A Low-power Real-time Pollution Monitoring System Using ESP LoRa
doi: 10.14456/mijet.2020.8
Keywords:
LoRa, Pollution Monitoring, Wireless Sensor Networks, Air quality, Dust, Pressure, Altitude, Temperature, HumidityAbstract
Air Quality (AQ) is a very topical issue for many cities and has a direct impact on the environment and health of its citizens. We propose to investigate the air quality at Khon Kaen city in Thailand. We design and realization of 4 sensors (PM2.5-PM10, Pressure, Altitude, Temperature, Humidity and Carbon dioxide) which is defined to operate on Wireless Sensor Network (WSN) form with LoRa technology. The experimental results have been shown the air quality on web application. The proposed of this paper can help the people know the historical and real-time data of air quality through a web browser.
References
[1] Pollution Control Department, Thailand (2018). Statistic Data, URL: http://air4thai.pcd.go.th/webV2/download.php
[2] C. Peng, K. Qian, and C. Wang (2015). Design and application of a VOC-monitoring system based on a ZigBee wireless sensor network, IEEE Sensors Journal, vol. 15, no. 4, Apr. 2015, pp. 2255-2268.
[3] J. Chen, W. Xu, S. He, Y. Sun, P. Thulasiraman, and X. Shen (2010). Utility-based asynchronous flow control algorithm for wireless sensor networks, IEEE Journal on Selected Areas in Communications, vol. 28, no. 7, Aug. 2010, pp. 1116-1126.
[4] Kan Zheng, Shaohang Zhao, Zhe Yang, Xiong Xiong, Wei Xiang (2016). Design and Implementation of LPWA-based Air Quality Monitoring System, IEEE Access, vol. 4, June 2016, pp. 3238 – 3245.
[5] Vadlamudi, MK and Brindha, GS (2015). Monitoring Of Green House Gases Using Wireless Sensor Networks with Arduino Board, International Journal of Science, Engineering and Technology Research (IJSETR), vol. 4, Issue 4, pp. 741-745.
[6] Reddy, MA and Natarajan, V (2015). On-line Monitoring of Green House gases Storage and Leakage Using Wireless Sensor Network, International Research Journal of Engineering and Technology (IRJET), vol.02, Issue: 01, pp.158-161.
[7] Yushuang Ma, Long Zhao, Rongjin Yang, Xiuhong Li, Qiao Song, Zhenwei Song and Yi Zhang (2018). Development and Application of an Atmospheric Pollutant Monitoring System Based on LoRa—Part I: Design and Reliability Tests. Sensors 2018, 18, 3891; doi:10.3390/s18113891, URL: www.mdpi.com/journal/sensors
[8] Kais Mekkia, Eddy Bajica, Frederic Chaxela and Fernand Meyerb (2018). A comparative study of LPWAN technologies for large-scale IoT deployment. Publishing Services by Elsevier, January 2018, URL: https://doi.org/10.1016/j.icte.2017.12.005
[9] K.Mikhaylov, T. Haenninen, Analysis of capacity and scalability of the LoRa low power wide area network technology, in: Proc. of EWC, Oulu, Finland, 2016, pp. 119–124.
[10] Semtech SX1278 137 MHz to 525 MHz Low Power Long Range Transceiver (2017). Accessed: Sep. 19, 2017. Available online: http://www.semtech.com/wireless-rf/rf-transceivers/sx1278/
[11] T. Zheng et al. (2018). Field evaluation of low-cost particulate matter sensors in high- and low-concentration environments, Published by Copernicus Publications on behalf of the European Geosciences Union, Atmos. Meas. Tech., 11, August 2018, pp. 4823–4846.
[12] Sanphet Chunitiphisan, Sirima Panyamethekul2, Suree Pumrin, Garavig Tanaksaranond, and Thawat Ngamsritrakul (2018). Particulate Matter Monitoring Using Inexpensive Sensors and Internet GIS: A Case Study in Nan, Thailand, ENGINEERING JOURNAL, Vol. 22 Issue 2, March 2018, pp. 25-37.
[13] Tanuj Ahuja, Vanita Jain and Shriya Gupta, Smart Pollution Monitoring for Instituting Aware Traveling. International Journal of Computer Applicationsm, Vol. 145 No.9, July 2016, pp. 0975 – 8887.
[14] Technical Assistance Document for the Reporting of Daily Air Quality – the Air Quality Index (AQI), EPA 454/B-18-007, September 2018.
