Pseudo-differential operator
An operator, acting on a space of functions on a differentiable manifold, that can locally be described by definite rules using a certain function, usually called the symbol of the pseudo-differential operator, that satisfies estimates for the derivatives analogous to the estimates for derivatives of polynomials, which are symbols of differential operators.
Let 
be an open set in 
, and let 
be the space of infinitely-differentiable functions on 
with compact support belonging to 
. The simplest pseudo-differential operator on 
is the operator 
given by
 | (1) |
Here, 
, 
, 
is Lebesgue measure on 
, 
is the usual inner product of the vectors 
and 
, 
is the Fourier transform of the function 
, i.e.
 |
(the integral, like the one in (1), is over all of 
), and 
is a smooth function on 
satisfying certain conditions and is called the symbol of the pseudo-differential operator 
(cf. also Symbol of an operator). An operator 
of the form (1) is denoted by 
or 
. If
 |
is a polynomial in 
with coefficients 
(here 
is a multi-index, i.e. 
, 
, 
are integers, 
, 
), then 
coincides with the differential operator obtained when 
is substituted for 
in the expression for 
.
One often uses the class of symbols 
satisfying the conditions
 | (2) |
 |
Here 
are multi-indices, 
, 
, and 
is a compact set in 
. This class is denoted by 
(or by 
).
It is usually assumed that 
. By 
(or 
) one denotes the class of operators of the form 
, where 
and 
is an integral operator with a 
-kernel, i.e. an operator of the form
 |
where 
. (Such operators 
are also called pseudo-differential operators in 
.) The function 
is called, like before, the symbol of 
. However, in this case it is not uniquely defined, but only up to a symbol from 
. An operator 
is called a pseudo-differential operator of order not exceeding 
and type 
. The differential operator described above belongs to the class 
. The smallest possible value of 
is called the order of the pseudo-differential operator. The classes 
and 
are often called the Hörmander classes.
One may specify pseudo-differential operators in 
by double symbols or amplitudes, i.e. write them in the form
 | (3) |
For 
this formula turns into (1). It is usually assumed that 
, i.e.
 | (4) |
 |
here 
is a compact set in 
. If 
, then the class of operators (3) (for all possible functions 
) coincides with 
. In this case the symbol 
(determined up to a symbol from 
) has the following asymptotic expansion:
 |
where 
and the summation extends over all multi-indices. This formula means that the difference between 
and the partial sum over all 
for which 
is a symbol in 
, i.e. is a symbol of order at most equal to the largest of the orders of the rest terms.
A pseudo-differential operator 
can be extended, by continuity or duality, to an operator 
. Here 
and 
are the space of generalized functions and the space of generalized functions with compact support in 
, respectively (cf. Generalized functions, space of). If 
, then the pseudo-differential operator has the following pseudo-locality property: If 
, where 
, then 
. Another formulation of this property is: The kernel 
(in the sense of L. Schwartz) of 
is infinitely differentiable in 
for 
.
A classical pseudo-differential operator of order 
in 
is an operator 
whose symbol 
has the asymptotic expansion
 |
where 
, 
for 
, 
for 
, and where 
is positively homogeneous in 
of order 
:
 |
A differential operator (with smooth coefficients) serves as an example of a classical pseudo-differential operator. The function 
is called the principal symbol of a classical pseudo-differential operator of order 
.
A pseudo-differential operator 
in 
is called properly supported if the projections of 
onto each factor when restricted to the support of the kernel of 
are proper mappings (cf. also Proper morphism). A properly supported pseudo-differential operator maps 
into 
and can be extended, by continuity, to mappings 
, 
and 
. It can be written in the form (1) with symbol 
, where the exponent is understood as a function of 
with 
as parameter.
Suppose that 
are pseudo-differential operators in 
one of which is properly supported. Then their product (composition) 
makes sense. The composition theorem plays an important role in the theory of pseudo-differential operators: If 
, 
, 
, then 
. If, moreover, 
and 
, 
and 
are the symbols of 
, 
and 
, then
 |
In particular, if 
are classical pseudo-differential operators of orders 
and 
, then 
is a classical pseudo-differential operator of order 
with principal symbol 
, where 
and 
are the principal symbols of 
and 
.
If 
, 
, then there exists a, moreover unique, adjoint pseudo-differential operator 
for which 
, 
, where 
is the inner product of 
and 
in 
. If, moreover, 
, 
is the symbol of 
and 
is the symbol of 
, then
 |
Thus, the properly supported pseudo-differential operators for 
form an algebra with involution given by transition to the adjoint operator. The arbitrary pseudo-differential operators form a module over this algebra.
