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arXiv:1701.00075v1 [math.GN] 31 Dec 2016
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Extending Baire-one functions on compact spaces
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Olena Karlova, Volodymyr Mykhaylyuk
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Department of Mathematical Analysis, Faculty of Mathematics and Informatics, Yurii Fedkovych Chernivtsi National University, Kotsyubyns'koho str., 2, Chernivtsi, Ukraine
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Abstract We answer a question of O. Kalenda and J. Spurny´ from [8] and give an example of a completely regular hereditarily Baire space X and a Baire-one function f : X [0, 1] which can not be extended to a Baire-one function on X.
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Keywords: extension; Baire-one function; fragmented function; countably fragmented function 2000 MSC: Primary 54C20, 26A21; Secondary 54C30, 54C50
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1. Introduction
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The classical Kuratowski's extension theorem [14, 35.VI] states that any map f : E Y of the first Borel class to a Polish space Y can be extended to a map g : X Y of the first Borel class if E is a G-subspace of a metrizable space X. Non-separable version of Kuratowski's theorem was proved by Hansell [4, Theorem 9], while abstract topological versions of Kuratowski's theorem were developed in [5, 8, 9].
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Recall that a map f : X Y between topological spaces X and Y is said to be - Baire-one, f B1(X, Y ), if it is a pointwise limit of a sequence of continuous maps fn : X Y ; - functionally F-measurable or of the first functional Borel class, f K1(X, Y ), if the preimage f -1(V ) of
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any open set V Y is a union of a sequence of zero sets in X. Notice that every functionally F-measurable map belongs to the first Borel class for any X and Y ; the converse inclusion is true for perfectly normal X; moreover, for a topological space X and a metrizable separable connected and locally path-connected space Y we have the equality B1(X, Y ) = K1(X, Y ) (see [10]).
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Kalenda and Spurny´ proved the following result [8, Theorem 13].
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Theorem A. Let E be a Lindel¨of hereditarily Baire subset of a completely regular space X and f : E R be a Baire-one function. Then there exists a Baire-one function g : X R such that g = f on E.
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The simple example shows that the assumption that E is hereditarily Baire cannot be omitted: if A and B are disjoint dense subsets of E = Q [0, 1] such that E = A B and X = [0, 1] or X = E, then the characteristic function f = A : E R can not be extended to a Baire-one function on X. In connection with this the following question was formulated in [8, Question 1].
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Question 1. Let X be a hereditarily Baire completely regular space and f a Baire-one function on X. Can f be extended to a Baire-one function on X?
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We answer the question of Kalenda and Spurny´ in negative. We introduce a notion of functionally countably fragmented map (see definitions in Section 2) and prove that for a Baire-one function f : X R on a completely regular space X the following conditions are equivalent: (i) f is functionally countably fragmented; (ii) f can be extended to a Baire-one function on X. In Section 3 we give an example of a completely regular hereditarily Baire (even scattered) space X and a Baire-one function f : X [0, 1] which is not functionally countably fragmented and consequently can not be extended to a Baire-one function on X.
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2. Extension of countably fragmented functions
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Let X be a topological space and (Y, d) be a metric space. A map f : X Y is called -fragmented for some > 0 if for every closed nonempty set F X there exists a nonempty relatively open set U F such that diamf (U ) < . If f is -fragmented for every > 0, then it is called fragmented.
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Let U = (U : [0, ]) be a transfinite sequence of subsets of a topological space X. Following [6], we define U to be regular in X, if
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Email addresses: maslenizza.ua@gmail.com (Olena Karlova), vmykhalyuk@ukr.net (Volodymyr Mykhaylyuk)
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�(a) each U is open in X;
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(b) = U0 U1 U2 · · · U = X;
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(c) U = < U for every limit ordinal [0, ). Proposition 1. Let X be a topological space, (Y, d) be a metric space and > 0. For a map f : X Y the following conditions are equivalent:
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(1) f is -fragmented;
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(2) there exists a regular sequence U = (U : [0, ]) in X such that diamf (U+1 \ U) < for all [0, ).
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Proof. (1)(2) is proved in [12, Proposition 3.1]. (2)(1). We fix a nonempty closed set F X. Denote = min{ [0, ] : F U = }. Property (c) implies
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that = + 1 for some < . Then the set U = U F is open in F and diamf (U ) diamf (U+1 \ U) < .
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If a sequence U satisfies condition (2) of Proposition 1, then it is called -associated with f and is denoted by U(f ).
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We say that an -fragmented map f : X Y is functionally -fragmented if U(f ) can be chosen such that every set U is functionally open in X. Further, f is functionally -countably fragmented if U(f ) can be chosen to be countable and f is functionally countably fragmented if f is functionally -countably fragmented for all > 0.
