Browse > Article
http://dx.doi.org/10.7780/kjrs.2014.30.1.6

Airborne Hyperspectral Imagery availability to estimate inland water quality parameter  

Kim, Tae-Woo (Department of Spatial Information Engineering System, Pukyong University)
Shin, Han-Sup (Chungang-Aerosurvey Co. Ltd.)
Suh, Yong-Cheol (Department of Spatial Information Engineering System, Pukyong University)
Publication Information
Korean Journal of Remote Sensing / v.30, no.1, 2014 , pp. 61-73 More about this Journal
Abstract
This study reviewed an application of water quality estimation using an Airborne Hyperspectral Imagery (A-HSI) and tested a part of Han River water quality (especially suspended solid) estimation with available in-situ data. The estimation of water quality was processed two methods. One is using observation data as downwelling radiance to water surface and as scattering and reflectance into water body. Other is linear regression analysis with water quality in-situ measurement and upwelling data as at-sensor radiance (or reflectance). Both methods drive meaningful results of RS estimation. However it has more effects on the auxiliary dataset as water quality in-situ measurement and water body scattering measurement. The test processed a part of Han River located Paldang-dam downstream. We applied linear regression analysis with AISA eagle hyperspectral sensor data and water quality measurement in-situ data. The result of linear regression for a meaningful band combination shows $-24.847+0.013L_{560}$ as 560 nm in radiance (L) with 0.985 R-square. To comparison with Multispectral Imagery (MSI) case, we make simulated Landsat TM by spectral resampling. The regression using MSI shows -55.932 + 33.881 (TM1/TM3) as radiance with 0.968 R-square. Suspended Solid (SS) concentration was about 3.75 mg/l at in-situ data and estimated SS concentration by A-HIS was about 3.65 mg/l, and about 5.85mg/l with MSI with same location. It shows overestimation trends case of estimating using MSI. In order to upgrade value for practical use and to estimate more precisely, it needs that minimizing sun glint effect into whole image, constructing elaborate flight plan considering solar altitude angle, and making good pre-processing and calibration system. We found some limitations and restrictions such as precise atmospheric correction, sample count of water quality measurement, retrieve spectral bands into A-HSI, adequate linear regression model selection, and quantitative calibration/validation method through the literature review and test adopted general methods.
Keywords
Airborne Hyperspectral Imagery; Water Quality Estimation; Regression model; Empirical method; Simulated Landsat TM; Confuse Matrix;
Citations & Related Records
Times Cited By KSCI : 7  (Citation Analysis)
연도 인용수 순위
1 Ben-Dor, E., B. Kindel and A.F.H. Goetz, 2004. Quality assessment of several methods to recover surface reflectance using synthetic imaging spectroscopy data, Remote Sensing of Environment, 90: 389-404.   DOI   ScienceOn
2 Chang, A.J., Y.I. Kim, S.K. Choi, D.Y. Han, J.W. Choi, Y.M. Kim, Y.K. Han, H.L. Park, Wang B. and H.C. Lim, 2013. Construction and data analysis of Test-bed by hyperspectral airborne remote sensing, Korean Journal of Remote Sensing, 29 (2): 161-172.   과학기술학회마을   DOI   ScienceOn
3 Bochow, M., B. Heim, T. Kuster, C. Robaß, I. Bartsch, K. Segl and H. Kaufmann, 2012. Automatic detection and delineation of surface water bodies in airborne hyperspectral data, IEEE IGARSS, Munich Germany Jul. 22-27, pp.5226-5229.
