多光谱图像
扰动(地质)
激光雷达
遥感
环境科学
生态学
地理
环境资源管理
地质学
生物
古生物学
作者
Chima Iheaturu,Samuel Hepner,Jonathan L. Batchelor,Georges Alex Agonvonon,Felicia O. Akinyemi,Vladimir Wingate,Chinwe Ifejika Speranza
标识
DOI:10.1016/j.ecoinf.2024.102876
摘要
Unmanned aerial vehicle (UAV) technologies have emerged as promising tools to improve forest ecosystem assessments. These technologies offer high-resolution data that can significantly enhance evaluations of forest structure, condition, and disturbance severity. UAV sensors such as LiDAR and multispectral provide complementary information about forest attributes, capturing structural and spectral details, yet their integration for comprehensive forest assessment remains understudied. In this paper, we explored the potential of combining UAV LiDAR and multispectral data to assess the disturbance severity of a West African forest patch (Benin). We developed an integrated disturbance index (IDI) that fuses structural properties from LiDAR data and spectral characteristics from multispectral vegetation indices through principal component analysis (PCA). This allowed us to delineate low (> 0.65), medium (0.35–0.65), and high (< 0.35) forest disturbance levels. We applied the IDI to the 560-ha Ewe-Adakplame relict forest in Benin, West Africa, and achieved 95 % overall accuracy in disturbance detection, outperforming both LiDAR-only (80 %) and multispectral-only (75 %) approaches. The IDI revealed that 23 % of the forest area has experienced low disturbance, while 28 % and 49 % face medium and high disturbance levels, respectively. These findings highlight that more than three-quarters of this relict forest is under considerable stress, underscoring the urgent need for tailored conservation strategies to strengthen forest resilience. This method's ability to differentiate disturbance levels can inform resource allocation, prioritize conservation efforts, and guide the development of site-specific management plans. The integration of UAV LiDAR and multispectral data demonstrated here has potential for application across diverse tropical forest patches, providing an effective means to monitor forest health, assess disturbance severity, and support data-driven decision-making in forest conservation and sustainable management. • Fused UAV LiDAR and multispectral data to map forest status and disturbance severity. • Derived an integrated disturbance index through principal component analysis. • The integrated disturbance index outperformed individual sensors used alone. • The method can enable tailored conservation interventions, thereby optimizing resource allocation.
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