A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms

Yang, Bicheng; Wu, Shanhe; Wang, Aizhen

doi:10.3390/sym12030342

Open AccessArticle

A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms

by

Bicheng Yang

¹,

Shanhe Wu

^2,*

and

Aizhen Wang

³

¹

Institute of Applied Mathematics, Longyan University, Longyan 364012, Fujian, China

²

Department of Mathematics, Longyan University, Longyan 364012, Fujian, China

³

Department of Mathematics, Guangdong University of Education, Guangzhou 510303, Guangdong, China

^*

Author to whom correspondence should be addressed.

Symmetry 2020, 12(3), 342; https://doi.org/10.3390/sym12030342

Submission received: 1 February 2020 / Revised: 19 February 2020 / Accepted: 24 February 2020 / Published: 28 February 2020

(This article belongs to the Special Issue Advance in Nonlinear Analysis and Optimization)

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Abstract

:

We establish a new inequality of Hilbert-type containing positive homogeneous kernel

{(\min {m, n})}^{λ}

and derive its equivalent forms. Based on the obtained Hilbert-type inequality, we discuss its equivalent forms and give the operator expressions in some particular cases.

Keywords:

Hilbert-type inequality; homogeneous kernel; equivalent statement; operator expression; Euler–Maclaurin summation formula

MSC:

26D15; 26D10; 26A42

1. Introduction

If

a_{m} \geq 0, b_{n} \geq 0, 0 < \sum_{m = 1}^{\infty} a_{m}^{2} < \infty a n d 0 < \sum_{n = 1}^{\infty} b_{n}^{2} < \infty,

then

\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} \frac{a_{m} b_{n}}{m + n} < π {(\sum_{m = 1}^{\infty} a_{m}^{2})}^{\frac{1}{2}} {(\sum_{n = 1}^{\infty} b_{n}^{2})}^{\frac{1}{2}},

(1)

where the constant factor

π

is the best possible. Inequality (1) is the celebrated Hilbert’s inequality (see [1]). Inequality (1) was generalized by Hardy as follows:

If

p > 1, \frac{1}{p} + \frac{1}{q} = 1, a_{m}, b_{n} \geq 0, 0 < \sum_{m = 1}^{\infty} a_{m}^{p} < \infty a n d 0 < \sum_{n = 1}^{\infty} b_{n}^{q} < \infty,

then

\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} \frac{a_{m} b_{n}}{m + n} < \frac{π}{\sin (π / p)} {(\sum_{m = 1}^{\infty} a_{m}^{p})}^{\frac{1}{p}} {(\sum_{n = 1}^{\infty} b_{n}^{q})}^{\frac{1}{q}}

(2)

where the constant factor

\frac{π}{\sin (π / p)}

is the best possible. Inequality (2) is called Hardy–Hilbert’s inequality (c.f. [1], Theorem 315).

The following analogue of Hardy–Hilbert’s inequality

\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} \frac{a_{m} b_{n}}{\max {m, n}} < p q {(\sum_{m = 1}^{\infty} a_{m}^{p})}^{\frac{1}{p}} {(\sum_{n = 1}^{\infty} b_{n}^{q})}^{\frac{1}{q}}

(3)

is known in the literature as Hardy–Littlewood–Polya’s inequality, and the constant factor

p q

in (3) is the best possible (c.f. [1], Theorem 341).

In 2006, Krnić and Pečarić [2] presented an extension of inequality (1) by introducing parameters

λ_{1}

and

λ_{2}

as follows:

\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} \frac{a_{m} b_{n}}{{(m + n)}^{λ}} < B (λ_{1}, λ_{2}) {[\sum_{m = 1}^{\infty} m^{p (1 - λ_{1}) - 1} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 - λ_{2}) - 1} b_{n}^{q}]}^{\frac{1}{q}}

(4)

where

λ_{i} \in (0, 2] (i = 1, 2), λ_{1} + λ_{2} = λ \in (0, 4],

B (u, v) = \int_{0}^{\infty} \frac{t^{u - 1}}{{(1 + t)}^{u + v}} d t (u, v > 0)

is the beta function, in (4) the constant factor

B (λ_{1}, λ_{2})

is the best possible.

