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Mathematica 7.0 seems to dislike having blanks in the denominator. Can anyone explain why this is?

Input:

ClearAll["Global`*"];
(*Without blanks:*)
a^2 / b^2 /. a^2 / b^2 -> d
(*with:*)
a^2 / b^2 /. a^c_ / b^c_ -> d
(*Without blanks:*)
a^2 / b^2 /. (a / b)^2 -> d
(*With:*)
a^2 / b^2 /. (a / b)^c_ -> d
(*Without blanks:*)    
a^2 / b^2 /. a^2 * b^(-2) -> d
(*With:*)
a^2 / b^2 /. a^c_ * b^(-c_) -> d

Output:

d
a^2/b^2
d
a^2/b^2
d
a^2/b^2

I'm trying to work this for a more complicated problem. The substitution that I want to make is in an expression of the form:

(a ^ c_. * Coefficient1_. / b ^ c_. / Coefficient2_.)  +  (a ^ d_. * Coefficient3_. / b ^ d_. / Coefficient4_.)

Where the coefficients may involve sums, products, and quotients of variables that may or may not includea and b.

Possibly relevant:

The FullForm shows that the power in the denominator is stored as a product of -1 and c:

Input:

FullForm[a^2/b^2]
FullForm[a^c_/b^c_]
FullForm[ (a / b)^2 ]
FullForm[(a / b)^c_ ]
FullForm[a^2 * b^(-2) ]
FullForm[a^c_ * b^(-c_)]

Output:

Times[Power[a,2],Power[b,-2]]
Times[Power[a,Pattern[c,Blank[]]],Power[b,Times[-1,Pattern[c,Blank[]]]]]
Times[Power[a,2],Power[b,-2]]
Power[Times[a,Power[b,-1]],Pattern[c,Blank[]]]
Times[Power[a,2],Power[b,-2]]
Times[Power[a,Pattern[c,Blank[]]],Power[b,Times[-1,Pattern[c,Blank[]]]]]

Edit: Bolded change to my actual case.

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3 Answers 3

up vote 6 down vote accepted

I agree with everything Mr.Wizard wrote. Having said that, a replacement rule that would work in this specific case would be:

a^2/b^2 /. (Times[Power[a,c_],Power[b,e_]]/; e == -c )-> d

or

a^2/b^2 /.  (a^c_ b^e_/; e == -c )-> d

Note that I added the constraint /; e == -c so that I effectively have a -c_ without actually creating the corresponding Times[-1,c_] expression

share|improve this answer
    
Rather clever. Did you keep the explicit full function names for clarity? I think you should include the normal form as well. –  Mr.Wizard Aug 24 '11 at 13:07
    
Yeah, I used that to illustrate the structural equality of this expression to the ones at the bottom of the question. Added the compact form too. Thanks! –  Sjoerd C. de Vries Aug 24 '11 at 13:14
    
Heheh. I hope that +1 on my comment in @rcollyer's answer was from you :) –  BenB Aug 24 '11 at 23:54
    
@maberib Actually it wasn't me, otherwise I wouldn't have posted this. I missed your comment and I'll delete my answer after you've read this. –  Sjoerd C. de Vries Aug 25 '11 at 5:39
    
No need to delete it. Great minds ... –  BenB Aug 26 '11 at 18:23

The primary reason a^2 / b^2 /. a^c_ / b^c_ -> d doesn't work is your using Rule (->) not RuleDelayed (:>). The second reason, as you found with FullForm, is that a/b is interpreted as Times[a, Power[b,-1]], so it is best to not use division. Making these changes,

a^2 / b^2 /. a^n_ b^m_ :> {n,m}

returns {2, -2}. Usually, you'll want to have a default value, so that

a / b^2 /. a^n_. b^m_. :> {n,m}

returns {1,-2}.

Edit: to ensure that the two exponents are equal, requires the addition of the Condition (/;)

a^2 / b^2 /. a^n_. b^m_. /; n == m :> n

Note: by using _. this will also catch a/b.

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1  
Switching to DelayedRule has no effect on any of the examples I provided. a^2 / b^2 /. a^c_ b^e_ -> d Works, but the problem is that it doesn't ensure that the top and bottom are of the same power. Although I suppose that could be fixed with a condition: a^2 / b^2 /. a^c_ b^e_ /; c == -e -> d . Still feels like a bit of a bug to me. –  BenB Aug 24 '11 at 1:35
    
You're right, I didn't consider ensuring that they were the same power, and it makes it a pain. I'd probably go with the condition, myself. –  rcollyer Aug 24 '11 at 1:46
    
@rcollyer I think I saw a good answer or comment by Leonid about using patterns to match denominators. I can't find it right now. –  belisarius Aug 24 '11 at 2:04
    
@belisarius, looked for it, too, could not find it. –  rcollyer Aug 24 '11 at 2:25
1  
I vaguely remember some discussion on the topic, but could not find anything related in my answers or comments on SO. On general grounds, for expressions of any complexity, exact matching with blanks becomes very fragile - I can only add my voice to the answer of @Mr.Wizard. –  Leonid Shifrin Aug 24 '11 at 21:42

Generally speaking you should try to avoid doing mathematical manipulation using ReplaceAll which is a structural tool.

As opposed to FullForm, I will use TreeForm to illustrate these expressions:

a^2/b^2   // TreeForm
a^c_/b^c_ // TreeForm

enter image description here enter image description here

You can see that while these expressions are mathematically similar, they are structurally quite different. You may be able to hammer out a functioning replacement rule for a specific case, but you will usually be better off using the Formula Manipulation (or Polynomial Algebra) tools that Mathematica provides.

If you carefully describe the mathematical manipulation you wish to achieve, I will attempt to provide a better solution.


As belisarius humorously points out in a comment, trying to force Mathematica to "see" or display expressions the way you do is often largely futile. This is one of the reasons that the opening statement above is true.

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1  
+1, good point. Use patterns for manipulation if you absolutely must, primarily because there is no way to check them. You can make mathematically absurd changes with using Replace extremely easily. –  rcollyer Aug 24 '11 at 2:23
    
+1 But the OP should be warned that trying to force Mma to write formulas the way humans usually do is (sometimes) like trying to feed a statue. –  belisarius Aug 24 '11 at 2:28
1  
@belisarius I added a note; does that cover what you meant, or would you care to edit the answer and say something more? –  Mr.Wizard Aug 24 '11 at 2:35
    
@Mr. I think it is Ok now. Every Mma user has been there at least once and hopefully learned to let the System go by its own ways. –  belisarius Aug 24 '11 at 2:48
1  
@rcollyer surely there are times that structural tools are appropriate for mathematical expressions. However, from the OP's description of "a more complicated problem" I think that is unlikely in this case. I did not intend to declare this as a rigid rule, but rather I used phrases like "generally speaking" and "usually be better." –  Mr.Wizard Aug 24 '11 at 14:42

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