# Mathematica: finding Extrema positions with Solve, Reduce and FindRoot. (derivative)

I want to determinate the local maxima and minima of the following 2 functions

1. `xE[t_] := 10 (t - Sin[t]) - Sqrt[40^2 - (10 (1 - Cos[t]))^2]`
2. `vE = xE'[t]`

So I tried to solve the first derivate of `xE[t]` with:

``````extremaXE = Solve[vE[t] == 0, t] (* vE is the 1st derivative of xE *)
``````

but I got this error:

``````Solve::ifun: Inverse functions are being used by Solve, so some solutions may not
be found; use Reduce for complete solution information.
``````

I tried then with reduce and I got this error:

``````Reduce::nsmet: This system cannot be solved with the methods available to Reduce
``````

so what should I do to determinate the local minima and maxima through the derivatives?

-
The functions have many maxima and minima, you could use `FindRoot` together with an initial guess. –  b.gatessucks Apr 29 '12 at 20:22
Also notice from the Help : `Solve` deals primarily with linear and polynomial equations. –  b.gatessucks Apr 29 '12 at 20:23
The Mathematica site is in public beta, if you have further questions, you're likely to get good answers there. –  rcollyer Apr 30 '12 at 1:17

Use NLOpt.

It has algorithms to find local/global extrema with/without derivatives. It is callable from C, C++, Fortran, Matlab or GNU Octave, Python, GNU Guile, and GNU R.

http://ab-initio.mit.edu/wiki/index.php/NLopt

Does this help?

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The OP wanted to know how to do it in Mathematica. –  Verbeia May 1 '12 at 3:03

I don't get an error with `Reduce`. For example, to find the local extrema of `xE` I tried

``````Reduce[xE'[t] == 0, t]
``````

which returned

``````C[1] \[Element] Integers && (t == 2 \[Pi] C[1] ||
t == 2 I ArcTanh[2/Sqrt[3]] + 2 \[Pi] C[1])
``````

Note that this gives you both real and complex solutions. If you only want the real ones you can try

``````Reduce[xE'[t] == 0, t, Reals]
``````

which gives

``````C[1] \[Element] Integers && t == 2 \[Pi] C[1]
``````

Edit

To substitute the solutions back into the original expression you could convert it to a list of rules using for example `ToRules`. Since `ToRules` can't handle expressions like `C[1] \[Element] Integers` we simplify the solution first

``````sol = Reduce[xE'[t] == 0, t];
sol = Simplify[sol, C[_] \[Element] Integers]

(* ==> t == 2 \[Pi] C[1] || t == 2 I ArcTanh[2/Sqrt[3]] + 2 \[Pi] C[1] *)
``````

`ToRules` will then convert this expression to a list of rules which you can substitute back into your expression using `ReplaceAll`

``````xE[t] /. {ToRules[sol]}

(* ==> {-Sqrt[1600 - 100 (1 - Cos[2 \[Pi] C[1]])^2] +
10 (2 \[Pi] C[1] - Sin[2 \[Pi] C[1]]),
-Sqrt[1600 - 100 (1 - Cosh[2 ArcTanh[2/Sqrt[3]] - 2 I \[Pi] C[1]])^2] +
10 (2 I ArcTanh[2/Sqrt[3]] + 2 \[Pi] C[1] -
I Sinh[2 ArcTanh[2/Sqrt[3]] - 2 I \[Pi] C[1]])} *)
``````

Note that the resulting expression still contains the constant `C[1]`. To find the extrema for a particular value of `C[1]` you can use another replacement rule, e.g.

``````({t, xE[t]} /. {ToRules[sol]}) /. {C[1] -> -4}
``````
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Danke Heike!! and then how to replace it to get the point with {t/.xE[t]} /. extremaXE ? –  ZelelB Apr 30 '12 at 10:26
@ZelelB I've expanded my answer a bit to answer your question. –  Heike May 1 '12 at 9:42