Abstract
Vegetation height plays a key role in many environmental applications such as landscape characterization, conservation planning and disaster management, and biodiversity assessment and monitoring. Traditionally, in situ measurements and airborne Light Detection and Ranging (LiDAR) sensors are among the commonly employed methods for vegetation height estimation. However, such methods are known for their high incurred labor, time, and infrastructure cost. The emergence of wearable technology offers a promising alternative, especially in rural environments and underdeveloped countries. A method for a locally designed data acquisition ubiquitous wearable platform has been put forward and implemented. Next, a regression model to learn vegetation height on the basis of attributes associated with a pressure sensor has been developed and tested. The proposed method has been tested in Oulu region. The results have proven particularly effective in a region where the land has a forestry structure. The linear regression model yields (r2 = 0.81 and RSME = 16.73 cm), while the use of a multi-regression model yields (r2 = 0.82 and RSME = 15.73 cm). The developed approach indicates a promising alternative in vegetation height estimation where in situ measurement, LiDAR data, or wireless sensor network is either not available or not affordable, thus facilitating and reducing the cost of ecological monitoring and environmental sustainability planning tasks.
Highlights
Vegetation height is a key indicator for many terrestrial ecosystems linked to habitats, their biodiversity, and biomass structure (Hyde et al 2006; Dong and Wu 2008; Nilsson 1996)
Our study aims to overcome the challenges of such operational costs experienced in remote sensing technologies and wireless sensor network (WSN) deployment infrastructure, by utilizing low-cost sensors in the form of wearable devices
We have conduced the analysis of variance (ANOVA) to identify the level of variability within the corresponding regression model and quantifies the significance level
Summary
Vegetation height is a key indicator for many terrestrial ecosystems linked to habitats, their biodiversity, and biomass structure (Hyde et al 2006; Dong and Wu 2008; Nilsson 1996). A comparative study conducted by Hyde et al (2006) using airborne LiDAR, SAR/InSAR, satellite Landsat ETM+, and Quickbird examined the estimation of canopy height in a forest structure in the USA. Wang et al (2011) employed a MODIS sensor with a moderate resolution imaging spectroradiometer for estimating vegetation height in a large forest region area of the USA and Costa Rica. Such techniques are alleged to be less effective and challenging with the short vegetation height mainly because short vegetation height does not provide detectable increase among the initial and last LiDar return (Petzold et al 1999). This is reinforced by Rosso’s study (Rosso et al 2006) which compared measurable errors of dataset obtained from LiDar and ground measurement in order to characterize wetland topology, and concluded that LiDar-based analysis has no potential to influence the ground
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