On a half-discrete reverse Mulholland-type inequality and an extension

Liu, Tuo; Yang, Bicheng; He, Leping

doi:10.1186/1029-242X-2014-103

On a half-discrete reverse Mulholland-type inequality and an extension

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Published: 04 March 2014

Volume 2014, article number 103, (2014)
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On a half-discrete reverse Mulholland-type inequality and an extension

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Tuo Liu¹,
Bicheng Yang² &
Leping He¹

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Abstract

By using the way of weight functions and the Hermite-Hadamard inequality, a half-discrete reverse Mulholland-type inequality with a best constant factor is given. The extension with multi-parameters, the equivalent forms as well as the relating homogeneous inequalities are also considered.

MSC:26D15.

A new half-discrete Mulholland-type inequality with multi-parameters

Article Open access 30 July 2015

On a more accurate reverse Mulholland-type inequality with parameters

Article Open access 04 July 2019

A reverse Mulholland-type inequality in the whole plane

Article Open access 10 April 2018

1 Introduction

Assuming that $f, g \in L^{2} (R_{+})$ , $∥ f ∥ = {\int_{0}^{\infty} f^{2} (x) d x}^{\frac{1}{2}} > 0$ , $∥ g ∥ > 0$ , we have the following Hilbert integral inequality (cf. [1]):

\int_{0}^{\infty} \int_{0}^{\infty} \frac{f (x) g (y)}{x + y} d x d y < π ∥ f ∥ ∥ g ∥,

(1)

where the constant factor π is best possible. If $a = {a_{n}}_{n = 1}^{\infty}, b = {b_{n}}_{n = 1}^{\infty} \in l^{2}$ , $∥ a ∥ = {\sum_{n = 1}^{\infty} a_{n}^{2}}^{\frac{1}{2}} > 0$ , $∥ b ∥ > 0$ , then we still have the following discrete Hilbert inequality:

\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} \frac{a_{m} b_{n}}{m + n} < π ∥ a ∥ ∥ b ∥,

(2)

with the same best constant factor π. Inequalities (1) and (2) are important in analysis and its applications (cf. [2–4]). Also we have the following Mulholland inequality with the same best constant factor π (cf. [1, 5]):

\sum_{m = 2}^{\infty} \sum_{n = 2}^{\infty} \frac{a_{m} b_{n}}{ln m n} < π {\sum_{m = 2}^{\infty} m a_{m}^{2} \sum_{n = 2}^{\infty} n b_{n}^{2}}^{\frac{1}{2}} .

(3)

In 1998, by introducing an independent parameter $λ \in (0, 1]$ , Yang [6] gave an extension of (1). For generalizing the results from [6], Yang [7] gave some best extensions of (1) and (2) as follows. If $p > 1$ , $\frac{1}{p} + \frac{1}{q} = 1$ , $λ_{1} + λ_{2} = λ$ , $k_{λ} (x, y)$ is a non-negative homogeneous function of degree −λ, $k (λ_{1}) = \int_{0}^{\infty} k_{λ} (t, 1) t^{λ_{1} - 1} d t \in R_{+}$ , $ϕ (x) = x^{p (1 - λ_{1}) - 1}$ , $ψ (x) = x^{q (1 - λ_{2}) - 1}$ , $f (\geq 0) \in L_{p, ϕ} (R_{+}) = {f | {∥ f ∥}_{p, ϕ} : = {\int_{0}^{\infty} ϕ (x) {| f (x) |}^{p} d x}^{\frac{1}{p}} < \infty}$ , $g (\geq 0) \in L_{q, ψ} (R_{+})$ , ${∥ f ∥}_{p, ϕ}, {∥ g ∥}_{q, ψ} > 0$ , then

\int_{0}^{\infty} \int_{0}^{\infty} k_{λ} (x, y) f (x) g (y) d x d y < k (λ_{1}) {∥ f ∥}_{p, ϕ} {∥ g ∥}_{q, ψ},