4 Brekke, C. and A.H.S. Solberg, 2005. Oil spill detection by satellite remote sensing, Remote Sensing of Environment, 95: 1-13.   DOI   ScienceOn
5 Brown, C.D., M.V. Hoyer, R.W. Bachmann and D.E. Canfield Jr., 2000. Nutrient-chlorophyll relationships: an evaluation of empirical nutrient-chlorophyll models using Florida and north-temperate lake data, Canadian Journal of Fisheries and Aquatic Sciences, 57(8): 1574-1583.   DOI   ScienceOn
6 Choi, S.P. and I.T. Yang, 1998. Water quality elements extraction of lake by the Landsat TM Images, Journal of the Korean Society of Surveying, Geodesy, Photogrammetry, and Cartography, 16 (2): 225-233.   과학기술학회마을
7 Choi, E.Y., J.W. Lee and J.K. Lee, 2011. Estimating of chlorophyll-a concentrations in the Nakdong River using high-resolution satellite image, Korea Journal of Remote Sensing, 27(5): 613-623.   DOI   ScienceOn
8 Dekker, A.G., R.J. Vos and S.W.M. Peters, 2001. Comapriso of remote sensing data, model results and in situ data for total suspended mateer (TSM) in the sourthern Frisian lakes, The Science of the Total Environment 268: 197-214.   DOI   ScienceOn
9 Gmur, S., D. Vogt, D. Zabowski and L.M. Moskal, 2012. Hyperspectral Analysis of Soil Nitrogen, Carbon, Carbonate, and Organic Matter Using Regression Trees, Sensors, 12: 10639-10658.   DOI
10 Govender, M., K. Chetty and H. Bulcock, 2007. A review of hyperspectral remote sensing and its application in vegetation and water resource studies, Water SA, 33(2): 145-152
11 Hochberg, E.J. and M.J. Atkinson, 2003. Capabilities of remote sensing to classify coral, algae, and san as pure and mixed spectra, Remote Sensing of Environment, 85: 174-189.   DOI   ScienceOn
12 Im, S.H. and J.C. Jeong, 1999. Comparison between neural network and conventional statistical analysis methods for estimation of water quality using remote sensing, Journal of the Korean Society of Remote Sensing, 15(2): 107-117.   과학기술학회마을   DOI
13 Hakvoort, H., J. dede Hann, R. Jordans, R. Vos, S. Peters and M. Rijeboer, 2002. Towards airborne remote sensing of water quality in the Netherlands-validation and error analysis, J. Photogr. Remote Sens, 57: 171-183.   DOI   ScienceOn
14 Han, E.J., K.T. Kim, D.H. Jeong, S.Y. Cheon, S.J. Kim, S.J. Yu, J.Y. Hwang, T.S. Kim and M.H. Kim, 1998. Assessment of trophic state for Daecheong reservoir using Landsat TM Imagery data, Environmental Impact Assessment, 7(1): 81-91.   과학기술학회마을
15 Han, L., 1997. Spectral reflectance with varying suspended sediment concentrtions in clear and algar-laden waters, Photogrammetric Engineering & Remote Sensing, 63(6): 701-705.
16 Jang, D.H., G.H. Jo and G.H. Chi, 1998. The analysis of spectral characteristics of water quality factors using airborne MSS data. Journal of the Korean Society of Remote Sensing, 14(3): 295-306.
17 Jang, T.I., S.W. Park and S.M. Kim, 2003. The Analysis of water quality and tidal flow of a freshwater lake using Landsat images, Proc. of Korean Society of agricultural engineers Annual Conference. 1 Nov.
18 Jensen, R., P. Mausel, N. Dias, R. Gonser, C. Yang, J. Everitt and R. Fletcher, 2007. Spectral analysis of coastal vegetation and land cover using AISA+ hyperspectral data, Geocarto International, 22(1): 17-28.   DOI   ScienceOn
19 Jeong, J.C., 1999. Water quality evaluation for coastal waters and lake Sihwa using remote sensing Techniques, Seoul University, Ph.D Thesis.
20 Jeong, J.C., 2000. Distribution of surface temperature and chlorophyll-a in lake Soyang using remoter sensing techniques. Environmental Impact Assessment, 9(3): 177-183.
21 Kim, T.G., T.S. Kim, G.S. Cho and H.G. Kim, 1996. Analysis of chlorophyll reflectance and assessment of trophic state for Daecheong reserior using remote sensing, Journal of the Korea society for geo-spatial information system, 4(2): 35-45.   과학기술학회마을
22 Ji, S.B., 2013. Monitoring of reservoir water quality using Multi-temporal satellite imagery, Chongju University, Master Thesis.
23 Kim, H.G. and T.G. Kim, 1996. The water Quality Management of Daecheong Reservoir using remote sensing, Journal of Korean society of Environmental Engineering, 18(10): 1383-1396.
24 Kim, H.Y., 2009. The Proposal of Turbidity Criteria and Trophic State Index in Artificial Lakes, Ph.D Thesis, Chunbuk University, pp.16-25.
25 Koponen, S., J. Pulliainen, K. Kallio and M. Hallikainen, 2002. Lake water quality classification with airborne hyperspectral spectrometer and simulated MERIS data, Remote Sens. Environ, 79: 51-59.   DOI   ScienceOn
26 K-water, 2013. Technology Development of Algae Monitoring in river/lake, based on Remotely Sensed Image, Symposium on Future Technology, 26 September 2013, K-water institute, Daejeon, KOREA.
