The Status of Earth Observation Techniques in Monitoring High Mountain Environments at the Example of Pasterze Glacier, Austria: Data, Methods, Accuracies, Processes, and Scales
暂无分享,去创建一个
Karlheinz Gutjahr | Matthias Schlögl | Michael A. Heroux | Barbara Widhalm | Christoph Hauer | Wolfgang Sulzer | Gernot Seier | Anton Neureiter | Christian Bauer | Michael Paster | Melina Frießenbichler | Gernot Weyss | Peter Flödl | M. Heroux | C. Bauer | Gernot Seier | W. Sulzer | C. Hauer | P. Flödl | M. Schlögl | B. Widhalm | K. Gutjahr | Anton Neureiter | G. Weyss | Michael Paster | Melina Frießenbichler
[1] Robert Charlier,et al. Engineering Geology for Infrastructure Planning in Europe , 2004 .
[2] Urs Wegmüller,et al. Mapping slope movements in Alpine environments using TerraSAR-X interferometric methods , 2015 .
[3] G. Moholdt,et al. Reanalysing glacier mass balance measurement series , 2013 .
[4] Andreas Kääb,et al. The 24 July 2008 outburst flood at the western Zyndan glacier lake and recent regional changes in glacier lakes of the Teskey Ala-Too range, Tien Shan, Kyrgyzstan , 2010 .
[5] S. Carver,et al. Contemporary geomorphological activity throughout the proglacial area of an alpine catchment , 2013 .
[6] Xiaodong Li,et al. Water Bodies' Mapping from Sentinel-2 Imagery with Modified Normalized Difference Water Index at 10-m Spatial Resolution Produced by Sharpening the SWIR Band , 2016, Remote. Sens..
[7] C. Hauer,et al. The non-fluvial nature of Western Norwegian rivers and the implications for channel patterns and sediment composition , 2018, CATENA.
[8] Josef Gspurning,et al. Contribution of UAS to the monitoring at the Lärchberg-Galgenwald landslide (Austria) , 2018 .
[9] Laurent Borgniet,et al. Using UAS optical imagery and SfM photogrammetry to characterize the surface grain size of gravel bars in a braided river (Vénéon River, French Alps) , 2017 .
[10] M. Sharp,et al. Development and application of a time-lapse photograph analysis method to investigate the link between tidewater glacier flow variations and supraglacial lake drainage events , 2013, Journal of Glaciology.
[11] J. Otto. Proglacial Lakes in High Mountain Environments , 2018, Geography of the Physical Environment.
[12] Oriol Monserrat,et al. DInSAR for a Regional Inventory of Active Rock Glaciers in the Dry Andes Mountains of Argentina and Chile with Sentinel-1 Data , 2018, Remote. Sens..
[13] Jan Klimeš,et al. Influence of glacial retreat on natural hazards of the Palcacocha Lake area, Peru , 2005 .
[14] Emmanuel P. Baltsavias,et al. Airborne laser scanning: basic relations and formulas , 1999 .
[15] David Parkes,et al. Attribution of global glacier mass loss to anthropogenic and natural causes , 2014, Science.
[16] Y. Sheng,et al. An automated scheme for glacial lake dynamics mapping using Landsat imagery and digital elevation models: a case study in the Himalayas , 2012 .
[17] M. Hoelzle,et al. Towards remote monitoring of sub-seasonal glacier mass balance , 2013, Annals of Glaciology.
[18] P. Holmlund,et al. Historically unprecedented global glacier decline in the early 21st century , 2015 .
[19] S. K. McFeeters. The use of the Normalized Difference Water Index (NDWI) in the delineation of open water features , 1996 .
[20] Matthias Huss,et al. Application and validation of long-range terrestrial laser scanning to monitor the mass balance of very small glaciers in the Swiss Alps , 2016 .
[21] L. Ravanel,et al. Effects of climate change on high Alpine mountain environments: Evolution of mountaineering routes in the Mont Blanc massif (Western Alps) over half a century , 2019, Arctic, Antarctic, and Alpine Research.
[22] Robert Kenner,et al. Investigation of rock and ice loss in a recently deglaciated mountain rock wall using terrestrial laser scanning: Gemsstock, Swiss Alps , 2011 .
