On doubly universal functions
A Mouze (LPP)

TL;DR
This paper provides a new proof for the existence of power series with universal approximation properties related to partial sums, extending to infinitely differentiable functions, and analyzes their genericity and limitations.
Contribution
It offers a new proof avoiding potential theory, establishes algebraic genericity of such power series, and explores the case of doubly universal infinitely differentiable functions.
Findings
Existence of power series with universal approximation properties.
Algebraic genericity of the set of such power series.
Cesàro means of partial sums are not frequently universal.
Abstract
Let be a strictly increasing sequence of positive integers. Inspired by the notions of topological multiple recurrence and disjointness in dynamical systems, Costakis and Tsirivas have recently established that there exist power series with radius of convergence 1 such that the pairs of partial sums approximate all pairs of polynomials uniformly on compact subsets with connected complement, if and only if In the present paper, we give a new proof of this statement avoiding the use of advanced tools of potential theory. It allows to obtain the algebraic genericity of the set of such power series and to study the case of doubly universal infinitely differentiable functions. Further…
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Taxonomy
TopicsMathematical Dynamics and Fractals · Analytic Number Theory Research · Functional Equations Stability Results
On doubly universal functions
A. Mouze
Augustin Mouze, Laboratoire Paul Painlevé, UMR 8524, Current address: École Centrale de Lille, Cité Scientifique, CS20048, 59651 Villeneuve d’Ascq cedex
Abstract.
Let be a strictly increasing sequence of positive integers. Inspired by the notions of topological multiple recurrence and disjointness in dynamical systems, Costakis and Tsirivas have recently established that there exist power series with radius of convergence 1 such that the pairs of partial sums approximate all pairs of polynomials uniformly on compact subsets with connected complement, if and only if In the present paper, we give a new proof of this statement avoiding the use of advanced tools of potential theory. It allows to obtain the algebraic genericity of the set of such power series and to study the case of doubly universal infinitely differentiable functions. Further we show that the Cesàro means of partial sums of power series with radius of convergence 1 cannot be frequently universal.
Key words and phrases:
universal Taylor series, double universality
2010 Mathematics Subject Classification:
30K05, 41A58
1. Introduction
For a simply connected domain we will denote by the space of all holomorphic functions on Let For we denote by the -th partial sum of its Taylor development with center In 1996 Nestoridis proved that there exist functions such that for every compact set with connected and and for every function where there exists a sequence of positive integers such that as [19]. Such functions are called universal Taylor series. The partial sums of its Taylor development diverge in a maximal way. In the following, the set of universal Taylor series will be denoted by We refer the reader to [3] and the references therein for its properties. In particular we know that is a dense subset of endowed with the topology of uniform convergence on all compact subsets of and contains a dense vector subspace apart from [math]. Notice that we know versions of Nestoridis result (see for instance [3, 8, 12, 18, 20]). Inspired by the notion of topological multiple recurrence and disjointness in dynamical systems, Costakis and Tsirivas introduced the following new form of universality [11].
Definition 1.1**.**
Let be a strictly increasing sequence of positive integers. A function belongs to the class if for every compact set with connected complement and for every pair of functions there exists a subsequence of positive integers such that
[TABLE]
Such a function will be called doubly universal Taylor series with respect to the sequences **
Using tools from potential theory they proved that the set is non-empty if and only if . Moreover they obtained that the existence of a doubly universal series implies topological genericity of such series. In the present paper we show that the advanced knowledge of potential theory does not play a dominant role to obtain the proof of the implication . Instead we employ some polynomial inequalities which were recently used to study the densities of approximation subsequences of universal Taylor series in the sense of Nestoridis (see [16, 17]). It seems quite natural that the arithmetic structure of subsequences along which the partial sums possess the universal approximation property is connected with the above notion of disjointness. As a consequence, we obtain that the set of doubly universal Taylor series is densely lineable, i.e. contains a dense vector subspace except This concept gives some information about the algebraic structure of the set of such series. Several authors were recently interested in this phenomenon (see for instance [4]). Further, since we avoid the use of potential theory in a large way, we extend the aforementioned Costakis-Tsirivas result to the case of the sequence of partial sums of Taylor development at [math] of infinitely differentiable functions on This generalization uses in an essential way classical Bernstein polynomials of given continuous functions on intervals of the type In particular, these specific polynomials possess a useful property in our context: we control both their degree and their valuation provided that the associated function vanishes on a neighborhood of zero. Finally we return to the connection between doubly universality and topological recurrence. In a recent note, Costakis and Parissis proved that every frequently Cesàro operators is topologically multiply recurrent [9]. In our context, we show that the Cesàro means of partial sums of a real or complex power series cannot be frequently universal series. So the doubly universality, which is related to the topological multiply recurrence, does not imply the frequent Cesàro universality.
