A python library for Tomography for Fusion
Project description
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:target: https://travis-ci.org/ToFuProject/tofu
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:target: https://anaconda.org/tofuproject/tofu/badges/
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:target: https://anaconda.org/tofuproject/tofu/badges/
.. image:: https://codecov.io/gh/ToFuProject/tofu/branch/master/graph/badge.svg
:target: https://codecov.io/gh/ToFuProject/tofu
ToFu
====
-----
**Warning**
This Pypi package focuses on tomography for fusion research.
It uses the same name as a previous package dedicated to a testing framework coupling fixtures and tests loosely, now renamed **reahl-tofu** and developped by Iwan Vosloo since 2006. If you ended up here looking for a web-oriented library, you should probably redirect to the more recent [**reahl-tofu**](https://pypi.python.org/pypi/reahl-tofu) page.
-----
ToFu stands for Tomography for Fusion, it is an open-source machine-independent python library
with non-open source plugins containing all machine-dependent routines.
It is distributed under the MIT license and aims at providing the fusion community with
a transparent and modular tool for creating / designing diagnostics and using them for
synthtic diagnostic (direct problem) and tomography (inverse problem).
It was first created at the Max-Planck Institute for Plasma Physics (IPP) in Garching, Germany,
by Didier Vezinet, and is now maintained / debugged / updated by him and other contributors.
A sphinx-generated documentation can be found at [the ToFu documentation page](https://ToFuProject.github.io/tofu/index.html),
and the code itself is hosted on [GitHub](https://github.com/ToFuProject/tofu).
----
ToFu provides the user with a series of python classes for creating, handling and visualizing a diagnostic geometry, meshes and basis functions,
geometry matrices, pre-treating experimental data and computing tomographic inversions.
Each one of these main tasks is accomplished by a dedicated module in the larger ToFu package.
In its current version, only the geometry and data-handling modules are released.
The others, while operational, are not user-friendly and documented yet, they will be available in future releases.
The geometry module is sufficient for diagnostic designing and for a synthetic diagnostic approach (i.e.: computing the integrated signal from a simulated 2D or 3D emissivity).
This geometry module allows in particular:
* To handle linear and toroidal vaccum vessels
* To define apertures and detectors as planar polygons of arbitrary shapes, or to define a spherical converging lens and a circular detector in its focal plane.
* To assign an arbitrary number of apertures to each detector (and the apertures do not have to stand in parallel planes)
* To automatically compute the full Volume of Sight (VOS) in 3D of each {detector+aperture(s)} set
* To discretise the VOS for a numerical 3D integration of a simulated emissivity in order to compute the associated signal
It is in this geometrical sense that ToFu enables a synthetic diagnostic approach, it does not provide the tools for simulating the emissivity (that should be an input, provided by another code).
:target: https://travis-ci.org/ToFuProject/tofu
.. image:: https://anaconda.org/tofuproject/tofu/badges/version.svg
:target: https://anaconda.org/tofuproject/tofu/badges/
.. image:: https://anaconda.org/tofuproject/tofu/badges/downloads.svg
:target: https://anaconda.org/tofuproject/tofu/badges/
.. image:: https://codecov.io/gh/ToFuProject/tofu/branch/master/graph/badge.svg
:target: https://codecov.io/gh/ToFuProject/tofu
ToFu
====
-----
**Warning**
This Pypi package focuses on tomography for fusion research.
It uses the same name as a previous package dedicated to a testing framework coupling fixtures and tests loosely, now renamed **reahl-tofu** and developped by Iwan Vosloo since 2006. If you ended up here looking for a web-oriented library, you should probably redirect to the more recent [**reahl-tofu**](https://pypi.python.org/pypi/reahl-tofu) page.
-----
ToFu stands for Tomography for Fusion, it is an open-source machine-independent python library
with non-open source plugins containing all machine-dependent routines.
It is distributed under the MIT license and aims at providing the fusion community with
a transparent and modular tool for creating / designing diagnostics and using them for
synthtic diagnostic (direct problem) and tomography (inverse problem).
It was first created at the Max-Planck Institute for Plasma Physics (IPP) in Garching, Germany,
by Didier Vezinet, and is now maintained / debugged / updated by him and other contributors.
A sphinx-generated documentation can be found at [the ToFu documentation page](https://ToFuProject.github.io/tofu/index.html),
and the code itself is hosted on [GitHub](https://github.com/ToFuProject/tofu).
----
ToFu provides the user with a series of python classes for creating, handling and visualizing a diagnostic geometry, meshes and basis functions,
geometry matrices, pre-treating experimental data and computing tomographic inversions.
Each one of these main tasks is accomplished by a dedicated module in the larger ToFu package.
In its current version, only the geometry and data-handling modules are released.
The others, while operational, are not user-friendly and documented yet, they will be available in future releases.
The geometry module is sufficient for diagnostic designing and for a synthetic diagnostic approach (i.e.: computing the integrated signal from a simulated 2D or 3D emissivity).
This geometry module allows in particular:
* To handle linear and toroidal vaccum vessels
* To define apertures and detectors as planar polygons of arbitrary shapes, or to define a spherical converging lens and a circular detector in its focal plane.
* To assign an arbitrary number of apertures to each detector (and the apertures do not have to stand in parallel planes)
* To automatically compute the full Volume of Sight (VOS) in 3D of each {detector+aperture(s)} set
* To discretise the VOS for a numerical 3D integration of a simulated emissivity in order to compute the associated signal
It is in this geometrical sense that ToFu enables a synthetic diagnostic approach, it does not provide the tools for simulating the emissivity (that should be an input, provided by another code).
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