forests, Trees, ATR continues in
Large Scale Models, City Scale Models, City Models .

Last update:Jan 20, 2022 at 13:32:42