Let ω be a Békollé-Bonami weight. We give a complete characterization of the positive measures μ such that ${\int }_{}|M_{\omega }{f\left(z\right)|}^{q}d\mu \left(z\right)\le C({\int }_{}{\left|f\left(z\right)\right|}^p{\omega \left(z\right)dV\left(z\right))}^{q/p}$ and $\mu \left(z\in :Mf\left(z\right)>\lambda \right)\le C/\left({\lambda }^q\right)({\int }_{}|f\left(z\right){{|}^p\omega \left(z\right)dV\left(z\right))}^{q/p}$, where $M_{\omega }$ is the weighted Hardy-Littlewood maximal function on the upper half-plane and 1 ≤ p,q <; ∞.

We define Beurling-Orlicz spaces, weak Beurling-Orlicz spaces, Herz-Orlicz spaces, weak Herz-Orlicz spaces, central Morrey-Orlicz spaces and weak central Morrey-Orlicz spaces. Moreover, the strong-type and weak-type estimates of the Hardy-Littlewood maximal function on these spaces are investigated.

The famous result of Muckenhoupt on the connection between weights w in Ap-classes and the boundedness of the maximal operator in Lp(w) is extended to the case p = ∞ by the introduction of the geometrical maximal operator. Estimates of the norm of the maximal operators are given in terms of the Ap-constants. The equality of two differently defined A∞-constants is proved. Thereby an answer is given to a question posed by R. Johnson. For non-increasing functions on the positive real line a parallel...

We show various $L^p$ estimates for Schrödinger operators $-\Delta +V$ on ${ℝ}^n$ and their square roots. We assume reverse Hölder estimates on the potential, and improve some results of Shen. Our main tools are improved Fefferman-Phong inequalities and reverse Hölder estimates for weak solutions of $-\Delta +V$ and their gradients.

The main aim of this paper is to prove that the maximal operator $\sigma ₀*:=supₙ|{\sigma }_{n,n}|$ of the Fejér means of the double Vilenkin-Fourier series is not bounded from the Hardy space $H_{1/2}$ to the space weak-$L_{1/2}$.

We consider the maximal regularity problem for the discrete time evolution equation $u_{n+1}-Tuₙ=fₙ$ for all n ∈ ℕ₀, u₀ = 0, where T is a bounded operator on a UMD space X. We characterize the discrete maximal regularity of T by two types of conditions: firstly by R-boundedness properties of the discrete time semigroup ${\left(Tⁿ\right)}_{n\in \mathbb{N}₀}$ and of the resolvent R(λ,T), secondly by the maximal regularity of the continuous time evolution equation u’(t) - Au(t) = f(t) for all t > 0, u(0) = 0, where A:= T - I. By recent results of...