Natural Hazards: Difference between revisions
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Please feed the list with other phenomena and resources. | Please feed the list with other phenomena and resources. | ||
=== Rockfall === | |||
*'''r.rockcone''' (soon in [http://svn.osgeo.org/grass/grass-addons/ GRASS-Addons]) | *'''r.rockcone''' (soon in [http://svn.osgeo.org/grass/grass-addons/ GRASS-Addons]) | ||
Rockcone implement a quick and low-cost determination of areas endangered by rockfalls following an heuristic approach: a block tarting from a source will travel down the slope and stop at the intersection point of the topography with a so called energy line drawn from the source point and making an angle φ with horizontal. | Rockcone implement a quick and low-cost determination of areas endangered by rockfalls following an heuristic approach: a block tarting from a source will travel down the slope and stop at the intersection point of the topography with a so called energy line drawn from the source point and making an angle φ with horizontal. | ||
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Sass3d is 3D rock fall model accounting for flying routine (air trajectory), rebound routine (energy loss) & rolling routine (equivalent sliding approach). | Sass3d is 3D rock fall model accounting for flying routine (air trajectory), rebound routine (energy loss) & rolling routine (equivalent sliding approach). | ||
=== Avalanche === | |||
missing, existing slope instability zonation applications (Raghavan et al. 2004) | missing, existing slope instability zonation applications (Raghavan et al. 2004) | ||
=== Debris Flow === | |||
*'''r.debris''' [http://www.osgeo.org/files/journal/v3/en-us/final_pdfs/mergili.pdf paper] | *'''r.debris''' [http://www.osgeo.org/files/journal/v3/en-us/final_pdfs/mergili.pdf paper] | ||
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Is an empirical model to estimate areas involved by the diffusion of the debris. It uses a Monte Carlo approach based on wolkers. The outputs are raster estimates of velocity, sedimentation height, and number of random walk. The Perla velocity model is applied. | Is an empirical model to estimate areas involved by the diffusion of the debris. It uses a Monte Carlo approach based on wolkers. The outputs are raster estimates of velocity, sedimentation height, and number of random walk. The Perla velocity model is applied. | ||
=== Flood === | |||
* {{cmd|r.sim.water}} - Overland flow hydrologic simulation using path sampling method (SIMWE). | |||
* {{cmd|r.sim.water}} | |||
* {{AddonCmd|HydroFOSS}} | * {{AddonCmd|HydroFOSS}} - a GIS embedded approach for Free & Open Source Hydrological modeling. | ||
* '''r.topkapi''' | * '''r.topkapi''' - ? | ||
* '''r.water.fea''' | * '''r.water.fea''' - Finite element analysis program for hydrologic simulations (GRASS 4 only, [http://grass.osgeo.org/gdp/hydrology/r_water_fea.ps.gz document]) | ||
* '''r.hydro.CASC2D''' (in {{AddonCmd|GIPE}}) | * '''r.hydro.CASC2D''' (in {{AddonCmd|GIPE}}) | ||
* {{AddonCmd|r.inund.fluv}} | * {{AddonCmd|r.inund.fluv}} - allows to obtain a fluvial potentially inundation map given a high-resolution DTM of the area surrounding the river and a water surface profile calculated through an 1-D hydrodynamic model. | ||
* | * {{AddonCmd|r.damflood}} - Estimate the area potentially inundated in case of dam break using the Shallow Water Equation (swe.h ANSI C library) | ||
* {{AddonCmd|r.traveltime}} - computes the travel time of surface runoff to an outlet | |||
* {{AddonCmd|r.traveltime}} | |||
* [[Psmap_flooding_example|ps.map flooding example]] | * [[Psmap_flooding_example|ps.map flooding example]] | ||
* [http:// | * {{cmd|r.lake}} - Simple [http://grass.osgeo.org/uploads/images/Gallery/raster/trento_flooding1966.jpg flood simulation] | ||
