Temporal interpolation of land surface fluxes derived from remote
sensing – results with an Unmanned Aerial System

Garcı́a, M. Esther; Ibrom, Andreas; Bauer‐Gottwein, Peter

doi:10.5194/hess-2019-490

Cited by 2 publications

(2 citation statements)

References 47 publications

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“…Lightweight drones have the further benefit of low financial cost, flexibility and enable deployment also in remote and harsh environments [10,11]. In tandem with the development and production of compact and lightweight turnkey multispectral sensors, there has been a surge in drone-based multispectral data applications during recent years which make use of the fine spatial resolution or frequent revisit capabilities [12][13][14][15]. Popular sensor solutions are multi-camera array (MCA) systems such as the Parrot Sequoia (Parrot SA, France) and Micasense RedEdge (Micasense, US) which consist of individual cameras with different band-pass filters to record reflected light at specific narrow (10-40 nm) wavelength intervals.…”

Section: Introductionmentioning

confidence: 99%

Multi-Scale Evaluation of Drone-Based Multispectral Surface Reflectance and Vegetation Indices in Operational Conditions

et al. 2020

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Compact multi-spectral sensors that can be mounted on lightweight drones are now widely available and applied within the geo- and environmental sciences. However; the spatial consistency and radiometric quality of data from such sensors is relatively poorly explored beyond the lab; in operational settings and against other sensors. This study explores the extent to which accurate hemispherical-conical reflectance factors (HCRF) and vegetation indices (specifically: normalised difference vegetation index (NDVI) and chlorophyll red-edge index (CHL)) can be derived from a low-cost multispectral drone-mounted sensor (Parrot Sequoia). The drone datasets were assessed using reference panels and a high quality 1 m resolution reference dataset collected near-simultaneously by an airborne imaging spectrometer (HyPlant). Relative errors relating to the radiometric calibration to HCRF values were in the 4 to 15% range whereas deviations assessed for a maize field case study were larger (5 to 28%). Drone-derived vegetation indices showed relatively good agreement for NDVI with both HyPlant and Sentinel 2 products (R2 = 0.91). The HCRF; NDVI and CHL products from the Sequoia showed bias for high and low reflective surfaces. The spatial consistency of the products was high with minimal view angle effects in visible bands. In summary; compact multi-spectral sensors such as the Parrot Sequoia show good potential for use in index-based vegetation monitoring studies across scales but care must be taken when assuming derived HCRF to represent the true optical properties of the imaged surface.

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Section: Introductionmentioning

confidence: 99%

Multi-Scale Evaluation of Drone-Based Multispectral Surface Reflectance and Vegetation Indices in Operational Conditions

et al. 2020

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“…Furthermore, Wang et al. (2020) developed a dynamic soil‐vegetation‐atmosphere transfer model to temporally interpolate the UAV‐based snapshots of land surface fluxes into continuous estimates. Thomas et al.…”

Section: Land‐atmosphere Interactionsmentioning

confidence: 99%

Unmanned Aerial Vehicles in Hydrology and Water Management: Applications, Challenges, and Perspectives

Acharya

Bhandari

Bandini

et al. 2021

Water Resources Research

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Global water withdrawal and usage have risen nearly sixfold since 1900. Approximately 69% of water withdrawals are used in agriculture, 19% in industries, and 12% for municipal purposes (Food and Agriculture Organization of the United Nations, 2020). Anthropogenic disturbances and climate change affect the water cycle, water supply and demand, and impose stress on the global water systems (Haddeland et al., 2014). As such, hydrologists, geologists, agronomists, soil scientists, and engineers need reliable tools to monitor and manage surface and groundwater resources, particularly in locations where traditional monitoring is inadequate.Traditional water monitoring and measurement techniques are time-consuming, costly, and typify an inadequate and disproportionate spatial and temporal range. Over the past few decades, airplanes and satellites have been the chief source of remotely sensed water resource data. However, the usefulness of these platforms is mainly restricted to the largest spatial scales. The low frequency of temporal sampling is dictated by logistical costs (aerial imagery) or tasking schedules (satellites; Becker et al., 2009;Xue & Su, 2017). The dearth of finer resolution data and temporal inflexibility of these platforms precludes the possibility of on-demand data acquisition that is often necessary to capture the highly transient processes operating at fine spatial scales necessary for the planning and management of water resources (e.g., freshwater abstraction) and the assessment of hazards (e.g., flood extents). However, with recent advances in sensors, cameras,

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Temporal interpolation of land surface fluxes derived from remote sensing – results with an Unmanned Aerial System

Cited by 2 publications

References 47 publications

Multi-Scale Evaluation of Drone-Based Multispectral Surface Reflectance and Vegetation Indices in Operational Conditions

Multi-Scale Evaluation of Drone-Based Multispectral Surface Reflectance and Vegetation Indices in Operational Conditions

Unmanned Aerial Vehicles in Hydrology and Water Management: Applications, Challenges, and Perspectives

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