Add to ORKGWe study a generalized spherical means operator, viz.\ generalized spherical mean Radon transform, acting on radial functions. As the main results, we find conditions for the associated maximal operator and its local variant to be bounded on power weighted Lebesgue spaces. This translates, in particular, into almost everywhere convergence to radial initial data results for solutions to certain Cauchy problems for classical Euler-Poisson-Darboux and wave equations. Moreover, our results shed some new light on the interesting and important question of optimality of the yet known $L^p$ boundedness results for the maximal operator in the general non-radial case. It appears that these could still be notably improved, as indicated by our c...
In dimensions n [greater than or equal to] 2 we obtain Lp1(Rn) x ... x Lpm(Rn) to Lp(Rn) boundedness...
We show that if f is locally in L log log L then the lacunary spherical means converge almost everyw...
The spherical maximal operator Af(x) = sup_(t>0) | Atf(x)| = sup_(t>0) ∣ ∫f(x−ty)dσ(y)∣ where σ is ...
We investigate a generalized spherical means operator, viz. generalized spherical mean Radon transf...
AbstractWe use simple one-dimensional operators to bound pointwise the spherical maximal operator ac...
We investigate a generalized spherical means operator, viz. generalized spherical mean Radon transf...
AbstractIn this paper we give a sufficient condition for radial weights ω such that the spherical su...
AbstractWe use simple one-dimensional operators to bound pointwise the spherical maximal operator ac...
AbstractIn this paper we study the maximal function associated to the Weyl transformW(μr) of the nor...
In this paper we study the regularity properties of certain maximal operators of convolution type at...
Weighted inequality on the Hardy-Littlewood maximal function is completely understood while it is no...
Let f∈Lp(Rd), d≥3, and let Atf(x) be the average of f over the sphere with radius t centered at x. F...
Improved $\ell^p$-Boundedness for Integral $k$-Spherical Maximal Functions, Discrete Analysis 2018:1...
Let f∈Lp(Rd), d≥3, and let Atf(x) be the average of f over the sphere with radius t centered at x. F...
Let f∈Lp(Rd), d≥3, and let Atf(x) be the average of f over the sphere with radius t centered at x. F...
In dimensions n [greater than or equal to] 2 we obtain Lp1(Rn) x ... x Lpm(Rn) to Lp(Rn) boundedness...
We show that if f is locally in L log log L then the lacunary spherical means converge almost everyw...
The spherical maximal operator Af(x) = sup_(t>0) | Atf(x)| = sup_(t>0) ∣ ∫f(x−ty)dσ(y)∣ where σ is ...
We investigate a generalized spherical means operator, viz. generalized spherical mean Radon transf...
AbstractWe use simple one-dimensional operators to bound pointwise the spherical maximal operator ac...
We investigate a generalized spherical means operator, viz. generalized spherical mean Radon transf...
AbstractIn this paper we give a sufficient condition for radial weights ω such that the spherical su...
AbstractWe use simple one-dimensional operators to bound pointwise the spherical maximal operator ac...
AbstractIn this paper we study the maximal function associated to the Weyl transformW(μr) of the nor...
In this paper we study the regularity properties of certain maximal operators of convolution type at...
Weighted inequality on the Hardy-Littlewood maximal function is completely understood while it is no...
Let f∈Lp(Rd), d≥3, and let Atf(x) be the average of f over the sphere with radius t centered at x. F...
Improved $\ell^p$-Boundedness for Integral $k$-Spherical Maximal Functions, Discrete Analysis 2018:1...
Let f∈Lp(Rd), d≥3, and let Atf(x) be the average of f over the sphere with radius t centered at x. F...
Let f∈Lp(Rd), d≥3, and let Atf(x) be the average of f over the sphere with radius t centered at x. F...
In dimensions n [greater than or equal to] 2 we obtain Lp1(Rn) x ... x Lpm(Rn) to Lp(Rn) boundedness...
We show that if f is locally in L log log L then the lacunary spherical means converge almost everyw...
The spherical maximal operator Af(x) = sup_(t>0) | Atf(x)| = sup_(t>0) ∣ ∫f(x−ty)dσ(y)∣ where σ is ...