- | * {{AddonCmd|r.hazard.flood}} - fast procedure to detect flood prone areas | ||
=== Landslide === | === Landslide === | ||
*missing flow models | *missing flow models | ||
*exists slope instability zonation (Avalanche risk management using GRASS GIS. Marco Ciolli and Paolo Zatelli, 2002, Geomatic Workbooks) | *exists slope instability zonation (Avalanche risk management using GRASS GIS. Marco Ciolli and Paolo Zatelli, 2002, Geomatic Workbooks) | ||
=== Erosion === | === Erosion === | ||
*Erosion/deposition modeling in complex terrain using GIS, [http://skagit.meas.ncsu.edu/~helena/gmslab/index.html Tutorial], Helena Mitasova. | |||
=== Tsunami === | === Tsunami === | ||
*'''r.tsunami''' in [ | |||
This script | *'''r.tsunami''' in [https://github.com/OSGeo/grass-addons/tree/master/grass6/raster/r.tsunami GRASS-Addons] | ||
This script implements the metodology described in MAPPE DI INONDAZIONE DOVUTE A TSUNAMI MEDIANTE IL GIS GRASS: APPLICAZIONE ALL'ISOLA DI ST. LUCIA, CARAIBI, Cannata M, B. Federici, M. Molinari, 2006, [http://gislab.dirap.unipa.it/grass_meeting/articoli/tsunami_santa_lucia.pdf PDF]. | |||
This work shows the application and the validation of a procedure in GRASS to realize tsunami inundation maps based | This work shows the application and the validation of a procedure in GRASS to realize tsunami inundation maps based | ||
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were compared historical data and other estimates, verifying the general validity of the method. | were compared historical data and other estimates, verifying the general validity of the method. | ||
=== Desertification === | |||
* RIADE project ([http://geomatica.como.polimi.it/workbooks/n6/articoli/riade_acs_en.pdf PDF]) | |||
=== Wildfire === | |||
=== | * The wildfire spread simulation in GRASS is done using three modules: | ||
** {{cmd|r.ros}} (for wildfire spread simulation) - Generates three, or four raster map layers showing 1) the base (perpendicular) rate of spread (ROS), 2) the maximum (forward) ROS, 3) the direction of the maximum ROS, and optionally 4) the maximum potential spotting distance. See also [[How to create parameters to run r.ros]]. | |||
** {{cmd|r.spread}} - Simulates elliptically anisotropic spread on a graphics window and generates a raster map of the cumulative time of spread, given raster maps containing the rates of spread (ROS), the ROS directions and the spread origins. It optionally produces raster maps to contain backlink UTM coordinates for tracing spread paths. | |||
** {{cmd|r.spreadpath}} - Recursively traces the least cost path backwards to cells from which the cumulative cost was determined. | |||
* Mapping Forest Fire Risk with Open Source Software, Pedro Venâncio (in Portuguese) [http://dl.dropbox.com/u/5772257/Cartografia_de_Risco_de_Incendio_Florestal_com_Software_Open_Source.pdf work] [http://www.osgeopt.pt/sites/default/files/files/Comunicacao_SASIG4_PedroVenancio.pdf presentation] [http://sigencontro.esa.ipcb.pt/Comunica/31_Cartografia%20de%20Risco%20de%20Inc%C3%AAndio%20Florestal_open%20source.pdf presentation 2] | |||
=== Earthquakes === | |||
* [http://adhoc.osgeo.osuosl.org/grass/earthquakes.png Recent Earthquakes]: map of earthquakes that have occurred in the last 7 days. A new image is generated every three hours by a GRASS batch job running on a headless server which fetches data from the USGS and creates a logarithmic bubble plot. The scripts that run this can be found in the [https://github.com/OSGeo/grass-promo/tree/master/tutorials/batch_processing/earthquakes "promo" tutorials section] of the GRASS GitHub repository. Some [http://adhoc.osgeo.osuosl.org/grass/New_Zealand/ additional real-time maps] centered on New Zealand can be found there too. | |||
=== Pests and diseases === | |||
* [[Invasive_Species_modelling | Invasive Species modelling]] | |||