For

λ = 1, λ_{1} = \frac{1}{q}, λ_{2} = \frac{1}{p},

inequality (4) reduces to inequality (2); for

p = q = 2,

λ_{1} = λ_{2} = \frac{λ}{2},

inequality (4) reduces to Yang’s inequality given in [3]. It is well known that inequalities (1–3) and their integral analogues play an important role in analysis and its applications (see [4,5,6,7,8,9,10,11,12,13,14]).

Recently, by applying inequality (3), Adiyasuren, Batbold and Azar [15] gave a new Hilber-type inequality with the kernel

\frac{1}{{(m + n)}^{λ}}

and partial sums.

In 2016, Hong and Wen [16] studied the equivalent statements of the extended inequalities (1) and (2), and estimated the best possible constant factor for several parameters.

The results proposed in [2,15,16] have greatly attracted our interest. In 2019, Yang, Wu and Wang [17] established the following Hardy–Hilbert-type inequality and discussed its equivalent forms

\begin{matrix} \int_{0}^{\infty} \sum_{n = 1}^{\infty} \frac{f (x) a_{n}}{{(x + n)}^{λ}} d x > B^{\frac{1}{p}} (σ, λ - σ) B^{\frac{1}{q}} (μ, λ - μ) \\ \times {\int_{0}^{\infty} (1 - ρ_{σ} (x)) x^{p [1 - (\frac{λ - σ}{p} + \frac{μ}{q})] - 1} f^{p} (x) d x}^{\frac{1}{p}} {\sum_{n = 1}^{\infty} n^{q [1 - (\frac{σ}{p} + \frac{λ - μ}{q})] - 1} a_{n}^{q}}^{\frac{1}{q}}, \end{matrix}

(5)

where

0 < p < 1, \frac{1}{p} + \frac{1}{q} = 1, λ \in (0, 5], σ \in (0, 2] \cap (0, λ), μ \in (0, λ),

ρ_{σ} (x) = \frac{{(1 + θ_{x})}^{- λ}}{σ B (σ, λ - σ)} \frac{1}{x^{σ}} = O (\frac{1}{x^{σ}}) \in {(0, 1)}^{} (θ_{x} \in (0, \frac{1}{x}); x > 0),

f (x) \geq 0, x \in (0, \infty), a_{n} \geq 0

In a recent paper [18], Yang, Wu and Liao gave an extension of Hardy–Hilbert’s inequality for

k_{λ} (λ_{i}) = {\frac{π}{λ \sin (π λ_{i} / λ)}}^{} (i = 1, 2),

as follows:

\begin{matrix} \sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} \frac{a_{m} b_{n}}{m^{λ} + n^{λ}} < k_{λ}^{\frac{1}{p}} (λ_{2}) k_{λ}^{\frac{1}{q}} (λ_{1}) \\ \times {\sum_{m = 1}^{\infty} m^{p [1 - (\frac{λ - λ_{2}}{p} + \frac{λ_{1}}{q})] - 1} a_{m}^{p}}^{\frac{1}{p}} {\sum_{n = 1}^{\infty} n^{q [1 - (\frac{λ_{2}}{p} + \frac{λ - λ_{1}}{q})] - 1} b_{n}^{q}}^{\frac{1}{q}}, \end{matrix}

(6)

where

p > 1,

\frac{1}{p} + \frac{1}{q} = 1

,

λ \in (0, \frac{5}{2}]

,

λ_{i} \in (0, \frac{5}{4}]

\cap (0, λ)

(i = 1, 2)

a_{m}, b_{n} \geq 0

.

For more results related to the extensions of inequalities (1) and (2) and their equivalent statements, we refer the reader to [19,20,21,22,23,24] and references cited therein.

Motivated by the ideas of [2] and [16], in the present paper we deal with a new Hilbert-type inequality containing positive homogeneous kernel

{(\min {m, n})}^{λ}

and deduce its equivalent forms. Furthermore, we discuss the equivalent statements relating to the best possible constant factor, based on the obtained Hilbert-type inequality.

2. Some Lemmas

In what follows, we suppose that

p > 1, \frac{1}{p} + \frac{1}{q} = 1,

λ \in (0, \frac{34}{11}],

λ_{i} \in (0, \frac{11}{8}]

\cap (0, λ)

(i = 1, 2)

,

a_{m}, b_{n} \geq 0

(m, n \in N = {1, 2, \dots})

such that

0 < \sum_{m = 1}^{\infty} m^{p (1 + \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} a_{m}^{p} < \infty a n d 0 < \sum_{n = 1}^{\infty} n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q} < \infty .

