# Mathematica integral with many singularities

What's the best way of getting Mathematica 7 or 8 to do the integral

``````NIntegrate[Exp[-x]/Sin[Pi x], {x, 0, 50}]
``````

There are poles at every integer - and we want the Cauchy principle value. The idea is to get a good approximation for the integral from 0 to infinity.

With `Integrate` there is the option `PrincipleValue -> True`.

With `NIntegrate` I can give it the option `Exclusions -> (Sin[Pi x] == 0)`, or manually give it the poles by

``````NIntegrate[Exp[-x]/Sin[Pi x], Evaluate[{x, 0, Sequence@@Range[50], 50}]]
``````

The original command and the above two `NIntegrate` tricks give the result `60980 +/- 10`. But they all spit out errors. What is the best way of getting a quick reliable result for this integral without Mathematica wanting to give errors?

-
FYI if I try different WorkingPrecision values I get totally different results. – Mr.Wizard Apr 7 '11 at 5:25

Simon, is there reason to believe your integral is convergent ?

``````In[52]:= f[k_Integer, eps_Real] :=
NIntegrate[Exp[-x]/Sin[Pi x], {x, k + eps, k + 1 - eps}]

In[53]:= Sum[f[k, 1.0*10^-4], {k, 0, 50}]

Out[53]= 2.72613

In[54]:= Sum[f[k, 1.0*10^-5], {k, 0, 50}]

Out[54]= 3.45906

In[55]:= Sum[f[k, 1.0*10^-6], {k, 0, 50}]

Out[55]= 4.19199
``````

It looks like the problem is at x==0. Splitting integrand k+eps to k+1-eps for integer values of k:

``````In[65]:= int =
Sum[(-1)^k Exp[-k ], {k, 0, Infinity}] Integrate[
Exp[-x]/Sin[Pi x], {x, eps, 1 - eps}, Assumptions -> 0 < eps < 1/2]

Out[65]= (1/((1 +
E) (I + \[Pi])))E (2 E^(-1 + eps - I eps \[Pi])
Hypergeometric2F1[1, (I + \[Pi])/(2 \[Pi]), 3/2 + I/(2 \[Pi]),
E^(-2 I eps \[Pi])] +
2 E^(I eps (I + \[Pi]))
Hypergeometric2F1[1, (I + \[Pi])/(2 \[Pi]), 3/2 + I/(2 \[Pi]),
E^(2 I eps \[Pi])])

In[73]:= N[int /. eps -> 10^-6, 20]

Out[73]= 4.1919897038160855098 + 0.*10^-20 I

In[74]:= N[int /. eps -> 10^-4, 20]

Out[74]= 2.7261330651934049862 + 0.*10^-20 I

In[75]:= N[int /. eps -> 10^-5, 20]

Out[75]= 3.4590554287709991277 + 0.*10^-20 I
``````

As you see there is a logarithmic singularity.

``````In[79]:= ser =
Assuming[0 < eps < 1/32, FullSimplify[Series[int, {eps, 0, 1}]]]

Out[79]= SeriesData[eps, 0, {(I*(-1 + E)*Pi -
2*(1 + E)*HarmonicNumber[-(-I + Pi)/(2*Pi)] +
Log[1/(4*eps^2*Pi^2)] - 2*E*Log[2*eps*Pi])/(2*(1 + E)*Pi),
(-1 + E)/((1 + E)*Pi)}, 0, 2, 1]

In[80]:= Normal[
ser] /. {{eps -> 1.*^-6}, {eps -> 0.00001}, {eps -> 0.0001}}

Out[80]= {4.191989703816426 - 7.603403526913691*^-17*I,
3.459055428805136 -
7.603403526913691*^-17*I,
2.726133068607085 - 7.603403526913691*^-17*I}
``````

EDIT Out[79] of the code above gives the series expansion for eps->0, and if these two logarithmic terms get combined, we get

``````In[7]:= ser = SeriesData[eps, 0,
{(I*(-1 + E)*Pi - 2*(1 + E)*HarmonicNumber[-(-I + Pi)/(2*Pi)] +
Log[1/(4*eps^2*Pi^2)] - 2*E*Log[2*eps*Pi])/(2*(1 + E)*
Pi),
(-1 + E)/((1 + E)*Pi)}, 0, 2, 1];

In[8]:= Collect[Normal[PowerExpand //@ (ser + O[eps])],
Log[eps], FullSimplify]

Out[8]= -(Log[eps]/\[Pi]) + (
I (-1 + E) \[Pi] -
2 (1 + E) (HarmonicNumber[-((-I + \[Pi])/(2 \[Pi]))] +
Log[2 \[Pi]]))/(2 (1 + E) \[Pi])
``````

Clearly the -Log[eps]/Pi came from the pole at x==0. So if one subtracts this, just like principle value method does this for other poles you end up with a finitely value:

``````In[9]:= % /. Log[eps] -> 0

Out[9]= (I (-1 + E) \[Pi] -
2 (1 + E) (HarmonicNumber[-((-I + \[Pi])/(2 \[Pi]))] +
Log[2 \[Pi]]))/(2 (1 + E) \[Pi])

In[10]:= N[%, 20]

Out[10]= -0.20562403655659928968 + 0.*10^-21 I
``````

Of course, this result is difficult to verify numerically, but you might know more that I do about your problem.