* | * Case study: [[GlobalChangeBiology | Assessing the invasiveness of exotic species using ecosystem models and GRASS GIS]] | ||
* Case study: [[Population_Genetics_and_GIS | Population Genetics and GIS]] | |||
* | == References == | ||
* Cannata M., Marzocchi R., and Molinari M.E. Modeling of landslide–generated tsunami with grass. Transaction in GIS 16(2) , page 191–214, 2012 | |||
* | * Cannata M. and Marzocchi R. Two dimensional dam break flooding simulation - a gis embedded approach. Natural Hazards 61(3) , pages 1143–1159, 2012 | ||
* Di Leo M., Manfreda S., Fiorentino M., An automated procedure for the detection of flood prone areas: r.hazard.flood, Geomatics Workbooks n.10, 2011. ([http://geomatica.como.polimi.it/workbooks/n10/GW10-FOSS4Git_2011.pdf PDF]) | |||
* Manfreda S., Di Leo M., Sole A., Detection of Flood Prone Areas using Digital Elevation Models, Journal of Hydrologic Engineering, (10.1061/(ASCE)HE.1943-5584.0000367), 2011. | |||
* | * Marzocchi R., Federici B., Cannata M., Cosso T., and Syriou A. The contribution of gis in flood mapping. two approaches using open source grass gis software. Applied geomatics , 2014 | ||
-- | * K. Suprit, Aravind Kalla and V. Vijith. A GRASS-GIS-Based Methodology for Flash Flood Risk Assessment in Goa, 2010. ([http://www.nio.org/nio/uploadnews/277_2_second_floods.pdf PDF]) | ||
[[Category:Applications]] | [[Category:Applications]] | ||
[[Category:Documentation]] | [[Category:Documentation]] | ||
[[Category:Hydrology]] | |||
[[Category:Risk]] | |||
[[Category:Hazards]] |
Latest revision as of 22:15, 16 March 2021
Review of Natural Hazard
The following is a list of natural events and relative existing models, procedures, or works. Please feed the list with other phenomena and resources.
Rockfall
- r.rockcone (soon in GRASS-Addons)
Rockcone implement a quick and low-cost determination of areas endangered by rockfalls following an heuristic approach: a block tarting from a source will travel down the slope and stop at the intersection point of the topography with a so called energy line drawn from the source point and making an angle φ with horizontal.
- r.sass3D (in development by the IST-SUPSI)
Sass3d is 3D rock fall model accounting for flying routine (air trajectory), rebound routine (energy loss) & rolling routine (equivalent sliding approach).
Avalanche
missing, existing slope instability zonation applications (Raghavan et al. 2004)
Debris Flow
- r.debris paper
- r.dfw
Is an empirical model to estimate areas involved by the diffusion of the debris. It uses a Monte Carlo approach based on wolkers. The outputs are raster estimates of velocity, sedimentation height, and number of random walk. The Perla velocity model is applied.
Flood
- r.sim.water - Overland flow hydrologic simulation using path sampling method (SIMWE).
- HydroFOSS - a GIS embedded approach for Free & Open Source Hydrological modeling.
- r.topkapi - ?
- r.water.fea - Finite element analysis program for hydrologic simulations (GRASS 4 only, document)
- r.hydro.CASC2D (in GIPE)
- r.inund.fluv - allows to obtain a fluvial potentially inundation map given a high-resolution DTM of the area surrounding the river and a water surface profile calculated through an 1-D hydrodynamic model.
- r.damflood - Estimate the area potentially inundated in case of dam break using the Shallow Water Equation (swe.h ANSI C library)
- r.traveltime - computes the travel time of surface runoff to an outlet
- r.lake - Simple flood simulation
- r.hazard.flood - fast procedure to detect flood prone areas
Landslide
- missing flow models
- exists slope instability zonation (Avalanche risk management using GRASS GIS. Marco Ciolli and Paolo Zatelli, 2002, Geomatic Workbooks)
Erosion
- Erosion/deposition modeling in complex terrain using GIS, Tutorial, Helena Mitasova.
