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In mathematics, the Dawson function or Dawson integral (named after
H. G. Dawson Henry Gordon Dawson (2 August 1862 in Omagh, County Tyrone22 February 1918 in Hastings, East Sussex) was an Irish mathematician. The Dawson function is named after him. Education and career Dawson was educated at Trinity College Dublin (BA 18 ...
) is the one-sided Fourier–Laplace
sine transform In mathematics, the Fourier sine and cosine transforms are forms of the Fourier transform that do not use complex numbers or require negative frequency. They are the forms originally used by Joseph Fourier and are still preferred in some applicatio ...
of the Gaussian function.


Definition

The Dawson function is defined as either: D_+(x) = e^ \int_0^x e^\,dt, also denoted as F(x) or D(x), or alternatively D_-(x) = e^ \int_0^x e^\,dt.\! The Dawson function is the one-sided Fourier–Laplace
sine transform In mathematics, the Fourier sine and cosine transforms are forms of the Fourier transform that do not use complex numbers or require negative frequency. They are the forms originally used by Joseph Fourier and are still preferred in some applicatio ...
of the
Gaussian function In mathematics, a Gaussian function, often simply referred to as a Gaussian, is a function of the base form f(x) = \exp (-x^2) and with parametric extension f(x) = a \exp\left( -\frac \right) for arbitrary real constants , and non-zero . It i ...
, >D_+(x) = \frac12 \int_0^\infty e^\,\sin(xt)\,dt. It is closely related to the
error function In mathematics, the error function (also called the Gauss error function), often denoted by , is a complex function of a complex variable defined as: :\operatorname z = \frac\int_0^z e^\,\mathrm dt. This integral is a special (non- elementa ...
erf, as : D_+(x) = e^ \operatorname (x) = - e^ \operatorname (ix) where erfi is the imaginary error function, Similarly, D_-(x) = \frac e^ \operatorname(x) in terms of the real error function, erf. In terms of either erfi or the
Faddeeva function The Faddeeva function or Kramp function is a scaled complex complementary error function, :w(z):=e^\operatorname(-iz) = \operatorname(-iz) =e^\left(1+\frac\int_0^z e^\textt\right). It is related to the Fresnel integral, to Dawson's integral, and ...
w(z), the Dawson function can be extended to the entire
complex plane In mathematics, the complex plane is the plane formed by the complex numbers, with a Cartesian coordinate system such that the -axis, called the real axis, is formed by the real numbers, and the -axis, called the imaginary axis, is formed by th ...
:Mofreh R. Zaghloul and Ahmed N. Ali,
Algorithm 916: Computing the Faddeyeva and Voigt Functions
" ''ACM Trans. Math. Soft.'' 38 (2), 15 (2011). Preprint available a
arXiv:1106.0151
 F(z) = e^ \operatorname (z) = \frac \left e^ - w(z) \right which simplifies to D_+(x) = F(x) = \frac \operatorname
(x) An emoticon (, , rarely , ), short for "emotion icon", also known simply as an emote, is a pictorial representation of a facial expression using characters—usually punctuation marks, numbers, and letters—to express a person's feelings, ...
/math> D_-(x) = i F(-ix) = -\frac \left e^ - w(-ix) \right/math> for real x. For , x, near zero, For , x, large, More specifically, near the origin it has the series expansion F(x) = \sum_^\infty \frac \, x^ = x - \frac x^3 + \frac x^5 - \cdots, while for large x it has the asymptotic expansion F(x) = \frac + \frac + \frac + \cdots. More precisely \left, F(x) - \sum_^ \frac\ \leq \frac. where n!! is the
double factorial In mathematics, the double factorial or semifactorial of a number , denoted by , is the product of all the integers from 1 up to that have the same parity (odd or even) as . That is, :n!! = \prod_^ (n-2k) = n (n-2) (n-4) \cdots. For even , the ...
. F(x) satisfies the differential equation \frac + 2xF = 1\,\! with the initial condition F(0) = 0. Consequently, it has extrema for F(x) = \frac, resulting in ''x'' = ±0.92413887... (), ''F''(''x'') = ±0.54104422... (). Inflection points follow for F(x) = \frac, resulting in ''x'' = ±1.50197526... (), ''F''(''x'') = ±0.42768661... (). (Apart from the trivial inflection point at x = 0, F(x) = 0.)