(4)

where the constant factor $k (λ_{1})$ is best possible. Moreover, if $k_{λ} (x, y)$ is finite and $k_{λ} (x, y) x^{λ_{1} - 1} (k_{λ} (x, y) y^{λ_{2} - 1})$ is strict decreasing for $x > 0$ ( $y > 0$ ), then for $a_{m,} b_{n} \geq 0$ , $a = {a_{m}}_{m = 1}^{\infty} \in l_{p, ϕ} = {a | {∥ a ∥}_{p, ϕ} : = {\sum_{n = 1}^{\infty} ϕ (n) {| a_{n} |}^{p}}^{\frac{1}{p}} < \infty}$ , $b = {b_{n}}_{n = 1}^{\infty} \in l_{q, ψ}$ , ${∥ a ∥}_{p, ϕ}, {∥ b ∥}_{q, ψ} > 0$ , we have

\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} k_{λ} (m, n) a_{m} b_{n} < k (λ_{1}) {∥ a ∥}_{p, ϕ} {∥ b ∥}_{q, ψ},

(5)

with the same best constant factor $k (λ_{1})$ . Clearly, for $p = q = 2$ , $λ = 1$ , $k_{1} (x, y) = \frac{1}{x + y}$ , $λ_{1} = λ_{2} = \frac{1}{2}$ , (4) reduces to (1), while (5) reduces to (2).

Some other results including the reverse Hilbert-type inequalities are provided by [8–16]. On half-discrete Hilbert-type inequalities with the non-homogeneous kernels, Hardy et al. provided a few results in Theorem 351 of [1]. But they did not prove that the constant factors in the inequalities are best possible. However, Yang [17] gave a result by introducing an interval variable and proved that the constant factor is best possible. Recently, Yang [18] gave a half-discrete Hilbert inequality with multi-parameters, and [19] gave the following half-discrete reverse Hilbert-type inequality with the best constant factor 4: For $0 < p < 1$ , $\frac{1}{p} + \frac{1}{q} = 1$ , we have $θ_{1} (x) \in (0, 1)$ , and

\begin{aligned} \int_{0}^{\infty} f (x) \sum_{n = 1}^{\infty} min {x, n} a_{n} d x \\ > 4 {\int_{0}^{\infty} \frac{1 - θ_{1} (x)}{x^{1 - \frac{3 p}{2}}} f^{p} (x) d x}^{\frac{1}{p}} {\sum_{n = 1}^{\infty} \frac{a_{n}^{q}}{n^{1 - \frac{3 q}{2}}}}^{\frac{1}{q}} . \end{aligned}

(6)

In this paper, by using the way of weight functions and the Hermite-Hadamard inequality, a half-discrete reverse Mulholland-type inequality similar to (6) is given as follows:

\begin{aligned} \int_{0}^{\infty} f (x) \sum_{n = 1}^{\infty} \frac{a_{n}}{ln e {(n + \frac{1}{2})}^{x}} d x \\ > π {\int_{0}^{\infty} \frac{1 - θ_{1} (x)}{x^{1 - \frac{p}{2}}} f^{p} (x) d x}^{\frac{1}{p}} {\sum_{n = 1}^{\infty} \frac{{(n + \frac{1}{2})}^{q - 1} a_{n}^{q}}{{ln}^{1 - \frac{q}{2}} (n + \frac{1}{2})}}^{\frac{1}{q}} . \end{aligned}

(7)

Moreover, a best extension of (7) with multi-parameters, the equivalent forms and the relating homogeneous inequalities are considered.

2 Some lemmas

Lemma 1 If $0 < λ \leq 2$ , $α \geq \frac{1}{2}$ , setting weight functions $ω (n)$ and $ϖ (x)$ as follows:

ω (n) : = {ln}^{\frac{λ}{2}} (n + α) \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} x^{\frac{λ}{2} - 1} d x, n \in N,

(8)

ϖ (x) : = x^{\frac{λ}{2}} \sum_{n = 1}^{\infty} \frac{{ln}^{\frac{λ}{2} - 1} (n + α)}{(n + α) {ln}^{λ} e {(n + α)}^{x}}, x \in (0, \infty),

(9)

we have

B (\frac{λ}{2}, \frac{λ}{2}) (1 - θ_{λ} (x)) < ϖ (x) < ω (n) = B (\frac{λ}{2}, \frac{λ}{2}),

(10)

where

θ_{λ} (x) = \frac{1}{B (\frac{λ}{2}, \frac{λ}{2})} \int_{0}^{x ln (1 + α)} \frac{t^{(λ / 2) - 1}}{{(1 + t)}^{λ}} d t \in (0, 1),

satisfying $θ_{λ} (x) = O (x^{\frac{λ}{2}})$ .

