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A publicação pode ser exportada nos seguintes formatos: referência da APA (American Psychological Association), referência do IEEE (Institute of Electrical and Electronics Engineers), BibTeX e RIS.

Exportar Referência (APA)
Pascoal, R. M., Naranjo Gómez, J. & Ricarte, É. (2026). EfMAR: An outdoor mobile augmented reality framework for geospatial measurements. Sensors. 26 (13)
Exportar Referência (IEEE)
R. M. Pascoal et al.,  "EfMAR: An outdoor mobile augmented reality framework for geospatial measurements", in Sensors, vol. 26, no. 13, 2026
Exportar BibTeX
@article{pascoal2026_1784188985504,
	author = "Pascoal, R. M. and Naranjo Gómez, J. and Ricarte, É.",
	title = "EfMAR: An outdoor mobile augmented reality framework for geospatial measurements",
	journal = "Sensors",
	year = "2026",
	volume = "26",
	number = "13",
	doi = "10.3390/s26134063",
	url = "https://www.mdpi.com/journal/sensors"
}
Exportar RIS
TY  - JOUR
TI  - EfMAR: An outdoor mobile augmented reality framework for geospatial measurements
T2  - Sensors
VL  - 26
IS  - 13
AU  - Pascoal, R. M.
AU  - Naranjo Gómez, J.
AU  - Ricarte, É.
PY  - 2026
SN  - 1424-8220
DO  - 10.3390/s26134063
UR  - https://www.mdpi.com/journal/sensors
AB  - Accurate distance measurement in outdoor environments remains a challenging problem for mobile augmented reality (AR) systems due to sensor noise, environmental variability, and the limitations of single-modality approaches. Existing consumer AR solutions often prioritize usability over metric robustness, leading to performance degradation in large-scale or heterogeneous outdoor scenarios. This work presents EfMAR, an adaptive framework for outdoor mobile AR-based geospatial measurements that integrates multiple sensing modalities through a structured sensor fusion architecture. EfMAR combines visual SLAM, inertial sensing, depth information, and global positioning cues to improve robustness and consistency in distance estimation across diverse outdoor conditions. Beyond implementation, the framework formalizes a reusable architectural model for adaptive multi-sensor fusion, supporting reproducibility and future comparative research. A dedicated dataset is described, comprising 584 unique real-world evaluation instances collected across representative outdoor scenarios. External literature-derived data were utilized strictly as calibration baselines for modeled operational degradation profiles, maintaining methodological transparency. Performance evaluation focuses on analyzing relative behavior, stability, and variability across sensing approaches rather than establishing absolute accuracy benchmarks. Comparative results across multiple distance ranges and environments indicate that hybrid sensor fusion strategies exhibit more stable and consistent performance trends compared to single-modality solutions, particularly in challenging urban contexts. Dispersion analysis further highlights the influence of environmental factors such as lighting conditions and spatial scale on measurement variability. Overall, the results position EfMAR as a flexible and adaptive framework designed to enhance robustness in outdoor AR-based geospatial measurement tasks. By emphasizing consistency, transparency, and architectural generalization, this work contributes a practical foundation for future research and development in mobile AR sensing for real-world outdoor applications.
ER  -