Tsunami
- r.tsunami in GRASS-Addons
This script implements the metodology described in MAPPE DI INONDAZIONE DOVUTE A TSUNAMI MEDIANTE IL GIS GRASS: APPLICAZIONE ALL'ISOLA DI ST. LUCIA, CARAIBI, Cannata M, B. Federici, M. Molinari, 2006, PDF.
This work shows the application and the validation of a procedure in GRASS to realize tsunami inundation maps based on the morphological characteristics, the vegetation and the settlements of the analyzed coast. Such a procedure, already illustrated in the VII GRASS Italian Users Meeting, and then improved, allow the estimation of the maximum vertical height of the tsunami waves hitting the coast (run-up) and the subsequent diffusion over the inland areas, as a function of the morphology, the vegetation, and the urbanization of the coastal area. The model, already successfully applied for the ligurian coast, has to be tested in different areas in order to validate a global applicability. For this reason the selected case study was the Caribbean island of St. Lucia. Based on elevation data, land-use, coast-line, observations, and studies, the methodology was applied and the inundation maps for three different event was estimated. The results were compared historical data and other estimates, verifying the general validity of the method.
Desertification
- RIADE project (PDF)
Wildfire
- The wildfire spread simulation in GRASS is done using three modules:
- r.ros (for wildfire spread simulation) - Generates three, or four raster map layers showing 1) the base (perpendicular) rate of spread (ROS), 2) the maximum (forward) ROS, 3) the direction of the maximum ROS, and optionally 4) the maximum potential spotting distance. See also How to create parameters to run r.ros.
- r.spread - Simulates elliptically anisotropic spread on a graphics window and generates a raster map of the cumulative time of spread, given raster maps containing the rates of spread (ROS), the ROS directions and the spread origins. It optionally produces raster maps to contain backlink UTM coordinates for tracing spread paths.
- r.spreadpath - Recursively traces the least cost path backwards to cells from which the cumulative cost was determined.
- Mapping Forest Fire Risk with Open Source Software, Pedro Venâncio (in Portuguese) work presentation presentation 2
Earthquakes
- Recent Earthquakes: map of earthquakes that have occurred in the last 7 days. A new image is generated every three hours by a GRASS batch job running on a headless server which fetches data from the USGS and creates a logarithmic bubble plot. The scripts that run this can be found in the "promo" tutorials section of the GRASS GitHub repository. Some additional real-time maps centered on New Zealand can be found there too.
Pests and diseases
- Invasive Species modelling
- Case study: Assessing the invasiveness of exotic species using ecosystem models and GRASS GIS
- Case study: Population Genetics and GIS
References
- Cannata M., Marzocchi R., and Molinari M.E. Modeling of landslide–generated tsunami with grass. Transaction in GIS 16(2) , page 191–214, 2012
- Cannata M. and Marzocchi R. Two dimensional dam break flooding simulation - a gis embedded approach. Natural Hazards 61(3) , pages 1143–1159, 2012
- Di Leo M., Manfreda S., Fiorentino M., An automated procedure for the detection of flood prone areas: r.hazard.flood, Geomatics Workbooks n.10, 2011. (PDF)
- Manfreda S., Di Leo M., Sole A., Detection of Flood Prone Areas using Digital Elevation Models, Journal of Hydrologic Engineering, (10.1061/(ASCE)HE.1943-5584.0000367), 2011.
- Marzocchi R., Federici B., Cannata M., Cosso T., and Syriou A. The contribution of gis in flood mapping. two approaches using open source grass gis software. Applied geomatics , 2014
- K. Suprit, Aravind Kalla and V. Vijith. A GRASS-GIS-Based Methodology for Flash Flood Risk Assessment in Goa, 2010. (PDF)