Proof Substituting of $t = x ln (n + α)$ in (8), by calculation, we have

ω (n) = \int_{0}^{\infty} \frac{1}{{(1 + t)}^{λ}} t^{\frac{λ}{2} - 1} d t = B (\frac{λ}{2}, \frac{λ}{2}) .

Since by the conditions and for fixed $x > 0$

h (x, y) : = \frac{{ln}^{\frac{λ}{2} - 1} (y + α)}{(y + α) {ln}^{λ} e {(y + α)}^{x}} = \frac{{ln}^{\frac{λ}{2} - 1} (y + α)}{(y + α) {[1 + x ln (y + α)]}^{λ}}

is strictly decreasing and strictly convex in $y \in (\frac{1}{2}, \infty)$ , then by the Hermite-Hadamard inequality (cf. [20]), we find

\begin{matrix} ϖ (x) < x^{\frac{λ}{2}} \int_{\frac{1}{2}}^{\infty} \frac{{ln}^{\frac{λ}{2} - 1} (y + α)}{(y + α) {[1 + x ln (y + α)]}^{λ}} d y \overset{t = x ln (y + α)}{=} \int_{x ln (\frac{1}{2} + α)}^{\infty} \frac{t^{\frac{λ}{2} - 1}}{{(1 + t)}^{λ}} d t \leq B (\frac{λ}{2}, \frac{λ}{2}), \\ \begin{aligned} ϖ (x) & > x^{\frac{λ}{2}} \int_{1}^{\infty} \frac{{ln}^{\frac{λ}{2} - 1} (y + α)}{(y + α) {[1 + x ln (y + α)]}^{λ}} d y \\ \overset{t = x ln (y + α)}{=} \int_{x ln (1 + α)}^{\infty} \frac{t^{\frac{λ}{2} - 1} d t}{{(1 + t)}^{λ}} = B (\frac{λ}{2}, \frac{λ}{2}) (1 - θ_{λ} (x)) > 0, \end{aligned} \\ \begin{array}{r} 0 < θ_{λ} (x) : = \frac{1}{B (\frac{λ}{2}, \frac{λ}{2})} \int_{0}^{x ln (1 + α)} \frac{t^{\frac{λ}{2} - 1}}{{(1 + t)}^{λ}} d t < \frac{1}{B (\frac{λ}{2}, \frac{λ}{2})} \int_{0}^{x ln (1 + α)} t^{\frac{λ}{2} - 1} d t = \frac{2 {[x ln (1 + α)]}^{\frac{λ}{2}}}{λ B (\frac{λ}{2}, \frac{λ}{2})}, \end{array} \end{matrix}

that is, (10) is valid. □

Lemma 2 Let the assumptions of Lemma 1 be fulfilled and, additionally, $0 < p < 1$ , $\frac{1}{p} + \frac{1}{q} = 1$ , $a_{n} \geq 0$ , $n \in N$ , $f (x)$ is a non-negative measurable function in $(0, \infty)$ . Then we have the following inequalities:

\begin{aligned} J & : = {\sum_{n = 1}^{\infty} \frac{{ln}^{\frac{p λ}{2} - 1} (n + α)}{n + α} {[\int_{0}^{\infty} \frac{f (x)}{{ln}^{λ} e {(n + α)}^{x}} d x]}^{p}}^{\frac{1}{p}} \\ \geq {[B (\frac{λ}{2}, \frac{λ}{2})]}^{\frac{1}{q}} {\int_{0}^{\infty} ϖ (x) x^{p (1 - \frac{λ}{2}) - 1} f^{p} (x) d x}^{\frac{1}{p}}, \end{aligned}

(11)

\begin{aligned} L_{1} & : = {\int_{0}^{\infty} \frac{x^{\frac{q λ}{2} - 1}}{{[ϖ (x)]}^{q - 1}} {[\sum_{n = 1}^{\infty} \frac{a_{n}}{{ln}^{λ} e {(n + α)}^{x}}]}^{q} d x}^{\frac{1}{q}} \\ \geq {B (\frac{λ}{2}, \frac{λ}{2}) \sum_{n = 1}^{\infty} {(n + α)}^{q - 1} {ln}^{q (1 - \frac{λ}{2}) - 1} (n + α) a_{n}^{q}}^{\frac{1}{q}} . \end{aligned}

