GTRPy is a python package that allows you to calculate the well-known tensors in the General Theory of Relativity without writing a single line of code. Furthermore, you can apply many operations to 6 different types of fields, in both 3D and 4D.
It's tested for GNU/Linux. However, it should also work in macOS. If you ever encounter with a problem, feel free to create an issue.
You can easily install the GTRPy via
python3 -m pip install gtrpy
or, you can directly clone the repository
git clone https://github.com/camarman/GTRPy.git
to your favourite directory
Install the python3
requirements by running
python3 -m pip install numpy Pillow pysimplegui sympy
Additionally, you will also need tkinter
and LaTeX
support to run the GTRPy. These can be installed by running:
in Fedora
sudo dnf install dvipng python3-tkinter texlive-collection-latex texlive-collection-latexextra
in Ubuntu
sudo apt install dvipng python3-tk texlive-latex-base texlive-latex-extra
To start GTRPy, simply run
python3 -m gtrpy.run
The program will create the logs
directory under your current directory, which will contain the outputs of the performed operations.
Please look at the
docs/user_guide.md
for a summary of the GTRPy. You can look at thedemos
directory, to see more detailed examples.
Either by using predefined coordinates or by defining the coordinate system yourself, you can calculate:
- Inverse Metric Tensor
- Christoffel Symbol
- Riemann Tensor
- Ricci Tensor
- Ricci Scalar
- Weyl Tensor
- Traceless Ricci Tensor
- Einstein Tensor
- Kretschmann Scalar
The one important point in GTRPy is that the variables defined in the metric tensor must be constant. For example, you can write the Schwarzschild Coordinates System as
g = diag[-(1-r_s/r), (1-r_s/r)**(-1), r^2, r^2sin^2(theta)]
and that is totally fine for GTRPy, since r_s = 2GM/c^2
is a constant.
Let us suppose you have another variable called F(r)
which is a function of r
. And the metric is given as
g = diag[-1, F, r^2, r^2sin^2(theta)]
Sadly, the GTRPy will interpret this F
as a constant and not as a function of r
. So the result will be wrong. On the other hand, if you know what that function is, for instance if F(r) = r^3
, then you should write r^3
instead of F
and use the GTRPy in that way. Thus, you should write the metric as
g = diag[-1, r^3, r^2, r^2sin^2(theta)]
and now, the GTRPy will work perfectly fine.
Currently, there are 6 different types of fields that you can carry out operations. These are:
- Scalar Field
- Type (1,0) Vector Field
- Type (0,1) Vector Field
- Type (2,0) Tensor Field
- Type (1,1) Tensor Field
- Type (0,2) Tensor Field
- Print out the equations obtained from each operation by clicking a single button
- Checking the Killing field condition for a given vector field
- Varying the type of a given vector and tensor field
- Calculating Covariant and Lie derivatives for scalar, vector, and tensor fields
4D/Main Page | 3D/Main Page |
---|---|
4D/Scalar Field | 4D/Vector Field | 4D/Tensor Field |
---|---|---|
3D/Scalar Field | 3D/Vector Field | 3D/Tensor Field |
---|---|---|
- Gradient, Divergence, Curl, and Laplace operations on fields
- Partial and Covariant derivatives of the GTR tensors
- Including more coordinate systems
- Adding a user-defined (custom) function support
I am looking for developers who would like to contribute to the project. If you are interested, feel free to create an issue by stating how would you like to contribute. Any help or idea is appreciated. For more information, you can also look at the CONTRIBUTING.md
.