Parametrix method
One of the methods for studying boundary value problems for differential equations with variable coefficients by means of integral equations.
Suppose that in some region 
of the 
-dimensional Euclidean space 
one considers an elliptic differential operator (cf. Elliptic partial differential equation) of order 
,
 | (1) |
In (1) the symbol 
is a multi-index, 
, where the 
are non-negative integers, 
, 
, 
. With every operator (1) there is associated the homogeneous elliptic operator
 |
with constant coefficients, where 
is an arbitrary fixed point. Let 
denote a fundamental solution of 
depending parametrically on 
. Then the function 
is called the parametrix of the operator (1) with a singularity at 
.
In particular, for the second-order elliptic operator
 |
one can take as parametrix with singularity at 
the Levi function
 | (2) |
In (2), 
, 
is the determinant of the matrix 
,
 |
and 
are the elements of the matrix inverse to 
.
Let 
be the integral operator
 | (3) |
acting on functions from 
and let
 |
Since, by definition of a fundamental solution,
 |
where 
is the identity operator, one has
 |
This equality indicates that for every sufficiently-smooth function 
of compact support in 
there is a representation
 | (4) |
Moreover, if
 |
then 
is a solution of the equation
 |
Thus, the question of the local solvability of 
reduces to that of invertibility of 
.
If one applies 
to functions 
that vanish outside a ball of radius 
with centre at 
, then for a sufficiently small 
the norm of 
can be made smaller than one. Then the operator 
exists; consequently, also 
exists, which is the inverse operator to 
. Here 
is an integral operator with as kernel a fundamental solution of 
.
The name parametrix is sometimes given not only to the function 
, but also to the integral operator 
with the kernel 
, as defined by (3).
In the theory of pseudo-differential operators, instead of 
a parametrix of 
is defined as an operator 
such that 
and 
are integral operators with infinitely-differentiable kernels (cf. Pseudo-differential operator). If only 
(or 
) is such an operator, then 
is called a left (or right) parametrix of 
. In other words, 
in (4) is a left parametrix if 
in this equality has an infinitely-differentiable kernel. If 
has a left parametrix 
and a right parametrix 
, then each of them is a parametrix. The existence of a parametrix has been proved for hypo-elliptic pseudo-differential operators (see [3]).
References
| [1] | L. Bers, F. John, M. Schechter, "Partial differential equations" , Interscience (1964) |
| [2] | C. Miranda, "Partial differential equations of elliptic type" , Springer (1970) (Translated from Italian) |
| [3] | L. Hörmander, , Pseudo-differential operators , Moscow (1967) (In Russian; translated from English) |
Comments
The operator 
is called the principal part of 
, cf. Principal part of a differential operator. The parametrix method was anticipated in two fundamental papers by E.E. Levi [a1], [a2]. The same procedure is also applicable for constructing the fundamental solution of a parabolic equation with variable coefficients (see, e.g., [a3]).
References
| [a1] | E.E. Levi, "Sulle equazioni lineari alle derivate parziali totalmente ellittiche" Rend. R. Acc. Lincei, Classe Sci. (V) , 16 (1907) |
| [a2] | E.E. Levi, "Sulle equazioni lineari totalmente ellittiche alle derivate parziali" Rend. Circ. Mat. Palermo , 24 (1907) pp. 275–317 |
| [a3] | A. Friedman, "Partial differential equations of parabolic type" , Prentice-Hall (1964) |
| [a4] | L.V. Hörmander, "The analysis of linear partial differential operators" , 1–4 , Springer (1983–1985) pp. Chapts. 7; 18 |
Parametrix method. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Parametrix_method&oldid=16020