27 Kruse, F.A., 2002. Comparison between AVIRIS and Hyperion hyperspectral mineral mapping, Proceedings of the 11th JPL airborne earth science workshop, JPL Publication 03-4 December 2002, Pasadena, CA, pp.171-180.
28 Ostlund, C., P. Flink, N. Strombeck, D. Pierson and T. Lindell, 2001. Mapping of the water quality of Lake Erken, Sweden, from imaging spectrometry and Landsat Thematic Mapper, The Science of the Total Environment, 268: 139-154.   DOI   ScienceOn
29 Lee, G.H. and S.H. Lee, 2012, Monitoring of Floating Green Algae Using Ocean Color Satellite Remote Sensing, Journal of the Korean Association of Geographic Information Studies, 15(3): 137-147.   과학기술학회마을   DOI   ScienceOn
30 Lee, S.M., J.Y. Lee, K.H. Baek, J.W. Choi and Y.S. Kim. 2012. Hyperspectral Imaging (HSI) Application for detection of Organic Compounds in Water. Journal of Korean Society for Environmental Analysis. 15(3): 179-187.
31 Lim, H.J., 2003. Methodical study to perform enhanced verification of water temperature model using remote sensing, Ewha Womans University, Master Thesis.
32 Mazumder, A. and K.E. Havens, 1999. Nutrientchlorophyll- Secchi relationships under contrasting grazer communities of temperate versus subtropical lakes, Canadian Journal of Fisheries and Aquatic Sciences, 55(7): 1652-1662.   DOI
33 Myung, H.C., 2009. Verification, validation and application of image SNR distribution based upon nonlinear image sensor model using simulation, Korea Aerospace Research institute, 8(2): 160-169.
34 Selige, T., J. Bohner and U. Schmidhalter, 2006. High resolution topsoil mapping using hyperspectral image and field data in multivariate regression modeling procedures, Geoderma, 136(1-2): 235-244.   DOI   ScienceOn
35 Son, Y.B., Y.H. Kang and J.H. Ryu, 2012. Monitoring Red Tide in South Sea of Korea (SSK) using the Geostationary Ocean Color Imager (GOCI), Korean Journal of Remote Sensing, 28(5): 531-548.   과학기술학회마을   DOI   ScienceOn
36 Thiemann, S. and H. Kaufmann, 2002. Lake water quality monitoring using hyperspectral airborn data - a semiempirical multisensor and multitemporal approach for the Mecklenburg Lake District, Germany, Remote Sens. Environ, 81: 228-237.   DOI   ScienceOn
37 Sudduth, K.A., G.S. Jang, R.N. Lerch and E.J. Sadler, 2005. Estimating water quality with airborne and ground-based hyperspectral sensing, An ASAE Meeting Presentation Tampa Convertion Center, paper nubmer:052006.
38 Suh, Y.S, N.K. Lee, L.H. Jang, J.D. Hwang, S.J. Yoo and H.S. Lim, 2002. Characteristic response of the OSMI bands to estimate chlorophyll a, Korea Journal of Remote Sensing, 18(4):187-199.   과학기술학회마을   DOI
39 Szekielda, K.H., J.H. Bowles, D.B. Gills and W.D. Miller, 2009. Interpretation of absorption bands in airborne hyerpsepctral radiance data, Sensors, 9:2907-2925.   DOI   ScienceOn
40 Wang, J.P., S.T. Cheng and H. F. Jia, 2008. Application of artificial neural network technology in water color remote sensing inversion of inland water body using TM data, The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, Proc. of ISPRS congress, Istanbul.
41 Yoo, S.J. and J.C. Jeong, 1999. Perspectrives on the application of remote sensing for observation of Ocean Environments, Journal of Korean Society of Remote Sensing, 15(3): 277-288 (in Korean with English abstract).
42 Kim, T.W., G.J. We and Y.C. Suh, 2012. Correlation Analysis with Vegetation Indices and Vegetation- Endmembers from Airborne Hyperspectral Data in Forest Area, Journal of the Korean Association of Geographic Information Stuides, 15(3): 52-65.   과학기술학회마을   DOI   ScienceOn
43 Bistani, L.F.C., 2009. Identifying total phosphorus spectral signal on tropical estuary lagoon using an hyperspectral sensor and its application to water quality modeling, Ph.D Thesis, University of Puerto rico, pp. 109-113.