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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?

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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:

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

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Same initially happens with Roots:

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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

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+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
@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 (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 -> 
      InputForm[#1]]] & )]


{{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

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