Schwarz alternating method
One of the general methods for finding a solution to the Dirichlet problem; it allows one to obtain a solution to the Dirichlet problem for a differential equation of elliptic type in domains 
that can be represented as the union of a finite number of domains 
in which the solution to the Dirichlet problem is already known. Studies of H.A. Schwarz (1869; see [1]) and a number of later studies by other authors were dedicated to this method for finding a solution to the Dirichlet problem for the Laplace equation in plane domains. The principal idea of the Schwarz alternating method as applied to the simplest case of the Laplace equation in the union of two plane domains is the following.
Let 
and 
be two domains in the plane with non-empty intersection and such that the solution to the Dirichlet problem for the Laplace equation is known for each of them. For instance, if 
and 
are discs, then the solution to the Dirichlet problem for each of them is given by the Poisson integral. Further, let 
be the union of 
and 
for which a solution to the Dirichlet problem is sought (see Fig.). Let 
denote the boundary of 
, let 
denote the parts of 
that are in 
(they are interior in 
) and let 
be the remaining parts, so that 
. Similarly, 
is the boundary of 
, 
are its parts that fall in 
(they are also interior in 
) and 
are the remaining parts, that is, 
. Then the boundary 
of 
can be represented in the form 
.
Figure: s083490a
Now, given a continuous function 
on 
, one has to find a harmonic function 
in 
that is continuous in the closed domain 
and that takes on 
the values of 
. The restriction of 
to 
can be continuously extended to the whole boundary 
, and for these boundary values one finds a solution 
to the Dirichlet problem in 
. The values of 
on 
together with the values of 
on 
now form a continuous function on 
for which a solution 
to the Dirichlet problem in 
is found. Further, a solution 
to the Dirichlet problem in 
is constructed, based on the values of 
on 
and 
on 
, etc. The sought function has the form
 |
and
 |
Using bounded solutions of the Dirichlet problem with piecewise-continuous boundary data allows one to choose the values zero on the remaining parts of the boundaries without having to worry about the continuous extension of 
.
A method analogous to the Schwarz alternating method (see [2]) can be applied to finding a solution to the Dirichlet problem in the intersection of two domains 
and 
, if its solutions for 
and 
are known.
Schwarz' alternating method is also used to solve boundary value problems of a more general nature for general equations of elliptic type (including equations of an order greater than two) under certain additional conditions [3], and also in domains in space.
Schwarz' alternating method is extremely important for the construction of various harmonic functions (with pre-assigned singularities) on Riemann surfaces [4].
References
| [1] | H.A. Schwarz, "Gesamm. math. Abhandl." , 2 , Springer (1890) |
| [2] | C. Neumann, Ber. Verh. Sächs. Akad. Wiss. Leipzig Math.-Nat. Kl. , 22 (1870) pp. 264–321 |
| [3] | L.V. Kantorovich, V.I. Krylov, "Approximate methods of higher analysis" , Noordhoff (1958) (Translated from Russian) |
| [4] | R. Nevanlinna, "Uniformisierung" , Springer (1967) |
Comments
Recently these ideas are meeting new interest among numerical analysts. They are essentially used to solve boundary value problems on complicated domains. Such domains are decomposed in smaller and simpler ones; therefore such methods are referred to as domain decomposition methods.
See [a1], pp. 200-203, for a more subtle application of the Schwarz alternating method in the study of boundary value problems.
References
| [a1] | L.L. Helms, "Introduction to potential theory" , Wiley (Interscience) (1969) |
| [a2] | T.F. Chan, et al., "Domain decomposition methods for partial differential equations" , SIAM (1990) |
Schwarz alternating method. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Schwarz_alternating_method&oldid=13958