A Python package for topographic template matching
Project description
# scarplet
[![Build Status](https://travis-ci.com/rmsare/scarplet.svg?branch=master)](https://travis-ci.com/rmsare/scarplet)
[![Documentation Status](https://readthedocs.org/projects/scarplet/badge/?version=latest)](https://scarplet.readthedocs.io/en/latest/?badge=latest)
scarplet is a Python package for applying template matching techniques to digital elevation data, in
particular for detecting and measuring the maturity of fault scarps and other
landforms [[0, 1]](#references).
It is intended for earth scientists who want to apply diffusion dating methods
to or extract landforms from large datasets. The scarplet API can be used to
estimate the height and relative age of a landform or identify DEM pixels
based on their fit to a landform template.
It was designed with two main goals:
* Allow contributors to define template functions for their problem area of interest
* Make it straightforward to apply these methods to large datasets by parallelizing/distrbuting computation using multiprocessing, [dask](https://dask.readthedocs.io), or other tools [[2]](#references)
## Getting started
### Installation
`scarplet` can be installed using `conda` or `pip`. It is developed for Python 3.4+ and currently works on Linux and Mac OS X.
```bash
conda install scarplet -c conda-forge
```
Or, to manually install the latest version from github:
```bash
git clone https://github.com/rmsare/scarplet
cd scarplet
conda install --file=requirements.txt -c conda-forge
python setup.py develop
```
The main dependencies are numpy, scipy, numexpr, pyfftw (which requires LibFFTW3)
and rasterio/GDAL.
## Examples
Example notebooks can be found in the [docs folder](docs/source/examples/) or [website](https://scarplet.readthedocs.io/en/latest/examples/scarps.html) and sample datasets can be loaded using the [datasets submodule](https://scarplet.readthedocs.io/en/latest/scarplet.datasets.base.html).
### Detecting fault scarps
This example uses a scarp template based on a diffusion model of scarp degradation
[[0]](#references) to identify scarp-like landforms along the San Andreas Fault near
Wallace Creek, CA.
```python
import numpy as np
import scarplet as sl
from scarplet.WindowedTemplate import Scarp
params = {'scale': 100,
'age': 10,
'ang_min': -10 * np.pi / 2,
'ang_max': 10 * np.pi / 2
}
data = sl.datasets.load_carrizo()
res = sl.match(data, Scarp, **params)
sl.plot_results(data, res)
```
<img src="docs/img/carrizo_example.png" alt="Fault scarp results" height="340">
### Extracting confined river channels
To illustrate template function flexibility, this example uses a Channel
template similar to the Ricker wavelet [[3]](#references) to extract part of a channel network.
This is example uses a moderate resolution SRTM data tile. In general, for
high resolution data like lidar, there are more robust alternatives for
channel network extraction or channel head identification [[4, 5]](#references).
```python
import numpy as np
import scarplet as sl
from scarplet.WindowedTemplate import Channel
params = {'scale': 10,
'age': 0.1,
'ang_min': -np.pi / 2,
'ang_max': np.pi / 2
}
data = sl.datasets.load_grandcanyon()
res = sl.match(data, Channel, **params)
sl.plot_results(data, res)
```
<img src="docs/img/rivers_example.png" alt="Channel results" height="340">
There are also [example notebooks](https://scarplet.readthedocs.io/en/latest/index.html) and [an API reference](https://scarplet.readthedocs.io/en/latest/api.html) in the documentation.
## Documentation
Read the documentation for example use cases, an API reference, and more. They
are hosted at [scarplet.readthedocs.io](https://scarplet.readthedocs.io).
## Contributing
### Bug reports
Bug reports are much appreciated. Please [open an issue](https://github.com/rmsare/scarplet/issues/new) with the `bug` label,
and provide a minimal example illustrating the problem.
### Suggestions
Feel free to [suggest new features](https://github.com/rmsare/scarplet/issues/new) in an issue with the `new-feature` label.
### Pull requests
Don't hestitate to file an issue; I would be happy to discuss extensions or help to build a new feature.