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Evident connections between kinds of fragmentability and its analogs are gathered in the following diagram.
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functional countable fragmentability
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functional fragmentability
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fragmentability
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countable fragmentability
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Baire-one
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continuity
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functional F-measurability
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Notice that none of the inverse implications is true.
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Remark 1. (a) If X is hereditarily Baire, then every Baire-one map f : X (Y, d) is barely continuous (i.e., for every nonempty closed set F X the restriction f |F has a point of continuity) and, hence, is fragmented (see [14, 31.X]).
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(b) If X is a paracompact space in which every closed set is G, then every fragmented map f : X (Y, d) is Baire-one in the case either dimX = 0, or Y is a metric contractible locally path-connected space [11, 12].
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(c) Let X = R be endowed with the topology generated by the discrete metric d(x, y) = 1 if x = y, and d(x, y) = 0 if x = y. Then the identical map f : X X is continuous, but is not countably fragmented.
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For a deeper discussion of properties and applications of fragmented maps and their analogs we refer the reader to [1, 2, 7, 13, 15].
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Proposition 2. Let X be a topological space, (Y, d) be a metric space, > 0 and f : X Y be a map. If one of the following conditions hold
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(1) Y is separable and f is continuous,
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(2) X is metrizable separable and f is fragmented,
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(3) X is compact and f B1(X, Y ),
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then f is functionally countably fragmented.
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�Proof. Fix > 0.
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(1) Choose a covering (Bn : n N) of Y by open balls of diameters < . Let U0 = , Un = f -1( kn Bk) for
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every n N and U0 =
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n=0
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Un.
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Then
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the
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sequence
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(U
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:
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[0, 0])
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is
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-associated
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with
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f.
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(2) Notice that any strictly increasing well-ordered chain of open sets in X is at most countable and every open
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set in X is functionally open.
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(3) By [12, Proposition 7.1] there exist a metrizable compact space Z, a continuous function : X Z and a
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function g B1(Z, Y ) such that f = g . Then g is functionally -countably fragmented by condition (2) of the
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theorem. It is easy to see that f is functionally -countably fragmented too.
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Lemma 3. Let X be a topological space, E X and f B1(E, R). If there exists a sequence of functions fn B1(X, R) such that (fn) n=1 converges uniformly to f on E, then f can be extended to a function g B1(X, R).
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Proof. Without loss of generality we may assume that f0(x) = 0 for all x E and
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|fn(x)
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-
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fn-1(x)|
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1 2n-1
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for all n N and x E. Now we put
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gn(x) = max{min{(fn(x) - fn-1(x)), 2-n+1}, -2-n+1}
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and notice that gn B1(X, R). Moreover, the series
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n=1
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gn
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(x)
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is
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uniformly
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convergent
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on
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X
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for
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a
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function
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g B1(X, R). Then g is the required extension of f .
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Recall that a subspace E of a topological space X is z-embedded in X if for any zero set F in E there exists a zero set H in X such that H E = F ; C-embedded in X if any bounded continuous function f on E can be
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extended to a continuous function on X.
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Proposition 4. Let E be a z-embedded subspace of a completely regular space X and f : E R be a functionally countably fragmented function. Then f can be extended to a functionally countably fragmented function g B1(X, R).
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Proof. Let us observe that we may assume the space X to be compact. Indeed, E is z-embedded in X, since X
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is C-embedded in X [3, Theorem 3.6.1], and if we can extend f to a functionally countably fragmented function
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h B1(X, R), then the restriction g = h|E is a functionally countably fragmented extension of f on X and
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g B1(X, R).
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Fix n N and consider
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1 n
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-associated
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with
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f
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sequence U
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= (U
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: ).
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Without loss of the generality we
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can assume that all sets U+1 \ U are nonempty. Since E is z-embedded in X, one can choose a countable family
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V = (V : ) of functionally open sets in X such that V V for all , V E = U for every
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and V = < V for every limit ordinal . For every [0, ) we take an arbitrary point y f (U+1 \ U). Now for every x X we put
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fn(x) =
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y, x V+1 \ V, y0, x X \ V.
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Observe that fn : X R is functionally F-measurable, since the preimage f -1(W ) of any open set W R is an
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at most countable union of functionally F-sets from the system {V+1 \ V : [0, )} {X \ V}. Therefore,
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fn B1(X, R). It is easy to see that the sequence (fn) n=1 is uniformly convergent to f on E. Now it follows from Lemma 3
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that f can be extended to a function g B1(X, R). According to Proposition 2 (3), g is functionally countably
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fragmented.
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Corollary 5. Every functionally countably fragmented function f : X R defined on a topological space X belongs to the first Baire class.
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Proof.