(12)

Proof By the reverse Hölder inequality (cf. [20]) and (10), it follows that

\begin{aligned} {[\int_{0}^{\infty} \frac{f (x) d x}{{ln}^{λ} e {(n + α)}^{x}}]}^{p} \\ = {\int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} [\frac{x^{(1 - \frac{λ}{2}) / q}}{{ln}^{(1 - \frac{λ}{2}) / p} (n + α)} \frac{f (x)}{{(n + α)}^{\frac{1}{p}}}] \\ {\cdot [\frac{{ln}^{(1 - \frac{λ}{2}) / p} (n + α)}{x^{(1 - \frac{λ}{2}) / q}} {(n + α)}^{\frac{1}{p}}] d x}}^{p} \\ \geq \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} \frac{x^{(1 - \frac{λ}{2}) (p - 1)}}{(n + α) {ln}^{1 - \frac{λ}{2}} (n + α)} f^{p} (x) d x \\ \cdot {\int_{0}^{\infty} \frac{{(n + α)}^{q - 1}}{{ln}^{λ} e {(n + α)}^{x}} \frac{{ln}^{(1 - \frac{λ}{2}) (q - 1)} (n + α)}{x^{1 - \frac{λ}{2}}} d x}^{p - 1} \\ = {ω (n) {(n + α)}^{q - 1} {ln}^{q (1 - \frac{λ}{2}) - 1} (n + α)}^{p - 1} \\ \cdot \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} \frac{x^{(1 - \frac{λ}{2}) (p - 1)}}{(n + α) {ln}^{1 - \frac{λ}{2}} (n + α)} f^{p} (x) d x \\ = {[B (\frac{λ}{2}, \frac{λ}{2})]}^{p - 1} (n + α) {ln}^{1 - \frac{p λ}{2}} (n + α) \\ \cdot \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} \frac{x^{(1 - \frac{λ}{2}) (p - 1)}}{(n + α) {ln}^{1 - \frac{λ}{2}} (n + α)} f^{p} (x) d x . \end{aligned}

Then, by the Lebesgue term-by-term integration theorem (cf. [21]), we have

\begin{aligned} J & \geq {[B (\frac{λ}{2}, \frac{λ}{2})]}^{\frac{1}{q}} {\sum_{n = 1}^{\infty} \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} \frac{x^{(1 - \frac{λ}{2}) (p - 1)} f^{p} (x) d x}{(n + α) {ln}^{1 - \frac{λ}{2}} (n + α)}}^{\frac{1}{p}} \\ = {[B (\frac{λ}{2}, \frac{λ}{2})]}^{\frac{1}{q}} {\int_{0}^{\infty} \sum_{n = 1}^{\infty} \frac{x^{\frac{λ}{2}}}{{ln}^{λ} e {((n + α))}^{x}} \frac{x^{p (1 - \frac{λ}{2}) - 1} f^{p} (x) d x}{(n + α) {ln}^{1 - \frac{λ}{2}} (n + α)}}^{\frac{1}{p}} \\ = {[B (\frac{λ}{2}, \frac{λ}{2})]}^{\frac{1}{q}} {\int_{0}^{\infty} ϖ (x) x^{p (1 - \frac{λ}{2}) - 1} f^{p} (x) d x}^{\frac{1}{p}}, \end{aligned}

and (11) follows. Still, by the reverse Hölder inequality, we have

\begin{aligned} {[\sum_{n = 1}^{\infty} \frac{a_{n}}{{ln}^{λ} e {(n + α)}^{x}}]}^{q} \\ = {\sum_{n = 1}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} [\frac{x^{(1 - \frac{λ}{2}) / q}}{{ln}^{(1 - \frac{λ}{2}) / p} (n + α)} \cdot \frac{1}{{(n + α)}^{\frac{1}{p}}}] [\frac{{ln}^{(1 - \frac{λ}{2}) / p} (n + α)}{x^{(1 - \frac{λ}{2}) / q}} {(n + α)}^{\frac{1}{p}} a_{n}]}^{q} \\ \leq {\sum_{n = 1}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} \frac{x^{(1 - \frac{λ}{2}) (p - 1)}}{(n + α) {ln}^{1 - \frac{λ}{2}} (n + α)}}^{q - 1} \\ \cdot \sum_{n = 1}^{\infty} \frac{{(n + α)}^{q - 1}}{{ln}^{λ} e {(n + α)}^{x}} \frac{{ln}^{(1 - \frac{λ}{2}) (q - 1)} (n + α)}{x^{1 - \frac{λ}{2}}} a_{n}^{q} \\ = \frac{{[ϖ (x)]}^{q - 1}}{x^{\frac{q λ}{2} - 1}} \sum_{n = 1}^{\infty} \frac{{(n + α)}^{q - 1}}{{ln}^{λ} e {(n + α)}^{x}} x^{\frac{λ}{2} - 1} {ln}^{(1 - \frac{λ}{2}) (q - 1)} (n + α) a_{n}^{q} . \end{aligned}

