This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Abayazid, H., 2015. Assessment of temporal and spatial alteration in coastal lakes-Egypt. In: Proceedings of the eighteenth International Water Technology Conference (IWTC 2015), Sharm El Sheikh, 12–14 Mar 2015, 598–608.AbayazidH.2015Assessment of temporal and spatial alteration in coastal lakes-Egypt. In:Proceedings of the eighteenth International Water Technology Conference (IWTC 2015)Sharm El Sheikh, 12–14 Mar2015598608Search in Google Scholar
Abayazid, H., El-Gamal, A., 2017. Employing remote sensing for water clarity monitoring in the Nile Delta coast. International Water Technology Journal IWTJ 7(4), 265-277.AbayazidH.El-GamalA.2017Employing remote sensing for water clarity monitoring in the Nile Delta coastInternational Water Technology Journal IWTJ74265277Search in Google Scholar
Akbar, T., Hassan, Q., Achari, G., 2010. A remote sensing based framework for predicting water quality of different source waters. International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences 34, Part XXX.AkbarT.HassanQ.AchariG.2010A remote sensing based framework for predicting water quality of different source watersInternational Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences34, Part XXXSearch in Google Scholar
Bilge, F., Yazici, B., Dogeroglu, T., Ayday, C., 2003. Statistical evaluation of remotely sensed data for water quality monitoring. International Journal of Remote Sensing 24(24), 5317–5326.BilgeF.YaziciB.DogerogluT.AydayC.2003Statistical evaluation of remotely sensed data for water quality monitoringInternational Journal of Remote Sensing24245317532610.1080/0143116031000156828Search in Google Scholar
Brezonik, P., Menken, K.D., Bauer, M., 2005. Landsat-based remote sensing of lake water quality characteristics, including chlorophyll and colored dissolved organic matter (CDOM). Lake Reserv. Manag. 21, 373–382.BrezonikP.MenkenK.D.BauerM.2005Landsat-based remote sensing of lake water quality characteristics, including chlorophyll and colored dissolved organic matter (CDOM)Lake Reserv. Manag.2137338210.1080/07438140509354442Search in Google Scholar
Brivio, P., Giardino, C., Zilioli, E., 2001. Determination of chlorophyll concentration changes in Lake Garda using an image-based reductive transfer code for landsat TM images. International Journal of Remote Sensing 22(2), 487-502.BrivioP.GiardinoC.ZilioliE.2001Determination of chlorophyll concentration changes in Lake Garda using an image-based reductive transfer code for landsat TM imagesInternational Journal of Remote Sensing22248750210.1080/014311601450059Search in Google Scholar
Chapra, S.C., 1997. Surface water quality modeling. McGraw-Hill Co. Inc.ChapraS.C.1997Surface water quality modelingMcGraw-Hill Co. Inc.Search in Google Scholar
Dona, C., Sánchez, J.M., Caselles, V., Domínguez, J.A., Camacho, A., 2014. Empirical relationships for monitoring water quality of lakes and reservoirs through multispectral images. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 7(5), 1632-1641.DonaC.SánchezJ.M.CasellesV.DomínguezJ.A.CamachoA.2014Empirical relationships for monitoring water quality of lakes and reservoirs through multispectral imagesIEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing751632164110.1109/JSTARS.2014.2301295Search in Google Scholar
Dorji, P., Fearns, P., 2016. A quantitative comparison of Total Suspended Sediment algorithms: A case study of the last decade for MODIS and Landsat-based sensors. Remote Sens. 8, 810; doi:10.3390/rs8100810.DorjiP.FearnsP.2016A quantitative comparison of Total Suspended Sediment algorithms: A case study of the last decade for MODIS and Landsat-based sensorsRemote Sens.8810; doi:10.3390/rs810081010.3390/rs8100810Search in Google Scholar
Environmental Protection Agency (EPA), 1999. Guidance manual for compliance with the interim enhanced surface water treatment rule. United States, Environmental Protection Agency, Office of Water (4607) publishing, EPA-815- R-99-010, 201p.Environmental Protection Agency (EPA)1999Guidance manual for compliance with the interim enhanced surface water treatment ruleUnited StatesEnvironmental Protection Agency, Office of Water (4607) publishing, EPA-815- R-99-010,201Search in Google Scholar
Ganoe, R., DeYoung, R., 2013. Remote sensing of Dissolved Oxygen and Nitrogen in water using raman spectroscopy. the NASA scientific and technical information (STI), NASA Center for AeroSpace Information, NASA/TM–2013-218142.GanoeR.DeYoungR.2013Remote sensing of Dissolved Oxygen and Nitrogen in water using raman spectroscopythe NASA scientific and technical information (STI)NASA Center for AeroSpace Information, NASA/TM–2013-218142Search in Google Scholar
Gholizadeh, M.H., Melesse, A.M., Reddi, L., 2016. A comprehensive review on water quality parameters estimation using remote sensing techniques. Sensors 16 (8), 1298; doi:10.3390/s16081298.GholizadehM.H.MelesseA.M.ReddiL.2016A comprehensive review on water quality parameters estimation using remote sensing techniquesSensors1681298; doi:10.3390/s1608129810.3390/s16081298Search in Google Scholar
