Low-cost electronic sensors for environmental research: Pitfalls and opportunities

Chan, Kristofer; Schillereff, Daniel; Baas, Andreas Cw; Chadwick, Michael A.; Main, Bruce W.; Mulligan, Mark; O’Shea, Francis T.; Pearce, Reagan; Smith, Thomas E. L.; Soesbergen, Arnout van; Tebbs, Emma; Thompson, Joseph R.

doi:10.1177/0309133320956567

Cited by 35 publications

(27 citation statements)

References 91 publications

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“…The majority of existing environmental applications are based on proprietary conventional commercial WSN apparatuses. Furthermore, there is a global shortage of low-cost, longrange wireless monitoring systems for measuring water table depths [36]. To date, no studies have reported on the use of LoRa-based, low-cost WSN in groundwater table management in Tanzania.…”

Section: A Primer On Lora Radio Technologymentioning

confidence: 99%

“…The system consists of a proprietary data collection unit and an open-source data handling and visualization web application. Furthermore, Chan et al [36] proposed a groundwater observatory model that includes a low-cost probe made with low-cost pressure sensors (NXP MPX5010DP and MS5803-02ba) to measure water table depths. The submersible sensor is housed in a waterproof (aluminum tube) enclosure and a common logger in a separate open to air enclosure sample atmospheric pressure.…”

Section: B Related Workmentioning

confidence: 99%

“…Notably, despite the lower costs and rapid adoption of LCS in various fields, deployment of these solutions in developing countries is uncommon [32], with technical and financial reasons among the barriers preventing wider adoption of LCS on that side of the world [34]. In general, the growing applications of LCS have seen a limited number of studies that provide open data in their reality and do not produce information for scientists and other potential stakeholders [36], [32].…”

Section: Introductionmentioning

confidence: 99%

“…It has been reported that low-cost sensors have been redesigned to provide more scalable and manageable instrumentation. The redesign of LCS has several advantages, including increased environmental spatial and temporal coverage, lower cost per sensor, and customization to a specific physical setting [36]. The simplicity, accuracy and robustness of these sensors have paved the way for promising alternatives in environmental monitoring [32], [38].…”

Section: Introductionmentioning

confidence: 99%

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Design and Application of a Low-Cost, Low- Power, LoRa-GSM, IoT Enabled System for Monitoring of Groundwater Resources With Energy Harvesting Integration

Kombo¹,

Kumaran

Bovim³

2021

IEEE Access

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The rapid expansion of Internet of Things (IoT) devices and applications has accelerated research in various areas of human development. However, the cost of commercial instrumentation impedes the momentum of technological growth in developing regions. In this study, a low-cost, low-power, wireless sensor network for groundwater monitoring (LWNGM) was developed to provide near real-time groundwater level data to support prudent decision making in groundwater resource management in Zanzibar, Tanzania. To facilitate reproducibility, we provided a detailed description of the LWNGM development procedure. The system is based on the ATmega328P microcontroller platform and incorporates low-cost MS5803-14BA and MB280 sensors. To provide a low-power scheme, the Arduino UNO wakes up in six-hour intervals for measurements and data-logging to the SD card, and at twelve-hour intervals for relaying data (in batches) to the LoRa gateway, before it goes back into a deep-sleep mode for the rest of the time (duty cycle<1% ). The average power consumption for the end node across all system cycles was 104.081mW. The power autonomy of all nodes is provided by a 3.7V, 5000mAh rechargeable LiPo battery, and a 9V, 600mAh rechargeable Liion battery, respectively, which are supported by 6V and, 3W solar chargers. The data processing and storage components, as well as the data visualization dashboard, were created using free and open-source software. The LWNGM was reasonably priced, ranging between $350 and $400. The proposed system allows for the adoption of hydrological monitoring, particularly in areas with a limited budget for hydrologic management.

