Metadata-Version: 2.1
Name: matadi
Version: 0.0.21
Summary: Material Definition with Automatic Differentiation
Home-page: https://github.com/adtzlr/matadi
Author: Andreas Dutzler
Author-email: a.dutzler@gmail.com
License: GPL-3.0-or-later
Project-URL: Code, https://github.com/adtzlr/matadi
Project-URL: Issues, https://github.com/adtzlr/matadi/issues
Platform: UNKNOWN
Classifier: Development Status :: 3 - Alpha
Classifier: Intended Audience :: Science/Research
Classifier: License :: OSI Approved :: GNU General Public License v3 or later (GPLv3+)
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Topic :: Scientific/Engineering
Classifier: Topic :: Scientific/Engineering :: Mathematics
Classifier: Topic :: Utilities
Requires-Python: >=3.6
Description-Content-Type: text/markdown
Provides-Extra: all
License-File: LICENSE

# matADi
Material Definition with Automatic Differentiation (AD)

![matADi](https://raw.githubusercontent.com/adtzlr/matadi/main/docs/logo/matadi-logo.svg)

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matADi is a simple Python module which acts as a wrapper on top of [casADi](https://web.casadi.org/) [[1](https://doi.org/10.1007/s12532-018-0139-4)] for easy definitions of hyperelastic strain energy functions. [Gradients](https://en.wikipedia.org/wiki/Gradient) (stresses) and [hessians](https://en.wikipedia.org/wiki/Hessian_matrix) (elasticity tensors) are carried out by casADi's powerful and fast [**Automatic Differentiation (AD)**](https://en.wikipedia.org/wiki/Automatic_differentiation) capabilities. It is designed to handle inputs with trailing axes which is especially useful for the application in Python-based finite element modules like [scikit-fem](https://scikit-fem.readthedocs.io/en/latest/) or [FElupe](https://adtzlr.github.io/felupe/). Mixed-field formulations are supported as well as single-field formulations.

## Installation
Install `matADi` from PyPI via pip.

```shell
pip install matadi
```

## Usage
First, a symbolic variable on which our strain energy function will be based on has to be created.

**Note**: *A variable of matADi is an instance of a symbolic variable of casADi (`casadi.SX.sym`). All `matadi.math` functions are simple links to (symbolic) casADi-functions.*

```python
from matadi import Variable, Material
from matadi.math import det, transpose, trace

F = Variable("F", 3, 3)
```

Next, take your favorite paper on hyperelasticity or be creative and define your own strain energy density function as a function of some variables `x` (where `x` is always a **list** of variables).

```python
def neohooke(x, C10=0.5, bulk=200.0):
    """Strain energy density function of a nearly-incompressible 
    Neo-Hookean isotropic hyperelastic material formulation."""

    F = x[0]
    
    J = det(F)
    C = transpose(F) @ F

    return C10 * (J ** (-2 / 3) * trace(C) - 3) + bulk * (J - 1) ** 2 / 2
```

With this simple Python function at hand, we create an instance of a **Material**, which allows extra `args` and `kwargs` to be passed to our strain energy function. This instance now enables the evaluation of both **gradient** (stress) and **hessian** (elasticity) via methods based on automatic differentiation - optionally also on input data containing trailing axes. If necessary, the strain energy density function itself will be evaluated on input data with optional trailing axes by the **function** method.

```python
Mat = Material(
    x=[F],
    fun=neohooke,
    kwargs={"C10": 0.5, "bulk": 10.0},
)

# init some random deformation gradients
import numpy as np

defgrad = np.random.rand(3, 3, 5, 100) - 0.5

for a in range(3):
    defgrad[a, a] += 1.0

W = Mat.function([defgrad])[0]
P = Mat.gradient([defgrad])[0]
A = Mat.hessian([defgrad])[0]
```

## Template classes for hyperelasticity
matADi provides several simple template classes suitable for simple hyperelastic materials. Some common isotropic hyperelastic material formulations are located in `matadi.models` (see list below). These strain energy functions have to be passed as the `fun` argument into an instance of `MaterialHyperelastic`. Usage is exactly the same as described above. To convert a hyperelastic material based on the deformation gradient into a mixed three-field formulation suitable for nearly-incompressible behavior (*displacements*, *pressure* and *volume ratio*) an instance of a `MaterialHyperelastic` class has to be passed to `ThreeFieldVariation`.

```python

from matadi import MaterialHyperelastic, ThreeFieldVariation
from matadi.models import neo_hooke

# init some random data
pressure = np.random.rand(5, 100)
volratio = np.random.rand(5, 100) / 10 + 1

kwargs = {"C10": 0.5, "bulk": 20.0}

NH = MaterialHyperelastic(fun=neo_hooke, **kwargs)

W = NH.function([defgrad])[0]
P = NH.gradient([defgrad])[0]
A = NH.hessian([defgrad])[0]

NH_upJ = ThreeFieldVariation(NH)

W_upJ = NH_upJ.function([defgrad, pressure, volratio])
P_upJ = NH_upJ.gradient([defgrad, pressure, volratio])
A_upJ = NH_upJ.hessian([defgrad, pressure, volratio])
```