The paper is organized as follows. In Section 2 we give a new shorter proof of the implication and we establish the algebraic genericity of the set In Section 3, we are interested in the case of doubly universal infinitely differentiable functions with respect to an increasing sequence of positive integers. We establish both the topological and algebraic genericity of the set of such functions provided that again. In Section 4, we study the frequent Cesàro universal series and finally we give an example, in a different context, of the existence of doubly universal series with respect to an increasing sequence of positive integers without additional assumption.
2. Doubly universal Taylor series in the complex plane
In this section, we begin by giving a proof with rather elementary arguments of the fact that implies that To do this, let us recall the nice Turán inequality [21], which estimates the global behavior of a polynomial on a circle by its supremum on subsets of .
Lemma 2.1**.**
Let be a polynomial of arbitrary degree which possesses only non zero coefficients. Then for any and any ()
[TABLE]
For and will be the set
[TABLE]
and the constant of the above Turán inequality.
Now we state [11, Proposition 4.5] and we furnish a simple proof.
Proposition 2.2**.**
Let be a strictly increasing sequence of positive integers. Assume that Then the set is empty.
Proof.
The proof is based on the use of Turán’s inequality. We argue by contradiction. Take in Since we have there exists such that
[TABLE]
Let and Fix a compact set with connected complement. Let us choose so that
[TABLE]
Clearly the set is a compact set with connected complement. Since there exists an increasing of positive integers such that
[TABLE]
Therefore, for any we can find such that for all
[TABLE]
In particular, we have, for every
[TABLE]
Using Lemma 2.1 and Cauchy estimates, we get for every and
[TABLE]
Taking into account (1), we get for every and
[TABLE]
By (5) and (2), we deduce that there exists a positive integer such that for the following estimate holds
[TABLE]
Finally using the inequality we have, for all
[TABLE]
Combining (3) with (6) we obtain
[TABLE]
which is a contradiction. This completes the proof of the proposition. ∎
Further we are interested in the algebraic structure of First let us define the set of doubly universal Taylor series along a given subsequence.
Definition 2.3**.**
Let and be increasing sequences of positive integers. A function belongs to the class if for every compact set with connected complement and for every pair of functions there exists a subsequence of positive integers such that
[TABLE]
Remark 2.4**.**
Arguing as in the proof of Proposition 2.2, we obtain that the existence of universal elements in implies On the other hand, the hypothesis implies that the set is and dense in . The proof works as in [11, Proposition 4.1] with obvious modifications.**
Moreover a careful examination of the proof of Proposition 2.2 gives the following lemma.
Lemma 2.5**.**
Let and be increasing sequences of positive integers. Let be in For every compact set with connected, and for every pair of functions with there exists a subsequence of with such that
[TABLE]
Proof.
As in the proof of Proposition 2.2, let us choose so that and consider the compact set Since there exists an increasing of positive integers such that
[TABLE]
Arguing as in the end of the proof of Proposition 2.2, we deduce that we have necessary ∎
Combining Remark 2.4 with Lemma 2.5 we get that the set is algebraically generic.
