Journal Design Engineering Masthead
African Structural Engineering | 09 September 2026

Design and Deployment of a Low-Cost IoT Sensor Network for Real-Time Environmental Monitoring in Togolese Mining Operations

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DOI: https://doi.org/10.5281/zenodo.18964664
IoT Sensor NetworksEnvironmental MonitoringLow-Cost SensorsMining Operations
Validated IoT network shows 12.3% mean error for PM2.5 versus commercial instruments.
Spatial analysis reveals 28% higher PM2.5 downwind of primary extraction zones.
System provides real-time data for proactive environmental management in West Africa.
LoRaWAN enables long-range, low-power communication in remote field deployments.

Abstract

{ "background": "Mining operations in West Africa face significant challenges in monitoring environmental impacts, particularly concerning dust and water quality. Conventional monitoring systems are often cost-prohibitive and lack real-time data capabilities, leading to reactive rather than proactive environmental management.", "purpose and objectives": "This study aimed to design, fabricate, and deploy a novel, low-cost Internet of Things (IoT) sensor network specifically for real-time particulate matter (PM2.5) and pH monitoring in active mining areas. The objective was to validate the system's reliability and accuracy against commercial instruments under field conditions.", "methodology": "A network of custom-built sensor nodes was developed using Arduino microcontrollers, low-cost PM2.5 optical sensors, and pH probes. Data transmission utilised LoRaWAN for long-range, low-power communication to a central gateway. The network was deployed across three operational zones within a mining site. Performance was evaluated using a linear mixed-effects model: $PM{2.5\\ (measured)} = \\beta0 + \\beta1 PM{2.5\\ (reference)} + u{site} + \\epsilon$, with robust standard errors to account for spatial clustering.", "findings": "The IoT network achieved a mean absolute percentage error of 12.3% for PM2.5 concentrations compared to a calibrated reference instrument. The statistical model showed a strong linear relationship ($\\beta1 = 0.94$, 95% CI: 0.89 to 0.99). Spatial analysis revealed that PM2.5 levels were, on average, 28% higher downwind of the primary extraction zone compared to upwind control points.", "conclusion": "The developed system provides a viable, cost-effective solution for continuous environmental monitoring in resource-limited settings. It delivers data of sufficient accuracy for operational oversight and identifying pollution hotspots in near real-time.", "recommendations": "Mining operators should integrate such low-cost IoT networks into their environmental management plans for continuous compliance monitoring. Future work