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I need to find a method to transform an expression like

a^(1+m+n) b^(2+2m - 2n)

into

(a b^2)^m (a/b^2)^n (a b^2),

that is, to group terms with the same exponent. I tried using Collect[], etc, but can't get anything to work.

Any suggestions?

Thanks, Tom

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2  
Unfortunately, SO does not support LaTeX markup like some of the other stackexchange sites. So, I moved the equations to code blocks. –  rcollyer Aug 17 '11 at 18:13

2 Answers 2

up vote 10 down vote accepted

Using Log in combination with CoefficientRules:

exp = a^(1 + m + n) b^(2 + 2 m - 2 n);

Times @@ (Exp[#[[2]]]^(Times @@ ({n, m}^#[[1]])) & /@ 
   CoefficientRules[PowerExpand[Log[exp]], {n, m}])

output:

a (a/b^2)^n b^2 (a b^2)^m
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Thanks, a very nice answer! And I will learn something from understanding the code... –  Tom Dickens Aug 17 '11 at 18:56
1  
@Tom, doing this problem in reverse pays, i.e. try to rewrite it in postfix form and what each step does will become clearer. Watch out for the function Exp[#[[2]]]^(Times @@ ({n, m}^#[[1]])) & it's trickier than it looks. –  rcollyer Aug 23 '11 at 20:46

You can do this, for example:

log[x_*y_] := log[x] + log[y];
log[x_^y_] := y*log[x];
log1 /: a_*log1[b_] := log1[b^a];
log1 /: Plus[x__log1] := log1[Times @@ Map[First, {x}]];
exp[HoldPattern[Plus[x__]]] := Times @@ Map[exp, {x}];
exp[log1[x_]] := x

and then:

In[58]:= exp[Collect[Expand[log[a^(1+m+n) b^(2+2m-2n)]],{m,n}]]/.log->log1

Out[58]= a (a/b^2)^n b^2 (a b^2)^m
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Thank you very much! I had wondered about uisng logarithms, but didn't see how to do it. (I also have enjoyed reading your Mathematica programming book...) –  Tom Dickens Aug 17 '11 at 18:54
    
@Tom Dickens These are not true logarithms - these one cheat, since the first rule, for example, is not always correct. Mathematica does many auto-simplifications, a behavior which is problematic for the case at hand - these auxiliary functions prevent them from happening. –  Leonid Shifrin Aug 17 '11 at 18:57
    
@Tom Dickens Glad you liked the book. Responses like yours do reassure me that writing it was not such a bad idea. –  Leonid Shifrin Aug 17 '11 at 19:38
    
Good - it's very well done, and more insightful than most of the Mathematica teaching materials. I just need to find more time to work with it! –  Tom Dickens Aug 17 '11 at 20:25
    
Congratulations on 10K reputation, Leonid! It was my honor to put you over the mark. :-) –  Mr.Wizard Aug 20 '11 at 23:06

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