Giardino, C., Bresciani, M., Stroppiana, D., Oggioni, A., Morabito, G., 2014. Optical remote sensing of lakes: an overview on Lake Maggiore. J. Limnol. 73(s1), 201-214; DOI: 10.4081/jlimnol.2014.817.GiardinoC.BrescianiM.StroppianaD.OggioniA.MorabitoG.2014Optical remote sensing of lakes: an overview on Lake MaggioreJ. Limnol.73s1201214; DOI: 10.4081/jlimnol.2014.81710.4081/jlimnol.2014.817Search in Google Scholar
He, W., Chen, S., Liu, X., Chen, J., 2008. Water quality monitoring in slightly-polluted inland water body through remote sensing - A case study in Guanting Reservoir, Beijing, China. Front. Environ. Sci. Engin. China 2(2), 163–171; DOI 10.1007/s11783-008-0027-7.HeW.ChenS.LiuX.ChenJ.2008Water quality monitoring in slightly-polluted inland water body through remote sensing - A case study in Guanting Reservoir, Beijing, ChinaFront. Environ. Sci. Engin. China22163171; DOI 10.1007/s11783-008-0027-710.1007/s11783-008-0027-7Search in Google Scholar
Hossen, H., Negm, A., 2017. Sustainability of water bodies of Edku Lake, Northwest of Nile Delta, Egypt: RS/GIS Approach. Procedia Engineering 181, 404 – 411.HossenH.NegmA.2017Sustainability of water bodies of Edku Lake, Northwest of Nile Delta, Egypt: RS/GIS ApproachProcedia Engineering18140441110.1016/j.proeng.2017.02.408Search in Google Scholar
Kloiber, S.M., Brezonik, P.L., Bauer, M.E, 2002. Application of Landsat imagery to regional-scale assessments of lake clarity. Water Res. (36, 4330–4340.KloiberS.M.BrezonikP.L.BauerM.E2002Application of Landsat imagery to regional-scale assessments of lake clarityWater Res.364330434010.1016/S0043-1354(02)00146-XSearch in Google Scholar
Li, S., Wu, Q., Wang, X., 2002. Correlations between reflectance spectra and contents of Chlorophyll-a in Chaohu Lake. Journal of Lake Sciences 9 (14), 228-234.LiS.WuQ.WangX.2002Correlations between reflectance spectra and contents of Chlorophyll-a in Chaohu LakeJournal of Lake Sciences91422823410.18307/2002.0306Search in Google Scholar
Okbah, M., Abd El-Halim, A., Abu El-Regal, M., Nassar, M., 2017. Water quality assessment of Lake Edku using physicochemical and nutrients salts, Egypt. Chemistry reseach journal 2 (4), 104-117.OkbahM.Abd El-HalimA.Abu El-RegalM.NassarM.2017Water quality assessment of Lake Edku using physicochemical and nutrients salts, EgyptChemistry reseach journal24104117Search in Google Scholar
Siam, E., Ghobrial, M., 2000. Pollution influence on bacterial abundance and Chlorophyll-a concentration: case study at Idku Lagoon, Egypt. Scientia Marina SCI. MAR. 64 (1), 1-8.SiamE.GhobrialM.2000Pollution influence on bacterial abundance and Chlorophyll-a concentration: case study at Idku Lagoon, EgyptScientia Marina SCI. MAR.6411810.3989/scimar.2000.64n11Search in Google Scholar
Sravanthi, N., Ramana, I.V., YunusAli, P., Ashraf, M., Ali, M.M., Narayana, A.C., 2013. An algorithm for estimating Suspended Sediment concentrations in the coastal waters of India using remotely sensed reflectance and its application to coastal environments. Int. J. Environ. Res., 7(4), 841-850.SravanthiN.RamanaI.V.YunusAliP.AshrafM.AliM.M.NarayanaA.C.2013An algorithm for estimating Suspended Sediment concentrations in the coastal waters of India using remotely sensed reflectance and its application to coastal environmentsInt. J. Environ. Res.74841850Search in Google Scholar
Swain, R., Sahoo, B., 2017. Improving river water quality monitoring using satellite data products and a genetic algorithm processing approach. Sustainability of Water Quality and Ecology (9–10), 88–114.SwainR.SahooB.2017Improving river water quality monitoring using satellite data products and a genetic algorithm processing approachSustainability of Water Quality and Ecology9–108811410.1016/j.swaqe.2017.09.001Search in Google Scholar
Thiemann, S., Kaufmann, H., 2000. Determination of Chlorophyll content and trophic state of lakes using field spectrometer and IRS-1C satellite data in the Mecklenburg Lake district - Germany. Remote Sensing of Environment 73, 227-235.ThiemannS.KaufmannH.2000Determination of Chlorophyll content and trophic state of lakes using field spectrometer and IRS-1C satellite data in the Mecklenburg Lake district - GermanyRemote Sensing of Environment7322723510.1016/S0034-4257(00)00097-3Search in Google Scholar
United States Geological Survey (USGS), Earth Resources Observation and Science (EROS) Center, 2015. LANDSAT 8 (L8) data users’ handbook, Version 1.0, LSDS-1574.United States Geological Survey (USGS)Earth Resources Observation and Science (EROS) Center, 2015. LANDSAT 8 (L8) data users’ handbook, Version 1.0, LSDS-1574Search in Google Scholar
Zhang, Y.Z., 2002. Application of an empirical neural network to surface water quality estimation in the Gulf of Finland using combined optical data and microwave data. Remote Sensing of Environment 81(2), 327–336.ZhangY.Z.2002Application of an empirical neural network to surface water quality estimation in the Gulf of Finland using combined optical data and microwave dataRemote Sensing of Environment81232733610.1016/S0034-4257(02)00009-3Search in Google Scholar
