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Symfem is a symbolic finite element definition library, that can be used to symbolically evaluate the basis functions of a finite element space. Symfem can:
- Symbolically compute the basis functions of a wide range of finite element spaces
- Symbolically compute derivatives and vector products and substitute values into functions
- Allow the user to define their own element using the Ciarlet definition of a finite element
- Be used to verify that the basis functions of a given space have some desired properties
You can find details of recent changes to Symfem in the changelog.
Symfem can be installed by downloading the GitHub repo and running:
pip3 install .You may also use -e to install in editable mode:
pip3 install -e .The latest release of Symfem can be installed by running:
pip3 install symfemThe latest release of Symfem can be installed by running:
conda install -c conda-forge symfemTo run the Symfem unit tests, clone the repository and run:
python3 -m pytest test/You may instead like to run the following, as this will skip the slowest tests.
python3 -m pytest test/ --speed fastFinite elements can be created in Symfem using the symfem.create_element()
function. For example, some elements are created in the following snippet:
import symfem
lagrange = symfem.create_element("triangle", "Lagrange", 1)
rt = symfem.create_element("tetrahedron", "Raviart-Thomas", 2)
nedelec = symfem.create_element("triangle", "N2curl", 1)
qcurl = symfem.create_element("quadrilateral", "Qcurl", 2)The basis functions of an element can be obtained by calling get_basis_functions():
lagrange = symfem.create_element("triangle", "Lagrange", 1)
print(lagrange.get_basis_functions())[-x - y + 1, x, y]
Each basis function will be a Sympy symbolic expression.
Derivative of these basis functions can be computed using the functions in
symfem.functions.
The function map_to_cell can be used to map the basis functions of a finite element
to a non-default cell:
lagrange = symfem.create_element("triangle", "Lagrange", 1)
print(lagrange.get_basis_functions())
print(lagrange.map_to_cell([(0,0), (2, 0), (2, 1)]))[-x - y + 1, x, y]
[1 - x/2, x/2 - y, y]
More detailed documentation of the latest release version of Symfem can be found on
Read the Docs. A series of example uses
of Symfem can be found in the demo folder or viewed on
Read the Docs.
Details of the definition of each element can be found on DefElement alongside Symfem snippets for creating the element.
You can ask questions about using Symfem by using GitHub Discussions. Bugs can be reported using the GitHub issue tracker.
If you find a bug in Symfem, please report it on the issue tracker.
If you want to suggest a new feature or an improvement of a current feature, you can submit this on the issue tracker.
If you want to add a new element to Symfem, take a look at the Adding an element guide.
If you want to directly submit code to Symfem, you can do this by forking the Symfem repo, then submitting a pull request. If you want to contribute, but are unsure where to start, have a look at the issues labelled "good first issue".
On opening a pull request, unit tests and flake8 style checks will run. You can click on these in the pull request to see where (if anywhere) there are errors in your code.
We expect all our contributors to follow the Contributor Covenant. Any unacceptable behaviour can be reported to Matthew ([email protected]).
The reference interval has vertices (0,) and (1,). Its sub-entities are numbered as follows.
- Bernstein (alternative names: Bernstein-Bezier)
- bubble
- dPc
- enriched Galerkin (alternative names: EG)
- Hermite
- Lagrange (alternative names: P)
- Morley-Wang-Xu (alternative names: MWX)
- P1-iso-P2 (alternative names: P2-iso-P1, iso-P2 P1)
- serendipity (alternative names: S)
- Taylor (alternative names: discontinuous Taylor)
- vector Lagrange (alternative names: vP)
- Wu-Xu
The reference triangle has vertices (0, 0), (1, 0), and (0, 1). Its sub-entities are numbered as follows.
- Alfeld-Sorokina (alternative names: AS)
- Argyris
- Arnold-Winther (alternative names: AW, conforming Arnold-Winther)
- Bell
- Bernardi-Raugel
- Bernstein (alternative names: Bernstein-Bezier)
- Brezzi-Douglas-Fortin-Marini (alternative names: BDFM)
- Brezzi-Douglas-Marini (alternative names: BDM, N2div)
- bubble
- bubble enriched Lagrange
- bubble enriched vector Lagrange
- conforming Crouzeix-Raviart (alternative names: conforming CR)
- Crouzeix-Raviart (alternative names: CR, Crouzeix-Falk, CF)
- enriched Galerkin (alternative names: EG)
- enriched vector Galerkin (alternative names: locking-free enriched Galerkin, LFEG)
- Fortin-Soulie (alternative names: FS)
- Guzman-Neilan first kind (alternative names: Guzman-Neilan)
- Guzman-Neilan second kind
- Hellan-Herrmann-Johnson (alternative names: HHJ)
- Hermite
- Hsieh-Clough-Tocher (alternative names: Clough-Tocher, HCT, CT)
- Kong-Mulder-Veldhuizen (alternative names: KMV)
- Lagrange (alternative names: P)
- Mardal-Tai-Winther (alternative names: MTW)
- matrix Lagrange
- Morley
- Morley-Wang-Xu (alternative names: MWX)
- Nedelec (alternative names: Nedelec1, N1curl)
- Nedelec2 (alternative names: N2curl)
- nonconforming Arnold-Winther (alternative names: nonconforming AW)
- P1 macro
- P1-iso-P2 (alternative names: P2-iso-P1, iso-P2 P1)
- Raviart-Thomas (alternative names: RT, N1div)
- reduced Hsieh-Clough-Tocher (alternative names: rHCT)
- Regge
- symmetric matrix Lagrange
- Taylor (alternative names: discontinuous Taylor)
- transition
- vector Lagrange (alternative names: vP)
- Wu-Xu
The reference quadrilateral has vertices (0, 0), (1, 0), (0, 1), and (1, 1). Its sub-entities are numbered as follows.