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For every n N we choose a
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1 n
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-associated
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with
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f
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family Un
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= (Un,
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: n) of functionally open sets Un,
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and corresponding family (n, : n) of continuous functions n, : X [0, 1] such that Un, = -n,1((0, 1]).
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We consider the at most countable set = n=1{n, : 0 n} and the continuous mapping : X [0, 1],
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(x) = ((x)).
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Show that f (x) = f (y) for every x, y X with (x) = (y). Let x, y X with (x) = (y). For every n N
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we choose n n such that x Un,n+1 \ Un,n . Then y Un,n+1 \ Un,n and
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|f (x)
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-
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f (y)|
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diam(Un,n+1
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\
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Un,n )
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1 n
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for every n N. Thus, f (x) = f (y).
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�Now we consider the function g : (X) R, g((x)) = f (x). Clearly, that every set (Un,) is open in the
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metrizable
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space
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(X ).
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Therefore,
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for
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every
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nN
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the
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family
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((Un,) :
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n)
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is
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1 n
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-associated
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with
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g.
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Thus,
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g
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is functionally countably fragmented. According to Proposition 4, g B1((X), R). Therefore, f B1(X, R).
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Combining Propositions 2 and 4 we obtain the following result.
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Theorem 6. Let X be a completely regular space. For a Baire-one function f : X R the following conditions are equivalent:
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(1) f is functionally countably fragmented;
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(2) f can be extended to a Baire-one function on X.
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3. A Baire-one bounded function which is not countably fragmented
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Theorem 7. There exists a completely regular scattered (and hence hereditarily Baire) space X and a Baire-one function f : X [0, 1] which can not be extended to a Baire-one function on X.
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Proof. Claim 1. Construction of X. Let Q = {rn : n N}, rn = rm for all distinct n, m N and
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{r2n-1 : n N} = {r2n : n N} = Q,
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A = {r2n-1} × [0, 1], B = {r2n} × [0, 1].
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n=1
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n=1
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We consider partitions A = (At : t [0, 1]) and B = (Bt : t [0, 1]) of the sets A and B into everywhere dense sets At and Bt, respectively, such that |At| = |Bt| = c. Moreover, let [0, 1] = <1 T with |T| = c for every < 1. For every [0, 1) we put
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Q =
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tT At, is even, tT Bt, is odd,
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Q=
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Q, X = Q × {} and X =
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X.
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<1
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<1
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Claim 2. Indexing of X. For every [0, 1) we consider the set
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I = {(i)[,1) : |{ : i = 0}| 0} [0, 1][,1) and notice that |I| = c. Let : I T be a bijection and
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X =
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X,j ,
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jI+1
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where
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X,j =
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A+1(j) × {}, B+1(j) × {},
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For all , [0, 1) with > and i I we put
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is even, is odd,
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Ji, = {j I : j|[,1) = i}.
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In particular, if = , = + 1 and i I+1, then we denote the set Ji +1, simply by Ji . Notice that |Ji | = c and we may assume that
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X,i = {xj : j Ji }.
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Then
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X = {xi : i I},
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since I = iI+1 Ji .
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Claim 3. Topologization of X. For all [1, 1), i I and x = xi X we put
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L<x = {xj X : j Ji ,}, Lx = {x} L<x.
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<
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�Notice that for all x X and y X with either Lx Ly, or Lx Ly = . Now we are ready to define a topology on X. Each point of X0 is isolated. For any [1, 1) and a point
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x X we construct a base Ux of -open neighborhoods of x in the following way. Take i I and q Q such that x = xi = (q, ) X. Let Vq be a base of clopen neighborhoods of q in the space Q equipped with the topology induced from R2. Then we put
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Ux = {(V × [0, 1)) (Lx \ Ly) : V Vq and Y L<x is finite}.
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yY
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Claim 4. Complete regularity and scatteredness of X. We show that the space (X, ) is completely regular. We prove firstly that every set Lx is clopen. Since the inclusion v Lu implies Lv Lu, every set Lx is open. Now let y Lx. Then Ly Lx = . Therefore, Ly Lx or Lx Ly. Assume that y Lx. Then x L<y and for a neighborhood W = Ly \ Lx of y we have W Lx = , which implies a contradiction. Thus, Lx = Lx and the set Lx is closed.
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Notice that for every clopen in Q set V the set (V × [0, 1)) X is clopen in X. Therefore, every U Ux is clopen in X for every x X. In particular, (X, ) is completely regular.
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In order to show that (X, ) is scattered we take an arbitrary nonempty set E X and denote = min{ [0, 1) : E X = }. Then any point x from E X is isolated in E.
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Claim 5. X = X for every [0, 1). It is sufficient to prove that
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X X
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<
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for every [1, 1). Let [1, 1), x = (q, ) X, V be an open neighborhood of q in Q, Y L<x be a finite set and
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U = (V × [0, 1)) (Lx \ Ly).