[23] Tazio Strozzi,et al. Contemporary glacier retreat triggers a rapid landslide response, Great Aletsch Glacier, Switzerland , 2016 .
[24] Anshuman Bhardwaj,et al. UAVs as remote sensing platform in glaciology: Present applications and future prospects , 2016 .
[25] V. Kaufmann,et al. Glaciological Studies at Pasterze Glacier (Austria) Based on Aerial Photographs , 2015 .
[26] Stuart N. Lane,et al. Lidar measurement of surface melt for a temperate Alpine glacier at the seasonal and hourly scales , 2015, Journal of Glaciology.
[27] D. Milan. Terrestrial Laser Scanning of grain roughness in a gravel-bed river , 2009 .
[28] Y. Weidmann,et al. Remote sensing of glacier- and permafrost-related hazards in high mountains: an overview , 2005 .
[29] S. Robson,et al. 3‐D uncertainty‐based topographic change detection with structure‐from‐motion photogrammetry: precision maps for ground control and directly georeferenced surveys , 2017 .
[30] Theodora Lendzioch,et al. UAV-Based Optical Granulometry as Tool for Detecting Changes in Structure of Flood Depositions , 2017, Remote. Sens..
[31] Neil Entwistle,et al. Drone Based Quantification of Channel Response to an Extreme Flood for a Piedmont Stream , 2019, Remote. Sens..
[32] Andreas Kääb,et al. Glacier and Permafrost Hazards in High Mountains , 2005 .
[33] Brief communication: Ad hoc estimation of glacier contributions to sea-level rise from the latest glaciological observations , 2020 .
[34] Olivia C. Molden,et al. Impacts of Glacier Recession and Declining Meltwater on Mountain Societies , 2017, Mountains: Physical, Human-Environmental, and Sociocultural Dynamics.
[35] W. Bertoldi,et al. Ecosystem shifts in Alpine streams under glacier retreat and rock glacier thaw: A review. , 2019, The Science of the total environment.
[36] Tommy A. Noble,et al. Guidelines on the use of structure‐from‐motion photogrammetry in geomorphic research , 2019, Earth Surface Processes and Landforms.
[37] I. Colomina,et al. Unmanned aerial systems for photogrammetry and remote sensing: A review , 2014 .
[38] Mark W. Smith,et al. Fluvial and aquatic applications of Structure from Motion photogrammetry and unmanned aerial vehicle/drone technology , 2018, WIREs Water.
[39] A. Simmons,et al. The Concept of Essential Climate Variables in Support of Climate Research, Applications, and Policy , 2014 .
[40] D. Morche,et al. Coarse sediment dynamics in a proglacial fluvial system (Fagge River, Tyrol) , 2014 .
[41] H. Zebker,et al. A new method for measuring deformation on volcanoes and other natural terrains using InSAR persistent scatterers , 2004 .
[42] Pablo Sánchez-Gámez,et al. Glacier Surface Velocity Retrieval Using D-InSAR and Offset Tracking Techniques Applied to Ascending and Descending Passes of Sentinel-1 Data for Southern Ellesmere Ice Caps, Canadian Arctic , 2017, Remote. Sens..
[43] Volker Wichmann,et al. Long‐range terrestrial laser scanning for geomorphological change detection in alpine terrain – handling uncertainties , 2017 .
[44] Rudolf Sailer,et al. Glacier Snowline Determination from Terrestrial Laser Scanning Intensity Data , 2017 .
[45] R. Ranzi,et al. Hydrologic vulnerability to climate change of the Mandrone glacier (Adamello-Presanella group, Italian Alps) , 2013 .
[46] Richard Szeliski,et al. Modeling the World from Internet Photo Collections , 2008, International Journal of Computer Vision.
[47] T. Strozzi,et al. Glacial lake outburst flood hazard assessment by satellite Earth observation in the Himalayas (Chomolhari area, Bhutan) , 2019, Geographica Helvetica.
[48] F. Godone,et al. The Support of Geomatics in Glacier Monitoring: The Contribution of Terrestrial Laser Scanner , 2012 .
[49] R. Bindschadler,et al. Consideration of the errors inherent in mapping historical glacier positions in Austria from the ground and space (1893-2001) , 2003 .
[50] L. Schrott,et al. Spatial distribution of sediment storage types in two glacier landsystems (Pasterze & Obersulzbachkees, Hohe Tauern, Austria) , 2012 .