Relation to Hilbert transform of Gaussian

The
Hilbert transform In mathematics and in signal processing, the Hilbert transform is a specific linear operator that takes a function, of a real variable and produces another function of a real variable . This linear operator is given by convolution with the func ...
of the Gaussian is defined as H(y) = \pi^ \operatorname \int_^\infty \frac \, dx P.V. denotes the
Cauchy principal value In mathematics, the Cauchy principal value, named after Augustin Louis Cauchy, is a method for assigning values to certain improper integrals which would otherwise be undefined. Formulation Depending on the type of singularity in the integrand ...
, and we restrict ourselves to real y. H(y) can be related to the Dawson function as follows. Inside a principal value integral, we can treat 1/u as a
generalized function In mathematics, generalized functions are objects extending the notion of functions. There is more than one recognized theory, for example the theory of distributions. Generalized functions are especially useful in making discontinuous functio ...
or distribution, and use the Fourier representation = \int_0^\infty dk \, \sin ku = \int_0^\infty dk \, \operatorname e^. With 1/u = 1/(y-x), we use the exponential representation of \sin(ku) and complete the square with respect to x to find \pi H(y) = \operatorname \int_0^\infty dk \,\exp k^2/4+iky\int_^\infty dx \, \exp (x+ik/2)^2 We can shift the integral over x to the real axis, and it gives \pi^. Thus \pi^ H(y) = \operatorname \int_0^\infty dk \, \exp k^2/4+iky We complete the square with respect to k and obtain \pi^H(y) = e^ \operatorname \int_0^\infty dk \, \exp (k/2-iy)^2 We change variables to u = ik/2+y: \pi^H(y) = -2e^ \operatorname i \int_y^ du\ e^. The integral can be performed as a contour integral around a rectangle in the complex plane. Taking the imaginary part of the result gives H(y) = 2\pi^ F(y) where F(y) is the Dawson function as defined above. The Hilbert transform of x^e^ is also related to the Dawson function. We see this with the technique of differentiating inside the integral sign. Let H_n = \pi^ \operatorname \int_^\infty \frac \, dx. Introduce H_a = \pi^ \operatorname \int_^\infty \, dx. The nth derivative is = (-1)^n\pi^ \operatorname \int_^\infty \frac \, dx. We thus find \left . H_n = (-1)^n \frac \_. The derivatives are performed first, then the result evaluated at a = 1. A change of variable also gives H_a = 2\pi^F(y\sqrt a). Since F'(y) = 1-2yF(y), we can write H_n = P_1(y)+P_2(y)F(y) where P_1 and P_2 are polynomials. For example, H_1 = -\pi^y + 2\pi^y^2F(y). Alternatively, H_n can be calculated using the recurrence relation (for n \geq 0) H_(y) = y^2 H_n(y) - \frac y.


See also

*


References

{{reflist


External links


gsl_sf_dawson
in the
GNU Scientific Library The GNU Scientific Library (or GSL) is a software library for numerical computations in applied mathematics and science. The GSL is written in C; wrappers are available for other programming languages. The GSL is part of the GNU Project and is d ...

libcerf
numeric C library for complex error functions, provides a function ''voigt(x, sigma, gamma)'' with approximately 13–14 digits precision. It is based on the
Faddeeva function The Faddeeva function or Kramp function is a scaled complex complementary error function, :w(z):=e^\operatorname(-iz) = \operatorname(-iz) =e^\left(1+\frac\int_0^z e^\textt\right). It is related to the Fresnel integral, to Dawson's integral, and ...
as implemented in th
MIT Faddeeva Package


''(at Mathworld)''
Error functions
Gaussian function Special functions