[1] Rosegrant, M. W. Cai, X. and S. A. Cline, World water and food to 2025: dealing with scarcity: Intl Food Policy Res Inst, 2002.
[2] Postel,S., The Last Oasis: Facing Water Scarcity: Routledge, 2014.
[3] Viessman, W., Hammer, M. J.E. M. Perez, and P. A. Chadik, “Water Supply and Pollution Control,” 1998.
[4] Sowers, J.,Vengosh, A. and Weinthal, E. “Climate Change, Water Resources, and the Politics of Adaptation in the Middle East and North Africa,” Climatic Change, vol. 104, 2011, pp. 599-627.
[5] Glasgow, H.B., Burkholder, J.M.,Reed, R.E., Lewitus, A.J. and Kleinman, J.E., “Real-Time Remote Monitoring of Water Quality: A Review of Current Applications, and Advancements in Sensor, Telemetry, and Computing Technologies,” Journal of Experimental MarineBiology and Ecology, vol. 300, 2004, pp. 409-448.
[6] Goel, P. Water pollution: causes, effects and control: New Age International, 2006.
[7] Gorchev, H.G., Ozolins, G., “Who Guidelines for Drinking-Water Quality,” WHO Chronicle, vol. 38, No. 3, 2011, pp. 104-108.
[8] Flanagan, P.J.,Parameters of Water Quality: Interpretation and Standards, vol. 6: An Foras Forbartha. Information and Training Centre, 1986.
[9] Estandard 822-F-18-001, 2018 Edition of the Drinking WaterStandards and Health Advisories, Office of Water U.S. Environmental Protection Agency Washington, DC, March 2018.
[10] Iran Institute of Standards and Industrial Research, drinking water - National Standard No. 1053, physical and chemical characteristics, 2019 (In Persian).
[11]Environmental Protection Organization, Human Environment Deputy, Iran Water Quality Standard, 2015 (In Persian).
[12] Chang, N.-B., Imen, S. and Vannah, B., “Remote Sensing for Monitoring Surface Water Quality Status and Ecosystem State in Relation to The Nutrient Cycle: A 40-Year Perspective,” Critical Reviews in Environmental Science and Technology, vol. 45, 2015, pp. 101-166.
[13] Gholizadeh, M., Melesse, A. and Reddi, L. “A Comprehensive Review on Water Quality Parameters Estimation using Remote Sensing Techniques,” Sensors, vol. 16, 2016, p. 1298.
[14]J. C. Ritchie, P. V. Zimba, and J. H. Everitt, “Remote Sensing Techniques to Assess Water Quality,” Photogrammetric Engineering & Remote Sensing, vol. 69, pp. 695-704, 2003.
[15] M. Oxford, “Remote Sensing of Suspended Sediments in Surface Waters,” Photogrammetric Engineering and Remote Sensing, vol. 42, pp. 1539-1545, 1976.
[16] Gitelson, A., “The Peak Near 700 nm on Radiance Spectra of Algae and Water: Relationships of its Magnitude and Position with Chlorophyll Concentration,” International Journal of Remote Sensing, vol. 13, 1992, pp. 3367-3373.
[17] Han, L. and Jordan, K.J,.“Estimating and Mapping Chlorophyll‐a Concentration in Pensacola Bay, Florida using Landsat ETM+ Data,” International Journal of Remote Sensing, vol. 26, 2005, pp. 5245-5254.
[18] Dekker, A.G., Malthus, T.J. and Seyhan, E.,“Quantitative Modelingof Inland Water Quality for High-Resolution MSS Systems,” IEEE Transactions on Geoscience and Remote Sensing, vol. 29, 1991, pp. 89-95.
[19] Kishino, M.,Ishimaru, T., Furuya, K.,Oishi, T. and Kawasaki, K.,“In-water Algorithms for ADEOS/OCTS,”Journal of Oceanography, vol. 54, 1998, pp. 431-436.
