Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

25.8 Approximations to integrals


Finally, we should mention that the lines in thez-plane on which the expo-

nents in the WKB solutions are purely imaginary, and the two solutions have


equal amplitudes, are usually called theanti-Stokes lines. For the general Bessel’s


equation they are the real positive and real negative axes.


25.8 Approximations to integrals

In this section we will investigate a method of finding approximations to the


values or forms of certain types of infinite integrals. The class of integrals to


be considered is that containing integrands that are, or can be, represented by


exponential functions of the general formg(z) exp[f(z) ]. The exponentsf(z)may


be complex, and so integrals of sinusoids can be handled as well as those with


more obvious exponential properties. We will be using the analyticity properties


of the functions of a complex variable to move the integration path to a part


of the complex plane where a general integrand can be approximated well by a


standard form; the standard form is then integrated explicitly.


The particular standard form to be employed is that of a Gausssian function of

a real variable, for which the integral between infinite limits is well known. This


form will be generated by expressingf(z) as a Taylor series expansion about a


pointz 0 , at which the linear term in the expansion vanishes, i.e. wheref′(z)=0.


Then, apart from a constant multiplier, the exponential function will behave like


exp[^12 f′′(z 0 )(z−z 0 )^2 ] and, by choosing an appropriate direction for the contour


to take as it passes through the point, this can be made into a normal Gaussian


function of a real variable and its integral may then be found.


25.8.1 Level lines and saddle points

Before we can discuss the method outlined above in more detail, a number of


observations about functions of a complex variable and, in particular, about the


properties of the exponential function need to be made. For a general analytic


function,


f(z)=φ(x, y)+iψ(x, y), (25.58)

of the complex variablez=x+iy, we recall that, not only do bothφandψ


satisfy Laplace’s equation, but∇φand∇ψare orthogonal. This means that the


lines on which one ofφandψis constant are exactly the lines on which the other


is changing most rapidly.


Let us apply these observations to the function

h(z)≡exp[f(z) ] = exp(φ) exp(iψ), (25.59)

recalling that the functionsφandψare themselves real. The magnitude ofh(z),


given by exp(φ), is constant on the lines of constantφ, which are known as the

Free download pdf