My problem concerns proving the existence of solutions to a set of linear PDEs on a semi-infinite strip. We have 2 variables, r which takes the range (h, infinity), h > 0, and xi which takes the range [-1, 1].

The issue is that I wish to solve the Cauchy problem near the boundary r = h, but on r = h the PDEs change type: here they are parabolic, and for r > h, they are elliptic. This is causing the problem that if I try to put the equations into canonical form, the variable that r is transformed to becomes singular on r = h.

What can be done here? The way it seems, if I use r = h for the Cauchy curve, and hence have a parabolic equation on the boundary, how can I define a solution arbitrarily near r = h if suddenly the type changes, for *any* r > h? Or am I thinking about it wrongly?

Thanks in advance for any pointers.

(EXTRA INFO: The equation in w(r, xi) is of the form

r^2*mu*(d^2 w/dr^2) + r^2*(d mu/dr)*(dw/dr) = f(xi)*(d^2 w/d xi^2)

with f(xi) >0 for all xi in (-1 ,1), and where mu(r) is a monotonically increasing one-to-one function such that mu(h) = 0 and where all d's are partial (except the one attached to mu). Transforming this to canonical form, we find we must use a variable like

alpha(r) = integral (from R = h to r) of [1/(R*sqrt(mu(R))) ] dR,

which clearly has problems with the lower limit - unless r = h in which case alpha(h) = 0, another thing which is slightly baffling me!)

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