Online Portal for StrainTool software
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estimate strain tensor parameters using different methods.
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Visualize results on interactive map
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Download output files for further processing
Check out the demo !!
StrainWebTool is a web application developed to estimate strain tensor parameters using StrainTool Software. The development of the application was based on Flask microframework for Python. Bootstrap open source toolkit was used to enable a responsive web design and Leaflet open-source JavaScript library for producing interactive maps.
The application consists of three basic parts:
webtool.py
: the main python source code file, that includes all necessary functions utilizing StrainTool software and enables the building of HTML templates.- static files: a folder including static files such as headers, footers, images, javascript source code files.
- templates: a folder including the main templates for the application.
Three different HTML templates have been formulated to implement the application:
tmpl_inputs.html
is the template where the user uploads their input files.tmpl_params.html
is the template where the user chooses the parameters that StrainTool will later on use to estimate strain tensor parameterstmpl_results.html
is the template where the results are presented. The user can download result files and see the results visualized on an interactive map. Each template consists of three basic columns. The first column contains all input forms for the parameters needed to estimate strain tensors. The second column contains the plot tools and options to generate GMT maps; these however are not active in the current beta version. The third column is where the interactive map is placed and the results are visualized
Install StrainTool - Flask - virtual enviroment
- Install **StrainTool** Software with all prerequisites needed **Install Flask** $> pip install Flask **Install Virtual Enviroment** **Debian, Ubuntu** sudo apt-get install python-virtualenv **CentOS, Fedora** sudo yum install python-virtualenv
Run app
**create virtual enviroment** virtualenv flask **activate venv** . flask/bin/activate **go to app directory** cd app **set flask application and run local server** export FLASK_APP=webtool.py flask run * Running on http://127.0.0.1:5000/inputs **OR** flask run --host=0.0.0.0 * will run on your public IP
Files tree
app (main application) |--> templates (html files) |--> static (images, style files, css) |--> website.py : app to serve main website for straintool |--> webtool.py " app to serve template for webtool.ONLY template
To perform the computations, StrainWebTool needs an input file, that holds input data. Usually, this implies a list of GPS/GNSS stations with their ellipsoidal coordinates (aka longitude and latitude) and their respective tectonic velocities (usually estimated using position time-series) along with the corresponding standard deviation values. The format of these files, should follow the convention:
station-name longtitude latitude Ve Vn SigmaVe SigmaVn Sne time-span string deg. deg. mm/yr mm/yr mm/yr mm/yr / dec. years
Station coordinates are provided in longitude/latitude pairs in decimal degrees. Velocities and velocity standard deviations are provided in mm per years (mm/yr). Sne is the correlation coefficient between East and North velocity components and time-span is the total time span of the station timeseries in decimal degrees. Note that at his point the last two columns (aka Sne and time-span) are not used, so they could have random values. There are no strict formatting rules on how the individual elements should be printed (i.e. how many fields, decimal places, etc.). The only condition is that fields are separated by whitespace(s). Note that the input file format is identical to what is used in StrainTool Software (Anastasiou et al., 2019 ); users can browse its dedicated web page (https://dsolab.github.io/StrainTool/) for a more detailed description.
After the uploading of the input-file, all the options for the estimation of strain tensor are unlocked.
The first part is the selection of the method for strain estimation. If 'shen' is passed in, the estimation will follow the algorithm described in Shen et al, 2015, using a weighted least squares approach. If 'veis' is passed in, then the region is going to be split into delaneuy triangles and a strain estimated in each barycenter. Default is 'shen'. If ‘One Tensor’ checked, then only one strain tensor will be estimated, at the region’s barycentre. In the second part, user specifies the region as a rectangle and x-axis/y-axis grid steps. Any station falling outside this region will be omitted. In the third part, the user selects the interpolation model parameters for ‘shen’ method. The options are:
- Wt: Let W=Σi*Gi, the total reweighting coefficients of the data, and let Wt be the threshold of W. For a given Wt, the smoothing constant D is determined by Wd=Wt . It should be noted that W is a function of the interpolation coordinate, therefore for the same Wt assigned, D varies spatially based on the in situ data strength; that is, the denser the local data array is, the smaller is D, and vice versa. Default is Wt=24.