Then, by the Lebesgue term-by-term integration theorem, we have

\begin{array}{l} L_{1} & \geq {\int_{0}^{\infty} \sum_{n = 1}^{\infty} \frac{{(n + α)}^{q - 1}}{{ln}^{λ} e {(n + α)}^{x}} x^{\frac{λ}{2} - 1} {ln}^{(1 - \frac{λ}{2}) (q - 1)} (n + α) a_{n}^{q} d x}^{\frac{1}{q}} \\ = {\sum_{n = 1}^{\infty} [{ln}^{\frac{λ}{2}} (n + α) \int_{0}^{\infty} \frac{x^{\frac{λ}{2} - 1} d x}{{ln}^{λ} e {(n + α)}^{x}}] {(n + α)}^{q - 1} {ln}^{q (1 - \frac{λ}{2}) - 1} (n + α) a_{n}^{q}}^{\frac{1}{q}} \\ = {\sum_{n = 1}^{\infty} ω (n) {(n + α)}^{q - 1} {ln}^{q (1 - \frac{λ}{2}) - 1} (n + α) a_{n}^{q}}^{\frac{1}{q}}, \end{array}

and then in view of (10), inequality (12) follows. □

3 Main results

In this paper, for $0 < p < 1$ ( $q < 0$ ), we still use the normal expressions ${∥ f ∥}_{p, Φ}$ and ${∥ a ∥}_{q, Ψ}$ . We also introduce two functions

\begin{matrix} Φ (x) : = (1 - θ_{λ} (x)) x^{p (1 - \frac{λ}{2}) - 1} (x > 0) and \\ Ψ (n) : = {(n + α)}^{q - 1} {ln}^{q (1 - \frac{λ}{2}) - 1} (n + α) (n \in N), \end{matrix}

wherefrom ${[Φ (x)]}^{1 - q} = {(1 - θ_{λ} (x))}^{1 - q} x^{\frac{q λ}{2} - 1}$ and ${[Ψ (n)]}^{1 - p} = \frac{{ln}^{\frac{p λ}{2} - 1} (n + α)}{n + α}$ .

Theorem 1 If $0 < λ \leq 2$ , $α \geq \frac{1}{2}$ , $0 < p < 1$ , $\frac{1}{p} + \frac{1}{q} = 1$ , $f (x), a_{n} \geq 0$ , $0 < {∥ f ∥}_{p, Φ} < \infty$ and $0 < {∥ a ∥}_{q, Ψ} < \infty$ , then we have the following equivalent inequalities:

\begin{aligned} I & : = \sum_{n = 1}^{\infty} a_{n} \int_{0}^{\infty} \frac{f (x)}{{ln}^{λ} e {(n + α)}^{x}} d x \\ = \int_{0}^{\infty} f (x) \sum_{n = 1}^{\infty} \frac{a_{n}}{{ln}^{λ} e {(n + α)}^{x}} d x > B (\frac{λ}{2}, \frac{λ}{2}) {∥ f ∥}_{p, Φ} {∥ a ∥}_{q, Ψ}, \end{aligned}

(13)

J = {\sum_{n = 1}^{\infty} {[Ψ (n)]}^{1 - p} {[\int_{0}^{\infty} \frac{f (x)}{{ln}^{λ} e {(n + α)}^{x}} d x]}^{p}}^{\frac{1}{p}} > B (\frac{λ}{2}, \frac{λ}{2}) {∥ f ∥}_{p, Φ},

(14)

L : = {\int_{0}^{\infty} {[Φ (x)]}^{1 - q} {[\sum_{n = 1}^{\infty} \frac{a_{n}}{{ln}^{λ} e {(n + α)}^{x}}]}^{q} d x}^{\frac{1}{q}} > B (\frac{λ}{2}, \frac{λ}{2}) {∥ a ∥}_{q, Ψ},

(15)

where the constant $B (\frac{λ}{2}, \frac{λ}{2})$ is best possible.

