64 lines
3.2 KiB
Markdown
64 lines
3.2 KiB
Markdown
Supervised Training
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=======================
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_Supervised_ here essentially means: "doing things the old fashioned way". Old fashioned in the context of
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deep learning (DL), of course, so it's still fairly new. Also, "old fashioned" of course also doesn't
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always mean bad - it's just that we'll be able to do better than simple supervised training later on.
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In a way, the viewpoint of "supervised training" is a starting point for all projects one would encounter in the context of DL, and
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hence is worth studying. And although it typically yields inferior results to approaches that more tightly
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couple with physics, it nonetheless can be the only choice in certain application scenarios where no good
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model equations exist.
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## Problem Setting
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For supervised training, we're faced with an
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unknown function $f^*(x)=y^*$, collect lots of pairs of data $[x_0,y^*_0], ...[x_n,y^*_n]$ (the training data set)
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and directly train a NN to represent an approximation of $f^*$ denoted as $f$, such
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that $f(x)=y \approx y^*$.
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The $f$ we can obtain is typically not exact,
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but instead we obtain it via a minimization problem:
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by adjusting weights $\theta$ of our representation with $f$ such that
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$\text{arg min}_{\theta} \sum_i (f(x_i ; \theta)-y^*_i)^2$.
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This will give us $\theta$ such that $f(x;\theta) \approx y$ as accurately as possible given
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our choice of $f$ and the hyperparameters for training. Note that above we've assumed
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the simplest case of an $L^2$ loss. A more general version would use an error metric $e(x,y)$
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to be minimized via $\text{arg min}_{\theta} \sum_i e( f(x_i ; \theta) , y^*_i) )$. The choice
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of a suitable metric is topic we will get back to later on.
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Irrespective of our choice of metric, this formulation
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gives the actual "learning" process for a supervised approach.
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The training data typically needs to be of substantial size, and hence it is attractive
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to use numerical simulations to produce a large number of training input-output pairs.
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This means that the training process uses a set of model equations, and approximates
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them numerically, in order to train the NN representation $\tilde{f}$. This
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has a bunch of advantages, e.g., we don't have measurement noise of real-world devices
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and we don't need manual labour to annotate a large number of samples to get training data.
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On the other hand, this approach inherits the common challenges of replacing experiments
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with simulations: first, we need to ensure the chosen model has enough power to predict the
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behavior of real-world phenomena that we're interested in.
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In addition, the numerical approximations have numerical errors
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which need to be kept small enough for a chosen application. As these topics are studied in depth
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for classical simulations, the existing knowledge can likewise be leveraged to
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set up DL training tasks.
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```{figure} resources/supervised-training.jpg
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---
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height: 220px
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name: supervised-training
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---
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A visual overview of supervised training. Quite simple overall, but it's good to keep this
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in mind in comparison to the more complex variants we'll encounter later on.
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```
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## Show me some code!
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Let's directly look at an implementation within a more complicated context:
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_turbulent flows around airfoils_ from {cite}`thuerey2020deepFlowPred`.
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