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Vieira, T., Paiva, S., Marinheiro, R. N. & Brito e Abreu, F. (2025). Building Optimized Wireless Pedestrian Counting Sensors Combining Passive and Active Technologies. In The 16th International Conference on Ubiquitous and Future Networks (ICUFN). (pp. 574-581). Lisbon

T. F. Vieira et al.,  "Building Optimized Wireless Pedestrian Counting Sensors Combining Passive and Active Technologies", in The 16th Int. Conf. on Ubiquitous and Future Networks (ICUFN), Lisbon, 2025, pp. 574-581

@inproceedings{vieira2025_1764926915754,
	author = "Vieira, T. and Paiva, S. and Marinheiro, R. N. and Brito e Abreu, F.",
	title = "Building Optimized Wireless Pedestrian Counting Sensors Combining Passive and Active Technologies",
	booktitle = "The 16th International Conference on Ubiquitous and Future Networks (ICUFN)",
	year = "2025",
	editor = "",
	volume = "",
	number = "",
	series = "",
	doi = "10.1109/ICUFN65838.2025.11170080",
	pages = "574-581",
	publisher = "",
	address = "Lisbon",
	organization = "IEEE",
	url = "https://icufn.org"
}

TY  - CPAPER
TI  - Building Optimized Wireless Pedestrian Counting Sensors Combining Passive and Active Technologies
T2  - The 16th International Conference on Ubiquitous and Future Networks (ICUFN)
AU  - Vieira, T.
AU  - Paiva, S.
AU  - Marinheiro, R. N.
AU  - Brito e Abreu, F.
PY  - 2025
SP  - 574-581
DO  - 10.1109/ICUFN65838.2025.11170080
CY  - Lisbon
UR  - https://icufn.org
AB  - Pedestrian flow monitoring plays a vital role in urban planning, transportation management, and smart city or tourism applications. However, monitoring is often needed in challenging scenarios with spatial constraints, low traffic, no power supply, and poor network connectivity, such as birdwatching observatories or open-air heritage sites.
This paper presents a cost-effective, energy-efficient pedestrian counting system tailored for such isolated locations. The system uses two pairs of active infrared (AIR) sensors to count individuals and determine movement direction. To reduce energy consumption, passive infrared (PIR) sensors are used to trigger both the AIR detectors and an IoT board that handles local processing and communication. Depending on local conditions, LoRaWAN or Wi-Fi is used for uplink communication, allowing flexible deployment.
The architecture is built with open-source software and off-the-shelf hardware, supporting low-cost real-world implementation. A comparative analysis of several AIR detectors was conducted, assessing power consumption, detection accuracy, susceptibility to interference, and horizontal beam angle. This fills a gap in the literature regarding the systematic evaluation of AIR sensors. Results highlight the effectiveness of the proposed system in achieving both accuracy and energy efficiency, supporting non-intrusive pedestrian monitoring in various smart city and tourism contexts. The system is currently being deployed and evaluated in the Tagus Estuary Bird Observation and Conservation Area (EVOA).
ER  -