Assessing the effect of different ground sampling distances for drone-based mapping of fractional cover: a case study from a vineyard field in Northern Greece

Monitoring the fractional cover of vegetation and bare soil is essential for sustainable land management, soil erosion control, and precision agriculture. However, accurately estimating these fractions from conventional satellite imagery is challenging due to mixed ground cover and limitations such as cloud contamination and coarse spatiotemporal resolution. High-resolution UAV imagery provides an effective solution by capturing fine-scale heterogeneity, enabling the application of spectral mixture modeling techniques to decompose each pixel into proportions of vegetation, bare soil, and other components. Understanding how GSD influences the performance of such mixture models is critical for optimizing UAV-based monitoring strategies and ensuring reliable, quantitative estimates of soil and vegetation fractions for informed land management decisions.

The objective of this study is to evaluate the sensitivity of fractional vegetation estimates to different ground sampling distances (GSDs) derived from unmanned aerial vehicle (UAV) imagery. Multispectral data were acquired using a UAV equipped with RGB, near-infrared, red, and red-edge sensors, flown at altitudes of 40 m, 80 m, and 120 m above ground level. The study area is a heterogeneous vineyard located in Drama, Macedonia, northern Greece. Image acquisition took place on 30 July 2025, under stable atmospheric and illumination conditions.

An object-based image analysis (OBIA) approach was applied to the UAV imagery, and the data were classified into three main land cover classes: photosynthetic vegetation, non-photosynthetic vegetation, and bare soil. Fractional vegetation cover estimates derived at each flight altitude were compared in order to assess the influence of spatial resolution on classification performance and vegetation fraction retrieval. Validation of the classification results was performed using an independent dataset generated through direct photo interpretation, allowing for an objective assessment of accuracy across the different GSDs.

This contribution aims to evaluate the effects of different ground sampling distances (GSDs) on the estimation of fractional vegetation cover (FVC) using multispectral UAV imagery over commercial vineyards in Northern Greece. The study highlights the influence of spatial resolution on canopy representation, particularly in young or sparsely developed vineyards, and supports the development of robust UAV-based tools for precision viticulture

Keywords: UAV, Vineyard, Fractional Vegetation Cover , ACCELERATE

Acknowledgement: This study is supported by ACCELERATE research project which has received funding from the European Union’s Horizon  research and innovation program under grant agreement No.101182930.