Abstract
Flood is a natural calamity and causes damage of life and property devastation. The main objective of this study was to analyse flood hazard and inundation area mapping of Paravanar sub-Basin. Flood generating factors, like elevation, slope, drainage density, rainfall, soil type and land use were analyzed and delineated flood zones using Geospatial techniques and multi criteria evaluation. The flood generating factor was computed by data integration, floodplain depiction, mapping, and evaluation. Various parameters such as Normalized difference vegetation index (NDVI), Normalized difference build-up index (NDBI), Normalized difference water index (NDWI) were acquired for performing Regression Analysis. This information can be further utilized for hydro-meteorological figures and Surge forecast. These data can be used in building hazard and risk maps for pre-flood prediction. The flood hazard threats in the southeast and in between southeast and west part of the Paravanar River basin are high flood hazard threat zone.
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23 May 2022
This article has been retracted. Please see the Retraction Notice for more detail: https://doi.org/10.1007/s12652-022-03959-x
References
Aboelnour M, Engel BA (2018) Application of remote sensing techniques and geographic information systems to analyze land surface temperature in response to land use/land cover change in Greater Cairo region, Egypt. J Geogr Inf Syst 10(01):57–88
Alemu B (2015) The effect of land use land cover change on land degradation in the highlands of Ethiopia. J Environ Earth Sci 5(1):1–13
Amin A, Fazal S (2012) Land transformation analysis using remote sensing and GIS techniques (a case study). J Geograph Inform Syst 4:229–236
Araya YH, Cabral P (2010) Analysis and modeling of urban land cover change in Setúbal and Sesimbra, Portugal. Remote Sens Environ 2(6):1549–1563
Aredehey G, Mezgebu A, Girma A (2018) Land-use land-cover classification analysis of Giba catchment using hyper temporal MODIS NDVI satellite images. Int J Remote Sens 39(3):810–821
Arora G, Wolter PT (2018) Tracking land cover change along the western edge of the US corn belt from 1984 through 2016 using satellite sensor data: observed trends and contributing factors. J Land Use Sci 13(1–2):1–22
Barraza V, Grings F, Salvia M, Perna P, Carbajo AE, Karszenbaum H (2013) Monitoring and modelling land surface dynamics in Bermejo River Basin, Argentina: time series analysis of MODIS NDVI data. Int J Remote Sens 34(15):5429–5451
Bechtel A, Karayiğit AI, Sachsenhofer RF, İnaner H, Christanis K, Gratzer R (2014) Spatial and temporal variability in vegetation and coal facies as reflected by organic petrological and geochemical data in the Middle Miocene Çayirhan coal field (Turkey). Int J Coal Geol 134–135:46–60
Bhandari AK, Kumar A (2012) Feature extraction using normalized difference Vegetation Index (NDVI): a case study of Jabalpur City. Proc Technol 6:612–621
Butt A, Shabbir R, Ahmad SS, Aziz N, Nawaz M, Shah MTA (2015a) Land cover classification and change detection analysis of Rawal watershed using remote sensing data. J Biol Environ Sci 6(1):236–248
Butt A, Shabbir R, Ahmad SS, Aziz N (2015b) Land use change mapping and analysis using remote sensing and GIS: a case study of Simly watershed, Islamabad, Pakistan. Egypt J Remote Sens Space Sci 18(2):251–259
Cheema MJM, Bastiaanssen WG (2010) Land use and land cover classification in the irrigated Indus Basin using growth phenology information from satellite data to support water management analysis. Agric Water Manag 97(10):1541–1552
Christiana O, Zachariah A (2013) Spatial and temporal variation of normalized difference Vegetation Index (NDVI) and rainfall in the North East Arid Zone of Nigeria. Atmos Clim Sci 3:421–426