The output of `NH_upJ.gradient([defgrad, pressure, volratio])` is a list with gradients of the functional as `[dWdF, dWdp, dWdJ]`. Hessian entries are provided as list of the upper triangle entries, e.g. `NH_upJ.hessian([defgrad, pressure, volratio])` returns `[d2WdFdF, d2WdFdp, d2WdFdJ, d2Wdpdp, d2WdpdJ, d2WdJdJ]`.

Available [isotropic hyperelastic material models](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py):
- [Linear Elastic](https://en.wikipedia.org/wiki/Linear_elasticity) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L5-L7))
- [Saint Venant Kirchhoff](https://en.wikipedia.org/wiki/Hyperelastic_material#Saint_Venant%E2%80%93Kirchhoff_model) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L10-L14))
- [Neo-Hooke](https://en.wikipedia.org/wiki/Neo-Hookean_solid) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L17-L21))
- [Mooney-Rivlin](https://en.wikipedia.org/wiki/Mooney%E2%80%93Rivlin_solid) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L24-L29))
- [Yeoh](https://en.wikipedia.org/wiki/Yeoh_(hyperelastic_model)) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L32-L37))
- [Third-Order-Deformation (James-Green-Simpson)](https://onlinelibrary.wiley.com/doi/abs/10.1002/app.1975.070190723) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L40-L51))
- [Ogden](https://en.wikipedia.org/wiki/Ogden_(hyperelastic_model)) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L54-L64))
- [Arruda-Boyce](https://en.wikipedia.org/wiki/Arruda%E2%80%93Boyce_model) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L67-L80))
- [Extended-Tube](https://meridian.allenpress.com/rct/article-abstract/72/4/602/92819/An-Extended-Tube-Model-for-Rubber-Elasticity?redirectedFrom=fulltext) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L83-L91))
- [Van-der-Waals (Kilian)](https://doi.org/10.1016/0032-3861(81)90200-7) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_isotropic.py#L94-L103))

Available [anisotropic hyperelastic material models](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_anisotropic.py):
- Fiber ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_anisotropic.py#L17-L35))
- Fiber-family (+/- combination of single Fiber) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_anisotropic.py#L38-L45))
- [Holzapfel Gasser Ogden](https://royalsocietypublishing.org/doi/full/10.1098/rsif.2005.0073) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/_hyperelasticity_anisotropic.py#L48-L77))

Available [micro-sphere hyperelastic frameworks](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere) (Miehe, Göktepe, Lulei) [[2](https://doi.org/10.1016/j.jmps.2004.03.011)]:
- [affine stretch](https://doi.org/10.1016/j.jmps.2004.03.011) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere/affine/_models.py#L6-L16))
- [affine tube](https://doi.org/10.1016/j.jmps.2004.03.011) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere/affine/_models.py#L19-L30))
- [non-affine stretch](https://doi.org/10.1016/j.jmps.2004.03.011) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere/nonaffine/_models.py#L7-L17))
- [non-affine tube](https://doi.org/10.1016/j.jmps.2004.03.011) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere/nonaffine/_models.py#L20-L32))

Available [micro-sphere hyperelastic material models](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere) (Miehe, Göktepe, Lulei) [[2](https://doi.org/10.1016/j.jmps.2004.03.011)]:
- [Miehe Göktepe Lulei](https://doi.org/10.1016/j.jmps.2004.03.011) ([code](https://github.com/adtzlr/matadi/blob/main/matadi/models/microsphere/nonaffine/_models.py#L35-L49))

Any user-defined isotropic hyperelastic strain energy density function may be passed as the `fun` argument of `MaterialHyperelastic` by using the following template:

```python
def fun(F, **kwargs):
    # user code
    return W
```