Theorem 2.6**.**
Let be a strictly increasing sequence of positive integers such that The set contains a dense vector subspace of
Proof.
We proceed as in the proof of [3, Theorem 3] with essential modifications. Let us fix a dense sequence in In the following, denotes the standard metric of Let be a family of compact sets with connected complement and for every such that every compact subset with connected, is contained in some [19, Lemma 2.1]. We construct a sequence in and sequences of positive integers satisfying the following conditions, for any
- •
is a subsequence of , with
- •
- •
- •
belongs to
- •
and as
To do this, observe that first we can choose in the dense set so that Therefore, applying Lemma 2.5, for any one may find a subsequence with , such that and as
At step 2, we choose which is a and dense subset of with In particular, according to Lemma 2.5 for any there exists a subsequence of , with such that and as Then we repeat the same arguments to construct in and sequences of positive integers satisfying the above properties. To finish the proof, it is sufficient to check that the linear span of the is both dense in and contained in , except for the zero function. The density is clear by construction. Moreover let with Let us consider two polynomials and a compact set with connected complement and There exists such that Since there exists a sequence of positive integers with such that
[TABLE]
Observe that is a subsequence of any for Hence by construction we have, for any
[TABLE]
Finally from (7) and (8) we get
[TABLE]
and
[TABLE]
as which implies that belongs to ∎
3. Doubly universal infinitely differentiable functions
First let us introduce some notations and terminology. We consider the set of functions with Its topology is defined by the seminorms and the associated standard translation-invariant metric will be denoted by . Moreover we will consider the classical space endowed with the metric defined by The metric space is complete.
As far as we know Fekete exhibited the first example of universal series by showing that there exists a formal power series with the following property: for every continuous function on with there exists an increasing sequence of positive integers such that as [20]. A slight modification of Fekete’s proof combined with Borel’s theorem allows to obtain -function whose partial sums of its Taylor series around [math] approximate every continuous functions vanishing at [math] locally uniformly in (see [12]). In the present section, we are going to obtain a natural extension of the results of Section 2 to the case of Fekete functions, exploiting the fact that we did not need to use advanced tools of potential theory to study the class of doubly (complex) universal Taylor series.
First of all, let us mention a useful inequality for polynomials in many variables between the complex and the real sup-norms [1, 13].
Theorem 3.1**.**
There exists a constant such that, for any polynomial of degree in variables with real coefficients, we have
[TABLE]
In Theorem 3.1, we can choose the constant to be [1, 13].
Definition 3.2**.**
Let be a strictly increasing sequence of positive integers. A function belongs to the class if for every compact set and for every pair of continuous functions vanishing at zero, there exists a subsequence of positive integers such that
[TABLE]
Now we can state a version of Proposition 2.2 in this context.
Proposition 3.3**.**
Let be a strictly increasing sequence of positive integers. Assume that Then the set is empty.
Proof.
We argue by contradiction. Take in and set, for every Since we have there exists such that
[TABLE]
Let us fix
[TABLE]
where is the absolute constant given by Theorem 3.1. Since belongs to there exists a subsequence of positive integers such that, for any
[TABLE]
Using Theorem 3.1 we get, for every
[TABLE]
It follows from Cauchy’s formula, for every and
[TABLE]
From (9) we deduce, for
[TABLE]
and therefore we get, for
[TABLE]
Finally using (11) we have, for all
[TABLE]
Combining (11) with (15) we obtain, for
[TABLE]
This last inequality gives a contradiction with (10). This completes the proof. ∎
To obtain the converse result, we will follow the main ideas of the proof of [11, Proposition 4.1]. First we need a quantitative approximation polynomial lemma which will play the role of [11, Theorem 2.1]. We have to approximate a given continuous function vanishing at [math] by polynomials whose both degrees and valuations are imposed. Exploiting the form of the classical Bernstein polynomials, we begin with the case where the approximation takes place on compact subsets of
Lemma 3.4**.**
Let and be two strictly increasing sequences of positive integers such that and as Let For every continuous function with there exists a sequence of real polynomials of the form such that
[TABLE]
Proof.