[51] Mountain guides facing the effects of climate change. What perceptions and adaptation strategies at the foot of Mont Blanc? , 2019 .
[52] Andreas Kääb,et al. The new remote-sensing-derived Swiss glacier inventory: II. First results , 2002, Annals of Glaciology.
[53] M. Tamura,et al. Mapping of Ground Deformations with Interferometric Stacking Techniques , 2014 .
[54] Michael Lehning,et al. A comparison of measurement methods: terrestrial laser scanning, tachymetry and snow probing for the determination of the spatial snow-depth distribution on slopes , 2008, Annals of Glaciology.
[55] M. Avian,et al. The response of partially debris‐covered valley glaciers to climate change: the example of the pasterze glacier (austria) in the period 1964 to 2006 , 2008 .
[56] Michele Manunta,et al. SBAS-DInSAR Parallel Processing for Deformation Time-Series Computation , 2014, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.
[57] Fabio Remondino,et al. UAV PHOTOGRAMMETRY FOR MAPPING AND 3D MODELING - CURRENT STATUS AND FUTURE PERSPECTIVES - , 2012 .
[58] M. Stoffel,et al. Data and knowledge gaps in glacier, snow and related runoff research – A climate change adaptation perspective , 2014 .
[59] Andreas Bauder,et al. Future high-mountain hydrology: a new parameterization of glacier retreat , 2010 .
[60] David P. Roy,et al. A Global Analysis of Sentinel-2A, Sentinel-2B and Landsat-8 Data Revisit Intervals and Implications for Terrestrial Monitoring , 2017, Remote. Sens..
[61] Mark A. Fonstad,et al. Topographic structure from motion: a new development in photogrammetric measurement , 2013 .
[62] Antonio Abellán,et al. Rockfall monitoring by Terrestrial Laser Scanning ¿ case study of the basaltic rock face at Castellfollit de la Roca (Catalonia, Spain) , 2011 .
[63] P. Verma,et al. Classification of glacial lakes using integrated approach of DFPS technique and gradient analysis using Sentinel 2A data , 2019 .
[64] Jan Beutel,et al. Monitoring mass movements using georeferenced time-lapse photography: Ritigraben rock glacier, western Swiss Alps , 2018 .
[66] Steven M. De Jong,et al. Monitoring river morphology & bank erosion using UAV imagery - A case study of the river Buëch, Hautes-Alpes, France , 2018, Int. J. Appl. Earth Obs. Geoinformation.
[67] Georg Kaser,et al. Contribution potential of glaciers to water availability in different climate regimes , 2010, Proceedings of the National Academy of Sciences.
[68] A. Kääb,et al. Glacial lake mapping with very high resolution satellite SAR data , 2012 .
[69] Jan Magnusson,et al. Snow accumulation distribution inferred from time‐lapse photography and simple modelling , 2010 .
[70] Molly H. Polk,et al. Glacier loss and hydro-social risks in the Peruvian Andes , 2017 .
[71] Antonio Pepe,et al. Improved EMCF-SBAS Processing Chain Based on Advanced Techniques for the Noise-Filtering and Selection of Small Baseline Multi-Look DInSAR Interferograms , 2015, IEEE Transactions on Geoscience and Remote Sensing.
[72] Andreas Kääb,et al. Remote sensing based assessment of hazards from glacier lake outbursts: a case study in the Swiss Alps , 2002 .
[73] Mike J. Smith,et al. Cameras and settings for aerial surveys in the geosciences , 2017 .
[74] T. Bolch,et al. Towards automated mapping and monitoring of potentially dangerous glacial lakes in Bhutan Himalaya using Sentinel-1 Synthetic Aperture Radar data , 2019, International Journal of Remote Sensing.
[75] Christophe Lambiel,et al. Inventorying slope movements in an Alpine environment using DInSAR , 2014 .
[76] Marco Tedesco,et al. Toward Monitoring Surface and Subsurface Lakes on the Greenland Ice Sheet Using Sentinel-1 SAR and Landsat-8 OLI Imagery , 2017, Front. Earth Sci..
[77] R. Goldstein,et al. Satellite Radar Interferometry for Monitoring Ice Sheet Motion: Application to an Antarctic Ice Stream , 1993, Science.
