Prototyping Low-Cost Automatic Weather Stations for Natural Disaster Monitoring

Weather events put human lives at risk mostly when people might reside in areas susceptible to natural disasters. Weather monitoring is a pivotal task that is accomplished in vulnerable areas with the support of reliable weather stations. Such stations are front-end equipment typically mounted on a fixed mast structure with a set of digital andmagnetic weather sensors connected to a datalogger. While remote sensing from a number of stations is paramount, the cost of professional weather instruments is extremely high. This imposes a challenge for large-scale deployment and maintenance of weather stations for broad natural disaster monitoring. To address this problem, in this paper, we validate the hypothesis that a Low-Cost Automatic Weather Station system (LCAWS) entirely developed from commercial-off-the-shelf and open-source IoT technologies is able to provide data as reliable as a Professional Weather Station (PWS) of reference for natural disaster monitoring. To achieve data reliability, we propose an intelligent sensor calibration method to correct weather parameters. From the experimental results of a 30-day uninterrupted observation period, we show that the results of the calibrated LCAWS sensors have no statistically significant differences with the PWS’s results. Together with The Brazilian National Center for Monitoring and Early Warning of Natural Disasters (Cemaden), LCAWS has opened new opportunities towards reducing maintenance cost of its weather observational network.

[1]  João Porto de Albuquerque,et al.  Flood Citizen Observatory: a crowdsourcing-based approach for flood risk management in Brazil , 2014, SEKE.

[2]  Seishi Ninomiya,et al.  Machine Learning-Based Calibration of Low-Cost Air Temperature Sensors Using Environmental Data , 2017, Sensors.

[3]  Ravi Kishore Kodali,et al.  IoT based weather station , 2016, 2016 International Conference on Control, Instrumentation, Communication and Computational Technologies (ICCICCT).

[4]  Thomas H. Clausen,et al.  A Study of LoRa: Long Range & Low Power Networks for the Internet of Things , 2016, Sensors.

[5]  Iain Bate,et al.  Using Multi-parameters for Calibration of Low-cost Sensors in Urban Environment , 2017, EWSN.

[6]  Konrad Wrona,et al.  Wireless Sensor Networks for Military Purposes , 2012 .

[7]  E. Mendiondo,et al.  Flood modelling using synthesised citizen science urban streamflow observations , 2018, Journal of Flood Risk Management.

[8]  Adnan Shaout,et al.  Low cost embedded weather station with intelligent system , 2014, 2014 10th International Computer Engineering Conference (ICENCO).

[9]  Prashant J. Shenoy,et al.  Predicting solar generation from weather forecasts using machine learning , 2011, 2011 IEEE International Conference on Smart Grid Communications (SmartGridComm).

[10]  István Z. Kovács,et al.  Coverage Comparison of GPRS, NB-IoT, LoRa, and SigFox in a 7800 km² Area , 2017, 2017 IEEE 85th Vehicular Technology Conference (VTC Spring).

[11]  A. Overeem,et al.  Quality Control for Crowdsourced Personal Weather Stations to Enable Operational Rainfall Monitoring , 2019, Geophysical Research Letters.

[12]  Sonam Tenzin,et al.  Low cost weather station for climate-smart agriculture , 2017, 2017 9th International Conference on Knowledge and Smart Technology (KST).

[13]  Javier Tomasella,et al.  Understanding shallow landslides in Campos do Jordão municipality – Brazil: disentangling the anthropic effects from natural causes in the disaster of 2000 , 2017 .

[14]  Paul W. Rhode,et al.  The Effect of Natural Disasters on Economic Activity in Us Counties: A Century of Data , 2017, Journal of Urban Economics.

[15]  Suryakant A. Sawant,et al.  Interoperable agro-meteorological observation and analysis platform for precision agriculture: A case study in citrus crop water requirement estimation , 2017, Comput. Electron. Agric..

[16]  M. V. van Aalst The impacts of climate change on the risk of natural disasters. , 2006, Disasters.

[17]  Mark J. van der Laan,et al.  Super Learner Prediction [R package SuperLearner version 2.0-26] , 2019 .

[18]  Grant Lockridge,et al.  Development of a Low-Cost Arduino-Based Sonde for Coastal Applications , 2016, Sensors.

[19]  J. Marengo,et al.  An index of Brazil’s vulnerability to expected increases in natural flash flooding and landslide disasters in the context of climate change , 2017, Natural Hazards.

[20]  M. Benghanem,et al.  Measurement of meteorological data based on wireless data acquisition system monitoring , 2009 .

[21]  Jason Kelley,et al.  Using Neural Networks to Estimate Site-Specific Crop Evapotranspiration with Low-Cost Sensors , 2019, Agronomy.

[22]  Massimiliano Cannata,et al.  Boosting a Weather Monitoring System in Low Income Economies Using Open and Non-Conventional Systems: Data Quality Analysis , 2019, Sensors.

[23]  Juan-Carlos Zúñiga,et al.  SIGFOX System Description , 2017 .

[24]  James P. Kossin,et al.  The Impact of Climate Change on Natural Disasters , 2014 .

[25]  M. J. van der Laan,et al.  Statistical Applications in Genetics and Molecular Biology Super Learner , 2010 .

[26]  Rafael Borge,et al.  Using statistical methods to carry out in field calibrations of low cost air quality sensors , 2018, Sensors and Actuators B: Chemical.

[27]  Robert Finger,et al.  Modeling the sensitivity of outdoor recreation activities to climate change , 2012 .

[28]  Andrea Zanella,et al.  Long-range communications in unlicensed bands: the rising stars in the IoT and smart city scenarios , 2015, IEEE Wireless Communications.

[29]  Naveen Kumar,et al.  Arduino based automatic wireless weather station with remote graphical application and alerts , 2016, 2016 3rd International Conference on Signal Processing and Integrated Networks (SPIN).

[30]  Allen L. Robinson,et al.  A machine learning calibration model using random forests to improve sensor performance for lower-cost air quality monitoring , 2018 .