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It seems that Mathematica's handling of principal value integrals fails on some corner cases. Consider these two expressions (which should give the same result):

Integrate[UnitBox[x]/(x0 - x), {x, -Infinity, Infinity},
  PrincipalValue -> True, Assumptions -> {x0 > 0}] /. x0 -> 1 // Simplify
Integrate[UnitBox[x]/(x0 - x) /. x0 -> 1, {x, -Infinity, Infinity}, 
  PrincipalValue -> True]

In Mathematica 7.0.0 I get

I Pi+Log[3]

Has this been fixed in later versions? Does anybody have an idea for a (more or less) general workaround?

EDIT: The two expressions above should calculate the same result, the first by calculating a general form of the integral and evaluating it at x0=1, the second by performing the integral with x0 set to 1. Since the Cauchy principal value has a precise mathematical definition, Mathematica should give the same result or decline to answer.

EDIT 2: A perhaps simpler example of the same bug, putting a factor of -1 inside and outside the Integral give different answers (second one gives the correct answer, first one doesn't):

-Integrate[ UnitBox[x]/(x0 - x), {x, -Infinity, Infinity}, PrincipalValue -> True, Assumptions -> {x0 > 0}]
 Integrate[-UnitBox[x]/(x0 - x), {x, -Infinity, Infinity}, PrincipalValue -> True, Assumptions -> {x0 > 0}]
share|improve this question
As pointed out by brainfsck below, this is fixed in v8. – Janus Feb 23 '11 at 5:50
Janus, at we just got a migrated question from stackoverflow/mathematica. You was one of the answerers and we noticed that you haven't registered yet there. We'd appreciate if you, as one of the SO/MMA regulars, would register at as well. – Sjoerd C. de Vries Apr 24 '12 at 20:37
up vote 2 down vote accepted

I don't think this is a bug in PrincipalValue. In the first line PrincipalValue does not work "correctly" because the position of the pole is not known until after Integrate is done.

EDIT: I played around in Mathematica a bit and this is exactly what happens. You can see for yourself by using the Trace[] command. The output is a bit messy (which is why I don't replicate it here), but you can see where the integration gets done and where the value for x0 is substituted and how that messes with PrincipalValue.

EDIT2: So back to solving your actual problem. If you use an Assumption that specifies which side of x=1/2 x0 lies, then the two examples give the same answer.

share|improve this answer
From your answer, it appears that you consider PrincipalValue as sort of a methods guidance for the integration algorithm, whereas I think of it as requesting a mathematically well defined result, namely the Cauchy principal value of the integral. As this result has a strict mathematical definition, it constitutes a bug (from my point of view) if Mathematica arrives at two different answers when asked for the result in two different (but mathematically equivalent) ways. – Janus Jun 3 '10 at 3:18
Well it is not strictly me who thinks of PrincipalValue that way, I'm just telling you how Mathematica behaves ;-). The question may be mathematically equivalent, but that does not mean that it is computationally equivalent or possible. Look at the output of Trace for both cases and think about what happens if x0->I. See how it becomes very difficult to decide on the principal value of the integral before the substitution? – Timo Jun 3 '10 at 5:54
I would also point out that the two ways are not mathematically equivalent. As you point out, the first integral is evaluated with x0 as a free parameter. Now my math is slightly rusty, but that seems to disqualify the integral from being a definite integral and thus make it impossible to select the Cauchy principal value even in a purely mathematical sense. – Timo Jun 3 '10 at 12:04
I don't quite agree on the mathematical equivalence -- but instead of continuing that discussion (without MathML), I have added another example of the bug to the question. For the new example I hope that we can agree that Mathematica spits out different results to exactly the same question? As flipping the sign fixes the problem in all the situations I need it, I wont be examining this much more -- at the price Wolfram charges, they should certainly do their own bughunting! – Janus Jun 3 '10 at 15:24
OK, that's a bug! For an even better demonstration remove the Assumptions->{x0>0} part. – Timo Jun 4 '10 at 5:23

Seems to be fixed in 8.0:

In[1]:= $Version
Out[1]= "8.0 for Mac OS X x86 (32-bit) (November 13, 2010)"

Integrate[UnitBox[x]/(x0 - x), {x, -Infinity, Infinity}, 
   PrincipalValue -> True, Assumptions -> {x0 > 0}] /. 
  x0 -> 1 // Simplify

Out[2]= Log[3]

In[3]:= Integrate[
 UnitBox[x]/(x0 - x) /. x0 -> 1, {x, -Infinity, Infinity}, 
 PrincipalValue -> True]

Out[3]= Log[3]
share|improve this answer

Well Wolfram Alpha, which I would assume uses the latest version of Mathematica, doesn't like your first expression and gives this for the second: log(3)+constant[UnitBox[x]%2F%28x0+-+x%29+%2F.+x0+-%3E+1%2C+{x%2C+-Infinity%2C+Infinity}%2C++++PrincipalValue+-%3E+True]

It may be that this article applies in this case but I'm not a math expert so I wouldn't know? There are some situations, however, where several different answers are all equally consistent with the formal mathematical definitions. Thus, for example, in computing symbolic integrals, there are often several different expressions which all yield the same derivative. Which of these expressions is actually generated by Integrate can then depend on how Integrate works inside.

share|improve this answer
Thanks. It seems that Wolfram Alpha doesn't understand the Replace and Rule syntax from standard Mathematica, so I am not quite sure what question it is answering. – Janus Jun 3 '10 at 14:58

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