# C#: Loop to find minima of function

I currently have this function:

``````    public double Max(double[] x, double[] y)
{
//Get min and max of x array as integer
int xMin = Convert.ToInt32(x.Min());
int xMax = Convert.ToInt32(x.Max());

// Generate a list of x values for input to Lagrange

double i = 2;
double xOld = Lagrange(xMin,x,y);
double xNew = xMax;
do
{
xOld = xNew;
xNew = Lagrange(i,x,y);
i = i + 0.01;
} while (xOld > xNew);

return i;
}
``````

This will find the minimum value on a curve with decreasing slope...however, given this curve, I need to find three minima.

How can I find the three minima and output them as an array or individual variables? This curve is just an example--it could be inverted--regardless, I need to find multiple variables. So once the first min is found it needs to know how to get over the point of inflection and find the next... :/

The Lagrange function can be found here.* For all practical purposes, the Lagrange function will give me f(x) when I input x...visually, it means the curve supplied by wolfram alpha.

Possible solution? Generate an array of input, say x[1,1.1,1.2,1.3,1.4...], get an array back from the Lagrange function. Then find the three lowest values of this function? Then get the keys corresponding to the values? How would I do this?

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I'm not sure this is a programming question. Anyway, what is Lagrange? And what's up with the commented line? – André Neves May 23 '12 at 14:54
So you've found the global minimum and are now looking for local minimums? – dtb May 23 '12 at 14:56
You need to first answer the question of how you determine the answer mathematically (outside of the realm of programming) before you can determine how you can program a computer to calculate it. – Servy May 23 '12 at 14:57
Every minimum has two neighbors with greater Y values. – Marko Juvančič May 23 '12 at 14:58
@MarkoJuvančič You also need to check the endpoints – Servy May 23 '12 at 14:58

Assuming you're just trying to "brute force" calculate this to a certain level of prcision, you need your algorithm to basically find any value where both neighbors are greater than the current value of your loop.

To simplify this, let's just say you have an array of numbers, and you want to find the indices of the three local minima. Here's a simple algorithm to do it:

``````public void Test()
{
var ys = new[] { 1, 2, 3, 4, 5, 4, 3, 2, 1, 2, 3, 4, 5, 4, 3, 4, 5, 4 };
var indices = GetMinIndices(ys);
}

public List<int> GetMinIndices(int[] ys)
{
var minIndices = new List<int>();
for (var index = 1; index < ys.Length; index++)
{
var currentY = ys[index];
var previousY = ys[index - 1];
if (index < ys.Length - 1)
{
var neytY = ys[index + 1];
if (previousY > currentY && neytY > currentY) // neighbors are greater
}
else // we're at the last index
{
if (previousY > currentY) // previous is greater
}
}
return minIndices;
}
``````

So, basically, you pass in your array of function results (ys) that you calculated for an array of inputs (xs) (not shown). What you get back from this function is the minimum indices. So, in this example, you get back 8, 14, and 17.

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DanM, I appreciate your answer. I'm new to programming, so I would greatly benefit from more information and/or examples. – Kevin Brown May 23 '12 at 15:02
Kevin, I updated my answer. I hope that helps. – devuxer May 23 '12 at 15:37
Great! One more thing...I need to disregard negative y-values in the loop (since the returned voltages will all be positive, but the interpolation function could render some negative values)...How would I do that? I'm fooling with your code right now! – Kevin Brown May 23 '12 at 21:09
Rephrase: If the y-value is zero, it still needs to be indexed as a minimum, but it needs to disregard the values less than zero. Tricky? – Kevin Brown May 23 '12 at 21:12
If you just need to filter `ys` to remove the negative numbers before you find the min values, all you need to do is put `using System.Linq;` at the top of the code file, then do `var nonNegativeYs = ys.Where(y => y >= 0);` – devuxer May 25 '12 at 0:00

It's been a while since I've taken a numerical methods class, so bear with me. In short there are a number of ways to search for the root(s) of a function, and depending on what your your function is (continuous? differentiable?), you need to choose one that is appropriate.

For your problem, I'd probably start by trying to use Newton's Method to find the roots of the second degree Lagrange polynomial for your function. I haven't tested out this library, but there is a C# based numerical methods package on CodePlex that implements Newton's Method that is open source. If you wanted to dig through the code you could.

The majority of root finding methods have cousins in the broader CS topic of 'search'. If you want a really quick and dirty approach, or you have a very large search space, consider something like Simulated Annealing. Finding all of your minima isn't guaranteed but it's fast and easy to code.

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