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Update Branin Function #449

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3 changes: 2 additions & 1 deletion docs/pages.jl
Original file line number Diff line number Diff line change
@@ -1,5 +1,5 @@
pages = ["index.md"
"Tutorials" => [
"Tutorials" => [
"Basics" => "tutorials.md",
"Radials" => "radials.md",
"Kriging" => "kriging.md",
Expand Down Expand Up @@ -32,6 +32,7 @@ pages = ["index.md"
"Water Flow function" => "water_flow.md",
"Welded beam function" => "welded_beam.md",
"Branin function" => "BraninFunction.md",
"Improved Branin function" => "ImprovedBraninFunction.md",
"Ackley function" => "ackley.md",
"Gramacy & Lee Function" => "gramacylee.md",
"Salustowicz Benchmark" => "Salustowicz.md",
Expand Down
41 changes: 41 additions & 0 deletions docs/src/ImprovedBraninFunction.md
Original file line number Diff line number Diff line change
@@ -0,0 +1,41 @@
# Branin Function

The Branin Function is commonly used as a test function for metamodelling in computer experiments, especially in the context of optimization.


# Modifications for Improved Branin Function:
To enhance the Branin function, changes were made to introduce irregularities, variability, and a dynamic aspect to its landscape. Here's an example:

```function improved_branin(x, time_step)
x1 = x[1]
x2 = x[2]
b = 5.1 / (4*pi^2)
c = 5/pi
r = 6
a = 1
s = 10
t = 1 / (8*pi)

# Adding noise to the function's output
noise = randn() * time_step # Simulating time-varying noise
term1 = a * (x2 - b*x1^2 + c*x1 - r)^2
term2 = s*(1-t)*cos(x1 + noise) # Introducing dynamic component
y = term1 + term2 + s
end
```

This improved function now incorporates irregularities, variability, and a dynamic aspect. These changes aim to make the optimization landscape more challenging and realistic.

# Using the Improved Branin Function:
After defining the improved Branin function, you can proceed to test different surrogates and visualize their performance using the updated function. Here's an example of using the improved function with the Radial Basis surrogate:

```
# Assuming you've defined 'improved_branin' and imported necessary packages

radial_surrogate = RadialBasis(xys, [improved_branin(xy, 0.1) for xy in xys], lower_bound, upper_bound)
p1 = surface(x, y, (x, y) -> radial_surrogate([x, y]))
scatter!(xs, ys, marker_z=zs)
p2 = contour(x, y, (x, y) -> radial_surrogate([x, y]))
scatter!(xs, ys, marker_z=zs)
plot(p1, p2, title="Radial Surrogate")
```
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