Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(Darren Dugan) #1

APPLICATIONS OF COMPLEX VARIABLES


(a) (b)

(c) (d)

v v

v

Figure 25.14 Amplitude–phase diagrams for stationary phase integration. (a)
Using a straight-through path on which the phase is a minimum. (b) Using
a straight-through path on which the phase is a maximum. (c) Using a level
line that turns through +π/2 at the saddle point but starts and finishes in
different valleys. (d) Using a level line that turns through a right angle but
finishes in the same valley as it started. In cases (a), (b) and (c) the integral
value is represented byv(see text). In case (d) the integral has value zero.

We do not have the space to consider cases with two or more saddle points,

but even more care is needed with the stationary phase approach than when


using the steepest-descents method. At a saddle point there is only one l.s.d. but


there are two level lines. If more than one saddle point is required to reach the


appropriate end-point of an integration, or an intermediate zero-level valley has


to be used, then care is needed in linking the corresponding level lines in such a


way that the links do not make a significant, but unknown, contribution to the


integral. Yet more complications can arise if a level line through one saddle point


crosses a line of steepest ascent through a second saddle.


We conclude this section with a worked example that has direct links to the

two preceding sections of this chapter.

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