If you would like to add a feature or fix a bug, please fork the repository, create a feature branch, and [submit a PR](https://github.com/rmsare/scarplet/compare) and reference any relevant issues. There are nice guides to contributing with GitHub [here](https://akrabat.com/the-beginners-guide-to-contributing-to-a-github-project/) and [here](https://yourfirstpr.github.io/). Please include tests where appropriate and check that the test suite passes (a Travis build or `pytest scarplet/tests`) before submitting.
### Support and questions
Please [open an issue](https://github.com/rmsare/scarplet/issues/new) with your question.
## References
[0] Hanks, T.C., 2000. The age of scarplike landforms from diffusion‐equation analysis. Quaternary Geochronology, 4, pp. 313-338. [doi](https://doi.org/10.1029/RF004p0313)
[1] Hilley, G.E., DeLong, S., Prentice, C., Blisniuk, K. and Arrowsmith, J.R., 2010. Morphologic dating of fault scarps using airborne laser swath mapping (ALSM) data. Geophysical Research Letters, 37(4). [doi](https://doi.org/10.1029/2009GL042044)
[2] Sare, R, Hilley, G. E., and DeLong, S. B., 2018, Regional scale detection of fault scarps and other tectonic landforms: Examples from Northern California, in review, Journal of Geophysical Research: Solid Earth.
[3] Lashermes, B., Foufoula‐Georgiou, E., and Dietrich, W. E., 2007, Channel network extraction from high resolution topography using wavelets. Geophysical Research Letters, 34(23). [doi](https://doi.org/10.1029/2007GL031140)
[4] Passalacqua, P., Tarolli, P., and Foufoula‐Georgiou, E., 2010, Testing space‐scale methodologies for automatic geomorphic feature extraction from lidar in a complex mountainous landscape. Water Resources Research, 46(11). [doi](https://doi.org/10.1029/2009WR008812)
[5] Clubb, F. J., Mudd, S. M., Milodowski, D. T., Hurst, M. D., and Slater, L. J., 2014, Objective extraction of channel heads from high‐resolution topographic data. Water Resources Research, 50(5). [doi](https://doi.org/10.1002/2013WR015167)
## License
This work is licensed under the MIT License (see [LICENSE](LICENSE)).
[![Build Status](https://travis-ci.com/rmsare/scarplet.svg?branch=master)](https://travis-ci.com/rmsare/scarplet)
[![Documentation Status](https://readthedocs.org/projects/scarplet/badge/?version=latest)](https://scarplet.readthedocs.io/en/latest/?badge=latest)
scarplet is a Python package for applying template matching techniques to digital elevation data, in
particular for detecting and measuring the maturity of fault scarps and other
landforms [[0, 1]](#references).
It is intended for earth scientists who want to apply diffusion dating methods
to or extract landforms from large datasets. The scarplet API can be used to
estimate the height and relative age of a landform or identify DEM pixels
based on their fit to a landform template.
It was designed with two main goals:
* Allow contributors to define template functions for their problem area of interest
* Make it straightforward to apply these methods to large datasets by parallelizing/distrbuting computation using multiprocessing, [dask](https://dask.readthedocs.io), or other tools [[2]](#references)
## Getting started
### Installation
`scarplet` can be installed using `conda` or `pip`. It is developed for Python 3.4+ and currently works on Linux and Mac OS X.
```bash
conda install scarplet -c conda-forge
```
Or, to manually install the latest version from github:
```bash
git clone https://github.com/rmsare/scarplet
cd scarplet
conda install --file=requirements.txt -c conda-forge
python setup.py develop
```
The main dependencies are numpy, scipy, numexpr, pyfftw (which requires LibFFTW3)
and rasterio/GDAL.
## Examples
Example notebooks can be found in the [docs folder](docs/source/examples/) or [website](https://scarplet.readthedocs.io/en/latest/examples/scarps.html) and sample datasets can be loaded using the [datasets submodule](https://scarplet.readthedocs.io/en/latest/scarplet.datasets.base.html).
### Detecting fault scarps
This example uses a scarp template based on a diffusion model of scarp degradation
[[0]](#references) to identify scarp-like landforms along the San Andreas Fault near
Wallace Creek, CA.
