TY  - JOUR
A1  - Mielke, Christian
A1  - Rogass, Christian
A1  - Bösche, Nina Kristine
A1  - Segl, Karl
A1  - Altenberger, Uwe
T1  - EnGeoMAP 2.0-Automated Hyperspectral Mineral Identification for the German EnMAP Space Mission
JF  - Remote sensing
N2  - Algorithms for a rapid analysis of hyperspectral data are becoming more and more important with planned next generation spaceborne hyperspectral missions such as the Environmental Mapping and Analysis Program (EnMAP) and the Japanese Hyperspectral Imager Suite (HISUI), together with an ever growing pool of hyperspectral airborne data. The here presented EnGeoMAP 2.0 algorithm is an automated system for material characterization from imaging spectroscopy data, which builds on the theoretical framework of the Tetracorder and MICA (Material Identification and Characterization Algorithm) of the United States Geological Survey and of EnGeoMAP 1.0 from 2013. EnGeoMAP 2.0 includes automated absorption feature extraction, spatio-spectral gradient calculation and mineral anomaly detection. The usage of EnGeoMAP 2.0 is demonstrated at the mineral deposit sites of Rodalquilar (SE-Spain) and Haib River (S-Namibia) using HyMAP and simulated EnMAP data. Results from Hyperion data are presented as supplementary information.
KW  - EnMAP
KW  - Hyperion
KW  - EnGeoMAP 2
KW  - 0
KW  - mineral mapping
KW  - imaging spectroscopy
Y1  - 2016
U6  - https://doi.org/10.3390/rs8020127
SN  - 2072-4292
VL  - 8
SP  - 392
EP  - 414
PB  - MDPI
CY  - Basel
ER  - 
TY  - JOUR
A1  - Mielke, Christian
A1  - Muedi, T.
A1  - Papenfuss, Anne
A1  - Bösche, Nina Kristine
A1  - Rogass, C.
A1  - Gauert, C. D. K.
A1  - Altenberger, Uwe
A1  - de Wit, M. J.
T1  - Multi- and hyperspectral spaceborne remote sensing of the Aggeneys base metal sulphide mineral deposit sites in the Lower Orange River region, South Africa
JF  - South African Journal of Geology
N2  - New tools and algorithms for geological femote Sensing are developed and verified at test sites throughout the world in preparation of the German hyperspectral satellite Mission (EnMAP), which is an Environmental Mapping and Analysis Program. The aggeneys Cu-Pb-Zn deposit, situated in the arid north western part of South Africa, represents a unique field laboratory for testing these new tools. Here spaceborne hyperspectral data covering the Swartberg, and hyperspectral spaceborne data can be demonkrated, such as the Iron Feature Depth index (IFD), which has recently been proposed for mine waste mapping in the North West Province of South Africa and for gossan detection at Haib River in South Namibia. The work presented here explores the potential of the IFD for gossan mapping and characterization at Gamsberg and Big Syncline, from EO-1 ALI and Landsat-8 OLI data together with mineral maps from expert systems such as the United States Geological Survey (USGS) Material Identification and Characterization Algorithm (MICA), and first results from EnMAPs EnGeoMAP algorithm. Field spectroscopic measurements and field sampling were carried out to validate and calibrate the results from the expert systems and the IFD. This ground truthing is a necessary complementary step to link the results from the expert systems and the IFD to in-situ field spectroscopy. Future mineral exploration initiatives may benefit from the techniques described here, because they can significantly narrow the expensive, exploration activities such as hyperspectral airborne data, field activities and drilling, by identifying the most promising mineral anomalies in an area from the spaceborne data.
Y1  - 2016
U6  - https://doi.org/10.2113/gssajg.119.1.63
SN  - 1012-0750
SN  - 1996-8590
VL  - 119
SP  - 63
EP  - 76
PB  - Geological Society of South Africa
CY  - Marshalltown
ER  - 
TY  - JOUR
A1  - Mielke, Christian
A1  - Bösche, Nina Kristine
A1  - Rogass, Christian
A1  - Kaufmann, Hermann
A1  - Gauert, Christoph
A1  - de Wit, Maarten
T1  - Spaceborne mine waste mineralogy monitoring in South Africa, applications for modern push-broom missions: Hyperion/OLI and EnMAP/Sentinel-2
JF  - Remote sensing
N2  - Remote sensing analysis is a crucial tool for monitoring the extent of mine waste surfaces and their mineralogy in countries with a long mining history, such as South Africa, where gold and platinum have been produced for over 90 years. These mine waste sites have the potential to contain problematic trace element species (e. g., U, Pb, Cr). In our research, we aim to combine the mapping and monitoring capacities of multispectral and hyperspectral spaceborne sensors. This is done to assess the potential of existing multispectral and hyperspectral spaceborne sensors (OLI and Hyperion) and future missions, such as Sentinel-2 and EnMAP (Environmental Mapping and Analysis Program), for mapping the spatial extent of these mine waste surfaces. For this task we propose a new index, termed the iron feature depth (IFD), derived from Landsat-8 OLI data to map the 900-nm absorption feature as a potential proxy for monitoring the spatial extent of mine waste. OLI was chosen, because it represents the most suitable sensor to map the IFD over large areas in a multi-temporal manner due to its spectral band layout; its (183 km x 170 km) scene size and its revisiting time of 16 days. The IFD is in good agreement with primary and secondary iron-bearing minerals mapped by the Material Identification and Characterization Algorithm (MICA) from EO-1 Hyperion data and illustrates that a combination of hyperspectral data (EnMAP) for mineral identification with multispectral data (Sentinel-2) for repetitive area-wide mapping and monitoring of the IFD as mine waste proxy is a promising application for future spaceborne sensors. A maximum, absolute model error is used to assess the ability of existing and future multispectral sensors to characterize mine waste via its 900-nm iron absorption feature. The following sensor-signal similarity ranking can be established for spectra from gold mining material: EnMAP 100% similarity to the reference, ALI 97.5%, Sentinel-2 97%, OLI and ASTER 95% and ETM+ 91% similarity.