The theorem on the boundedness of pseudo-differential operators from the Hörmander classes in the 
-norm, in its most precise form, asserts the following (cf. [8]): Let 
and let 
be an operator of the form (3) with double symbol 
satisfying (4), in which the numbers 
satisfy the conditions
 | (5) |
then 
can be extended to a bounded operator 
. In particular, under the conditions (5) pseudo-differential operators of the form (1) with symbols satisfying conditions (2) uniformly in 
(i.e. such that the constants 
do not depend on 
) are bounded in 
. This implies, e.g., the boundedness in 
of operators 
if 
and if the kernel of 
has compact support (when the bounds on the symbol are, again, uniform in 
). For 
or for 
, operators of such a form need not be bounded [19a]. Analogously, in general, if one of the two latter conditions of (5) are not fulfilled, then one already obtains a class of pseudo-differential operators that contains unbounded ones.
In terms of bounds on symbols one can give conditions for the boundedness of pseudo-differential operators in 
-norms, as well as in Hölder and in Gevrey norms (cf. [8]).
If an operator 
is given on 
, where 
, 
and where (2) holds uniformly in 
, then this operator can be extended to a bounded operator 
, 
, where 
denotes the usual Sobolev space over 
(which is sometimes denoted also by 
).
The class of pseudo-differential operators in 
for 
is naturally invariant under diffeomorphisms. Its subclass of classical pseudo-differential operators has the same property. This makes it possible to define the class 
and classical pseudo-differential operators on an arbitrary smooth manifold 
. The formula for change of variables in the symbol under a diffeomorphism 
, where 
are domains in 
, has the form
 |
Here 
is the symbol of 
; 
is the symbol of the operator 
given by 
, i.e. that obtained from 
by a change of variables 
; 
denotes the Jacobian of 
; 
is the transposed matrix; and
 |
In particular, this implies that the principal symbol of a classical pseudo-differential operator on a manifold 
is a well-defined function on the cotangent bundle 
.
If 
is a compact manifold (without boundary), then the pseudo-differential operators on 
form an algebra with involution, if the involution is introduced by means of an inner product, given by a smooth positive density. An operator 
is bounded in 
, and if 
for 
, then it is compact in 
. For classical pseudo-differential operators 
of order 
on 
,
 |
where 
is the principal symbol of 
and 
runs over the set of compact operators in 
. An operator 
can by continuity be extended to a bounded linear operator from 
into 
for any 
.
A parametrix of a pseudo-differential operator 
is a pseudo-differential operator 
such that 
and 
are pseudo-differential operators of order 
, i.e. are integral operators with a smooth kernel. Suppose that 
, 
, and that 
is the symbol of 
. A sufficient condition for 
to have a parametrix is that the conditions
 | (6) |
are fulfilled.
In this case a parametrix 
exists. The simplest implication from the existence of a parametrix is that 
is a hypo-elliptic operator: If 
, where 
, then 
. In other words, 
(cf. Support of a generalized function). The following exact result (the regularity theorem) is also valid: If 
, then 
. A micro-local regularity theorem is also valid: 
, where 
denotes the wave front of the generalized function 
.
Condition (6) is invariant under diffeomorphisms for 
. Therefore the corresponding class of pseudo-differential operators on a manifold 
has a meaning. If 
is compact, then such an operator 
is Fredholm in 
(cf. Fredholm operator), i.e. has finite-dimensional kernel and co-kernel in 
, and has a closed image.
A classical pseudo-differential operator 
of order 
with smooth symbol 
is called elliptic if 
for 
. For such an operator 
condition (6) holds with 
, and 
has a parametrix that is also a classical pseudo-differential operator of order 
. On a compact manifold 
such an operator 
gives rise to a Fredholm operator
 |
All these definitions and statements can be transferred to pseudo-differential operators acting on vector functions, or, more generally, on sections of vector bundles. For an elliptic operator on a compact manifold 
the index of the mapping 
determined by it on the Sobolev classes of sections does not depend on 
and can be explicitly computed (cf. Index formulas).
The role of pseudo-differential operators lies in the fact that there is a number of operations leading outside the class of differential operators but preserving the class of pseudo-differential operators. E.g., the resolvent and complex powers of an elliptic differential operator on a compact manifold are classical pseudo-differential operators; they arise when reducing an elliptic boundary value problem to the boundary (cf., e.g., [7], [8], and [1e]).
There are several versions of the theory of pseudo-differential operators, adapted to the solution of various problems in analysis and mathematical physics. Often, pseudo-differential operators with a parameter arise; they are necessary, e.g., in the study of resolvent and asymptotic expansions for eigen values. An important role is played by different versions of the theory of pseudo-differential operators in 
, taking into account effects related to the description of the behaviour of functions at infinity, and often inspired by mathematical problems in quantum mechanics arising in the study of quantization of classical systems (cf. [5], [11]). In the theory of local solvability of partial differential equations and in spectral theory it is expedient to use pseudo-differential operators whose behaviour can be described by weight functions replacing 
in estimates of the type (2) (cf. [8], [14]). One has constructed an algebra of pseudo-differential operators on manifolds with boundary, containing, in particular, the parametrix of elliptic boundary value problems (cf. [3], [13]).
A particular case of pseudo-differential operators are the multi-dimensional singular integral and integro-differential operators, whose study prepared the emergence of the theory of pseudo-differential operators (cf. [12] and also Singular integral).
