Architecture of a hydroelectrically powered wireless sensor node for underground environmental monitoring

Mecocci, A.; Peruzzi, Giacomo; Pozzebon, Alessandro; Vaccarella, Pietro

doi:10.1049/iet-wss.2016.0103

Cited by 12 publications

(7 citation statements)

References 18 publications

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“…By monitoring the electricity consumption during six production processes of typical sewage discharge factories in the jurisdiction, it was found that the major production periods of large sewage discharge enterprises in November 2018 were concentrated in the following four sections: [4][5][6][7][8][9][10][11][12], [15][16][17][18][19][20][21][22][23], [24][25] and [27][28][29][30]. This performance was consistent with the time section when the concentration of pollution factors was increased in our urban environmental information monitoring analysis.…”

Section: Resultssupporting

confidence: 72%

A Wireless Sensor Network for Monitoring Environmental Quality in the Manufacturing Industry

et al. 2019

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Urban industrial plant areas are highly concentrated, and air pollution is increasingly serious. The quantity of outdoor air quality monitoring sites is insufficient. Aiming at the above questions, related studies propose solutions that use relatively cheap equipment networking to collect pollution data and accurately analyze local monitoring information. In this paper, a new type of outdoor air quality monitoring system is studied and preliminarily practiced and has proven certain feasibility and applicability. The main contributions of this paper are: first, we improve the network layout by employing the Zigbee network, which is combined with factory characteristics, and collected data on carbonic oxide, nitrogen dioxide, sulfur dioxide, ozone, particulate matter, temperature, and humidity. And then, to establish the dilution coefficient and diffusion coefficient of pollution diffusion, we adopt air movement as the energy model and, by utilizing the method of pollution traceability, achieve the complete coverage pollution monitoring of the whole city by local monitoring sites. Finally, we propose an improved long short-term memory (LSTM) method to predict the pollution period of urban air quality. The experimental results show that the improved LSTM prediction model has strong applicability and high accuracy in the period prediction of pollution weather. Meanwhile, by analyzing the specific case in detail, we prove that air pollution in the city is mainly caused by the manufacturing industry. We conclude that it will make a great contribution to the atmospheric environment protection of cities by using weather quality prediction to dynamically adjust the production.

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Section: Resultssupporting

confidence: 72%

A Wireless Sensor Network for Monitoring Environmental Quality in the Manufacturing Industry

et al. 2019

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“…In general, the most immediate energy-saving strategy obviously is to provide the sensor node with an energy harvesting solution [ 18 ]: the most common is the use of photovoltaic panels [ 19 ] but also other strategies have been proposed [ 20 , 21 ]. An hydroelectrically powered sensor node was already discussed by the authors in [ 22 ]. While all these solutions are able to continuously power the monitoring system, they are unsustainable in term of costs.…”

Section: Related Workmentioning

confidence: 99%

A Low Power IoT Sensor Node Architecture for Waste Management Within Smart Cities Context

Cerchecci

Luti

Mecocci

et al. 2018

Sensors

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125

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This paper focuses on the realization of an Internet of Things (IoT) architecture to optimize waste management in the context of Smart Cities. In particular, a novel typology of sensor node based on the use of low cost and low power components is described. This node is provided with a single-chip microcontroller, a sensor able to measure the filling level of trash bins using ultrasounds and a data transmission module based on the LoRa LPWAN (Low Power Wide Area Network) technology. Together with the node, a minimal network architecture was designed, based on a LoRa gateway, with the purpose of testing the IoT node performances. Especially, the paper analyzes in detail the node architecture, focusing on the energy saving technologies and policies, with the purpose of extending the batteries lifetime by reducing power consumption, through hardware and software optimization. Tests on sensor and radio module effectiveness are also presented.

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“…Indeed, common energy-harvesting solutions like solar cells and wind turbines are useless due to the lack of the primary source of energy (i.e., the sun light and/or the wind). Hence, some recent works have investigated the possibility of deploying alternative energy-harvesting solutions [1,2]. However, off-the-shelf devices that incorporate these mechanisms are still difficult to be found.…”

Section: Introductionmentioning

confidence: 99%

A Multi-Hop LoRa Linear Sensor Network for the Monitoring of Underground Environments: The Case of the Medieval Aqueducts in Siena, Italy

Abrardo

Pozzebon

2019

Sensors

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In this paper, a pervasive monitoring system to be deployed in underground environments is presented. The system has been specifically designed for the so-called “Bottini”, i.e., the medieval aqueducts dug beneath the Centre of Siena, Italy. The results of a measurement campaign carried out in the deployment scenario show that the transmission range of LoRa (Long Range) technology is limited to a maximum of 200 m, thus, making the adoption of a classical star topology impossible. Hence, a Linear Sensor Network topology is proposed based on multi-hop LoRa chain-type communications. In this scenario, an ad-hoc transmission scheme is presented that optimally evaluates the wake-up time of all nodes with the aim of minimizing the average energy dissipation deriving from clock offsets. Numerical results show that the proposed wake-up time optimization leads in the best case to a 50% reduction in power dissipation with respect to a scheme that evaluates the wake-up time in a non-optimal way.

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Architecture of a hydroelectrically powered wireless sensor node for underground environmental monitoring

Cited by 12 publications

References 18 publications

A Wireless Sensor Network for Monitoring Environmental Quality in the Manufacturing Industry

A Wireless Sensor Network for Monitoring Environmental Quality in the Manufacturing Industry

A Low Power IoT Sensor Node Architecture for Waste Management Within Smart Cities Context

A Multi-Hop LoRa Linear Sensor Network for the Monitoring of Underground Environments: The Case of the Medieval Aqueducts in Siena, Italy

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