Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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?

share|improve this question
    
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

2 Answers 2

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}
share|improve this answer
    
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

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?

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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.