Proof By the Lebesgue term-by-term integration theorem, there are two expressions for I in (13). In view of (11), for $ϖ (x) > B (\frac{λ}{2}, \frac{λ}{2}) (1 - θ_{λ} (x))$ , we have (14). By the reverse Hölder inequality, we have

I = \sum_{n = 1}^{\infty} [Ψ^{\frac{- 1}{q}} (n) \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} f (x) d x] [Ψ^{\frac{1}{q}} (n) a_{n}] \geq J {∥ a ∥}_{q, Ψ} .

(16)

Then by (14) we have (13). On the other hand, assuming that (13) is valid, setting

a_{n} : = {[Ψ (n)]}^{1 - p} {[\int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} f (x) d x]}^{p - 1}, n \in N,

we obtain that $J^{p - 1} = {∥ a ∥}_{q, Ψ}$ . By (11), we find $J > 0$ . If $J = \infty$ , then (14) is trivially valid; if $J < \infty$ , then by (13) we have

\begin{matrix} {∥ a ∥}_{q, Ψ}^{q} = J^{p} = I > B (\frac{λ}{2}, \frac{λ}{2}) {∥ f ∥}_{p, Φ} {∥ a ∥}_{q, Ψ}, i.e., \\ {∥ a ∥}_{q, Ψ}^{q - 1} = J > B (\frac{λ}{2}, \frac{λ}{2}) {∥ f ∥}_{p, Φ}, \end{matrix}

that is, (14) is equivalent to (13). In view of (12), for

{[ϖ (x)]}^{1 - q} > {[B (\frac{λ}{2}, \frac{λ}{2}) (1 - θ_{λ} (x))]}^{1 - q},

we have (15). By the reverse Hölder inequality, we find

I = \int_{0}^{\infty} [Φ^{\frac{1}{p}} (x) f (x)] [Φ^{\frac{- 1}{p}} (x) \sum_{n = 1}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} a_{n}] d x \geq {∥ f ∥}_{p, Φ} L .

(17)

Then by (15) we have (13). On the other hand, assuming that (13) is valid, setting

f (x) : = {[Φ (x)]}^{1 - q} {[\sum_{n = 1}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} a_{n}]}^{q - 1}, x \in (0, \infty),

we obtain that $L^{q - 1} = {∥ f ∥}_{p, Φ}$ . By (12), we find $L > 0$ . If $L = \infty$ , then (15) is trivially valid; if $L < \infty$ , then by (13) we have

\begin{matrix} {∥ f ∥}_{p, Φ}^{p} = L^{q} = I > B (\frac{λ}{2}, \frac{λ}{2}) {∥ f ∥}_{p, Φ} {∥ a ∥}_{q, Ψ}, i.e., \\ {∥ f ∥}_{p, Φ}^{p - 1} = L > B (\frac{λ}{2}, \frac{λ}{2}) {∥ a ∥}_{q, Ψ}, \end{matrix}

that is, (15) is equivalent to (13). Hence, inequalities (13), (14) and (15) are equivalent.

For $0 < ε < \frac{p λ}{2}$ , set $\tilde{f} (x) = x^{\frac{λ}{2} + \frac{ε}{p} - 1}$ , $x \in (0, 1)$ ; $\tilde{f} (x) = 0$ , $x \in [1, \infty)$ , and

{\tilde{a}}_{n} = \frac{1}{n + α} {ln}^{\frac{λ}{2} - \frac{ε}{q} - 1} (n + α), n \in N .

