Lavrent'ev theorem
Lavrent'ev's theorem in descriptive set theory:
A topological mapping between two sets in
can be extended to a
homeomorphism
between certain sets of type
containing them. A consequence of this theorem is that the
Hausdorff type of a set is a topological invariant (see
).
Lavrent'ev's theorem in the theory of quasi-conformal mapping:
Let
and
be two simply-connected domains in the plane bounded by piecewise-smooth curves and let
and
be triples of positively enumerated points on their
boundaries. Then for any strongly-elliptic system of equations
with uniformly continuous partial derivatives of the functions that specify
the equations of the characteristics, there is always a unique homeomorphic mapping of
onto
that realizes a solution
 ,
of the system, and under which the given
triples of boundary points correspond to each other.
For
Lavrent'ev's theorem in mechanics
(aerofoil theory, solitary wave, forms of dynamical loss of stability,
flows, the theory of cumulative charge, directed detonation) see
[4].
Theorems 1)–4) are due to
M.A. Lavrent'ev.
References| [1] |
M. [M.A. Lavrent'ev] Lavrentieff,
"Contribution à la théorie des ensembles homéomorphes"
Fund. Math.
, 6
(1924)
pp. 149–160 | | [2] |
M.A. Lavrent'ev,
Izv. Akad. Nauk SSSR Ser. Mat.
, 12
: 6
(1948)
pp. 513–554 | | [3] |
M.A. Lavrent'ev,
"On the theory of conformal mapping"
Tr. Fiz.-Mat. Inst. Akad. Nauk SSSR, Otdel. Mat.
, 5
(1934)
pp. 195–245
(In Russian) | | [4] |
"Mikhail Alekseevich Lavrent'ev"
, Bibliography of Soviet Scientists, Mathematics Series
, 12
, Acad. Sci. USSR
, Moscow
(1971)
(In Russian) |
V.A. Zorich
Comments
1)
This theorem is valid in the following more general situation: If
and
are completely-metrizable spaces,
 ,
and
is a homeomorphism, then there are
sets (cf.
Set of type
 ( ))
and
with
 ,
and a homeomorphism
extending
 .
This theorem has proved to be very useful in
extension theory and in the construction of counterexamples.
2)
This theorem is subsumed by the
Mergelyan theorem.
See
[a6]–[a8],
[a11].
5)
Another problem related with the name of Lavrent'ev is as follows.
Consider the following two optimization problems:
I.e.
is supposed to be absolutely continuous in
(a1)
and
continuously differentiable in
(a2),
Then it may happen that
 .
This is known as the
Lavrent'ev phenomenon.
As a consequence, the minimizer for
(a1)
will not satisfy the
Euler–Lagrange equation
even though
is smooth.
References| [a1] |
J. Aarts,
"Completeness degree, a generalization of dimension"
Fund. Math.
, 63
(1968)
pp. 28–41 | | [a2] |
T.A. Chapman,
"Dense
 -compact subsets of infinite-dimensional manifolds"
Trans. Amer. Math. Soc.
, 154
(1971)
pp. 399–426 | | [a3] |
E.K. van Douwen,
"A compact space with a measure that knows which sets are homeomorphic"
Adv. Math.
, 52
(1984)
pp. 1–33 | | [a4] |
R. Engelking,
"General topology"
, Heldermann
(1989) | | [a5] |
J. van Mill,
"Domain invariance in infinite-dimensional linear spaces"
Proc. Amer. Math. Soc.
, 101
(1987)
pp. 173–180 | | [a6] |
S.N. Mergelyan,
"On a theorem of M.A. Lavrent'ev"
Transl. Amer. Math. Soc.
, 3
(1962)
pp. 281–286
Dokl. Akad. Nauk SSSR
, 77
(1951)
pp. 565–568 | | [a7] |
S.N. Mergelyan,
"On the representation of functions by series of polynomials on closed sets"
Transl. Amer. Math. Soc.
, 3
(1962)
pp. 287–293
Dokl. Akad. Nauk SSSR
, 78
(1951)
pp. 405–408 | | [a8] |
E.F. Collingwood,
A.J. Lohwater,
"The theory of cluster sets"
, Cambridge Univ. Press
(1966) | | [a9] |
L. Cesari,
"Optimization - Theory and applications"
, Springer
(1983)
pp. Sect. 18.5 | | [a10] |
M. [M.A. Lavrent'ev] Lavrentiev,
"Sur quelques problèmes du calcul des variations"
Ann. Mat. Pura Appl.
, 4
(1926)
pp. 7–28 | | [a11] |
P.J. Davis,
"Interpolation and approximation"
, Dover, reprint
(1975)
pp. 278ff | | [a12] |
M.A. Lavrent'ev,
"Variational methods for boundary value problems for systems of elliptic equations"
, Noordhoff
(1963)
(Translated from Russian) |
This text originally appeared in Encyclopaedia of Mathematics
- ISBN 1402006098
|