Weighted Lorentz norm inequalities for integral operators

Elida Ferreyra

Displaying similar documents to “Weighted Lorentz norm inequalities for integral operators”

Factorization and extrapolation of pairs of weights

Eugenio Hernández (1989)

Studia Mathematica

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Weighted inequalities for monotone and concave functions

Hans Heinig, Lech Maligranda (1995)

Studia Mathematica

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Characterizations of weight functions are given for which integral inequalities of monotone and concave functions are satisfied. The constants in these inequalities are sharp and in the case of concave functions, constitute weighted forms of Favard-Berwald inequalities on finite and infinite intervals. Related inequalities, some of Hardy type, are also given.

Weighted inequalities for the two-dimensional Hardy operator

E. Sawyer (1985)

Studia Mathematica

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Mapping properties of integral averaging operators

H. Heinig, G. Sinnamon (1998)

Studia Mathematica

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Characterizations are obtained for those pairs of weight functions u and v for which the operators $T f (x) = ʃ_{a (x)}^{b (x)} f (t) d t$ with a and b certain non-negative functions are bounded from $L_{u}^{p} (0, \infty)$ to $L_{v}^{q} (0, \infty)$ , 0 < p,q < ∞, p≥ 1. Sufficient conditions are given for T to be bounded on the cones of monotone functions. The results are applied to give a weighted inequality comparing differences and derivatives as well as a weight characterization for the Steklov operator.

Weighted inequalities through factorization.

Eugenio Hernández (1991)

Publicacions Matemàtiques

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In [4] P. Jones solved the question posed by B. Muckenhoupt in [7] concerning the factorization of A_p weights. We recall that a non-negative measurable function w on Rⁿ is in the class A_p, 1 < p < ∞ if and only if the Hardy-Littlewood maximal operator is bounded on L^p(Rⁿ, w). In what follows, L^p(X, w) denotes the class of all measurable functions f defined...

Weighted generalized weak type inequalities for modified Hardy operators.

Pedro Ortega Salvador (2000)

Collectanea Mathematica

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First and second order Opial inequalities

Steven Bloom (1997)

Studia Mathematica

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Let $T_{γ} f (x) = ʃ_{0}^{x} k {(x, y)}^{γ} f (y) d y$ , where k is a nonnegative kernel increasing in x, decreasing in y, and satisfying a triangle inequality. An nth-order Opial inequality has the form $ʃ_{0}^{\infty} (\prod_{i = 1}^{n} | T_{γ_{i}} {f (x) |}^{q_{i}} {|) | f (x) |}^{q_{0}} w (x) d x \leq C (ʃ_{0}^{\infty} {| f (x) |}^{p} {v (x) d x)}^{(q_{0} + \dots + q_{n}) / p}$ . Such inequalities can always be simplified to nth-order reduced inequalities, where the exponent $q_{0} = 0$ . When n = 1, the reduced inequality is a standard weighted norm inequality, and characterizing the weights is easy. We also find necessary and sufficient conditions on the weights for second-order reduced Opial inequalities to hold. ...

Boundedness of classical operators on classical Lorentz spaces

E. Sawyer (1990)

Studia Mathematica

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A sharp rearrangement inequality for the fractional maximal operator

A. Cianchi, R. Kerman, B. Opic, L. Pick (2000)

Studia Mathematica

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We prove a sharp pointwise estimate of the nonincreasing rearrangement of the fractional maximal function of ⨍, $M_{γ} ⨍$ , by an expression involving the nonincreasing rearrangement of ⨍. This estimate is used to obtain necessary and sufficient conditions for the boundedness of $M_{γ}$ between classical Lorentz spaces.

Two-weight mixed ф-inequalities for the one-sided maximal function

Qinsheng Lai (1995)

Studia Mathematica

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On weighted Hardy inequalities on semiaxis for functions vanishing at the endpoints.

Nasyrova, Masha, Stepanov, Vladimir (1997)

Journal of Inequalities and Applications [electronic only]

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