WolframLanguageForJupyter
SetReplace
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WolframLanguageForJupyter | SetReplace | |
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7 | 1 | |
975 | 211 | |
2.3% | - | |
0.0 | 0.0 | |
4 months ago | over 2 years ago | |
Mathematica | Mathematica | |
MIT License | MIT License |
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WolframLanguageForJupyter
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Family of Curves
You can find it here https://www.wolfram.com/engine/, also you can use it in a notebook environment like python in jupyther, here is a github repository for the setup instructions https://github.com/WolframResearch/WolframLanguageForJupyter
- Mathics: A free, open-source alternative to Mathematica
- Why isn't Wolfram more popular?
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[Win10] Need Help with Installation of Wolfram Language for Jupyter
I'm trying to add Wolfram language to Jupyter using these instructions.
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Best book to learn mathematica?
You can use mathematica with jupyter notebooks. https://github.com/WolframResearch/WolframLanguageForJupyter
- Launching Version 13.0 of Wolfram Language and Mathematica
- Python Programming and Numerical Methods: A Guide for Engineers and Scientists
SetReplace
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Multicomputation as a General Paradigm for Theoretical Science
Some of the ideas in this post might pan out, some might not. Regardless, I do think token event graphs will turn out to be important. Of course, I'm biased: I coined the name TEG -- although the underlying idea originated with Max Piskunov and his "local multiway systems" [0]
What's promising about TEGs (and their incidence hypergraph, the rewrite hypergraph) is that they offer a clean methodology to decompose the behavior of a non-deterministic automaton into its causally independent parts. We're still trying to understand how to think about them, but the most promising approach seems to use the lens of (modular) representation theory, which gives us a rich mathematical toolkit to work with.
If this methodology works, there will be possibility to represent many kinds of systems in disparate fields, ranging from distributed computation to physics to biology to machine learning, in the common language of TEGs and their representations. Of course it may turn out to be merely a recasting of older ideas. In particular the Khrone-Rhodes theorem [1], categorical Petri nets [2], and the GNS construction [3] seem like they might be describing the same or an analogous procedure.
I hope to soon be describing this approach in full detail using quiver geometry [4].
[0]: https://github.com/maxitg/SetReplace/blob/master/Research/Lo...
[1]: https://www.wikiwand.com/en/Krohn–Rhodes_theory
[2]: https://arxiv.org/abs/2101.04238
[3]: https://www.youtube.com/watch?v=OmaSAG4J6nw
[4]: https://quivergeometry.net
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