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yY
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We show that U ( < X) = . For every y Y we choose y < such that y Xy . We put = max{y : y Y } and = + 1. Since < , . We choose i I such that x = xi and choose j J such that j|[,1) = i. We consider the set X,j. Recall that X,j = At × {} or X,j = Bt × {}, where t = (j). Therefore, the set
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P = {p Q : (p, ) X,j}
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is dense in Q. Thus, the set P V is infinite. Moreover, |Ly X| 1 for every y Y . Hence, the set
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S = {p P : (p, ) Ly}
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yY
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is finite. Therefore, the set (P V ) \ S is infinite, in particular, it is nonempty. We choose a point p (P V ) \ S. Then z = (p, ) X,j. Thus, z Lx. Moreover, z V × [0, 1) and z yY Ly. Thus, z U . Since X,j X, z < X. Therefore, Ux < X = for every Ux Ux and x < X.
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Claim 6. Construction of a Baire-one function f . We put
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C=
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X
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<1, is even
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and show that the function f : X [0, 1],
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f = C,
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belongs to the first Baire class. Consider a mapping : X Q, (x) = r if x = (q, ) and q = (r, t) for some t [0, 1] and < 1. The
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mapping is continuous, because for every open in Q set V the set
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-1(V ) = (V × [0, 1] × [0, 1)) X
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is open in X. Clearly, the function g : Q R,
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g(t) =
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1, t = r2n-1, 0, t = r2n,
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�belongs to the first Baire class. Therefore, the function f (x) = g((x)) belongs to the first Baire class too.
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Claim 7. The function f is not countably fragmented. Finally, we prove that f is not countably frag-
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mented. Assume the contrary and take a countable sequence U = (U : < ) of functionally open sets such that
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U
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is
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1 2
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-associated
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with
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f.
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We show that U < X for every . We will argue by induction on . For = 0 the assertion is
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obvious. Assume that the inclusion is valid for all < . If is a limit ordinal, then
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U = U
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X = X.
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<
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< <
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<
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Now let = + 1. Suppose that there exists x U \ ( X). Notice that x X X according to Claim 6. Therefore, there exist z1 U X and z2 U X. According to the inductive assumption, we have U < X. Therefore, z1, z2 U \ U = U+1 \ U. Thus, we have
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1
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=
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|f (z1)
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-
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f (z2)|
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diam(U+1
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\
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U )
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<
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1 2
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,
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a contradiction. Theorem 6 implies that f can not be extended to a Baire-one function on X.
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References
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[1] Angosto C., Cascales B., Namioka I. Distances to spaces of Baire one functions, Math. Zeit. 263 (1) (2009), 103124.
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[2] Banakh T., Bokalo B. Weakly discontinuous and resolvable functions between topological spaces, Hacettepe Journal of Mathematics and Statistics, DOI: 10.15672/HJMS.2016.399.
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[3] Engelking R. General Topology. Revised and completed edition. Heldermann Verlag, Berlin (1989).
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[4] Hansell R. W. On Borel mappings and Baire functions, Trans. Amer. Math. Soc. 194 (1974), 195211.
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[5] Holicky´ P. Extensions of Borel measurable maps and ranges of Borel bimeasurable maps, Bulletin Polish Acad. Sci. Math. 52 (2004), 151167.
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[6] Holicky´ P., Spurny´ J. Perfect images of absolute Souslin and absolute Borel Tychonoff spaces, Top. Appl. 131 (3) (2003), 281294.
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[7] Jayne J. E., Orihuela J., Pallar´es A. J., Vera G. -fragmentability of multivalued maps and selection theorems, J. Funct. Anal. 117 (1993), 243273.
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[8] Kalenda O., Spurny´ J. Extending Baire-one functions on topological spaces, Topol. Appl. 149 (1-3) (2005), 195216.
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[9] Karlova O. On -embedded sets and extension of mappings, Comment. Math. Univ. Carolin. 54 (3) (2013), 377396.
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[10] Karlova O., Mykhaylyuk V. Functions of the first Baire class with values in metrizable spaces, Ukr. Math. J. 58 (4) (2006), 640644.
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[11] Karlova O., Mykhaylyuk V. On composition of Baire functions, Top. Appl. 216 (2017), 824.
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[12] Karlova O., Mykhaylyuk V. Baire classification of fragmented maps and approximation of separately continuous functions, Eur. J. Math. (2017), DOI:10.1007/s40879-016-0123-3.
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[13] Koumoullis G. A generalization of functions of the first class, Top. Appl. 50 (1993), 217239.
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[14] Kuratowski K. Topology, I, PWN, Warszawa, 1966.
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[15] Spurny´ J. Borel sets and function in topological spaces, Acta Math. Hungar. 129 (12), (2010), 4769.
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