The theory of pseudo-differential operators serves as a basis for the study of Fourier integral operators (cf. Fourier integral operator; [7], [10]), which play the same role in the theory of hyperbolic equations as do pseudo-differential operators in the theory of elliptic equations.
References
| [1a] | J.J. Kohn, L. Nirenberg, "An algebra of pseudo-differential operators" Commun. Pure Appl. Math. , 18 : 1–2 (1965) pp. 269–305 |
| [1b] | L. Hörmander, "Pseudo-differential operators" Commun. Pure Appl. Math. , 18 : 3 (1965) pp. 501–517 |
| [1c] | J.J. Kohn, L. Nirenberg, "Non-coercive boundary value problems" Commun. Pure Appl. Math. , 18 : 3 (1965) pp. 443–492 |
| [1d] | L. Hörmander, "Pseudo-differential operators and non-elliptic boundary problems" Ann. of Math. , 83 : 1 (1966) pp. 129–209 |
| [1e] | L. Hörmander, "Pseudo-differential operators and hypoelliptic equations" A.P. Calderòn (ed.) , Singular Integrals , Proc. Symp. Pure Math. , 10 , Amer. Math. Soc. (1966) pp. 138–183 |
| [2] | M.S. Agranovich, M.I. Vishik, "Pseudo-differential operators" , Moscow (1988) (In Russian) |
| [3] | G.I. Eskin, "Boundary value problems for elliptic pseudodifferential equations" , Amer. Math. Soc. (1981) (Translated from Russian) |
| [4] | V.V. Grushin, "Pseudodifferential operators" , Moscow (1975) (In Russian) |
| [5] | M.A. Shubin, "Pseudo-differential operators and spectral theory" , Springer (1987) (Translated from Russian) |
| [6] | K.O. Friedrichs, "Pseudo-differential operators" , Courant Inst. Math. (1970) |
| [7] | F. Trèves, "Introduction to pseudo-differential and Fourier integral operators" , 1–2 , Plenum (1980) |
| [8] | M.E. Taylor, "Pseudo-differential operators" , Springer (1974) |
| [9] | H. Kumanogo, "Pseudo-differential operators" , M.I.T. (1981) |
| [10] | J.J. Duistermaat, "Fourier integral operators" , Courant Inst. Math. (1973) |
| [11] | V.P. Maslov, M.V. Fedoryuk, "Quasi-classical approximation for the equations of quantum mechanics" , Reidel (1981) (Translated from Russian) |
| [12] | M.S. Agranovich, "Elliptic singular integro-differential operators" Russian Math. Surveys , 20 : 5 (1965) pp. 1–121 Uspekhi Mat. Nauk , 20 : 5 (1965) pp. 3–120 |
| [13] | L. Boutet de Monvel, "Boundary value problems for pseudodifferential operators" Acta Math. , 126 (1971) pp. 11–51 |
| [14] | L. Hörmander, "The Weyl calculus of pseudo-differential operators" Commun. Pure Appl. Math. , 32 : 3 (1979) pp. 359–443 |
| [15a] | H.O. Cordes, "Elliptic pseudo-differential operators - an abstract theory" , Lect. notes in math. , 756 , Springer (1979) |
| [15b] | H.O. Cordes, "Spectral theory of linear differential operators and comparison algebras" , Cambridge Univ. Press (1986) |
| [16] | Yu.V. Egorov, "Linear differential equations of principal type" , Consultants Bureau (1986) (Translated from Russian) |
| [17] | G. Grubb, "Functional calculus of pseudo-differential boundary problems" , Birkhäuser (1986) |
| [18] | B. Helffer, "Théorie spectrale pour des opérateurs globalement elliptiques" Astérisque , 112 (1984) |
| [19a] | L. Hörmander, "Pseudo-differential operators of type 1,1" Comm. Partial Diff. Eq. , 13 : 9 (1988) pp. 1085–1111 |
| [19b] | L. Hörmander, "Continuity of pseudo-differential operators of type 1,1" Comm. Partial Diff. Eq. , 14 : 2 (1989) pp. 231–243 |
| [20] | V. Ivrii, "Precise spectral asymptotics for elliptic operators" , Lect. notes in math. , 1100 , Springer (1984) |
| [21] | S. Rempel, B.-W. Schulze, "Index theory of elliptic boundary problems" , Akademie Verlag (1982) |
Comments
The phrase "pseudo-differential operator" is often abbreviated to 
, just like 
for "partial differential operator" .
For algebras of 
on manifolds with singularities, in particular 
with discontinuous symbols, see [a2].
References
| [a1] | L.V. Hörmander, "The analysis of linear partial differential operators" , 1–4 , Springer (1983–1985) |
| [a2] | B.A. Plamenevskii, "Algebras of pseudodifferential operators" , Kluwer (1989) (Translated from Russian) |
| [a3] | M.E. Taylor, "Pseudo-differential operators" , Princeton Univ. Press (1981) |
| [a4] | J. Chazarain, A. Piriou, "Introduction to the theory of linear partial differential equations" , North-Holland (1982) (Translated from French) |
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