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The complex error function w(z) is defined as e^(-x^2) erfc(-ix). The problem with using w(z) as defined above is that the erfc tends to explode out for larger x (complemented by the exponential going to 0 so everything stays small), so that Mathematica reverts to arbitrary precision calculations that make life VERY slow. The function is used in implementing the voigt profile - a line shape commonly used in spectroscopy and other related areas. Right now I'm reverting to calculating the lineshape once and using an interpolation to speed things up, however this doesn't let me alter the parameters of the lineshape (or fit to them) easily.

scipy has a nice and fast implementation of w(z) as scipy.special.wofz, and I was wondering if there is an equivalent in Mathematica.

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Shouldn't it be the other way around in that the error function blows up and the exponential decays for x large (and real)? –  Heike Jul 24 '11 at 8:52
I tried playing with SetSystemOptions["CatchMachineUnderflow"->False], which, however, results in getting 0. +0. I for large arguments. Then I tried defining the function as Exp[Log[-z^2+Log@Erfc[-I*z]]], but this turns out to not be any faster than with automatic switching. So, it seems hard to speed this up, except as @Daniel Lichtblau suggests –  acl Jul 24 '11 at 23:46
@Heike you are right, a bit of a slip on my part. –  crasic Jul 25 '11 at 1:11

4 Answers 4

The complex error function can be written in terms of the Hermite "polynomial" H_{-1}(x):

In[1]:= FullSimplify[2 HermiteH[-1,I x] == Sqrt[Pi] Exp[-x^2] Erfc[I x]]
Out[1]= True

And the evaluation does not suffer as many underflows and overflows

In[68]:= 2 HermiteH[-1, I x] /. x -> 100000.
Out[68]= 6.12323*10^-22 - 0.00001 I

In[69]:= Sqrt[Pi] E^-x^2 Erfc[I x] /. x -> 100000.
During evaluation of In[69]:= General::unfl: Underflow occurred in computation. >>
During evaluation of In[69]:= General::ovfl: Overflow occurred in computation. >>
Out[69]= Indeterminate

That said, some quick tests show that the evaluation speed of the Hermite function to be slower than that of the product of the exponential and error function...

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A series expansion at infinity shows that the real and imaginary parts are of very different scales. I'd suggest computing them separately and not adding them. Below I use the first few terms of the series expansion to get the imaginary part.

w[x_?NumericQ] := {N[Exp[-SetPrecision[x, 25]^2], 20], 
  N[(3 /(4 Sqrt[\[Pi]] x^5) + 1/(2 Sqrt[\[Pi]] x^3) + 1/(
     Sqrt[\[Pi]] x))]}

In[187]:= w[11]

Out[187]= {2.8207700884601354011*10^-53, 0.05150453151309212}

In[188]:= w[1000]

Out[188]= {3.296831478088558579*10^-434295, 0.0005641898656429712}

Not sure how badly you want that very small real part. If you can drop it that will keep the numbers in a reasonable range. In some ranges (or if higher than machine precision is desired) you may want to use more terms from the expansion on that imaginary part.

Daniel Lichtblau Wolfram Research

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Because the real part is effectively zero far enough out (and the voigt profile is defined as the real part of w(z)) it would suffice for me to just set the whole thing to 0 far enough out (say before mathematica switches to arbitrary precision - but I'm not very well versed with the mechanism) since in the end I'm doing a numerical fit, and 10^-53 is well below the machine sigma for floating point. –  crasic Jul 25 '11 at 1:15

The real and imaginary parts of the complex error function on the real line can be explicitly and efficiently computed in Mathematica using Dawson integral:

In[9]:= Sqrt[Pi] Exp[-x^2] Erfc[I x] == 
  E^-x^2 Sqrt[\[Pi]] - 2 I DawsonF[x] // FullSimplify

Out[9]= True

This is about 4 times faster than using HermiteH[-1,z].

In[10]:= w1[x_] := E^-x^2 Sqrt[\[Pi]] - 2 I DawsonF[x]
w2[x_] := 2 HermiteH[-1, I x]

In[15]:= AbsoluteTiming[w1 /@ Range[-5.0, 5.0, 0.001];]

Out[15]= {2.3272327, Null}

In[16]:= AbsoluteTiming[w2 /@ Range[-5.0, 5.0, 0.001];]

Out[16]= {10.2400239, Null}
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I was running some old code (from 2007) the other day and the manual erf simplification/replacement rules were broken because of those DawsonF functions. They're new in version 7. Do you know where they arise and why they were added to Mma? –  Simon Jul 26 '11 at 12:54
@Simon if "where they arise" refers to applications, I have met them in doing path integral monte carlo (or generally working with imaginary time actions). I would imagine the main attraction is that there exist approximations for these functions for which the series converge very rapidly indeed (then again I only know this from numerical recipes, and have never used these functions in anger myself) –  acl Jul 26 '11 at 14:39
@Simon Given that Dawson was active in plasma research, I expect the integral to arise in plasma physics, although I have not seen the use myself. –  Sasha Jul 26 '11 at 19:05
@acl, Sasha: Thanks guys! –  Simon Jul 27 '11 at 0:38

Just wrap the C library libcerf.

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This is not really a Mathematica answer unless you show how to call that library from Mathematica (in a simpler way than the scipy one the OP mentions). Also, it would have been in order to at least disclose your affiliation. –  Szabolcs May 15 '13 at 23:30
Calling C from Mathematica is standard, reference.wolfram.com/mathematica/guide/CLanguageInterface.html. And yes, it's me who published libcerf, sorry and thanks for informing me about the disclosure rule. –  Joachim Wuttke May 16 '13 at 6:14

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