Cipolla E, Maniscalco U, Rizzo R et al (2017) Analysis and visualization of meteorological emergencies. J Ambient Intell Human Comput 8:57–68
Del Castillo EM, García-Martin A, Aladrén LAL, De Luis M (2015) Evaluation of forest cover change using remote sensing techniques and landscape metrics in Moncayo Natural Park (Spain). Appl Geogr 62:247–255
Demirel H, Ozcinar C, Anbarjafari G (2010) Satellite image contrast enhancement using discrete wavelet transform and singular value Decomposition. IEEE Geosci Remote Sens Lett 7(2):333–337
Dewan TH (2015) Societal impacts and vulnerability to floods in Bangladesh and Nepal. Weather Clim Extrem 7:36–42
Dewan AM, Yamaguchi Y (2009) Using remote sensing and GIS to detect and monitor land use and land cover change in Dhaka Metropolitan of Bangladesh during 1960–2005. Environ Monit Assess 150:237–249
Dhamodaran S, Lakshmi M (2020) Comparative analysis of spatial interpolation with climatic changes using inverse distance method. J Ambient Intell Human Comput. https://doi.org/10.1007/s12652-020-02296-1
Dutta D, Kundu A, Patel NR, Saha SK, Siddiqui AR (2015) Assessment of agricultural drought in Rajasthan (India) using remote sensing derived Vegetation Condition Index (VCI) and Standardized Precipitation Index (SPI). Egypt J Remote Sens Space Sci 18:53–63
El-Shikha DM, Waller P, Hunsaker D, Clarke T, Barnes E (2007) Ground-based remote sensing for assessing water and nitrogen status of broccoli. Agric Water Manag 92:183–193
Felix AY et al (2018) Trend analysis of NDVI for detecting vegetation change of cuddalore, Tamil Nadu. Int J Plant Res 31(3):95–100. https://doi.org/10.5958/2229-4473.2018.00079.4
Felix AY, Sasipraba T (2019) Flood detection using gradient boost machine learning approach. In: International conference on computational intelligence and knowledge economy (ICCIKE), Dubai, United Arab Emirates, pp 779–783. https://doi.org/10.1109/ICCIKE47802.2019.9004419.
Felix A, Sasipraba T (2016) Incident mapping and EAS using decision support system. ARPN J Eng Appl Sci 11(15):9266–9269
Fisseha G et al (2011) Analysis of land use/land cover changes in the Debre-Mewi watershed at the upper catchment of the Blue Nile Basin. Northwest Ethiopia 1(6):184–198
Foody GM (2010) Assessing the accuracy of land cover change with imperfect ground reference data. Remote Sens Environ 114:2271–2285
Forkel M, Carvalhais N, Verbesselt J, Mahecha MD, Neigh CS, Reichstein M (2013) Trend change detection in NDVI time series: effects of inter-annual variability and methodology. Remote Sens 5:2113–2144
Forkuor G, Cofie O (2011) Dynamics of land-use/land-cover change in Freetown Sierra Leone and its effects on urban and peri-urban agriculture—a remote sensing approach. Int J Remote Sens 32(4):1017–1037
Gao B (1996) NDWI—a normalized difference water index for remote sensing of vegetation liquid water from space. Remote Sens Environ 58:257–266
Haregeweyn N, Fikadu G, Tsunekawa A, Tsubo M, Meshesha DT (2012) The dynamics of urban expansion and its impacts on land use/land cover change and small scale farmers living near the urban fringe: a case study of BahirDar, Ethiopia. Landsc Urban Plan 106(2):149–157
Harris A, Carrb AS, Dashc J (2014) Remote sensing of vegetation cover dynamics and resilience across southern Africa. Int J Appl Earth Obs Geoinf 28:131–139
Jeyaseelan AT (2004) Droughts and floods assessment and monitoring using remote sensing and GIS. In: Proceedings of satellite remote sensing and GIS applications in agricultural meteorology, pp 291–313
Jovanovic D, Goverdarica M, Sabo F, Bugarinovic Z, Novovic O, Beker T, Lauter M (2015) Land cover change detection by using remote sensing: a case study of Zlatibor (Serbia). Geographica Pannonica 19(4):162–173
Kim H, Kwak HS, Yoo JS (2008) Improved clustering algorithm for change detection in remote sensing. Int J Digit Content Technol Appl 2(2):55–59