[78] Helmut Rott,et al. Advances in interferometric synthetic aperture radar (InSAR) in earth system science , 2009 .
[79] M. Guglielmin,et al. Accelerating climate change impacts on alpine glacier forefield ecosystems in the European Alps. , 2008, Ecological applications : a publication of the Ecological Society of America.
[80] Andreas Kääb,et al. Glacier displacement on Comfortlessbreen, Svalbard, using 2-pass differential SAR interferometry (DInSAR) with a digital elevation model , 2011, Polar Record.
[81] Ludovic Ravanel,et al. Using Terrestrial Laser Scanning for the Recognition and Promotion of High-Alpine Geomorphosites , 2014, Geoheritage.
[82] A. Kääb. Combination of SRTM3 and repeat ASTER data for deriving alpine glacier flow velocities in the Bhutan Himalaya , 2005 .
[83] Andreas Kääb,et al. The new remote-sensing-derived Swiss glacier inventory: I. Methods , 2002, Annals of Glaciology.
[84] Brian J. Moorman,et al. Detecting Short-Term Surface Melt on an Arctic Glacier Using UAV Surveys , 2018, Remote. Sens..
[85] N. Otsu. A threshold selection method from gray level histograms , 1979 .
[86] Karsten Schulz,et al. PRACTISE – Photo Rectification And ClassificaTIon SoftwarE (V.1.0) , 2013 .
[87] S. Gascoin,et al. Optical Remote Sensing of Snow Cover , 2016 .
[88] Evan S. Miles,et al. Optimising NDWI supraglacial pond classification on Himalayan debris-covered glaciers , 2018, Remote Sensing of Environment.
[89] Núria Devanthéry,et al. Persistent Scatterer Interferometry: A review , 2016 .
[90] Michele Manunta,et al. An On-Demand Web Tool for the Unsupervised Retrieval of Earth's Surface Deformation from SAR Data: The P-SBAS Service within the ESA G-POD Environment , 2015, Remote. Sens..
[91] Higinio González-Jorge,et al. Unmanned Aerial Systems for Civil Applications: A Review , 2017 .
[92] Dong Liang,et al. High-Frequency Glacial Lake Mapping Using Time Series of Sentinel-1A/1B SAR Imagery: An Assessment for the Southeastern Tibetan Plateau , 2020, International journal of environmental research and public health.
[93] M. Avian,et al. Geomorphic consequences of rapid deglaciation at Pasterze Glacier, Hohe Tauern Range, Austria, between 2010 and 2013 based on repeated terrestrial laser scanning data , 2018, Geomorphology.
[94] O. Sass,et al. Combining airborne and terrestrial laser scanning for quantifying erosion and deposition by a debris flow event , 2012 .
[95] H. Zebker,et al. Persistent scatterer interferometric synthetic aperture radar for crustal deformation analysis, with application to Volcán Alcedo, Galápagos , 2007 .
[96] Antonio Pepe,et al. On the Extension of the Minimum Cost Flow Algorithm for Phase Unwrapping of Multitemporal Differential SAR Interferograms , 2006, IEEE Transactions on Geoscience and Remote Sensing.
[97] Jeffrey S. Kargel,et al. Glacier Mapping and Monitoring Using Multispectral Data , 2014 .
[98] D. Benn,et al. PyTrx: A Python-Based Monoscopic Terrestrial Photogrammetry Toolset for Glaciology , 2020, Frontiers in Earth Science.
[99] S. Ullman. The interpretation of structure from motion , 1979, Proceedings of the Royal Society of London. Series B. Biological Sciences.
[100] Michael Eineder,et al. Mitigation of Tropospheric Delay in SAR and InSAR Using NWP Data: Its Validation and Application Examples , 2018, Remote. Sens..
[101] Lado W. Kenyi,et al. Estimation of rock glacier surface deformation using SAR interferometry data , 2003, IEEE Trans. Geosci. Remote. Sens..
[102] R. Bradley,et al. Economic impacts of rapid glacier retreat in the Andes , 2007 .
[103] Wolfgang Sulzer,et al. UAS-Based Change Detection of the Glacial and Proglacial Transition Zone at Pasterze Glacier, Austria , 2017, Remote. Sens..
[104] Marco Scaioni,et al. Combination of UAV and terrestrial photogrammetry to assess rapid glacier evolution and map glacier hazards , 2018 .