- Arbogast-Correa (alternative names: AC, AC full, Arbogast-Correa full)
- Arnold-Boffi-Falk (alternative names: ABF)
- Bogner-Fox-Schmit (alternative names: BFS)
- Brezzi-Douglas-Fortin-Marini (alternative names: BDFM)
- bubble
- direct serendipity
- dPc
- enriched Galerkin (alternative names: EG)
- enriched vector Galerkin (alternative names: locking-free enriched Galerkin, LFEG)
- Huang-Zhang (alternative names: HZ)
- NCE (alternative names: RTCE, Qcurl, Nedelec, Ncurl)
- NCF (alternative names: RTCF, Qdiv)
- P1-iso-P2 (alternative names: P2-iso-P1, iso-P2 P1)
- Q (alternative names: Lagrange, P)
- Rannacher-Turek
- Regge
- serendipity (alternative names: S)
- serendipity Hcurl (alternative names: Scurl, BDMCE, AAE)
- serendipity Hdiv (alternative names: Sdiv, BDMCF, AAF)
- tiniest tensor (alternative names: TNT)
- tiniest tensor Hcurl (alternative names: TNTcurl)
- tiniest tensor Hdiv (alternative names: TNTdiv)
- trimmed serendipity Hcurl (alternative names: TScurl)
- trimmed serendipity Hdiv (alternative names: TSdiv)
- vector dPc
- vector Q (alternative names: vQ)
The reference tetrahedron has vertices (0, 0, 0), (1, 0, 0), (0, 1, 0), and (0, 0, 1). Its sub-entities are numbered as follows.
- Bernardi-Raugel
- Bernstein (alternative names: Bernstein-Bezier)
- Brezzi-Douglas-Fortin-Marini (alternative names: BDFM)
- Brezzi-Douglas-Marini (alternative names: BDM, N2div)
- bubble
- Crouzeix-Raviart (alternative names: CR, Crouzeix-Falk, CF)
- enriched Galerkin (alternative names: EG)
- enriched vector Galerkin (alternative names: locking-free enriched Galerkin, LFEG)
- Guzman-Neilan first kind (alternative names: Guzman-Neilan)
- Guzman-Neilan second kind
- Hellan-Herrmann-Johnson (alternative names: HHJ)
- Hermite
- Kong-Mulder-Veldhuizen (alternative names: KMV)
- Lagrange (alternative names: P)
- Mardal-Tai-Winther (alternative names: MTW)
- matrix Lagrange
- Morley-Wang-Xu (alternative names: MWX)
- Nedelec (alternative names: Nedelec1, N1curl)
- Nedelec2 (alternative names: N2curl)
- Raviart-Thomas (alternative names: RT, N1div)
- Regge
- symmetric matrix Lagrange
- Taylor (alternative names: discontinuous Taylor)
- transition
- vector Lagrange (alternative names: vP)
- Wu-Xu
The reference hexahedron has vertices (0, 0, 0), (1, 0, 0), (0, 1, 0), (1, 1, 0), (0, 0, 1), (1, 0, 1), (0, 1, 1), and (1, 1, 1). Its sub-entities are numbered as follows.
- Brezzi-Douglas-Duran-Fortin (alternative names: BDDF)
- Brezzi-Douglas-Fortin-Marini (alternative names: BDFM)
- bubble
- dPc
- enriched Galerkin (alternative names: EG)
- enriched vector Galerkin (alternative names: locking-free enriched Galerkin, LFEG)
- NCE (alternative names: RTCE, Qcurl, Nedelec, Ncurl)
- NCF (alternative names: RTCF, Qdiv)
- Q (alternative names: Lagrange, P)
- Rannacher-Turek
- Regge
- serendipity (alternative names: S)
- serendipity Hcurl (alternative names: Scurl, BDMCE, AAE)
- serendipity Hdiv (alternative names: Sdiv, BDMCF, AAF)
- tiniest tensor (alternative names: TNT)
- tiniest tensor Hcurl (alternative names: TNTcurl)
- tiniest tensor Hdiv (alternative names: TNTdiv)
- trimmed serendipity Hcurl (alternative names: TScurl)
- trimmed serendipity Hdiv (alternative names: TSdiv)
- vector dPc
- vector Q (alternative names: vQ)
The reference prism has vertices (0, 0, 0), (1, 0, 0), (0, 1, 0), (0, 0, 1), (1, 0, 1), and (0, 1, 1). Its sub-entities are numbered as follows.
- Lagrange (alternative names: P)
- Nedelec (alternative names: Ncurl)
The reference pyramid has vertices (0, 0, 0), (1, 0, 0), (0, 1, 0), (1, 1, 0), and (0, 0, 1). Its sub-entities are numbered as follows.
- Lagrange (alternative names: P)
The reference dual polygon (hexagon example shown) has vertices (1, 0), (3/4, sqrt(3)/4), (1/2, sqrt(3)/2), (0, sqrt(3)/2), (-1/2, sqrt(3)/2), (-3/4, sqrt(3)/4), (-1, 0), (-3/4, -sqrt(3)/4), (-1/2, -sqrt(3)/2), (0, -sqrt(3)/2), (1/2, -sqrt(3)/2), and (3/4, -sqrt(3)/4). Its sub-entities are numbered as follows.
- Buffa-Christiansen (alternative names: BC)
- dual polynomial (alternative names: dual P, dual)
- rotated Buffa-Christiansen (alternative names: RBC)