[15] Thai Meteorological Department Automatic Weather System (TMD), URL: http://www.aws-observation.tmd.go.th/web/
[16] Pollution Control Department, Thailand (2019). Statistic Data, URL: http://air4thai.pcd.go.th/webV2/history/
[2] C. Peng, K. Qian, and C. Wang (2015). Design and application of a VOC-monitoring system based on a ZigBee wireless sensor network, IEEE Sensors Journal, vol. 15, no. 4, Apr. 2015, pp. 2255-2268.
[3] J. Chen, W. Xu, S. He, Y. Sun, P. Thulasiraman, and X. Shen (2010). Utility-based asynchronous flow control algorithm for wireless sensor networks, IEEE Journal on Selected Areas in Communications, vol. 28, no. 7, Aug. 2010, pp. 1116-1126.
[4] Kan Zheng, Shaohang Zhao, Zhe Yang, Xiong Xiong, Wei Xiang (2016). Design and Implementation of LPWA-based Air Quality Monitoring System, IEEE Access, vol. 4, June 2016, pp. 3238 – 3245.
[5] Vadlamudi, MK and Brindha, GS (2015). Monitoring Of Green House Gases Using Wireless Sensor Networks with Arduino Board, International Journal of Science, Engineering and Technology Research (IJSETR), vol. 4, Issue 4, pp. 741-745.
[6] Reddy, MA and Natarajan, V (2015). On-line Monitoring of Green House gases Storage and Leakage Using Wireless Sensor Network, International Research Journal of Engineering and Technology (IRJET), vol.02, Issue: 01, pp.158-161.
[7] Yushuang Ma, Long Zhao, Rongjin Yang, Xiuhong Li, Qiao Song, Zhenwei Song and Yi Zhang (2018). Development and Application of an Atmospheric Pollutant Monitoring System Based on LoRa—Part I: Design and Reliability Tests. Sensors 2018, 18, 3891; doi:10.3390/s18113891, URL: www.mdpi.com/journal/sensors
[8] Kais Mekkia, Eddy Bajica, Frederic Chaxela and Fernand Meyerb (2018). A comparative study of LPWAN technologies for large-scale IoT deployment. Publishing Services by Elsevier, January 2018, URL: https://doi.org/10.1016/j.icte.2017.12.005
[9] K.Mikhaylov, T. Haenninen, Analysis of capacity and scalability of the LoRa low power wide area network technology, in: Proc. of EWC, Oulu, Finland, 2016, pp. 119–124.
[10] Semtech SX1278 137 MHz to 525 MHz Low Power Long Range Transceiver (2017). Accessed: Sep. 19, 2017. Available online: http://www.semtech.com/wireless-rf/rf-transceivers/sx1278/
[11] T. Zheng et al. (2018). Field evaluation of low-cost particulate matter sensors in high- and low-concentration environments, Published by Copernicus Publications on behalf of the European Geosciences Union, Atmos. Meas. Tech., 11, August 2018, pp. 4823–4846.
[12] Sanphet Chunitiphisan, Sirima Panyamethekul2, Suree Pumrin, Garavig Tanaksaranond, and Thawat Ngamsritrakul (2018). Particulate Matter Monitoring Using Inexpensive Sensors and Internet GIS: A Case Study in Nan, Thailand, ENGINEERING JOURNAL, Vol. 22 Issue 2, March 2018, pp. 25-37.
[13] Tanuj Ahuja, Vanita Jain and Shriya Gupta, Smart Pollution Monitoring for Instituting Aware Traveling. International Journal of Computer Applicationsm, Vol. 145 No.9, July 2016, pp. 0975 – 8887.
[14] Technical Assistance Document for the Reporting of Daily Air Quality – the Air Quality Index (AQI), EPA 454/B-18-007, September 2018.
[15] Thai Meteorological Department Automatic Weather System (TMD), URL: http://www.aws-observation.tmd.go.th/web/
[16] Pollution Control Department, Thailand (2019). Statistic Data, URL: http://air4thai.pcd.go.th/webV2/history/
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Published
2020-01-22
How to Cite
Atiwanwong, T., & Hongprasit, S. (2020). A Low-power Real-time Pollution Monitoring System Using ESP LoRa: doi: 10.14456/mijet.2020.8. Engineering Access, 6(1), 36–40. retrieved from https://ph02.tci-thaijo.org/index.php/mijet/article/view/10.14456.mijet.2020.8
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