In order to apply the above material model only on the isochoric part of the deformation gradient [[3](https://doi.org/10.1016/0045-7825(85)90033-7)], use the decorator [`@isochoric_volumetric_split`](https://github.com/adtzlr/matadi/blob/main/matadi/models/_helpers.py#L7-L31). If the keyword `bulk` is passed, an additional [volumetric strain energy function](https://github.com/adtzlr/matadi/blob/main/matadi/models/_helpers.py#L34-L35) is added to the base material formulation.

```python
from matadi.models import isochoric_volumetric_split
from matadi.math import trace, transpose

@isochoric_volumetric_split
def nh(F, C10=0.5):
    # user code of strain energy function, e.g. neo-hooke
    return C10 * (trace(transpose(F) @ F) - 3)

NH = MaterialHyperelastic(nh, C10=0.5, bulk=200.0)
```

## Lab
In the `Lab` :lab_coat: experiments on homogenous loadcases can be performed. Let's take the non-affine micro-sphere material model suitable for rubber elasticity with parameters from [[2](https://doi.org/10.1016/j.jmps.2004.03.011), Fig. 19] and run **uniaxial**, **biaxial** and **planar shear** tests.

```python
from matadi import Lab, MaterialHyperelastic
from matadi.models import miehe_goektepe_lulei

mat = MaterialHyperelastic(
    miehe_goektepe_lulei, 
    mu=0.1475, 
    N=3.273, 
    p=9.31, 
    U=9.94, 
    q=0.567, 
    bulk=5000.0,
)

lab = Lab(mat)
data = lab.run(
    ux=True, 
    bx=True, 
    ps=True, 
    shear=True, 
    stretch_min=1.0, 
    stretch_max=2.0, 
    shear_max=1.0,
)
fig, ax = lab.plot(data, stability=True)
fig2, ax2 = lab.plot_shear(data)
```

![Lab experiments(Microsphere)](https://raw.githubusercontent.com/adtzlr/matadi/main/docs/images/plot_lab-microsphere.svg)

![Lab experiments shear(Microsphere)](https://raw.githubusercontent.com/adtzlr/matadi/main/docs/images/plot_shear_lab-microsphere.svg)

Unstable states of deformation can be indicated as dashed lines with the stability argument `lab.plot(data, stability=True)`. This checks whether if 
a) the volume ratio is greater zero,
b) the monotonic increasing slope of force per undeformed area vs. stretch and
c) the sign of the resulting stretch from a small superposed force in one direction.

## Hints and usage in FEM modules
For tensor-valued material definitions use `MaterialTensor` (e.g. any stress-strain relation). Please have a look at [casADi's documentation](https://web.casadi.org/). It is very powerful but unfortunately does not support all the Python stuff you would expect. For example Python's default if-else-statements can't be used in combination with symbolic conditions (use `math.if_else(cond, if_true, if_false)` instead).

Simple examples for using `matadi` with [`scikit-fem`](https://github.com/adtzlr/matadi/discussions/14#) as well as with [`felupe`](https://github.com/adtzlr/matadi/discussions/22) are shown in the Discussion section.

## References
[1] J. A. E. Andersson, J. Gillis, G. Horn, J. B. Rawlings, and M. Diehl, *CasADi - A software framework for nonlinear optimization and optimal control*, Math. Prog. Comp., vol. 11, no. 1, pp. 1–36, 2019, [![DOI:10.1007/s12532-018-0139-4](https://zenodo.org/badge/DOI/10.1007/s12532-018-0139-4.svg)](https://doi.org/10.1007/s12532-018-0139-4)

[2] C. Miehe, S. Göktepe and F. Lulei, *A micro-macro approach to rubber-like materials. Part I: the non-affine micro-sphere model of rubber elasticity*, Journal of the Mechanics and Physics of Solids, vol. 52, no. 11. Elsevier BV, pp. 2617–2660, Nov. 2004. [![DOI:10.1016/j.jmps.2004.03.011](https://zenodo.org/badge/DOI/10.1016/j.jmps.2004.03.011.svg)](https://doi.org/10.1016/j.jmps.2004.03.011)

[3] J. C. Simo, R. L. Taylor, and K. S. Pister, *Variational and projection methods for the volume constraint in finite deformation elasto-plasticity*, Computer Methods in Applied Mechanics and Engineering, vol. 51, no. 1–3, pp. 177–208, Sep. 1985, [![DOI:10.1016/0045-7825(85)90033-7](https://zenodo.org/badge/DOI/10.1016/0045-7825(85)90033-7.svg)](https://doi.org/10.1016/0045-7825(85)90033-7)