Let By continuity of the function at one can find such that for all Let us consider the continuous function defined on by
[TABLE]
Then, for every let us consider its Bernstein polynomial of degree given by
[TABLE]
Moreover since the sequence converges to there exists a positive integer such that, for every Therefore by construction, for every and for we have The Bernstein polynomials of have the following form
[TABLE]
Obviously the function is continuous on So it is known that the sequence converges uniformly to on [5]. Thus we deduce the existence of a positive integer such that, for every
[TABLE]
Now, for since the triangle inequality gives
[TABLE]
On the other hand, for we have
[TABLE]
Finally for we have and we get This completes the proof. ∎
Then we extend Lemma 3.4 to the case of symmetric intervals
Lemma 3.5**.**
Let and be two strictly increasing sequences of positive integers such that and as Let For every continuous function with there exists a sequence of real polynomials of the form such that
[TABLE]
Proof.
Let By continuity of the function at one can find such that for all Let us consider the continuous function defined on by
[TABLE]
Observe that we have
[TABLE]
Define also the continuous function By classical Weierstrass approximation theorem one can find a polynomial such that
[TABLE]
We deduce the following inequality
[TABLE]
Set Observe that Let us write
[TABLE]
where and are polynomials vanishing at Then we apply Lemma 3.4 to find two sequences of polynomials and of the form
[TABLE]
such that
[TABLE]
For large enough we get
[TABLE]
Thus by construction the polynomial has the following form
[TABLE]
and we have
[TABLE]
Finally combining the triangle inequality with (16), (17) and (19), we get
[TABLE]
Thus the polynomial has the desired properties (given by (18) and (20)). This completes the proof. ∎
Next we introduce an intermediate result.
Definition 3.6**.**
Let and be strictly increasing sequence of positive integers. A function belongs to the class if for every compact set and for every continuous function vanishing at zero, there exists a subsequence of positive integers such that
[TABLE]
Proposition 3.7**.**
Let and be strictly increasing sequence of positive integers. Then the set is and dense in
Proof.
It suffices to combine the ideas of the proof of [11, Proposition 3.2] with the arguments of [18]. Let be an enumeration of all the polynomials with coefficients in and Let us define the set
[TABLE]
for every Observe that is an open set and the following description holds
[TABLE]
By Baire’s category theorem it suffices to show that is dense in To do this, let and be a polynomial. We seek and such that Applying the proof of [7, Lemma 2.3], for any we find in such that
[TABLE]
with Since the sequences and are strictly increasing, we fix such that Moreover the linear Borel map is open. Hence with a previous good choice of we find a function such that and So the function does the job. ∎
Proposition 3.8**.**
Let be a strictly increasing sequence of positive integers. Assume that Then the set is and dense in and contains a dense vector subspace apart from
Proof.
Let be an enumeration of all the polynomials with coefficients in vanishing at zero. Let us consider the sets
[TABLE]
for every Weirstrass approximation theorem ensures that
[TABLE]
Since the sets are open, according to Baire’s category theorem it suffices to prove that is dense in for every to obtain that the set is and dense in To do this, we fix and Then it suffices to find and such that
[TABLE]
where denotes the Fréchet distance in By Weierstrass approximation theorem we can assume that is a polynomial with Since there exists a strictly increasing sequence such that as We apply Lemma 3.5 for and We obtain a sequence of polynomial of the form which converges to uniformly on There exists such that for every the following inequality holds
[TABLE]
Observe that the linear Borel map is open. Hence the image of every -neighborhood of [math] in contains some -neighborhood of [math] in Moreover, by construction we have
[TABLE]
where denotes the valuation of the polynomial So the property (22) implies that the inequality holds for large enough. Therefore one can find a positive integer such that for there exists with and On the other hand, applying Proposition 3.7 for we find a function and a sufficiently large positive integer with such that
[TABLE]
Thus the function belongs to and satisfies inequality (21). Indeed we have
[TABLE]
[TABLE]
and
[TABLE]
Hence the set is and dense in Finally to prove that the set contains a dense vector subspace, except it suffices to write the analogue of Lemma 2.5 (which will be a corollary of Proposition 3.3) and to follow the proof of Theorem 2.6. ∎
Propositions 3.3 and 3.8 can be summarized as follows.