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Section: A Primer On Lora Radio Technologymentioning

confidence: 99%

Section: B Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Design and Application of a Low-Cost, Low- Power, LoRa-GSM, IoT Enabled System for Monitoring of Groundwater Resources With Energy Harvesting Integration

Kombo¹,

Kumaran

Bovim³

2021

IEEE Access

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“…With data transmission via high-gain antennae (e.g. Carvallo et al, 2017) or satellite internet, we hypothesise that low-cost sensors, embedded within an AI framework, could revolutionise mountain glacier monitoring, as it has done in many other geoscience disciplines (Chan et al, 2020). For example, such sensors could include Arduinos or Raspberry Pis (Vujovic and Maksimovic, 2014) that could act as a webcam, capture infrared images at night, detect thermal signatures, record acoustic events, detect ground displacement or tremors from calving, track velocity with GPS, or communicate with satellites for real-time ground-truthing.…”

Section: Artificial Intelligence and Machine Learningmentioning

confidence: 99%

Remote sensing of the mountain cryosphere: Current capabilities and future opportunities for research

Taylor

Quincey

Smith

et al. 2021

Progress in Physical Geography: Earth and Environment

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Remote sensing technologies are integral to monitoring the mountain cryosphere in a warming world. Satellite missions and field-based platforms have transformed understanding of the processes driving changes in mountain glacier dynamics, snow cover, lake evolution, and the associated emergence of hazards (e.g. avalanches, floods, landslides). Sensors and platforms are becoming more bespoke, with innovation being driven by the commercial sector, and image repositories are more frequently open access, leading to the democratisation of data analysis and interpretation. Cloud computing, artificial intelligence, and machine learning are rapidly transforming our ability to handle this exponential increase in data. This review therefore provides a timely opportunity to synthesise current capabilities in remote sensing of the mountain cryosphere. Scientific and commercial applications were critically examined, recognising the technologies that have most advanced the discipline. Low-cost sensors can also be deployed in the field, using microprocessors and telecommunications equipment to connect mountain glaciers to stakeholders for real-time monitoring. The potential for novel automated pipelines that can process vast volumes of data is also discussed, from reimagining historical aerial imagery to produce elevation models, to automatically delineating glacier boundaries. Finally, the applications of these emerging techniques that will benefit scientific research avenues and real-world societal programmes are discussed.

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Arduinos in the wild: A novel, low‐cost sensor network for high‐resolution microclimate monitoring in remote ecosystems

Mühlbauer,

Zavattoni,

Virtanen

et al. 2023

Ecol Sol and Evidence

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The importance of microclimate conditions is becoming increasingly recognised in ecological research, especially as they can differ widely from macro‐ and mesoclimate. Effective measurement of microclimate variability in heterogeneous field conditions requires measurements from a large number of sensors, ideally sampling across both small and large scales, which necessitates the development of cost‐effective sensor networks. Here, we develop an environmental microcontroller (EMU) sensor network for measuring soil moisture and temperature with high spatiotemporal coverage. The system can easily be implemented in larger or smaller setups, though our study consisted of 40 plots distributed across 4 sites in northern Lapland. Using 40 EMUs, each equipped with 10 soil temperature and 10 soil moisture sensors, we collected roughly 3.5 million unique soil temperature and moisture records over the course of about 2 months. We then compared these measurements to those from commercial temperature sensors (iButtons) and TDR soil moisture probes. We show that our sensor network is able to successfully characterise microclimate variation at the site, plot and within‐plot scales with high accuracy and good reliability. Moreover, even including development costs, the total price per EMU unit was less than €100, yielding a much cheaper and higher resolution system than is currently available from commercial producers. For both temperature and soil moisture, we found a strong relationship between the sensor network measurement and those obtained from commercial systems. Roughly 10% of the overall spatial variation in temperature and moisture occurred within plots—that is. over the scale of 25–50 cm. Our results show that accurate measurements of microclimate soil temperature and soil moisture can be obtained using low‐cost sensor networks. We also show that microclimate variability at small scales can make up a considerable fraction of total environmental variability. To this end, we discuss some of the difficulties encountered during the development process and suggest possible improvements for further studies. While the sensor network described here can be applied without any modifications for quantifying topsoil conditions, we note that with minor changes to our code and hardware, the system can be customised for other kinds of measurements.

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Low-cost electronic sensors for environmental research: Pitfalls and opportunities

Cited by 35 publications

References 91 publications

Design and Application of a Low-Cost, Low- Power, LoRa-GSM, IoT Enabled System for Monitoring of Groundwater Resources With Energy Harvesting Integration

Design and Application of a Low-Cost, Low- Power, LoRa-GSM, IoT Enabled System for Monitoring of Groundwater Resources With Energy Harvesting Integration

Remote sensing of the mountain cryosphere: Current capabilities and future opportunities for research

Arduinos in the wild: A novel, low‐cost sensor network for high‐resolution microclimate monitoring in remote ecosystems

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