[105] Dorothy K. Hall,et al. Reflectances of glaciers as calculated using Landsat-5 Thematic Mapper data , 1988 .
[106] Roberto Salzano,et al. Snow cover monitoring with images from digital camera systems , 2011 .
[107] S. Robson,et al. Straightforward reconstruction of 3D surfaces and topography with a camera: Accuracy and geoscience application , 2012 .
[108] J. Carrivick,et al. Climate change and rock fall events in high mountain areas: numerous and extensive rock falls in 2007 at mittlerer burgstall, central austria , 2012 .
[109] M. Westoby,et al. ‘Structure-from-Motion’ photogrammetry: A low-cost, effective tool for geoscience applications , 2012 .
[110] Andreas Kääb,et al. Glacier Remote Sensing Using Sentinel-2. Part II: Mapping Glacier Extents and Surface Facies, and Comparison to Landsat 8 , 2016, Remote. Sens..
[111] Günter Blöschl,et al. Potential of time‐lapse photography of snow for hydrological purposes at the small catchment scale , 2012 .
[112] Karlheinz Gutjahr,et al. On the Analysis of the Phase Unwrapping Process in a D-InSAR Stack with Special Focus on the Estimation of a Motion Model , 2019, Remote. Sens..
[113] Reiko Ide,et al. A cost-effective monitoring method using digital time-lapse cameras for detecting temporal and spatial variations of snowmelt and vegetation phenology in alpine ecosystems , 2013, Ecol. Informatics.
[114] B. Schaefli,et al. The role of glacier retreat for Swiss hydropower production , 2019, Renewable Energy.
[115] Daene C. McKinney,et al. Brief communication: Observations of a glacier outburst flood from Lhotse Glacier, Everest area, Nepal , 2016 .
[116] M. Zemp,et al. Worldwide Assessment of National Glacier Monitoring and Future Perspectives , 2019, Mountain Research and Development.
[117] C. Fey,et al. Deformation characteristics and multi-slab formation of a deep-seated rock slide in a high alpine environment (Bliggspitze, Austria) , 2019, Bulletin of Engineering Geology and the Environment.
[118] M. Hoelzle,et al. Integrated monitoring of mountain glaciers as key indicators of global climate change: the European Alps , 2007, Annals of Glaciology.
[119] H. L. Miller,et al. Climate Change 2007: The Physical Science Basis , 2007 .
[120] Hankui K. Zhang,et al. Characterization of Sentinel-2A and Landsat-8 top of atmosphere, surface, and nadir BRDF adjusted reflectance and NDVI differences , 2018, Remote Sensing of Environment.
[121] M. Hoelzle,et al. Glacier Monitoring and Capacity Building: Important Ingredients for Sustainable Mountain Development , 2017, Mountain Research and Development.
[122] David G. Lowe,et al. Distinctive Image Features from Scale-Invariant Keypoints , 2004, International Journal of Computer Vision.
[123] Lin Yan,et al. Sentinel-2A multi-temporal misregistration characterization and an orbit-based sub-pixel registration methodology , 2018, Remote Sensing of Environment.
[124] S. Kotlarski,et al. 21st century climate change in the European Alps--a review. , 2014, The Science of the total environment.
[125] Gianfranco Fornaro,et al. A new algorithm for surface deformation monitoring based on small baseline differential SAR interferograms , 2002, IEEE Trans. Geosci. Remote. Sens..
[126] Wei Zhou,et al. Monitoring and Analyzing Mountain Glacier Surface Movement Using SAR Data and a Terrestrial Laser Scanner: A Case Study of the Himalayas North Slope Glacier Area , 2019, Remote. Sens..
[127] Fabio Rocca,et al. Permanent scatterers in SAR interferometry , 2001, IEEE Trans. Geosci. Remote. Sens..
[128] S. M. Jong,et al. High-resolution monitoring of Himalayan glacier dynamics using unmanned aerial vehicles , 2014 .
[129] Francesco De Zan,et al. Coregistration of Interferometric Stacks of Sentinel-1 TOPS Data , 2016, IEEE Geoscience and Remote Sensing Letters.
[130] A. Bauer,et al. LiDAR for monitoring mass movements in permafrost environments at the cirque Hinteres Langtal, Austria, between 2000 and 2008 , 2009 .