WebGIS-Based Real-Time Surveillance and Response System for Vector-Borne Infectious Diseases
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[1] B. S. Deepapriya,et al. A novel method for prediction of skin disease through supervised classification techniques , 2022, Soft Comput..
[2] Md. Siddikur Rahman,et al. Mapping the spatial distribution of the dengue vector Aedes aegypti and predicting its abundance in northeastern Thailand using machine-learning approach. , 2021, One health.
[3] A. Zia,et al. Malaria Malaria in the Population District Dir Lower Khyber Pakhtunkhwa, Pakistan , 2021 .
[4] M. Combe,et al. Spatial variations in Leishmaniasis: A biogeographic approach to mapping the distribution of Leishmania species , 2021, One health.
[5] M. Uriarte,et al. Environmental and socioeconomic risk factors for visceral and cutaneous leishmaniasis in São Paulo, Brazil. , 2021, The Science of the total environment.
[6] Caterina M. Scoglio,et al. A Windowed Correlation-Based Feature Selection Method to Improve Time Series Prediction of Dengue Fever Cases , 2021, IEEE Access.
[7] Dina M. Ibrahim,et al. Deep-chest: Multi-classification deep learning model for diagnosing COVID-19, pneumonia, and lung cancer chest diseases , 2021, Computers in Biology and Medicine.
[8] M. Wimberly,et al. Remote sensing of environmental risk factors for malaria in different geographic contexts , 2021, International Journal of Health Geographics.
[9] Sam Takavarasha,et al. Micro-spatial modelling of malaria cases and environmental risk factors in Buhera rural district, Zimbabwe , 2021, 2021 Conference on Information Communications Technology and Society (ICTAS).
[10] A. Clements,et al. Dengue risk assessment using multicriteria decision analysis: A case study of Bhutan. , 2021, PLoS neglected tropical diseases.
[11] Yuanyuan Wang,et al. Short-Term Load Forecasting for Industrial Customers Based on TCN-LightGBM , 2020, IEEE Transactions on Power Systems.
[12] B. Niu,et al. Prediction for Global Peste des Petits Ruminants Outbreaks Based on a Combination of Random Forest Algorithms and Meteorological Data , 2021, Frontiers in Veterinary Science.
[13] M. Mohebali,et al. Situation of Asymptomatic Malaria among Iranian Native and Afghan and Pakistani Immigrants in a Malarious Area under the National Malaria Elimination Program of Iran , 2020, Iranian journal of parasitology.
[14] Agustinus Bimo Gumelar,et al. Prediction of Dengue Fever Outbreak Based on Climate Factors Using Fuzzy-Logistic Regression , 2020, 2020 International Seminar on Intelligent Technology and Its Applications (ISITIA).
[15] F. Conraths,et al. Modelling the monthly abundance of Culicoides biting midges in nine European countries using Random Forests machine learning , 2020, Parasites & Vectors.
[16] Donato Malerba,et al. A Multi-Stage Machine Learning Approach to Predict Dengue Incidence: A Case Study in Mexico , 2020, IEEE Access.
[17] S. A. Mahmood,et al. Towards a Web GIS-based approach for mapping a dengue outbreak , 2020, Applied Geomatics.
[18] Sk Ajim Ali,et al. Mapping of mosquito-borne diseases in Kolkata Municipal Corporation using GIS and AHP based decision making approach , 2019, Spatial Information Research.
[19] J. Malone,et al. Use of Geospatial Surveillance and Response Systems for Vector-Borne Diseases in the Elimination Phase , 2019, Tropical medicine and infectious disease.
[20] Philipp Probst,et al. Hyperparameters and tuning strategies for random forest , 2018, WIREs Data Mining Knowl. Discov..
[21] Bernd Bischl,et al. Tunability: Importance of Hyperparameters of Machine Learning Algorithms , 2018, J. Mach. Learn. Res..
[22] G. Glass,et al. Machine learning approaches in GIS-based ecological modeling of the sand fly Phlebotomus papatasi, a vector of zoonotic cutaneous leishmaniasis in Golestan province, Iran. , 2018, Acta tropica.
