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 was playing with the (beautiful) polynomial x^4 - 10x^2 + 1. Look what happens:

 In[46]:= f[x_] := x^4 - 10x^2 + 1
          a = Sqrt[2];
          b = Sqrt[3];
          Simplify[f[ a + b]]
          Simplify[f[ a - b]]
          Simplify[f[-a + b]]
          Simplify[f[-a - b]]
 Out[49]= 0
 Out[50]= 0
 Out[51]= 0
 Out[52]= 0

 In[53]:= Solve[f[x] == 0, x]
 Out[53]= {{x->-Sqrt[5-2 Sqrt[6]]},{x->Sqrt[5-2 Sqrt[6]]},{x->-Sqrt[5+2 Sqrt[6]]},{x->Sqrt[5+2 Sqrt[6]]}}
 In[54]:= Simplify[Solve[f[x] == 0, x]]
 Out[54]= {{x->-Sqrt[5-2 Sqrt[6]]},{x->Sqrt[5-2 Sqrt[6]]},{x->-Sqrt[5+2 Sqrt[6]]},{x->Sqrt[5+2 Sqrt[6]]}}
 In[55]:= FullSimplify[Solve[f[x] == 0, x]]
 Out[55]= {{x->Sqrt[2]-Sqrt[3]},{x->Sqrt[5-2 Sqrt[6]]},{x->-Sqrt[5+2 Sqrt[6]]},{x->Sqrt[2]+Sqrt[3]}}

Sqrt[5-2 Sqrt[6]] is equal to Sqrt[3]-Sqrt[2].
However, Mathematica's FullSimplify does not simplify Sqrt[5-2 Sqrt[6]].

Question: Should I use other more specialized functions to algebraically solve the equation? If so, which one?

share|improve this question
5  
LeafCount@Sqrt[5 - 2 Sqrt[6]] gives 13, and LeafCount[Sqrt[3] - Sqrt[2]] gives also 13. Try to use the ComplexityFunction for Simplify to customize what is considered simpler for you. I think Mathematica uses LeafCount by default. –  Nasser Dec 19 '11 at 21:47
    
@NasserM.Abbasi From the GuideBook for Symbolics: "The meaning of Automatic in the ComplexityFunction option setting is basically to minimize the LeafCount. Some exceptions are made for numbers." For example, Simplify[Exp[Log[12] + 13 (Sqrt[2] + 1)^2 Log[6] - 2*13 Sqrt[2] Log[6]]] isn't an Integer, although Integers have LeafCount 1. –  Andrew MacFie Dec 20 '11 at 15:51
    
No need to include the answer in the question ;-) –  David Z Dec 20 '11 at 22:44

2 Answers 2

up vote 9 down vote accepted

Indeed, Solve doesn't simplify all roots to the max:

enter image description here

A FullSimplify postprocessing step simplifies two roots and leaves two others untouched:

enter image description here

Same initially happens with Roots:

enter image description here

Strange enough, now FullSimplify simplifies all roots:

enter image description here

The reason for this is, I assume, that for the default ComplexityFunction some of the solutions written above in nested radicals are in a sense simpler than the others.

BTW FunctionExpand knows how to deal with those radicals:

enter image description here

enter image description here

share|improve this answer
    
+1 for FunctionExpand - I wouldn't have thought to use it on Sqrt or Power functions of integers... –  Simon Dec 19 '11 at 22:37
1  
@Sjoerd Thanks, very educating. Mathematica is almost like mathematics itself. Once you think you have mastered it, new mountains to climb appear at the horizon. –  ndroock1 Dec 20 '11 at 7:39
    
@Sjoerd In v.7 FullSimplify[Solve[x^4 - 10 x^2 + 1 == 0, x]] yields {{x -> Sqrt[2] - Sqrt[3]}, {x -> -Sqrt[2] + Sqrt[3]}, {x -> -Sqrt[ 5 + 2 Sqrt[6]]}, {x -> Sqrt[2] + Sqrt[3]}} while in v.8 two radicals remain not FullSimplified. Strange enough. Congratulations for Mathematica golden badge ! –  Artes Dec 20 '11 at 12:09
1  
+1 (voted already some time ago), and congrats with the Mathematica Gold badge! –  Leonid Shifrin Dec 20 '11 at 20:53
    
@Leonid Thanks! Yoda told me before I was aware of it. I think I should quit now. All goals in life achieved... ;-) –  Sjoerd C. de Vries Dec 20 '11 at 21:43
FullSimplify[ Solve[x^4-10x^2+1==0,x]
, 
  ComplexityFunction -> 
   (StringLength[ToString[
      InputForm[#1]]] & )]

gives

{{x -> Sqrt[2] - Sqrt[3]}, {x -> -Sqrt[2] + Sqrt[3]}, {x -> -Sqrt[2] -
 Sqrt[3]}, {x -> Sqrt[2] + Sqrt[3]}}
share|improve this answer
    
Nice it obviously works but i don't buy that you should add ComplexityFunction -> (StringLength[ToString[ InputForm[#1]]] & )] every time you want a correct answer. –  ndroock1 Dec 20 '11 at 7:41

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.