1 / 20

L. Pulvirenti 1 , M. Chini 2 , N. Pierdicca 1 , L. Guerriero 3

Combined use of Electromagnetic Scattering Models, Fuzzy Logic and Mathematical Morphology for Flood Mapping from COSMO- SkyMED data. L. Pulvirenti 1 , M. Chini 2 , N. Pierdicca 1 , L. Guerriero 3 (1) Sapienza, University of Rome (2) Istituto Nazionale di Geofisica e Vulcanologia

babu
Download Presentation

L. Pulvirenti 1 , M. Chini 2 , N. Pierdicca 1 , L. Guerriero 3

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Combined use of Electromagnetic Scattering Models, Fuzzy Logic and Mathematical Morphology for Flood Mapping from COSMO-SkyMED data L. Pulvirenti 1, M. Chini 2, N. Pierdicca 1, L. Guerriero 3 (1) Sapienza, University of Rome (2) Istituto Nazionale di Geofisica e Vulcanologia (3) Tor Vergata University of Rome

  2. Introduction • Several overflows occurred in Italy in the recent years • ASI is presently funding some investigations about the use of Earth Observation data for civil protection from floods (e.g., OPERA). • Potential of SAR for flood monitoring • The synoptic view, the good spatial resolution, the capabilities to operate in almost all-weather conditions and both during daytime and nighttime are the key features of radar sensors. • Possible advantages of using X-band COSMO-SkyMED images: • Veryhigh spatialresolution (especially in the spotlight configuration) →An accurate flood boundary delineation can be expected. • Short revisit time (constellation of 4 satellites) →A Multi-temporalanalysis can be performed.

  3. Motivations • SAR data interpretation often not straightforward, especially in the presence of vegetation (challenging problem). • Need to rely on electromagnetic scattering models, simulating s0 under flooded conditions, to correctly interpret the SAR observations. • Fuzzy logic suitable for representing the set of flooded pixels in SAR images for which the definition of a criterion of membership is a difficult task. • Spatial details of high resolution images generally smaller than the dimensions of the targets → large within-class variances (also because of the speckle noise) • Need to segment imagery for dealing with homogeneous areas. • Mathematical morphology allows identifying objects with different spatial extension (when used in a multi-scale manner).

  4. Steps of the designed algorithm and case studies • Segmentation of a multi-temporal series of CSK observations of a flood. • Computation of the average s0 for each segment. • Application to the segmented images of the fuzzy-logic-based approach • allowing us to account for different scattering mechanisms. • Methodology tested on two case studies (OPERA team activated): • the overflow of the Tanaro River, close to the city of Alessandria (Northern Italy) in April 2009 (4 CSK images used). • the flood occurred in Tuscany (central Italy) in December 2009 near the Massaciuccoli lake (5 CSK images used). • In both cases a portion of flooded area was vegetated.

  5. Segmentation • The opening (erosion followed by dilation) and closing morphological operators are applied with structuring elements (se) of different sizes. • Structures in a SAR image may have a high response for a specific selected se size and a lower response for other sizes. • The morphological profile is built for each image of the available multi-temporal series. • A K-means clustering is applied to the multi-temporal profile. • The final segmentation (extraction of contiguous objects belonging to the same class) is performed. N

  6. Z function S function 1 1 0 0 The fuzzysets • Degree of membership to a fuzzy set defined through the standard S and Z functions. fuzzy thresholds • Default values of the fuzzy thresholds based on the outputs of the EM scattering model developed at the Tor Vergata University of Rome. It assumes: • Bare soil: IEM • Vegetation: homogeneous half space overlaid by a layer filled with discrete dielectric scatterers representing stems and leaves. • Flooded conditions: simulated substituting the soil with a semi-infinite layer having the e of water and a negligible roughness.

  7. s0HH SMC [%] Fuzzy set of flooded bare soils • Flooded bare soils generally much smoother than the surrounding dry land, thus acting as specular reflectors, giving low s0. 1 Flooded 0 s° X Band, HH pol

  8. s0HH wheat plant height=70 cm SMC [%] Set of vegetated flooded areas • Protruding vegetation may produce large s0. • Reflections between water surface and upright vegetation may enhance backscattering → flooded vegetation may show a bright radar return in a SAR image. 1 0 Ds°

  9. Multitemporalanalysis Tanaro river overflow. RGB color composite of the CSK observations of the flood Red:April, 29 2009Green: April, 30 2009 Blue: May, 1 2009 vegetated bare vegetated Mean (s 0) [dB] dry NDVI map(AVNIR-2 image acquired on April 23, 2009) April, 29 April, 30 May, 1 May, 16

  10. Dependence of s0 on water level • Radar return predicted by the EM model (small leaves) versus the water level (hw). Large double buonce effect Small double buonce effect 75 cm plant 60 cm plant s 0 [dB] 25cm plant hw > h hw[cm]

  11. 1 0 Otherfuzzyrules(multitemporalanalysis) • Non-flooded objects at time t are generally non-flooded at time t+1 • Flooded objects that at time t have small s0may be flooded at time t+1 if s0(t+1) considerably larger than s0(t) (decrease of hw) • Flooded objects that at time t have large s0may be flooded at time t+1 if s0(t+1) < s0(t) (decrease of hw) • Non-flooded objects surronded by flooded ones placed at higher altitude are probably flooded (DEM-based correction) 75 cm plant 60 cm plant s 0 [dB] 25cm plant hw[cm]

  12. The Tanaro overflow • Occurred near the town of Alessandria (Northern Italy) on April 27-28, 2009. • ~ 6000 people were evacuated for precaution. • Some agricultural fields were inundated. These fields were either bare or covered by wheat at different stage of growth (early – intermediate).

  13. Segmentationresults Tanaro flood: original images Tanaro flood: segmented image RGB color composite (3500x5000 pixels) Red:April 29, 2009Green: April 30, 2009 Blue: May 1, 2009 ~ 8000 objects

  14. Flood evolution map (Apr. 29- May 1) Cyan :flooded Blue: water bodies

  15. Flood map of April 29, 2009

  16. The Tuscany flood • Occurred near the Massaciuccoli lake (Central Italy) on December 25-26, 2009.

  17. Segmentationresults Tuscanyflood: original image Tuscanyflood: segmented image RGB color composite (3000x1500 pixels) Red:December, 20 2009Green: December, 30 2009 Blue: December, 31 2009 ~ 3700 objects (codes represented in grayscale)

  18. A distinctive multi-temporal signature Dec. 27, 2009 dry

  19. Floodevolutionmap Cyan :flooded Blue: water bodies

  20. Conclusions • The COSMO-SkyMed mission offers a unique opportunity to obtain radar images characterized by short revisit time • Potential usefulness for monitoring the temporal evolution of floods. • A combined approach using an advanced segmentation technique and a well-established surface scattering model has been presented • The objects with distinctive multi-temporal trends have been identified by the segmentation algorithm. • Simulations has allowed us to explain COSMO-SkyMed multi-temporal signatures of different surface types (vegetated or bare). • This work has been supported by the Italian Space Agency (ASI) under contract No. I/048/07/0.

More Related