1 Cartography and GIS Research Group-Department of Geography 2 Department of Hydrology and Hydraulic Engineering 3 Department of Electronics and Informatics.

Slides:

Advertisements

Similar presentations

Lab for Remote Sensing Hydrology and Spatial Modeling Dept. of Bioenvironmental Systems Engineering, NTU Satellite Remote Sensing for Land-Use/Land-Cover.

Advertisements

URBAN AREA PRODUCT SIMULATION FOR THE ENMAP HYPERSPECTRAL SENSOR P.Gamba, A. Villa, A. Plaza, J. Chanussot, J. A. Benediktsson.

Some of my current research: Modeling sediment delivery on a daily basis for meso-scale catchments: a new tool: LAPSUS-D By: Saskia Keesstra and Arnaud.

Land Use Change and Its Effect on Water Quality: A Watershed Level BASINS-SWAT Model in West Georgia Gandhi Raj Bhattarai Diane Hite Upton Hatch Prepared.

Vegetation and Population Density in Urban and Suburban Areas in the U.S.A. Francesca Pozzi Center for International Earth Science Information Network.

Multiple Criteria for Evaluating Land Cover Classification Algorithms Summary of a paper by R.S. DeFries and Jonathan Cheung-Wai Chan April, 2000 Remote.

Remote Sensing of Hydrological Variables over the Red Arkansas Eric Wood Matthew McCabe Rafal Wojcik Hongbo Su Huilin Gao Justin Sheffield Princeton University.

Data Merging and GIS Integration

Globally distributed evapotranspiration using remote sensing and CEOP data Eric Wood, Matthew McCabe and Hongbo Su Princeton University.

Department of Geography, University of California, Santa Barbara

Abstract In the case of the application of the Soil Moisture and Ocean Salinity (SMOS) mission to the field of hydrology, the question asked is the following:

Mapping Roads and other Urban Materials using Hyperspectral Data Dar Roberts, Meg Gardner, Becky Powell, Phil Dennison, Val Noronha.

Digital Imaging and Remote Sensing Laboratory Real-World Stepwise Spectral Unmixing Daniel Newland Dr. John Schott Digital Imaging and Remote Sensing Laboratory.

Published in Remote Sensing of the Environment in May 2008.

CSIRO LAND and WATER Estimation of Spatial Actual Evapotranspiration to Close Water Balance in Irrigation Systems 1- Key Research Issues 2- Evapotranspiration.

Remote Sensing of Drought Lecture 9. What is drought? Drought is a normal, recurrent feature of climate. It occurs almost everywhere, although its features.

Chapter 12 Spatial Sharpening of Spectral Image Data.

1 Impervious Surface Mapping with Multi-Spectral Remote Sensing Dr. Qihao Weng Associate Professor of Geography; Director, Ctr. Urban & Environmental Change.

TARGETED LAND-COVER CLASSIFICATION by: Shraddha R. Asati Guided by: Prof. P R.Pardhi.

Eric Rafn and Bill Kramber Idaho Department of Water Resources

Co-authors: Maryam Altaf & Intikhab Ulfat

Remote Sensing Hyperspectral Remote Sensing. 1. Hyperspectral Remote Sensing ► Collects image data in many narrow contiguous spectral bands through the.

TAILING MODELLED AND MEASURED SPECTRUM FOR MINE TAILING MAPPING IN TUNISIAN SEMI-ARID CONTEXT N. Mezned 1,2, S. Abdeljaouad 1, M. R. Boussema

Noise-Robust Spatial Preprocessing Prior to Endmember Extraction from Hyperspectral Data Gabriel Martín, Maciel Zortea and Antonio Plaza Hyperspectral.

Chenghai Yang 1 John Goolsby 1 James Everitt 1 Qian Du 2 1 USDA-ARS, Weslaco, Texas 2 Mississippi State University Applying Spectral Unmixing and Support.

The use of MOD09 product and in situ data in a reservoir Valério, A.M.; Kampel, M.; Stech, J.L. alineval, milton, stech COSPAR Training.

Development of indicators of fire severity based on time series of SPOT VGT data Stefaan Lhermitte, Jan van Aardt, Pol Coppin Department Biosystems Modeling,

Geometric Activity Indices for Classification of Urban man-made Objects using Very-High Resolution Imagery R. Bellens, L. Martinez-Fonte, S. Gautama Ghent.

Slide #1 Emerging Remote Sensing Data, Systems, and Tools to Support PEM Applications for Resource Management Olaf Niemann Department of Geography University.

1 Exploiting Multisensor Spectral Data to Improve Crop Residue Cover Estimates for Management of Agricultural Water Quality Magda S. Galloza 1, Melba M.

May 6, 2015 Huidae Cho Water Resources Engineer, Dewberry Consultants

1 Enviromatics Environmental sampling Environmental sampling Вонр. проф. д-р Александар Маркоски Технички факултет – Битола 2008 год.