KW  - mine waste
KW  - spatial extent
KW  - gold
KW  - platinum
KW  - South Africa
KW  - EnMAP
KW  - OLI
KW  - Hyperion
KW  - Sentinel-2
KW  - iron feature depth (IFD)
Y1  - 2014
U6  - https://doi.org/10.3390/rs6086790
SN  - 2072-4292
VL  - 6
IS  - 8
SP  - 6790
EP  - 6816
PB  - MDPI
CY  - Basel
ER  - 
TY  - JOUR
A1  - Mielke, Christian
A1  - Bösche, Nina Kristine
A1  - Rogass, Christian
A1  - Kaufmann, Hermann
A1  - Gauert, Christoph
T1  - New geometric hull continuum removal algorithm for automatic absorption band detection from spectroscopic data
JF  - Remote sensing letters : an official journal of the Remote Sensing and Photogrammetry Society
N2  - Modern imaging spectrometers produce an ever-growing amount of data, which increases the need for automated analysis techniques. The algorithms employed, such as the United States Geological Survey (USGS) Tetracorder and the Mineral Identification and Characterization Algorithm (MICA), use a standardized spectral library and expert knowledge for the detection of surface cover types. Correct absorption feature definition and isolation are key to successful material identification using these algorithms. Here, a new continuum removal and feature isolation technique is presented, named the 'Geometric Hull Technique'. It is compared to the well-established, knowledge-based Tetracorder feature database together with the adapted state of the art techniques scale-space filtering, alpha shapes and convex hull.
 The results show that the geometric hull technique yields the smallest deviations from the feature definitions of the MICA Group 2 library with a median difference of only 8nm for the position of the features and a median difference of only 15% for the feature shapes. The modified scale-space filtering hull technique performs second best with a median feature position difference of 16nm and a median difference of 25% for the feature shapes. The scale-space alpha hull technique shows a 23nm median position difference and a median deviation of 77% for the feature shapes. The geometric hull technique proposed here performs best amongst the four feature isolation techniques and may be an important building block for next generation automatic mapping algorithms.
Y1  - 2015
U6  - https://doi.org/10.1080/2150704X.2015.1007246
SN  - 2150-704X
SN  - 2150-7058
VL  - 6
IS  - 2
SP  - 97
EP  - 105
PB  - Routledge, Taylor & Francis Group
CY  - Abingdon
ER  - 
TY  - JOUR
A1  - Bösche, Nina Kristine
A1  - Rogass, Christian
A1  - Lubitz, Christin
A1  - Brell, Maximilian
A1  - Herrmann, Sabrina
A1  - Mielke, Christian
A1  - Tonn, Sabine
A1  - Appelt, Oona
A1  - Altenberger, Uwe
A1  - Kaufmann, Hermann
T1  - Hyperspectral REE (Rare Earth Element) Mapping of Outcrops-Applications for Neodymium Detection
JF  - Remote sensing
N2  - In this study, an in situ application for identifying neodymium (Nd) enriched surface materials that uses multitemporal hyperspectral images is presented (HySpex sensor). Because of the narrow shape and shallow absorption depth of the neodymium absorption feature, a method was developed for enhancing and extracting the necessary information for neodymium from image spectra, even under illumination conditions that are not optimal. For this purpose, the two following approaches were developed: (1) reducing noise and analyzing changing illumination conditions by averaging multitemporal image scenes and (2) enhancing the depth of the desired absorption band by deconvolving every image spectrum with a Gaussian curve while the rest of the spectrum remains unchanged (Richardson-Lucy deconvolution). To evaluate these findings, nine field samples from the Fen complex in Norway were analyzed using handheld X-ray fluorescence devices and by conducting detailed laboratory-based geochemical rare earth element determinations. The result is a qualitative outcrop map that highlights zones that are enriched in neodymium. To reduce the influences of non-optimal illumination, particularly at the studied site, a minimum of seven single acquisitions is required. Sharpening the neodymium absorption band allows for robust mapping, even at the outer zones of enrichment. From the geochemical investigations, we found that iron oxides decrease the applicability of the method. However, iron-related absorption bands can be used as secondary indicators for sulfidic ore zones that are mainly enriched with rare earth elements. In summary, we found that hyperspectral spectroscopy is a noninvasive, fast and cost-saving method for determining neodymium at outcrop surfaces.
Y1  - 2015
U6  - https://doi.org/10.3390/rs70505160
SN  - 2072-4292
VL  - 7
IS  - 5
SP  - 5160
EP  - 5186
PB  - MDPI
CY  - Basel
ER  -