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# Examples | |
### Preamble | |
```python | |
import numpy as np | |
from pysr import * | |
``` | |
We'll also set up some default options that will | |
make these simple searches go faster (but are less optimal | |
for more complex searches). | |
```python | |
kwargs = dict(populations=5, niterations=5, annealing=True) | |
``` | |
## 1. Simple search | |
Here's a simple example where we | |
find the expression `2 cos(x3) + x0^2 - 2`. | |
```python | |
X = 2 * np.random.randn(100, 5) | |
y = 2 * np.cos(X[:, 3]) + X[:, 0] ** 2 - 2 | |
model = PySRRegressor(binary_operators=["+", "-", "*", "/"], **kwargs) | |
model.fit(X, y) | |
print(model) | |
``` | |
## 2. Custom operator | |
Here, we define a custom operator and use it to find an expression: | |
```python | |
X = 2 * np.random.randn(100, 5) | |
y = 1 / X[:, 0] | |
model = PySRRegressor( | |
binary_operators=["plus", "mult"], | |
unary_operators=["inv(x) = 1/x"], | |
**kwargs | |
) | |
model.fit(X, y) | |
print(model) | |
``` | |
## 3. Multiple outputs | |
Here, we do the same thing, but with multiple expressions at once, | |
each requiring a different feature. | |
```python | |
X = 2 * np.random.randn(100, 5) | |
y = 1 / X[:, [0, 1, 2]] | |
model = PySRRegressor( | |
binary_operators=["plus", "mult"], | |
unary_operators=["inv(x) = 1/x"], | |
**kwargs | |
) | |
model.fit(X, y) | |
``` | |
## 4. Plotting an expression | |
Here, let's use the same equations, but get a format we can actually | |
use and test. We can add this option after a search via the `set_params` | |
function: | |
```python | |
model.set_params(extra_sympy_mappings={"inv": lambda x: 1/x}) | |
model.sympy() | |
``` | |
If you look at the lists of expressions before and after, you will | |
see that the sympy format now has replaced `inv` with `1/`. | |
For now, let's consider the expressions for output 0: | |
```python | |
expressions = expressions[0] | |
``` | |
This is a pandas table, which we can filter: | |
```python | |
best_expression = expressions.iloc[expressions.MSE.argmin()] | |
``` | |
We can see the LaTeX version of this with: | |
```python | |
import sympy | |
sympy.latex(best_expression.sympy_format) | |
``` | |
We can access the numpy version with: | |
```python | |
f = best_expression.lambda_format | |
print(f) | |
``` | |
Which shows a PySR object on numpy code: | |
``` | |
>> PySRFunction(X=>1/x0) | |
``` | |
Let's plot this against the truth: | |
```python | |
from matplotlib import pyplot as plt | |
plt.scatter(y[:, 0], f(X)) | |
plt.xlabel('Truth') | |
plt.ylabel('Prediction') | |
plt.show() | |
``` | |
Which gives us: | |
![](https://github.com/MilesCranmer/PySR/raw/master/docs/images/example_plot.png) | |