What is an image? What is an image and which image bands are “best” for visual interpretation?

Remote Analysis of Asian Cold Desert Ecosystems Cheney M. Shreve & Gregory S. Okin: Univ. of Virginia and Univ. of California, Los Angeles Remote Analysis.

Spectral classification of WorldView-2 multi-angle sequence Atlanta city-model derived from a WorldView-2 multi-sequence acquisition N. Longbotham, C.

7 elements of remote sensing process 1.Energy Source (A) 2.Radiation & Atmosphere (B) 3.Interaction with Targets (C) 4.Recording of Energy by Sensor (D)

Lecture 3 The Digital Image – Part I - Single Channel Data 12 September

Understanding Glacier Characteristics in Rocky Mountains Using Remote Sensing Yang Qing.

BIOPHYS: A Physically-based Algorithm for Inferring Continuous Fields of Vegetative Biophysical and Structural Parameters Forrest Hall 1, Fred Huemmrich.

DEVELOPING HIGH RESOLUTION AOD IMAGING COMPATIBLE WITH WEATHER FORECAST MODEL OUTPUTS FOR PM2.5 ESTIMATION Daniel Vidal, Lina Cordero, Dr. Barry Gross.

Chernobyl Nuclear Power Plant Explosion

Spectral unmixing of vegetation, soil and dry carbon cover in arid regions: comparing multispectral and hyperspectral observations G.P.Asner and K.B.Heidebrecht.

Remotely sensed land cover heterogeneity

IGARSS 2011, Vancouver, Canada HYPERSPECTRAL UNMIXING USING A NOVEL CONVERSION MODEL Fereidoun A. Mianji, Member, IEEE, Shuang Zhou, Member, IEEE, Ye Zhang,

14 ARM Science Team Meeting, Albuquerque, NM, March 21-26, 2004 Canada Centre for Remote Sensing - Centre canadien de télédétection Geomatics Canada Natural.

Validation of MODIS Snow Mapping Algorithm Jiancheng Shi Institute for Computational Earth System Science University of California, Santa Barbara.

Characterizing the Physical Environment of Urban Centers in Rondônia with Landsat ETM+ Rebecca L. Powell 1 and Dar A. Roberts 2 Department of Geography,

Hyperspectral remote sensing

Goal: to understand carbon dynamics in montane forest regions by developing new methods for estimating carbon exchange at local to regional scales. Activities:

Remote Sensing Unsupervised Image Classification.

2011 IEEE International Geoscience and Remote Sensing Symposium (IGARSS) Aihua Li Yanchen Bo

Hydrologic Data Assimilation with a Representer-Based Variational Algorithm Dennis McLaughlin, Parsons Lab., Civil & Environmental Engineering, MIT Dara.

Data Models, Pixels, and Satellite Bands. Understand the differences between raster and vector data. What are digital numbers (DNs) and what do they.

Land Cover Classification and Monitoring Case Studies: Twin Cities Metropolitan Area –Multi-temporal Landsat Image Classification and Change Analysis –Impervious.

Sub pixelclassification

Remote Sensing Theory & Background III GEOG370 Instructor: Yang Shao.

Stochastic Hydrology Random Field Simulation Professor Ke-Sheng Cheng Department of Bioenvironmental Systems Engineering National Taiwan University.

Environmental Modeling Weighting GIS Layers Weighting GIS Layers.

References: 1)Ganguly, S., Samanta, A., Schull, M. A., Shabanov, N. V., Milesi, C., Nemani, R. R., Knyazikhin, Y., and Myneni, R. B., Generating vegetation.

A method to map flooding-prone areas in Iran using Landsat satellite images and GIS Ali Bozorgi, Iran Water Resources Management Company,

Integrating LiDAR Intensity and Elevation Data for Terrain Characterization in a Forested Area Cheng Wang and Nancy F. Glenn IEEE GEOSCIENCE AND REMOTE.

Remote Sensing Section Global soil monitoring and mineral mapping from emerging remote sensing technologies Sabine Chabrillat and the group “hyperspectral.

Estimation of surface characteristics over heterogeneous landscapes from medium resolution sensors. F. Baret 1, S. Garrigues 1, D. Allard 2, R. Faivre.

Retrieval of Land Surface Temperature from Remote Sensing Thermal Images Dr. Khalil Valizadeh Kamran University of Tabriz, Iran.