[20] Keiner, L.E. and Yan, X.-H.,“A Neural Network Model for Estimating Sea Surface Chlorophyll and Sediments from Thematic Mapper Imagery,”Remote Sensing of Environment, vol. 66, 1998, pp. 153-165.
[21] Chang, N.-B.,Daranpob, A.,Yang, Y. J. and Jin, K.-R.“Comparative Data Mining Analysis for Information Retrieval of MODIS Images: Monitoring Lake Turbidity Changes At Lake Okeechobee, Florida,” Journal of Applied Remote Sensing, vol. 3, 2009, p. 033549.
[22] Wang, H.,Fan, T.,Shi, A., Huang, F. and Wang, H., “Fuzzy Integral Based Information Fusion for Water Quality Monitoring Using Remote Sensing Data,” International Journal of Communications, Network and System Sciences, vol. 3, 2010, p. 737.
[23] Ahn,Y.-H., “Development of an Inverse Model from Ocean Reflectance,” Marine Technology Society Journal, vol. 33, 1999, pp. 69-80.
[24] Dekker, A.,Vos, R. and Peters, S., “Comparison of Remote Sensing Data, Model Results and in Situ Data for Total Suspended Matter (TSM) in the Southern Frisian Lakes,” Science of the Total Environment, vol. 268, 2001, pp. 197-214.
[25] Dekker, A.,Zamurović-Nenad, Ž.,Hoogenboom, H. and Peters, S., “Remote Sensing, Ecological Water Quality Modelling and in Situ Measurements: a Case Study in Shallow Lakes,” Hydrological sciences journal, vol. 41, 1996, pp. 531-547.
[26] Ciotti, Á.M., Cullen, J.J. and Lewis, M.R., “A Semi‐Analytical Model of the Influence of Phytoplankton Community Structure on the Relationship between Light Attenuation and Ocean Color,” Journal of Geophysical Research: Oceans, vol. 104, 1999, pp. 1559-1578.
[27] Lal, R., Soil Erosion Research Methods: CRC Press, 1994.
[28] Robinson, A., “Sediment, our greatest pollutant?,” Focus on Environmental Geology. R. Tank, ed, 1976.
[29] Schalles, J.F., Schiebe, F.R. and Starks, P.J., “Estimation of Algal and Suspended Sediment Loads (Singly and Combined) Using Hyperspectral Sensors and Integrated Mesocosm Experiments,” Environmental Research Institute of Michigan, Ann Arbor, MI (United States)1997.
[30] Everitt, J.,Yang, C., Escobar, D.,Webster, C.,Lonard, R. and Davis, M., “Using Remote Sensing and Spatial Information Technologies to Detect and Map Two Aquatic Macrophytes,” Journal of Aquatic Plant Management, vol. 37, 1999, pp. 71-80.
[31] Harrington, J. and Repic, R., “Hyperspectral and Video Remote Sensing of Oklahoma Lakes,” Papers and Proceedings of Applied Geography Conferences, 1995, pp. 79-86.
[32] Dekker, A. and Peters, S., “The use of the Thematic Mapper for the Analysis of Eutrophic Lakes: a Case Study in the Netherlands,” International Journal of Remote Sensing, vol. 14, 1993, pp. 799-821.
[33] Aiken, G.R., “Humic Substances in Soil, Sediment, and Water: Geochemistry, Isolation, and Characterization,” 1985.
[34] Mobley, C.D.,Light and water: radiative transfer in natural waters: Academic press, 1994.
[35] Wu, M.,Zhang, W.,Wang, X. and Luo, D., “Application of MODIS Satellite Data in Monitoring Water Quality Parameters of Chaohu Lake in China,” Environmental monitoring and assessment, vol. 148, 2009, pp. 255-264.
[36] Ahn, Y.-H., Shanmugam, P., Lee, J.-H., and Kang, Y.Q., “Application of Satellite Infrared Data for Mapping of Thermal Plume Contamination in Coastal Ecosystem of Korea,”Marine environmental research, vol. 61, 2006, pp. 186-201.
