Tauberian theorems for weighted mean statistical summability of double sequences of fuzzy numbers

We discuss Tauberian conditions under which the statistical convergence of double sequences of fuzzy numbers follows from the statistical convergence of their weighted means. We also prove some other results which are necessary to establish the main results

Necessary and sufficient conditions under which convergence follows from summability by weighted means

We prove necessary and sufficient Tauberian conditions for sequences summable by weighted mean methods. The main results of this paper apply to all weighted mean methods and unify the results known in the literature for particular methods. Among others, the conditions in our theorems are easy consequences of the slowly decreasing condition for real numbers, or slowly oscillating condition for complex numbers. Therefore, practically all classical (one-sided as well as two-sided) Tauberian conditions for weighted mean methods are corollaries of our two main theorems

A study of bounded operators on martingale Hardy spaces

The classical Fourier Analysis has been developed in an almost unbelievable way from the first fundamental discoveries by Fourier. Especially a number of wonderful results have been proved and new directions of such research has been developed e.g. concerning Wavelets Theory, Gabor Theory, Time-Frequency Analysis, Fast Fourier Transform, Abstract Harmonic Analysis, etc. One important reason for this is that this development is not only important for improving the "State of the art", but also for its importance in other areas of mathematics and also for several applications (e.g. theory of signal transmission, multiplexing, filtering, image enhancement, coding theory, digital signal processing and pattern recognition). The classical theory of Fourier series deals with decomposition of a function into sinusoidal waves. Unlike these continuous waves the Vilenkin (Walsh) functions are rectangular waves. The development of the theory of Vilenkin-Fourier series has been strongly influenced by the classical theory of trigonometric series. Because of this it is inevitable to compare results of Vilenkin series to those on trigonometric series. There are many similarities between these theories, but there exist differences also. Much of these can be explained by modern abstract harmonic analysis, which studies orthonormal systems from the point of view of the structure of a topological group. The aim of my thesis is to discuss, develop and apply the newest developments of this fascinating theory connected to modern harmonic analysis. In particular, we investigate some strong convergence result of partial sums of Vilenkin-Fourier series. Moreover, we derive necessary and sufficient conditions for the modulus of continuity so that norm convergence of subsequences of Fejér means is valid. Furthermore, we consider Riesz and Nörlund logarithmic means. It is also proved that these results are the best possible in a special sense. As applications both some well-known and new results are pointed out. In addition, we investigate some T means, which are "inverse" summability methods of Nörlund, but only in the case when their coefficients are monotone. The main body of the PhD thesis consists of seven papers (Papers A -- G). We now continue by describing the main content of each of the papers. In Paper A we investigate some new strong convergence theorems for partial sums with respect to Vilenkin system. In Paper B we characterize subsequences of Fejér means with respect to Vilenkin systems, which are bounded from the Hardy space Hp to the Lebesgue space Lp for all 0 < p < ½. We also proved that this result is in a sense sharp. In Paper C we find necessary and sufficient condition for the modulus of continuity for which subsequences of Fejér means with respect to Vilenkin systems are bounded from the Hardy space Hp to the Lebesgue space Lp for all 0 < p < ½. In Paper D we prove and discuss some new (Hp, weak-Lp) type inequalities of maximal operators of T means with respect to Vilenkin systems with monotone coefficients. We also apply these results to prove a.e. convergence of such T means. It is also proved that these results are the best possible in a special sense. As applications, both some well-known and new results are pointed out. In Paper E we prove and discuss some new (Hp, Lp) type inequalities of weighted maximal operators of T means with respect to the Vilenkin systems with monotone coefficients. We also show that these inequalities are the best possible in a special sense. Moreover, we apply these inequalities to prove strong convergence theorems of such T means. We also show that these results are the best possible in a special sense. As applications, both some well-known and new results are pointed out. In Paper F we derive a new strong convergence theorem of Riesz logarithmic means of the one-dimensional Vilenkin-Fourier (Walsh-Fourier) series. The corresponding inequality is pointed out and it is also proved that the inequality is in a sense sharp, at least for the case with Walsh-Fourier series. In Paper G we investigate (Hp, Lp) type inequalities for weighted maximal operators of Nörlund logaritmic means, for 0 < p < 1. Moreover, we apply these inequalities to prove strong convergence theorems of such Nörlund logaritmic means. These new results are put into a more general frame in an Introduction, where, in particular, a comparison with some new international research and broad view of such interplay between applied mathematics and engineering problems is presented and discussed

Wiener amalgams and summability of Fourier series

ome recent results on a general summability method, on the so-called µ-summability is summarized. New spaces, such as Wiener amalgams, Feichtinger’s algebra and modulation spaces are investigated in summability theory. Sufficient and necessary conditions are given for the norm and a.e. convergence of the µ-means. Key Words: Wiener amalgam spaces, Feichtinger’s algebra, homogeneous Banach spaces, Besov-, Sobolev-, fractional Sobolev spaces, modulation spaces, Herz spaces, Hardy-Littlewood maximal function, µ-summability of Fourier series, Lebesgue points. AMS Classification Number: Primary 42B08, 46E30, Secondary 42B30, 42A3