Pathik Thakkar University of Texas at Dallas

HIERARCHICAL CLASSIFICATION OF DIFFERENT CROPS USING

Incorporating Ancillary Data for Classification

Image Information Extraction

EC Workshop on European Water Scenarios Brussels 30 June 2003

Igor Appel Alexander Kokhanovsky

Presentation transcript:

1 Cartography and GIS Research Group-Department of Geography 2 Department of Hydrology and Hydraulic Engineering 3 Department of Electronics and Informatics Vrije Universiteit Brussel, Belgium Session on “Imaging Spectroscopy” Luca Demarchi 1, Eva M.Ampe 2, Frank Canters 1, Jonathan Cheung-Wai Chan 1,3, Juliette Dujardin 2, Imtiaz Bashir 2, Okke Batelaan 2 Use of Land-Cover Fractions Obtained from Multiple Endmember Unmixing of Chris/Proba Imagery for Distributed Runoff Estimation 32 nd EARSEL Symposium 2012 “Advances in Geosciences” May Mykonos, Greece

Page 2 Introduction Use of remote sensing and GIS technology in hydrological modeling has strongly increased in the last decades:  Mapping spatial variability of several parameters for deriving runoff estimation  Land-cover types Multiple Endmember Spectral Mixture Analysis (MESMA) Hyperspectral have opened up new possibilities for land-cover mapping  Recent work has focused on the potential of hyperspectral CHRIS/Proba data for estimating sub-pixel land-cover fractions in urban areas[1]. [1] Demarchi L., Canters F., Chan J.C.-W and Van de Voorde, T. (2012). Multiple endmember unmixing of CHRIS/Proba imagery for mapping of impervious surfaces in urban and suburban environments. IEEE Transactions on Geosciences and Remote Sensing, DOI: /TGRS

Integrate the results of MESMA in the Wetspass model:  Spatially distributed hydrological model for estimating the main water balance components: evapotranspiration, surface runoff and groundwater recharge  Compare the effects of different land-cover input scenarios on the spatial distribution of runoff. Page 3 Objectives Study area:  Woluwe catchment  Brussels Capital Region, east of city center  High heterogeneity and dense urban morphology Hyperspectral CHRIS/Proba:  Spectral range: 410 – 1050 nm  MODE3: 18 spectral bands, 18m spatial resolution (August 2009)

Introduction Methodology:  Unmixing CHRIS/Proba data with MESMA  Wetspass hydological modeling  Improving Wetspass with MESMA results: scenarios definition Results and discussion Conclusions Overview Page 4

Page 5 Mapping land-cover types with multiple endmember unmixing (MESMA) Sub-pixel land-cover mapping with medium-resolution multispectral imagery (Landsat, SPOT,...) in urban areas:  Spectral similarity of impervious surfaces and other non-artificial land-cover types (bare soil, dark vegetated areas,...)  Spectral heterogeneity of impervious surfaces  difficult to define representative endmembers for unmixing MESMA: effective method on increasing land-over mapping accuracy when heterogeneity of land-over classes is very high. Brightness normalization: technique proposed by Wu [2], reduces within- class spectral heterogeneity and emphasizes the shape information [2] Wu C. (2003). Normalized spectral mixture analysis for monitoring urban composition using ETM+ imagery. Remote Sensing of Environment, vol. 93, no. 4, pp

Page 6 ●Brightness normalization Before After Brightness normalization r’ b is the normalized reflectance for band b, r b is the original reflectance for band b, μ is the average reflectance for the pixel, M is the total number of bands.

Page 7 ●Brightness normalization Before After r’ b is the normalized reflectance for band b, r b is the original reflectance for band b, μ is the average reflectance for the pixel, M is the total number of bands. Brightness normalization

Multiple endmember unmixing Per-pixel basis approach Each pixel is unmixed with multiple models:  all combinations of endmembers, using 2, 3 or 4 EMs: only one retained!  Different spatial distribution of models using 2-, 3- or 4- land-cover classes for unmixing  more efficient fraction estimation Page 8 Linear spectral unmixing Unique endmembers are used for the entire scene:  Differences in land-cover composition and spectral variations within the same land-cover type are not taken into account r ib is the reflectance of endmember i for a specific band b, f i is the fraction of endmember i, N is the total number of endmembers, e b is the residual for band b. Mapping land-cover types with multiple endmember unmixing (MESMA)

Page 9 Spatial distribution of models selected by MESMA

Page 10 Sub-pixel validation Stratified validation set: Fractions derived for each land-cover class from 0.25m ortho-photos 30 pixels for all combinations of 2-, 3- and 4- land-cover classes 30 pure pixels for each of the four land-cover classes (grey sealed surfaces, red sealed surfaces, vegetation and bare soil) 12 combinations=360 ground truth pixels Amplitude OverallSystematic

Page 11 Impervious surfaces Land-cover fractions

Page 12 Vegetation Land-cover fractions

Page 13 Bare soil Land-cover fractions

Introduction Methodology:  Unmixing CHRIS/Proba data with MESMA  Wetspass hydological modeling  Improving Wetspass with MESMA results: scenarios definition Results and discussion Conclusions Overview Page 14