If there exists a positive number k ( $\geq B (\frac{λ}{2}, \frac{λ}{2})$ ) such that (13) is valid when replacing $B (\frac{λ}{2}, \frac{λ}{2})$ with k, then, in particular, it follows that

\begin{aligned} \tilde{I} : = & \sum_{n = 1}^{\infty} \int_{0}^{\infty} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} {\tilde{a}}_{n} \tilde{f} (x) d x > k {∥ \tilde{f} ∥}_{p, Φ} {∥ \tilde{a} ∥}_{q, Ψ} \\ = & k {\int_{0}^{1} (1 - O (x^{\frac{λ}{2}})) \frac{d x}{x^{- ε + 1}}}^{\frac{1}{p}} {\frac{1}{(1 + α) {ln}^{ε + 1} (1 + α)} + \sum_{n = 2}^{\infty} \frac{1}{(n + α) {ln}^{ε + 1} (n + α)}}^{\frac{1}{q}} \\ > & k {\frac{1}{ε} - O (1)}^{\frac{1}{p}} {\frac{1}{(1 + α) {ln}^{ε + 1} (1 + α)} + \int_{1}^{\infty} \frac{d x}{(x + α) {ln}^{ε + 1} (x + α)}}^{\frac{1}{q}} \\ = & \frac{k}{ε} {1 - ε O (1)}^{\frac{1}{p}} {\frac{ε}{(1 + α) {ln}^{ε + 1} (1 + α)} + \frac{1}{{ln}^{ε} (1 + α)}}^{\frac{1}{q}}, \end{aligned}

(18)

\begin{aligned} \tilde{I} & = \sum_{n = 1}^{\infty} \frac{1}{n + α} {ln}^{\frac{λ}{2} - \frac{ε}{q} - 1} (n + α) \int_{0}^{1} \frac{1}{{ln}^{λ} e {(n + α)}^{x}} x^{\frac{λ}{2} + \frac{ε}{p} - 1} d x \\ \overset{t = x ln (n + α)}{=} \sum_{n = 1}^{\infty} \frac{1}{(n + α) {ln}^{ε + 1} (n + α)} \int_{0}^{ln (n + α)} \frac{1}{{(t + 1)}^{λ}} t^{\frac{λ}{2} + \frac{ε}{p} - 1} d t \\ \leq B (\frac{λ}{2} + \frac{ε}{p}, \frac{λ}{2} - \frac{ε}{p}) [\frac{1}{(1 + α) {ln}^{ε + 1} (1 + α)} + \sum_{n = 2}^{\infty} \frac{1}{(n + α) {ln}^{ε + 1} (n + α)}] \\ < B (\frac{λ}{2} + \frac{ε}{p}, \frac{λ}{2} - \frac{ε}{p}) [\frac{1}{(1 + α) {ln}^{ε + 1} (1 + α)} + \int_{1}^{\infty} \frac{1}{(y + α) {ln}^{ε + 1} (y + α)} d y] \\ = \frac{1}{ε} B (\frac{λ}{2} + \frac{ε}{p}, \frac{λ}{2} - \frac{ε}{p}) [\frac{ε}{(1 + α) {ln}^{ε + 1} (1 + α)} + \frac{1}{{ln}^{ε} (1 + α)}] . \end{aligned}

(19)

Hence by (18) and (19) it follows that

\begin{aligned} B (\frac{λ}{2} + \frac{ε}{p}, \frac{λ}{2} - \frac{ε}{p}) [\frac{ε}{(1 + α) {ln}^{ε + 1} (1 + α)} + \frac{1}{{ln}^{ε} (1 + α)}] \\ > k {1 - ε O (1)}^{\frac{1}{p}} {\frac{ε}{(1 + α) {ln}^{ε + 1} (1 + α)} + \frac{1}{{ln}^{ε} (1 + α)}}^{\frac{1}{q}}, \end{aligned}

and $B (\frac{λ}{2}, \frac{λ}{2}) \geq k (ε \to 0^{+})$ . Hence $k = B (\frac{λ}{2}, \frac{λ}{2})$ is the best value of (13).

By the equivalence, the constant factor $B (\frac{λ}{2}, \frac{λ}{2})$ in (14) and (15) is best possible. Otherwise we would reach a contradiction by (16) and (17) that the constant factor in (13) is not best possible. □

Remark 1 (i) For $λ = 1$ , $λ_{1} = λ_{2} = \frac{1}{2}$ , $α = \frac{1}{2}$ in (13), (14) and (15), we have (7) and the following equivalent inequalities:

\begin{aligned} \sum_{n = 1}^{\infty} \frac{{ln}^{\frac{p}{2} - 1} (n + \frac{1}{2})}{n + \frac{1}{2}} {[\int_{0}^{\infty} \frac{f (x)}{ln e {(n + \frac{1}{2})}^{x}} d x]}^{p} \\ > π^{p} \int_{0}^{\infty} \frac{1 - θ_{1} (x)}{x^{1 - \frac{p}{2}}} f^{p} (x) d x, \end{aligned}