EDIT 2

This edit is to justify In[65] input that computes the original regularized integral. We are computing

``````Sum[ Integrate[ Exp[-x]/Sin[Pi*x], {x, k+eps, k+1-eps}], {k, 0, Infinity}] ==
Sum[ Integrate[ Exp[-x-k]/Sin[Pi*(k+x)], {x, eps, 1-eps}], {k, 0, Infinity}] ==
Sum[ (-1)^k*Exp[-k]*Integrate[ Exp[-x]/Sin[Pi*x], {x, eps, 1-eps}],
{k, 0, Infinity}] ==
Sum[ (-1)^k*Exp[-k], {k, 0, Infinity}] *
Integrate[ Exp[-x]/Sin[Pi*x], {x, eps, 1-eps}]
``````

In the third line Sin[Pi*(k+x)] == (-1)^k*Sin[Pi*x] for integer k was used.

-
Hi Sasha, thanks for all of your work on this problem. I actually got this problem from a Mathematician who said that he uses Mma4 because it has a package that gives better support than the later built-in support for PrincipleValue numerical integrals. He gave me this example, and now that you've made me think more about it, I agree... it's not a good one! The problem at lim x->+0 is because there isn't the corresponding lim x->-0 to cancel the pole. – Simon Apr 9 '11 at 0:57
I have a question about your `In[65]` where you define `int`. The `Sum` appears to be unrelated to everything else... I think this leads to problems in the rest of your analysis - but not your conclusions! – Simon Apr 9 '11 at 1:00
@Simon In[65] is easily justifiable by splitting integral 0..inf into 0+ .. 1- and 1+..2- and so on. Then it becomes a sum over k of integrals of Exp[-k-x]/Sin[Pi*(k+x)] for x from eps to 1-eps. But Sin[Pi*(k+x)] == (-1)^kSin[Pix] and the integrand becomes (-1)^kExp[-k]*Exp[-x]/Sin[Pix]. Thus the sum and integral can now be carried out independently as in In[65]. I your question makes it worth putting in an edit explaining this step. – Sasha Apr 9 '11 at 14:06

Simon, I haven't spent much time with your integral, but you should try looking at stationary phase approximation. What you have is a smooth function (exp), and a highly oscillatory function (sine). The work involved is now in brow-beating the `1/sin(x)` into the form `exp(if(x))`

Alternatively, you could use the series expansion of the `cosecant` (not valid at poles):

``````In[1]:=Series[Csc[x], {x, 0, 5}]
(formatted) Out[1]=1/x + x/6 + 7/360 x^3 + 31/15120 x^5 +O[x]^6
``````

Note that for all `m>-1`, you have the following:

``````In[2]:=Integrate[x^m Exp[-x], {x, 0, Infinity}, Assumptions -> m > -1]
Out[2]=Gamma[1+m]
``````

However, summing the series with the coefficients of cosecant (from wikipedia), not including `1/x Exp[-x]` case, which doesn't converge on `[0,Infinity]`.

``````c[m_] := (-1)^(m + 1) 2 (2^(2 m - 1) - 1) BernoulliB[2 m]/Factorial[2 m];
Sum[c[m] Gamma[1 + 2 m - 1], {m, 1, Infinity}]
``````

does not converge either...

So, I'm not sure that you can work out an approximation for the integral to infinity, but I if you're satisfied with a solution upto some large N, I hope these help.

-
Thanks R.M. The integral was a bad example given to me by someone whose math ability I trusted.... There's a pole at zero where we only take a one-sided limit. This means we can't get a PrincipleValue for this pole... – Simon Apr 9 '11 at 1:02

I have to agree with Sasha, the integral does not appear to be convergent. However, if you exclude `x == 0` and break the integral into pieces

``````Integrate[Exp[-x]/Sin[Pi x], {x, n + 1/2, n + 3/2}, PrincipalValue -> True]
``````

where `n >= 0 && Element[n, Integers]`, then it seems you may get an alternating series

``````I Sum[ (-1/E)^n, {n, 1, Infinity}] == - I / (1 + E )
``````

Now, I only took it out to `n == 4`, but it looks reasonable. However, for the integral above with `Assumptions -> Element[n, Integers] && n >= 0` Mathematica gives

``````If[ 2 n >= 1, - I / E, Integrate[ ... ] ]
``````

which just doesn't conform to the individual cases. As an additional note, if the pole lies at the boundary of the integration region, i.e. your limits are `{x, n, n + 1}`, you only get `DirectedInfinity`s. A quick look at the plot implies that you with the limits `{x, n, n + 1}` you only have a strictly positive or negative integrand, so the infinite value may be due to the lack of compensation which `{x, n + 1/2, n + 3/2}` gives you. Checking with `{x, n, n + 2}`, however it only spits out the unevaluated integral.

-
I don't get an alternating series... rather one with all positive terms (see my answer above). The integral expands out to be a sum of `Gamma` functions (which is not convergent) plus an integral of `Exp[-x]/x` term, which is also not convergent due to the singularity at the origin. – abcd Apr 7 '11 at 16:36
@R. M., actually we're using different integration regions. I exclude the `x == 0` part by starting at `x == 1/2` and integrating over intervals 1 unit wide; the sum of which looks like an alternating series, which is convergent. – rcollyer Apr 7 '11 at 17:37
ah, I stand corrected. – abcd Apr 7 '11 at 17:56
Thanks rcollyer. You're right, the x=0 point is a one sided limit that can't be balanced by the other side. And that `Integrate[Exp[-x]/Sin[Pi x], {x, n + 1/2, n + 3/2}, PrincipalValue -> True, Assumptions -> n \[Element] Integers]` gives a complex constant times `(-1/E)^n`. But this doesn't match `NIntegrate[Exp[-x]/Sin[Pi x], {x, n + 1/2, n, n + 3/2}, WorkingPrecision -> 100, MaxRecursion -> 40]` which gives an answer highly dependent on the `WorkingPrecision`. All in all, it was a bad question/example. – Simon Apr 9 '11 at 1:11