Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

25.8 APPROXIMATIONS TO INTEGRALS


are self-cancelling, as discussed previously. However, the ends of the contourmust


be in regions where the integrand is vanishingly small, and so at each end of


the level line we need to add a further section of path that makes the contour


terminate correctly.


Fortunately, this can be done without adding to the value of the integral. This

is because, as noted in the second paragraph following equation (25.67), far from


the saddle the level line will be at a finite height up a ‘precipitous cliff’ that


separates the region where the integrand grows without limit from the one where


it tends to zero. To move down the cliff-face into the zero-level valley requires


an ever smaller step the further we move away from the saddle; as the integrand


is finite, the contribution to the integral is vanishingly small. In figure 25.12, this


additional piece of path length might, for example, correspond to the infinitesimal


move from a point on the large positivex-axis (whereh(z) has value 1) to a point


just above it (whereh(z)≈0).


Now that formula (25.73) has been justified, we may note that it is exactly

the same as that for the method of steepest descents, equation (25.66). A similar


calculation using the level line on which the phase is a maximum also reproduces


the steepest-descents formula. It would appear that ‘all roads lead to Rome’.


However, as we explain later, some roads are more difficult than others. Where


a problem involves using more than one saddle point, if the steepest-descents


approach is tractable, it will usually be the more straight forward to apply.


Typical amplitude-phase diagrams for an integration along a level line that

goes straight through the saddle are shown in parts (a) and (b) of figure 25.14.


The value of the integral is given, in both magnitude and phase, by the vector


vjoining the initial to the final winding points and, of course, is the same in


both cases. Part (a) corresponds to the case of the phase being a minimum at the


saddle; the vector path crossesvat an angle of−π/4. When a path on which the


phase at the saddle is a maximum is used, the Cornu spiral is as in part (b) of


the figure; then the vector path crossesvat an angle of +π/4. As can be seen,


the two spirals are mirror images of each other.


Clearly a straight-through level line path will start and end in different zero-

level valleys. For one that turns through a right angle at the saddle point, the


end-point could be in a different valley (for a function such as exp(−z^2 ), there is


only one other) or in the same one. In the latter case the integral will give a zero


value, unless a singularity ofh(z) happens to have been enclosed by the contour.


Parts (c) and (d) of figure 25.14 illustrate the phase–amplitude diagrams for these


two cases. In (c) the path turns through a right angle (+π/2, as it happens) at the


saddle point, but finishes up in a different valley from that in which it started. In


(d) it also turns through a right angle but returns to the same valley, albeit close


to the other precipice from that near its starting point. This makes no difference


and the result is zero, the two half spirals in the diagram producing resultants


that cancel.

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