Mathematical Methods for Physics and Engineering : A Comprehensive Guide

(lu) #1

PDES: GENERAL AND PARTICULAR SOLUTIONS


C


y

x

dx

dy

nˆds

dr

Figure 20.4 A boundary curveCand its tangent and unit normal at a given
point.

For second-order equations we might expect that relevant boundary conditions

would involve specifyingu, or some of its first derivatives, or both, along a


suitable set of boundaries bordering or enclosing the region over which a solution


is sought. Three common types of boundary condition occur and are associated


with the names of Dirichlet, Neumann and Cauchy. They are as follows.


(i)Dirichlet: The value ofuis specified at each point of the boundary.
(ii)Neumann: The value of∂u/∂n,thenormal derivativeofu,isspecifiedat
each point of the boundary. Note that∂u/∂n=∇u·ˆn,wherenˆis the
normal to the boundary at each point.
(iii)Cauchy:Bothuand∂u/∂nare specified at each point of the boundary.

Let us consider for the moment the solution of (20.43) subject to the Cauchy

boundary conditions, i.e.uand∂u/∂nare specified along some boundary curve


Cin thexy-plane defined by the parametric equationsx=x(s),y=y(s),sbeing


the arc length alongC(see figure 20.4). Let us suppose that alongCwe have


u(x, y)=φ(s)and∂u/∂n=ψ(s). At any point onCthe vectordr=dxi+dyjis


a tangent to the curve andnˆds=dyi−dxjis a vector normal to the curve. Thus


onCwe have


∂u
∂s

≡∇u·

dr
ds

=

∂u
∂x

dx
ds

+

∂u
∂y

dy
ds

=

dφ(s)
ds

,

∂u
∂n

≡∇u·nˆ=

∂u
∂x

dy
ds


∂u
∂y

dx
ds

=ψ(s).

These two equations may then be solved straightforwardly for the first partial


derivatives∂u/∂xand∂u/∂yalongC. Using the chain rule to write


d
ds

=

dx
ds


∂x

+

dy
ds


∂y

,
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