Mineralogical Mapping with Accurately Corrected Shortwave Infrared Hyperspectral Data Acquired Obliquely from UAVs

Thiele, Samuel T.; Bnoulkacem, Zakaria; Lorenz, Sandra; Bordenave, A.; Menegoni, Niccolò; Madriz, Yuleika; Dujoncquoy, Emmanuel; Gloaguen, Richard; Kenter, J.A.M.

doi:10.3390/rs14010005

Cited by 12 publications

(9 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…All of which is detailed on in the next sections. Only a limited number of publications using UAS-mounted SWIR cameras are currently available (e.g., [80][81][82][83][84]), which means this research field is only just emerging and our understanding of good methodologies remains nascent. Similarly, the best-practice guidelines for the acquisition and correction of coaligned VNIR-SWIR datasets, and accurate georeferencing and geometrical correction of such combined datasets, remain a topic of current research.…”

Section: Best-practice For Uas-based Spectral Imagingmentioning

confidence: 99%

Imaging Spectroscopy for the Mining Life Cycle: A Guide for Drone Applications

Koerting,

Asadzadeh,

Hildebrand

et al. 2024

Preprint

View full text Add to dashboard Cite

Hyperspectral imaging data holds great potential for the different stages of the mining life cycle in active and post-mining environments. However, the technology has yet to reach the stage of large-scale industrial implementation and acceptance. While hyperspectral satellite imagery can achieve high spectral resolution, signal-to-noise ratio (SNR) and global availability with break-through satellite systems like EnMAP, EMIT and PRISMA, limited spatial resolution poses chal-lenges for sectors like mining, which require decimetre to centimetre scale resolution for applica-tions such as reconciliation, ore/waste estimates, geotechnical assessments and environmental monitoring. Hyperspectral imaging from drones (referred to herein as Uncrewed Aerial Systems; UASs) offers high spatial resolution data relevant to the camp/ mine scale, with the capability for frequent, user-defined re-visit times. This has been made possible by the miniaturization of hy-perspectral imaging systems. Collection of data in the visible to near and shortwave infrared (VNIR-SWIR) wavelength regions enables the detection of different minerals and surface altera-tion patterns potentially revealing crucial information for exploration, extraction, re-mining, waste remediation, and rehabilitation. In this paper, we provide a review of relevant studies de-ploying hyperspectral imaging in or applicable to the mining sector, especially for the use of hy-perspectral VNIR-SWIR Uncrewed Aerial Systems. Where required, we draw on previous in-sights derived from satellite or ground-based systems. We also discuss UAS survey planning, and sampling considerations for validation and interpretation.

show abstract

Section: Best-practice For Uas-based Spectral Imagingmentioning

confidence: 99%

Imaging Spectroscopy for the Mining Life Cycle: A Guide for Drone Applications

Koerting,

Asadzadeh,

Hildebrand

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…The data produced by hyper-spectral cameras are not only useful for investigating the reflected spectral intensity of green plants but also for analyzing the chemical properties of ground targets. Hyper-spectral data can provide information about the chemical composition and water content of soil [48], as well as the chemical composition of ground minerals [49,50]. This is because hyper-spectral cameras can capture data across many narrow and contiguous wavelength bands, allowing for detailed analysis of the unique spectral signatures of different materials.…”

Section: Multi-spectral and Hyper-spectral Cameramentioning

confidence: 99%

A Review on Unmanned Aerial Vehicle Remote Sensing: Platforms, Sensors, Data Processing Methods, and Applications

Zhang

Zhu

2023

Drones

View full text Add to dashboard Cite

In recent years, UAV remote sensing has gradually attracted the attention of scientific researchers and industry, due to its broad application prospects. It has been widely used in agriculture, forestry, mining, and other industries. UAVs can be flexibly equipped with various sensors, such as optical, infrared, and LIDAR, and become an essential remote sensing observation platform. Based on UAV remote sensing, researchers can obtain many high-resolution images, with each pixel being a centimeter or millimeter. The purpose of this paper is to investigate the current applications of UAV remote sensing, as well as the aircraft platforms, data types, and elements used in each application category; the data processing methods, etc.; and to study the advantages of the current application of UAV remote sensing technology, the limitations, and promising directions that still lack applications. By reviewing the papers published in this field in recent years, we found that the current application research of UAV remote sensing research can be classified into four categories according to the application field: (1) Precision agriculture, including crop disease observation, crop yield estimation, and crop environmental observation; (2) Forestry remote sensing, including forest disease identification, forest disaster observation, etc.; (3) Remote sensing of power systems; (4) Artificial facilities and the natural environment. We found that in the papers published in recent years, image data (RGB, multi-spectral, hyper-spectral) processing mainly used neural network methods; in crop disease monitoring, multi-spectral data are the most studied type of data; for LIDAR data, current applications still lack an end-to-end neural network processing method; this review examines UAV platforms, sensors, and data processing methods, and according to the development process of certain application fields and current implementation limitations, some predictions are made about possible future development directions.

show abstract

“…Because remotely sensed spectral imaging via aerial or satellite data can only capture the external portions of rocks or rock masses, model calibration may be required for upscaling efforts. However, the increasing availability of hyperspectral remote sensing data, from satellites (e.g., PRISMA), airborne (e.g., AVIRIS), or ground-based platforms (Kereszturi et al, 2018;Cogliati et al, 2021;Thiele et al, 2022), is opening new avenues for the mapping and analysis of alteration and volcano stability at volcanoes worldwide. Furthermore, remote sensing methods are important as partially lithified pyroclastic rocks (e.g., breccia-horizons and tephra) are often complicated and difficult to measure accurately in the laboratory (Schaefer et al, 2018) and are also subject to eruptionrelated porosity changes and thermal cracking (Vinciguerra et al, 2005;Heap and Violay, 2021;Kanakiya et al, 2021).…”

Section: Implications For (Volcano) Slope Stability Analysismentioning

confidence: 99%

“…Reflectance spectroscopy has become increasingly used to explore soil and rock types by spectral band analysis, such as in the visible and near-infrared (350-1000 nm; VNIR), shortwave infrared (1000-2500 nm; SWIR) and thermal infrared (7000-13000 nm; TIR) bands relevant for hydrothermal alteration mapping (Rowan et al, 2003;Darmawan et al, 2018;Kereszturi et al, 2018;Müller et al, 2021). In particular, those alteration zones including iron oxide, as well as argillic, phyllic, and propylitic alterations min-erals, can be identified using both multispectral (Loughlin, 1991;Rowan et al, 2003) and hyperspectral data (Clark et al, 2003;Neal et al, 2018;Kereszturi et al, 2020;Thiele et al, 2022). Airborne, drone-based or carry-on devices can also effectively map physico-chemical changes of volcanic rocks and, when combined with effective processing algorithms (e.g., Partial Least Squares Regression) that can handle collinearity and high dimensionality (e.g., Wold et al, 2001), they can become effective platforms for characterising the mineralogy and alteration of volcanic rocks.…”

Section: Introductionmentioning

confidence: 99%