Luzin problem
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A problem in the theory of trigonometric series. It consists in proving Luzin's conjecture, stating that the Fourier series
$$ \tag{* } a _ {0} ( f ) + \sum _ { n= } 1 ^ \infty \{ a _ {n} ( f ) \cos nx + b _ {n} ( f ) \sin nx \} $$
of a Lebesgue-measurable function $ f $, defined on the interval $ [ 0 , 2 \pi ] $, with finite integral
$$ \int\limits _ { 0 } ^ { {2 } \pi } | f ( x) | ^ {2} dx, $$
converges almost everywhere on $ [ 0 , 2 \pi ] $. The conjecture was made by N.N. Luzin in 1915 in his dissertation (see [a1]). Luzin's problem was solved in 1966 in the affirmative sense by L. Carleson (see Carleson theorem). Until Carleson's paper [a2] it was not even known whether the Fourier series of a continuous function on the interval $ [ 0 , 2 \pi ] $ converges at least at one point.
Comments
See Luzin set for usual terminology. For other problems of Luzin see Luzin theorem.
B.S. Kashin
One of a number of fundamental problems in set theory posed by N.N. Luzin [b1], for the solution of which he proposed the method of resolvents. Namely, a problem $ P $ of set theory is posed in a resolvent if one can indicate a set of points $ E $ such that $ P $ is solved affirmatively every time one can indicate a point of $ E $, and is solved negatively if one can prove that $ E $ is empty. The set $ E $ itself is called the resolvent of the problem $ P $.
Problem 1. Are all co-analytic sets (cf. $ C {\mathcal A} $- set) countable or do they have the cardinality of the continuum? The resolvent $ E $ of this problem is a Luzin set of class at most 3; that is, if one can find a point of $ E $, then there is an uncountable co-analytic set without perfect part, while if $ E $ is empty, then there are no such co-analytic sets.
Problem 2. Do there exists Lebesgue-unmeasurable Luzin sets?
Problem 3. Does there exist a Luzin set without the Baire property?
Luzin conjectured that the Problems 1, 2, 3 are undecidable. This conjecture has been confirmed (see [b3], [b4]). Connections between these problems have been established. For example, from the existence of an unmeasurable set of type $ A _ {2} $ follows the existence of an uncountable set of type $ C {\mathcal A} $ not containing a perfect subset. I. Novak [b5] obtained an affirmative solution of Luzin's problem about parts of the series of natural numbers, starting from the continuum hypothesis or the negation of the Luzin hypothesis.
B.A. Efimov
References
[a1] | N.N. Luzin, "The integral and trigonometric series" , Moscow-Leningrad (1953) pp. 219 (In Russian) (Thesis; also: Collected Works, Vol. 1, Moscow, 1953, pp. 48–212) |
[a2] | L. Carleson, "Convergence and growth of partial sums of Fourier series" Acta Math. , 116 (1966) pp. 135–157 |
[b1] | N.N. [N.N. Luzin] Lusin, "Sur le problème de M. Emile Borel et la méthode des résolvants" C.R. Acad. Sci. Paris , 181 (1925) pp. 279–281 |
[b2] | N.N. Luzin, "Collected works" , 2 , Moscow (1958) (In Russian) |
[b3] | P.S. Novikov, "On the non-contradictibility of certain propositions in descriptive set theory" Trudy Mat. Inst. Steklov. , 38 (1951) pp. 279–316 (In Russian) |
[b4] | R. Solovay, "A model of set theory in which every set of reals is Lebesgue measurable" Ann. of Math. (2) , 92 : 1 (1970) pp. 1–56 |
[b5] | J. Novak, "On some problems of Lusin concerning the subsets of natural numbers" Czechoslovak. Math. J. , 3 (1953) pp. 385–395 |
[c1] | T.J. Jech, "Set theory" , Acad. Press (1978) pp. Chapt. 7 (Translated from German) |
[c2] | Y.N. Moschovakis, "Descriptive set theory" , North-Holland (1980) |
Luzin problem. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Luzin_problem&oldid=54976