[37] Giardino, C., Pepe, M., Brivio, P.A.,Ghezzi, P. and Zilioli, E., “Detecting Chlorophyll, Secchi Disk Depth and Surface Temperature in a Sub-Alpine Lake using Landsat Imagery,” Science of the Total Environment, vol. 268, 2001, pp. 19-29.
[38] Ramasamy, S.,Venkatasubramanian, V., Sam, K. and Chandrasekhar, G., “Remote Sensing in Pollution Monitoring in Cauvery River,” Remote Sensing in Water Resources; Rawat Publications: New Delhi, India, 2005.
[39] Bhattf, A.M., Rundquist, D.,Schalles, J. andRamirez, L., “Application of Hyperspectral Remotely Sensed Data for Water Quality Monitoring: Accuracy and Limitation,” 9th International Symposium on Spatial Accuracy Assessment in Natural Resources and Environmental Sciences, Accuracy 2010, 2010.
[40] Lim, J. and Choi, M., “Assessment of Water Quality Based on Landsat 8 Operational Land Imager Associated with Human Activities in Korea,” Environmental monitoring and assessment, vol. 187, 2015, p. 384.
[41] Zhang, C. and Han, M., “Mapping Chlorophyll-A Concentration in Laizhou Bay using Landsat 8 Oli Data,” Proceedings of the 36th IAHR World Congress, Netherland, 2015.
[42] Kim, S.-i., Kim, H.-c. and Hyun, C.-U., “High Resolution Ocean Color Products Estimation in Fjord of Svalbard, Arctic Sea Using Landsat-8 Oli," Korean Journal of Remote Sensing, vol. 30, 2014, pp. 809-816.
[43] Giardino, C., Bresciani, M., Cazzaniga, I., Schenk, K., Rieger, P., Braga, F., Matta, E. and Brando, V. E., “Evaluation of Multi-Resolution Satellite Sensors for Assessing Water Quality and Bottom Depth of Lake Garda,”Sensors, vol. 14, 2014, pp. 24116-24131.
[44] Hellweger, F., Schlosser, P., Lall, U. and Weissel, J., “Use of Satellite Imagery for Water Quality Studies in New York Harbor,” Estuarine, Coastal and Shelf Science, vol. 61, 2004, pp. 437-448.
[45] Kloiber, S.M., Brezonik, P.L. and Bauer, M.E., “Application of Landsat Imagery to Regional-Scale Assessments of Lake Clarity,”Water Research, vol. 36, 2002, pp. 4330-4340.
[46] Olmanson, L.G., Bauer, M.E. and Brezonik, P.L.,“A 20-year Landsat Water Clarity Census of Minnesota's 10,000 Lakes,”Remote Sensing of Environment, vol. 112, 2008, pp. 4086-4097.
[47] Allan, M.G.,Hamilton, D.P.,Hicks, B.J. and Brabyn, L., “Landsat remote sensing of chlorophyll a Concentrations in Central North Island Lakes of New Zealand,” International Journal of Remote Sensing, vol. 32, 2011, pp. 2037-2055.
[48] J. Xu, C. Fang, D. Gao, H. Zhang, C. Gao, Z. Xu, and Y. Wang, “Optical Models For Remote Sensing of Chromophoric Dissolved Organic Matter (CDOM) absorption in Poyang Lake,” ISPRS Journal of Photogrammetry and Remote Sensing, vol. 142, 2018, pp. 124-136.
[49] F. L. Lobo, M. p. Costa, and E. M. Novo, “Time-Series Analysis of Landsat-MSS/TM/OLI Images Over Amazonian Waters Impacted by Goldmining Activities,” Environ, vol. 157, 2015, pp. 170-184.
[50] Matthews, M.W., Bernard, S. and Winter, K.,“Remote Sensing of Cyanobacteriadominant Algal Blooms and Water Quality Parameters in Zeekoevlei, a Small Hypertrophic Lake, using MERIS,” Remote Sens. Environ, vol. 114, 2010, pp. 2070-2087.
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