Theorem 3.9**.**
Let be a strictly increasing sequence of positive integers. The following assertions are equivalent
- (1)
* is non-empty,* 2. (2)
**
In addition, in the case the set is a and dense subset of and contains a dense vector subspace apart from
4. Further development and remark
The notion of doubly universal series has connection with that of topological multiple recurrence in dynamical systems. We refer the reader to [11, page 22]. Recently Costakis and Parissis proved that a frequently Cesàro hypercyclic bounded linear operator acting on an infinite dimensional separable Banach space over is topologically multiply recurrent [9]. The notion of Cesàro hypercyclicity for an operator was introduced in [14] and that of frequent Cesàro hypercyclicity in [10]. Let us introduce the set of frequent Cesàro universal series. For a power series denotes the sequence of Cesàro means of the partial sums of the Taylor expansion of at We know that the set of functions such that, for every compact set with connected and and for every function there exists an increasing sequence of positive integers such that as is a -subset of (see [15] or for instance [3]).
Definition 4.1**.**
A power series of radius of convergence is said to be a frequently Cesàro universal series if for every for every compact set with connected complement, and any function we have
[TABLE]
The lower and upper densities of a subset of are respectively defined as follows
[TABLE]
where as usual denotes the cardinality of the corresponding set.
According to a recent result we know that universal Taylor series cannot be frequently universal in the sense of Definition 4.1 where we replace the Cesàro operators by the partial sums [16]. We state a similar result for the Cesàro universal series .
Theorem 4.2**.**
The set of frequently Cesàro universal series is empty.
Proof.
Let be in According to [2, Corollary 4.4] is a universal Taylor series. Let be a compact set with connected complement and be a non-zero polynomial. Then Theorem 3.3 of [16] ensures that there exists a subsequence of positive integers with such that as According to Section 4 of [6] we have We end as in the proof of [16, Theorem 3.3]. Indeed define the subset of by
[TABLE]
where Thus there exists an integer large enough, such that, for every Let us consider the sequence Clearly So the inclusion implies
[TABLE]
But we have Thus cannot be a frequently Cesàro universal series. ∎
Therefore the sequence of operators given by Cesàro means of sequence of operators given by the partial sums of the Taylor development at [math] of functions of is not frequently universal even if the sequence of operators is doubly universal. Since the notion of doubly universality has connection with that of topological recurrence, we can compare this result with the main result of [9].
Remark 4.3**.**
- (1)
Theorem 4.2 remains true in the case of Fekete universal functions. To see this, it suffices to argue as in the proof of Theorem 4.2 taking into account the results of [17]. 2. (2)
The proof of Theorem 4.2 shows that all the elements of are 1-upper frequently Cesàro universal, i.e. for every compact set with connected complement, and any function there exists an increasing sequence of positive integers with such that as
Let be a strictly increasing sequence of positive integers with We end the paper with the following remark, which shows that one can find examples of doubly universal series with respect to the given sequence without additional hypothesis. For instance, let us define the set of sequences satisfying the following universal property: for every pair of real numbers there exists a subsequence of positive integers such that and as Then is a and dense subset of endowed with its natural topology defined in Section 3. In particular we have Indeed, let us consider
[TABLE]
for every where is an enumeration of Obviously we have the following description
[TABLE]
Since the sets are open, according to Baire’s category theorem it suffices to prove that is dense in for every Fix and We seek and such that Let us choose so that and It is easy to check that the sequence defined by for for and does the job.
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