(20)

\begin{aligned} \int_{0}^{\infty} \frac{{(1 - θ_{1} (x))}^{1 - q}}{x^{1 - \frac{q}{2}}} {[\sum_{n = 1}^{\infty} \frac{a_{n}}{ln e {(n + \frac{1}{2})}^{x}}]}^{q} d x \\ < π^{q} \sum_{n = 1}^{\infty} \frac{{(n + \frac{1}{2})}^{q - 1}}{{ln}^{1 - \frac{q}{2}} (n + \frac{1}{2})} a_{n}^{q} . \end{aligned}

(21)

(ii) Setting $x = \frac{1}{ln y}$ , $g (y) : = \frac{1}{y} {(ln y)}^{λ - 2} f (\frac{1}{ln y})$ and

ϕ (y) : = (1 - θ_{λ} (\frac{1}{ln y})) y^{p - 1} {(ln y)}^{p (1 - \frac{λ}{2}) - 1} (y \in (1, \infty))

in (13), by simplifications, we find the following inequality with the homogeneous kernel:

\begin{aligned} \sum_{n = 1}^{\infty} a_{n} \int_{1}^{\infty} \frac{g (y)}{{ln}^{λ} y (n + α)} d y \\ = \int_{1}^{\infty} g (y) \sum_{n = 1}^{\infty} \frac{a_{n}}{{ln}^{λ} y (n + α)} d x > B (\frac{λ}{2}, \frac{λ}{2}) {∥ g ∥}_{p, ϕ} {∥ a ∥}_{q, Ψ} . \end{aligned}

(22)

It is evident that (22) is equivalent to (13), and then the constant factor $B (\frac{λ}{2}, \frac{λ}{2})$ in (22) is still best possible. In the same way as in (14) and (15), we have the following inequalities equivalent to (13) with the best constant factor $B (\frac{λ}{2}, \frac{λ}{2})$ :

{\sum_{n = 1}^{\infty} {[Ψ (n)]}^{1 - p} {[\int_{1}^{\infty} \frac{g (y)}{{ln}^{λ} y (n + α)} d y]}^{p}}^{\frac{1}{p}} > B (\frac{λ}{2}, \frac{λ}{2}) {∥ g ∥}_{p, ϕ},

(23)

{\int_{1}^{\infty} {[ϕ (y)]}^{1 - q} {[\sum_{n = 1}^{\infty} \frac{a_{n}}{{ln}^{λ} y (n + α)}]}^{q} d y}^{\frac{1}{q}} > B (\frac{λ}{2}, \frac{λ}{2}) {∥ a ∥}_{q, Ψ} .

(24)

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Acknowledgements

This work is supported by the National Natural Science Foundation of China (No. 61370186).

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College of Mathematics and Statistics, Jishou University, Hunan, Jishou, 416000, P.R. China
Tuo Liu & Leping He
Department of Mathematics, Guangdong University of Education, Guangzhou, Guangdong, 510303, P.R. China
Bicheng Yang

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Tuo Liu
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TL participated in the design of the study and performed the numerical analysis. BY carried out the mathematical studies, participated in the sequence alignment and drafted the manuscript. LH conceived of the study, and participated in its design and coordination. All authors read and approved the final manuscript.

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Liu, T., Yang, B. & He, L. On a half-discrete reverse Mulholland-type inequality and an extension. J Inequal Appl 2014, 103 (2014). https://doi.org/10.1186/1029-242X-2014-103

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Received: 19 November 2013
Accepted: 06 February 2014
Published: 04 March 2014
DOI: https://doi.org/10.1186/1029-242X-2014-103

On a half-discrete reverse Mulholland-type inequality and an extension

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On a half-discrete reverse Mulholland-type inequality and an extension

Abstract

Similar content being viewed by others

A new half-discrete Mulholland-type inequality with multi-parameters

On a more accurate reverse Mulholland-type inequality with parameters

A reverse Mulholland-type inequality in the whole plane

1 Introduction

2 Some lemmas

3 Main results

References

Acknowledgements

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