Metadata-Version: 2.1
Name: f3dasm
Version: 0.2.5
Summary: Stub for own interpretation of F3DASM code.
Home-page: https://github.com/bessagroup/F3DASM/tree/versionmartin
Author: Martin van der Schelling
Author-email: M.P.vanderSchelling@tudelft.nl
License: BSD 3-Clause
Keywords: keyword_1,keyword_2
Classifier: License :: OSI Approved :: BSD License
Classifier: Programming Language :: Python
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.10
Requires-Python: >=3.7
Description-Content-Type: text/markdown

<center>
	<img src="./docs/img/f3dasm-logo.png" alt="F3DASM logo" />
</center>

***

This code intends to facilitate the design and analysis of materials & structures/metamaterials

The Bessa research group at TU Delft is small... At the moment, we have limited availability to help future users/developers adapting the code to new problems, but we will do our best to help!

Created by M.A. Bessa (M.A.Bessa@tudelft.nl) in September 2016

Current developers: [M.P. van der Schelling](https://github.com/mpvanderschelling/)

## Links

* Link to [documentation](https://bessagroup.github.io/F3DASM/)
* Link to [GitHub repository](https://github.com/bessagroup/F3DASM/tree/versionmartin)
* Link to [PyPI package](https://pypi.org/project/f3dasm/)


## Referencing

If you use or edit our work, please cite at least one of the appropriate references:

[1] Bessa, M. A., Bostanabad, R., Liu, Z., Hu, A., Apley, D. W., Brinson, C., Chen, W., & Liu, W. K. (2017). A framework for data-driven analysis of materials under uncertainty: Countering the curse of dimensionality. Computer Methods in Applied Mechanics and Engineering, 320, 633-667.

[2] Bessa, M. A., & Pellegrino, S. (2018). Design of ultra-thin shell structures in the stochastic post-buckling range using Bayesian machine learning and optimization. International Journal of Solids and Structures, 139, 174-188.

[3] Bessa, M. A., Glowacki, P., & Houlder, M. (2019). Bayesian machine learning in metamaterial design: fragile becomes super-compressible. Advanced Materials, 31(48), 1904845.

[4] Mojtaba, M., Bostanabad, R., Chen, W., Ehmann, K., Cao, J., & Bessa, M. A. (2019). Deep learning predicts path-dependent plasticity. Proceedings of the National Academy of Sciences, 116(52), 26414-26420.