Page 15 Wetspass : a spatially distributed hydrological model for runoff estimation Stands for Water and Energy Transfer between Soil, Plants and Atmosphere under quasi-Steady State [3]. [3] Batelaan, O. and De Smedt, F. (2001). WetSpass: a flexible, GIS based, distributed recharge methodology for regional groundwater modeling. Impact of Human Activity on Groundwater Dynamics, (IAHS Publ. No. 269). pp Physically based model able to simulate long-term average spatial patterns of groundwater recharge, surface runoff and evapotranspiration Fully integrated in a geographical information system as a raster model It is able to handle the spatial distribution of several inputs such as soil types, land-use types, slope, groundwater depth and long-term average climatic data

Page 16 Wetspass : a spatially distributed hydrological model for runoff estimation Water balance computation at cell level : For each raster cell, the balance is split into independent water balances By summing up each water balances, weighed by the corresponding fraction component, the total water balance at raster level can be obtained

Introduction Methodology:  Unmixing CHRIS/Proba data with MESMA  Wetspass hydological modeling  Improving Wetspass with MESMA results: scenarios definition Results and discussion Conclusions Overview Page 17

Page 18 Improving Wetspass estimations using land-cover fractions from MESMA Wetspass defines default fractions for each land-use type.

Page 19 Improving Wetspass estimations using land-cover fractions from MESMA Wetspass defines default fractions for each land-use type. Sub-pixel estimates obtained from CHRIS/Proba imagery are used in this study to improve runoff mapping within Wetspass. Scenario 1: Semi-distributed (based on default Wetspass parameters)  a v, a b, a i and a w are fixed a priori for each land-use class Scenario 2: Semi-distributed (based on MESMA derived parameters)  a v, a b, a i and a w are fixed a priori for each land-use class  Mean land-cover fractions are calculated from MESMA results for each land-use type Scenario 3: Fully-distributed (pixel-based derived from MESMA)  a v, a b, a i and a w are obtained at pixel-level from the MESMA results In each scenario, average estimation and standard deviation of runoff are calculated for each land-use type

Introduction Methodology:  Unmixing CHRIS/Proba data with MESMA  Wetspass hydological modeling  Improving Wetspass with MESMA results: scenarios definition Results and discussion Conclusions Overview Page 20

Page 21 Improving Wetspass estimations using land-cover fractions from MESMA In scenario 2 new average land-cover fractions were calculated based on MESMA results - 10%

Page 22 Improving Wetspass estimations using land-cover fractions from MESMA + 10% In scenario 2 new average land-cover fractions were calculated based on MESMA results

Page 23 Results of Runoff estimates For each scenario, average runoff and standard deviation values have been calculated for each land-use type Urban land-use classes - 10%

Page 24 Results of Runoff estimates Urban land-use classes + 10%

Page 25 Results of Runoff estimates High standard deviations

Page 26

Page 27 Scenario 1 and 2: similar values of runoff, spatial pattern very similar and clearly linked to the pattern of land-use

Page 28 Scenario 1 and 2: similar values of runoff, spatial pattern very similar and clearly linked to the pattern of land-use

Page 29 Variations within each land-use type are limited, confirming the small standard deviation obtained Scenario 1 and 2: similar values of runoff, spatial pattern very similar and clearly linked to the pattern of land-use

Page 30 Scenario 3: strong local variation In each pixel the Runoff is derived from its land- cover class composition and not from the land- use type High local variability= high standard deviation. and therefore more realistic hydrological parameters estimates

Page 31 Runoff scenario 1

Page 32 Land-use map

Page 33 Runoff scenario 3

Impervious surfaces from MESMA Page 34

Introduction Methodology:  Unmixing CHRIS/Proba data with MESMA  Wetspass hydological modeling  Improving Wetspass with MESMA results: scenarios definition Results and discussion Conclusions Overview Page 35

Page 36 Conclusions For most urban land-use classes, land-cover fraction values derived from RS are different from Wetspass default parameters:  Impervious surfaces level is systematically overestimated in Wetspass  Smaller runoff values are produced when RS data are used  Strong link between runoff and imperviou-sness level within each land- use type Combining MESMA-per-pixel basis unmixing approach-with Wetspass-a spatially distributed modeling-allows to generate fully distributed and more realistic hydrological estimates. Limitations of CHRIS/Proba in urban areas are pointed out:  Spectral similarity of some land-cover types may negatively affect the quality of runoff in some locations.  Hyperspectral data with higher spectral resolution and wider spectral range may enhance this distinction and therefore runoff estimation Sub-pixel estimates derived from MESMA directly used at cell level:  Local variation of land-cover composition fully taken into account: high local variation of runoff within each land-use type  Benefits of using RS for obtaining more detailed information on the spatial pattern of runoff.

Page 37 Conclusions