Liang SZ, Ma WD, Sui XY, Yao HM, Li HZ, Liu T, Wang M (2017) Extracting the spatiotemporal pattern of cropping systems from NDVI time series using a combination of the spline and HANTS Algorithms: a case study for Shandong Province. Can J Remote Sens 43(1):1–15
Matsushita B, Yang W, Chen J, Onda Y, Qiu G (2007) Sensitivity of the Enhanced Vegetation Index (EVI) and Normalized Difference Vegetation Index (NDVI) to topographic effects: a case study in high-density cypress forest. Sensors 7(11):2636–2651
McFeeters SK (1996) The use of the normalized difference water index (NDWI) in the delineation of open water features. Int J Remote Sens 17:1425–1432
Molla M (2015) Land use/land cover dynamics in the central rift valley region of Ethiopia: case of ArsiNegele District. Afr J Agric Res 10:434–449
Panda PK (2014) Vulnerability of flood in India: a remote sensing and GIS approach for warning, mitigation and management. Asian J Sci Technol 5(12):843–846
Rani M, KumarP YM, Hooda R (2011) Wetland assessment and monitoring using image processing techniques: a case study of Ranchi India. J Geograph Inf Syst 3(4):345–350
Rawat JS, Kumar M (2015) Monitoring land use/cover change using remote sensing and GIS techniques: a case study of Hawalbagh block, district Almora, Uttarakhand, India. Egypt J Remote Sens Space Sci 18:77–84
Richards JA (1993) Remote sensing digital image analysis: an introduction. Springer, Berlin. https://doi.org/10.1007/978-3-642-88087-2
Ricotta C, Avena G, Palma AD (1999) Mapping and monitoring net primary productivity with AVHRRNDVI time-series: statistical equivalence of cumulative vegetation indices. ISPRS J Photogramm Remote Sens 54:325–331
Sanyal J, Lu XX (2004) Application of remote sensing in flood management with special reference to monsoon Asia: a review. Nat Hazards 33:283–301
Vogelmann JE, Helder D, Morfitt R, Choate MJ, Merchant JW, Bulley H (2001) Effects of Landsat 5 Thematic Mapper and Land sat 7 Enhanced Thematic Mapper Plus radiometric and geometric calibrations and corrections on landscape characterization. Remote Sens Environ 78(1):55–70
Wang Z, Xu J, Wang Y et al (2020) Study of the key technology on the Geo-hazard spatial information sharing platform in Meizoseismal Region of Wenchuan Earthquake Zone. J Ambient Intell Human Comput. https://doi.org/10.1007/s12652-020-02117-5
Wondie M et al (2011) Spatial and temporal land cover changes in the semen mountains national park, a world heritage Site in northwestern Ethiopia. Remote Sens 3(4):752–766
Wondie M et al (2016) Modelling the dynamics of landscape transformations and population growth in the highlands of Ethiopia using remote-sensing data. Int J Remote Sens 37(23):5647–5667
Yamaguchi T, Kishida K, Nunohiro E, Park JG, Mackin KJ, Matsushita KHK, Harada I (2010) Artificial neural network paddy field classifier using spatiotemporal remote sensing data. Artif Life Robot 15(2):221–224
Yang Y, Zhu J, Zhao C, Liu S, Tong X (2011) The spatial continuity study of NDVI based on Kriging and BPNN algorithm. J Math Comp Model 54:1138–1144
Zhang X, Hu Y, Zhuang D, Oi Y, Ma X (2009) NDVI spatial pattern and its differentiation on the Mongolian plateau. J GeogrSci 19:403–415
Zha Y, Gao J, Ni S (2003) Use of normalized difference built-up index in automatically mapping urban areas from TM imagery. Int J Remote Sens 24(3):583–594
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Felix, A.Y., Sasipraba, T. RETRACTED ARTICLE: Spatial and temporal analysis of flood hazard assessment of Cuddalore District, Tamil Nadu, India. Using geospatial techniques. J Ambient Intell Human Comput 12, 2573–2584 (2021). https://doi.org/10.1007/s12652-020-02415-y
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DOI: https://doi.org/10.1007/s12652-020-02415-y