- D min: This is the lower limit for searching for an optimal d-param value. Unit is km. Default is dmin=1km.
- D max: This is the upper limit for searching for an optimal d-param value. Unit is km. Default is dmax=500km.
- D step: This is the step size for searching for an optimal d-param value. Unit is km. Default is dstep=2km.
- D parameter: This is the 'D' parameter for computing the spatial weights. If this option is used, then the parameters: dmin, dmax, dstep and Wt are not used. Final there are two special argument as:
- cut excess stations: If this option is enabled, then any station (from the input file) outside the region limit (passed in via the 'region' option) is not considered in the strain estimation.
- generate statistics: This option will create an output file, named 'strain_stats.dat', where estimation info and statistics will be written.
Note thast users can browse StrainTool’s dedicated web page (https://dsolab.github.io/StrainTool/) for a more detailed description.
Results of StrainWebTool
are recorded in the following three files:
- strain_info.dat : This file includes strain tensor parameters, principal axis, rotational rates, dilatation etc.
The columns of the file are structured as below:
Latitude Longtitude vx+dvx vy+dvy w+dw exx+dexx exy+dexy eyy+deyy emax+demax emin+demin shr+dshr azi+dazi dilat+ddilat sec.inv.+dsec.inv. deg deg mm/yr mm/yr deg/Myr nstrain/yr nstrain/yr nstrain/yr nstrain/yr nstrain/yr nstrain/yr deg. nstrain/yr nstrain/yr
- station_info.dat : Stations' data used for the calculation of strain tensor are written at htis file. Format is:
Code Longtitude Latitude Ve Vn dVe dVn string deg deg mm/yr
- strain_stats.dat : Output file for statistics:
--HEADER-- Parameters and arguments used for estimation of strain tensors. --statistics-- Longtitude Latitude # stations D (optimal) CutOff dis. Sigma deg. deg. # Km # /
For the results visualization, the application uses an active map developed using the Leaflet javascript library. In this map, user can choose to plot principal axes, shear strain, dilatation or second invariant results. In addition, user can add as separate layer the stations and their respective velocities used to estimate strain tensors.
- Create an issue and describe your idea
- Fork it
- Create your feature branch (
git checkout -b my-new-idea
) - Commit your changes (
git commit -am 'Add some feature'
) - Publish the branch (
git push origin my-new-idea
) - Create a new Pull Request
- Profit! ✅
The work is licensed under MIT-license
Dimitrios G. Anastasiou
Dr. Rural & Surveying Engineer | Dionysos Satellite Observatory - NTUA | [email protected]
Xanthos Papanikolaou
Rural & Surveying Engineer | Dionysos Satellite Observatory - NTUA | [email protected]
Dr. Athanassios Ganas
Research Director | Institute of Geodynamics | National Observatory of Athens | [email protected]
Prof. Demitris Paradissis
Professor NTUA | Dionysos Satellite Observatory - NTUA | [email protected]
The history of releases can be viewed at ChangeLog
EPOS IP - EPOS Implementation Phase
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement N° 676564
Disclaimer: the content of this website reflects only the author’s view and the Commission is not responsible for any use that may be made of the information it contains.
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Anastasiou D., Ganas A., Legrand J., Bruyninx C., Papanikolaou X., Tsironi V. and Kapetanidis V. (2019). Tectonic strain distribution over Europe from EPN data. EGU General Assembly 2019, Geophysical Research Abstracts, Vol. 21, EGU2019-17744-1 Abstract
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Shen, Z.-K., M. Wang, Y. Zeng, and F. Wang, (2015), Strain determination using spatially discrete geodetic data, Bull. Seismol. Soc. Am., 105(4), 2117-2127, doi: 10.1785/0120140247
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Veis, G., Billiris, H., Nakos, B., and Paradissis, D. (1992), Tectonic strain in greece from geodetic measurements, C.R.Acad.Sci.Athens, 67:129--166
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Python Software Foundation. Python Language Reference, version 2.7. Available at http://www.python.org
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Flask microframework for Python (v1.0.2).
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Bootstrap open source toolkit (v4.2).
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Leaflet open-source JavaScript library (v1.4.0).