```python
import numpy as np
import scarplet as sl
from scarplet.WindowedTemplate import Scarp
params = {'scale': 100,
'age': 10,
'ang_min': -10 * np.pi / 2,
'ang_max': 10 * np.pi / 2
}
data = sl.datasets.load_carrizo()
res = sl.match(data, Scarp, **params)
sl.plot_results(data, res)
```
<img src="docs/img/carrizo_example.png" alt="Fault scarp results" height="340">
### Extracting confined river channels
To illustrate template function flexibility, this example uses a Channel
template similar to the Ricker wavelet [[3]](#references) to extract part of a channel network.
This is example uses a moderate resolution SRTM data tile. In general, for
high resolution data like lidar, there are more robust alternatives for
channel network extraction or channel head identification [[4, 5]](#references).
```python
import numpy as np
import scarplet as sl
from scarplet.WindowedTemplate import Channel
params = {'scale': 10,
'age': 0.1,
'ang_min': -np.pi / 2,
'ang_max': np.pi / 2
}
data = sl.datasets.load_grandcanyon()
res = sl.match(data, Channel, **params)
sl.plot_results(data, res)
```
<img src="docs/img/rivers_example.png" alt="Channel results" height="340">
There are also [example notebooks](https://scarplet.readthedocs.io/en/latest/index.html) and [an API reference](https://scarplet.readthedocs.io/en/latest/api.html) in the documentation.
## Documentation
Read the documentation for example use cases, an API reference, and more. They
are hosted at [scarplet.readthedocs.io](https://scarplet.readthedocs.io).
## Contributing
### Bug reports
Bug reports are much appreciated. Please [open an issue](https://github.com/rmsare/scarplet/issues/new) with the `bug` label,
and provide a minimal example illustrating the problem.
### Suggestions
Feel free to [suggest new features](https://github.com/rmsare/scarplet/issues/new) in an issue with the `new-feature` label.
### Pull requests
Don't hestitate to file an issue; I would be happy to discuss extensions or help to build a new feature.
If you would like to add a feature or fix a bug, please fork the repository, create a feature branch, and [submit a PR](https://github.com/rmsare/scarplet/compare) and reference any relevant issues. There are nice guides to contributing with GitHub [here](https://akrabat.com/the-beginners-guide-to-contributing-to-a-github-project/) and [here](https://yourfirstpr.github.io/). Please include tests where appropriate and check that the test suite passes (a Travis build or `pytest scarplet/tests`) before submitting.
### Support and questions
Please [open an issue](https://github.com/rmsare/scarplet/issues/new) with your question.
## References
[0] Hanks, T.C., 2000. The age of scarplike landforms from diffusion‐equation analysis. Quaternary Geochronology, 4, pp. 313-338. [doi](https://doi.org/10.1029/RF004p0313)
[1] Hilley, G.E., DeLong, S., Prentice, C., Blisniuk, K. and Arrowsmith, J.R., 2010. Morphologic dating of fault scarps using airborne laser swath mapping (ALSM) data. Geophysical Research Letters, 37(4). [doi](https://doi.org/10.1029/2009GL042044)
[2] Sare, R, Hilley, G. E., and DeLong, S. B., 2018, Regional scale detection of fault scarps and other tectonic landforms: Examples from Northern California, in review, Journal of Geophysical Research: Solid Earth.
[3] Lashermes, B., Foufoula‐Georgiou, E., and Dietrich, W. E., 2007, Channel network extraction from high resolution topography using wavelets. Geophysical Research Letters, 34(23). [doi](https://doi.org/10.1029/2007GL031140)
[4] Passalacqua, P., Tarolli, P., and Foufoula‐Georgiou, E., 2010, Testing space‐scale methodologies for automatic geomorphic feature extraction from lidar in a complex mountainous landscape. Water Resources Research, 46(11). [doi](https://doi.org/10.1029/2009WR008812)
[5] Clubb, F. J., Mudd, S. M., Milodowski, D. T., Hurst, M. D., and Slater, L. J., 2014, Objective extraction of channel heads from high‐resolution topographic data. Water Resources Research, 50(5). [doi](https://doi.org/10.1002/2013WR015167)
## License
This work is licensed under the MIT License (see [LICENSE](LICENSE)).
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