Browse > Article
http://dx.doi.org/10.7780/kjrs.2017.33.6.1.6

Observation on the Shoreline Changes Using Digital Aerial Imagery for Bangamoeri Beaches  

Yun, Kong-Hyun (Institute of Engineering Research, Yonsei University)
Song, Yeong Sun (Dept. of Aerial Geoinformatics, Inha Technical College)
Publication Information
Korean Journal of Remote Sensing / v.33, no.6_1, 2017 , pp. 971-980 More about this Journal
Abstract
In this research, it was presented that the strategic approach for the long-term shoreline changes using historic digital aerial images can be effective for the analysis on the bangameori beach, west coast of South Korea. For this purpose, we collected several historic digital aerial images over 9 years in the research filed and conducted GPS-VRS surveying for GCP (Ground Control Point) acquisition. Also we collected existing two dimensional shoreline digital map which was published by KHOA (Korea Hydrographic and Oceanographic Agency) in the year 2013. With these multi data sets, we provided quantitative analysis on coastal erosion using the long-term shoreline changes in the beach. Also, As the results it was found that 2m sea level was retreated in the research period with maximum 0.31m length.
Keywords
shoreline changes; digital aerial images; bangamoeri beach; coastal erosion;
Citations & Related Records
Times Cited By KSCI : 4  (Citation Analysis)
연도 인용수 순위
1 Goncalves, J.A. and R. Henriques, 2015. UAV photogrammetry for topographic monitoring of coastal areas, ISPRS Journal of Photogrammetry and Remote Sensing, 104: 101-111.   DOI
2 Horn, D. P., 2002. Mesoscale beach processes, Progress in Physical Geography, 26(2): 271-289.   DOI
3 Jang, D.H., M.K. Kim, and G.H. Kim, 2003. Change of the Sedimentary Environment system around the Baramarae Beach, Anmyeondo Area in West Coast of Korea, Journal of the Korean Geomorphological Association, 10(2): 143-155 (in Korean with English abstract).
4 Jang, S.W., S.K. Lee, and H.J. Yeoun, 2011. Detection of Marine Debris by using Unmanned Aerial Photograph, Journal of the Korean Society Of Marine Environment & Safety, 17(4): 307-314 (in Korean with English abstract).   DOI
5 Jung, S.H., H.M. Lim, and J.K. Lee, 2010. Acquisition of 3D Spatial Information using UAV Photogrammetric Method, Journal of the Korean Society of Surveying, Geodesy, Photogrammetry and Cartography, 28(1): 161-167 (in Korean with English abstract).
6 Kim, B., K. Yun, and C. Lee, 2014. The Use of Elevation Adjusted Ground Control Points for Aerial Triangulation in Coastal Areas, KSCE Journal of Civil Engineering, 18(6): 1825-1830 (in Korean with English abstract).   DOI
7 Kim, J. and D. Jang, 2011. Time-series Analysis of Baramarae Beach in Anmyeondo Using Aerial Photographs and Field Measurement Data, Journal of The Geomophological Association, 18(2): 39-51 (in Korean with English abstract).
8 Kim, Y.S., N.W. Park, D.H. Jang, and H.Y. Yoo, 2013. Error Analysis of Waterline-based DEM in Tidal Flats and Probabilistic Flood Vulnerability Assessment using Geostatistical Simulation, Journal of the Korean Geomorphological Association, 20(4): 85-99 (in Korean with English abstract).
9 Lee, K., J. Choi, and C.-H. Joh, 2015. Method to Extract Coastline Changes Using Unmanned Aerial Vehicle, Journal of the Korean Geographical Society, 50(5): 473-483 (in Korean with English abstract).
10 Mitasova, H., T.G. Drake, R.S. Harmon, and D. Bernstein, 2004. Quantifying rapid changes in coastal topography using modern mapping techniques and Geographic Information System, Environmental and Engineering Geoscience, 10(1): 1-11.   DOI
11 Mitasova, H., M.F. Overton, J.J. Recalde, D.J. Bernstein, and C.W. Freeman, 2009. Raster - Based analysis of coastal terrain dynamics from multitemporal LIDAR data, Journal of Coastal Research, 25(2): 507-514.   DOI
12 Mills, J. P., S. J. Buckley, and H. L. Mitchell, 2003. Synergistic fusion of GPS and photogrammetrically generated elevation models, Photogrammetric Engineering and Remote Sensing, 69(4): 341-349.   DOI
13 Moore, L. J., 2000. Shoreline mapping techniques, Journal of Coastal Research, 16(1): 111-124.
14 Ruggiero, P., G.M. Kaminsky, and G. Gelfenbaum, 2003. Linking proxy-based and datum-based shorelines on a high-Energy coastline: implications for shoreline change analyses, Journal of Coastal Research, 38: 57-82.
15 Kim, K., J. Ryu, S. Kim, and J. Choi, 2010. Application of SAR data to the study on the characteristics of sedimentary environments in a tidal flat, Korean Journal of Remote Sensing, 26(5): 497-510 (in Korean with English abstract).   DOI
16 White, S.A. and Y. Wang, 2003. Utilizing DEMs derived from LIDAR data to analyse morphologic change in the North Carolina coastline, Remote Sensing of Environment, 85(1): 39-47.   DOI
17 Sallenger Jr, A.H., W.B. Krabill, R.N. Swift, J. Brock, J. List, M. Hansen, R.A. Holman, S. Manizade, J. Sontag, A. Meredith, K. Morgan, J.K. Yunkel, E.B. Frederick, and H. Stockdon, 2003. Evaluation of airborne topographic lidar for quantifying beach changes, Journal of Coastal Research, 19(1): 125-133.
18 Thieler, E.R., E.A. Himmelstoss, J.L. Zichichi, and A. Ergul, 2009. Digital Shoreline Analysis System (DSAS) version 4.0 - An ArcGIS extension for calculating shoreline change, U.S. Geological Survey Open-File Report No. 2008-1278.
19 U.S. Army, 1971. Report on the national shoreline study, U.S. Army Corps Engineers, Washington, DC.
20 Zhang, Y., X. Xiong, X. Shen, and Z. Ji, 2012. Bundle block adjustment of weakly connected aerial imagery, Photogrammetric Engineering and Remote Sensing, 78(9): 983-989.   DOI
21 Zhen Xu, D. Kim, and S. H. Kim, 2013. Research of Topography Changes by Artificial Structures and Scattering Mechanism in Yoobu-Do Intertidal Flat Using Remote Sensing Data, Korean Journal of Remote Sensing, 29(1): 57-68 (in Korean with English abstract).   DOI