[23] N. Khatoon,et al. Report: Incidence of malaria in the population of Korangi creek area, Karachi, Pakistan. , 2018, Pakistan journal of pharmaceutical sciences.
[24] F. Catteruccia,et al. Vector biology meets disease control: using basic research to fight vector-borne diseases , 2018, Nature Microbiology.
[25] Stavros I. Dimitriadis,et al. How random is the random forest? Random forest algorithm on the service of structural imaging biomarkers for Alzheimer's disease: from Alzheimer's disease neuroimaging initiative (ADNI) database , 2018, Neural regeneration research.
[26] M. Sarfraz,et al. SPATIO-TEMPORAL ANALYSIS TO PREDICT ENVIRONMENTAL INFLUENCE ON MALARIA , 2018 .
[27] Margarida Mendes Jorge,et al. A qualitative study of community perception and acceptance of biological larviciding for malaria mosquito control in rural Burkina Faso , 2018, BMC Public Health.
[28] B. R. Naik,et al. Data mapping of Vector Borne Disease with Geographical Information System & Global Position System technology: In tribal areas Khammam District, Telangana State , 2017 .
[29] Carlos Marcelo Scavuzzo,et al. MODIS Environmental Data to Assess Chikungunya, Dengue, and Zika Diseases Through Aedes (Stegomia) aegypti Oviposition Activity Estimation , 2016, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.
[30] A. Mollalo,et al. Zoonotic cutaneous leishmaniasis in northeastern Iran: a GIS-based spatio-temporal multi-criteria decision-making approach , 2016, Epidemiology and Infection.
[31] S. Ahmad,et al. Spatio-temporal surveillance of water based infectious disease (malaria) in Rawalpindi, Pakistan using geostatistical modeling techniques , 2015, Environmental Monitoring and Assessment.
[32] J. Shaw,et al. Recent advances in phlebotomine sand fly research related to leishmaniasis control , 2015, Parasites & Vectors.
[33] Usama Ijaz Bajwa,et al. Mapping urban and peri-urban breeding habitats of Aedes mosquitoes using a fuzzy analytical hierarchical process based on climatic and physical parameters. , 2014, Geospatial health.
[34] N. Tripathi,et al. Analyzing the spatio-temporal relationship between dengue vector larval density and land-use using factor analysis and spatial ring mapping , 2012, BMC Public Health.
[35] Sobia Idrees,et al. A brief review on dengue molecular virology, diagnosis, treatment and prevalence in Pakistan , 2012, Genetic vaccines and therapy.
[36] A. Tatem,et al. Web-based GIS: the vector-borne disease airline importation risk (VBD-AIR) tool , 2012, International Journal of Health Geographics.
[37] M. Ismail,et al. GIS application to identify the potential for certain irrigated agriculture uses on some soils in Western Desert, Egypt , 2012 .
[38] Wei Wei,et al. Research on the Application of Geographic Information System in Tourism Management , 2012 .
[39] Jean-Philippe Waaub,et al. Spatially explicit multi-criteria decision analysis for managing vector-borne diseases , 2011, International journal of health geographics.
[40] Vili Podgorelec,et al. Decision trees , 2018, Encyclopedia of Database Systems.
[41] A. Mondini,et al. Spatial correlation of incidence of dengue with socioeconomic, demographic and environmental variables in a Brazilian city. , 2008, The Science of the total environment.
[42] Nicolas Bacaër,et al. The epidemic threshold of vector-borne diseases with seasonality , 2006, Journal of mathematical biology.
[43] S. Sathiya Keerthi,et al. Evaluation of simple performance measures for tuning SVM hyperparameters , 2003, Neurocomputing.
[44] Andre Zerger,et al. Impediments to using GIS for real-time disaster decision support , 2003, Comput. Environ. Urban Syst..
[45] S W Lindsay,et al. Climate change and vector-borne diseases: a regional analysis. , 2000, Bulletin of the World Health Organization.
[46] J Dangermond,et al. What is a Geographic Information System(GIS) , 1992 .