Lemma 1.

Define the weight coefficient with positive homogeneous kernel

ϖ_{λ} (λ_{1}, m) : = \frac{1}{m^{λ_{1}}} {\sum_{n = 1}^{\infty} \frac{{(\min {m, n})}^{λ}}{n^{λ - λ_{1} + 1}}}^{} (m \in N)

Then, we have the following inequalities

k_{λ} (λ_{1}) (1 - \frac{λ - λ_{1}}{λ m^{λ_{1}}}) < ϖ_{λ} (λ_{1}, m) < k_{λ} (λ_{1}) : = {\frac{λ}{λ_{1} (λ - λ_{1})}}^{} (m \in N)

(7)

Proof.

For fixed

m \in N

, we define a function

g_{m} (t) : = \frac{{(\min {m, t})}^{λ}}{t^{λ - λ_{1} + 1}} (t > 0)

, and obtain

g_{m} (t) = {\begin{matrix} t^{λ_{1} - 1}, 0 < t < m, \\ \frac{m^{λ}}{t^{λ - λ_{1} + 1}}, t \geq m \end{matrix}, {g^{'}}_{m} (t) = {\begin{matrix} (λ_{1} - 1) t^{λ_{1} - 2}, 0 < t < m, \\ - (λ - λ_{1} + 1) \frac{m^{λ}}{t^{λ - λ_{1} + 2}}, t > m \end{matrix},

g_{m} (1) = 1

, and

\int_{0}^{1} g_{m} (t) d t = \int_{0}^{1} \frac{t^{λ}}{t^{λ - λ_{1} + 1}} d t = \frac{1}{λ_{1}} .

To prove the inequalities in (7), we consider two cases below:

(i) For

λ_{1} \in (0, 1] \cap (0, λ),

it is easy to observe that

g_{m} (t)

is decreasing in

(0, \infty)

, and strictly decreasing in

[m, \infty)

. By following the decreasing property of the series, we find

ϖ_{λ} (λ_{1}, m) < \frac{1}{m^{λ_{1}}} \int_{0}^{\infty} \frac{{(\min {m, t})}^{λ} d t}{t^{λ - λ_{1} + 1}} = \frac{1}{m^{λ_{1}}} [\int_{0}^{m} \frac{t^{λ} d t}{t^{λ - λ_{1} + 1}} + \int_{m}^{\infty} \frac{m^{λ} d t}{t^{λ - λ_{1} + 1}}] = k_{λ} (λ_{1}),

\begin{array}{l} ϖ_{λ} (λ_{1}, m) & > \frac{1}{m^{λ_{1}}} \int_{1}^{\infty} \frac{{(\min {m, t})}^{λ} d t}{t^{λ - λ_{1} + 1}} = \frac{1}{m^{λ_{1}}} \int_{0}^{\infty} \frac{{(\min {m, t})}^{λ} d t}{t^{λ - λ_{1} + 1}} - \frac{1}{m^{λ_{1}}} \int_{0}^{1} \frac{t^{λ} d t}{t^{λ - λ_{1} + 1}} \\ = k_{λ} (λ_{1}) - \frac{1}{λ_{1} m^{λ_{1}}} = k_{λ} (λ_{1}) (1 - \frac{λ - λ_{1}}{λ m^{λ_{1}}}), \end{array}

which implies the required inequalities in (7).

(ii) For

λ_{1} \in (1, \frac{11}{8}] \cap (0, λ)

, by using the Euler–Maclaurin summation formula (c.f. [2,3]) with the Bernoulli function of 1-order

ρ (t) : = t - [t] - \frac{1}{2},

we obtain

\begin{array}{l} \sum_{n = 2}^{m} g_{m} (n) & = \int_{1}^{m} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{1}^{m} + \int_{1}^{m} ρ (t) {g^{'}}_{m} (t) d t \\ = \int_{1}^{m} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{1}^{m} + (λ_{1} - 1) \int_{1}^{m} ρ (t) t^{λ_{1} - 2} d t \\ = \int_{1}^{m} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{1}^{m} + (λ_{1} - 1) \frac{\tilde{ε}}{12} t^{λ_{1} - 2} |_{1}^{m} \\ \leq \int_{1}^{m} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{1}^{m} (1 < λ_{1} < 2, 0 < \tilde{ε} < 1), \end{array}

\begin{array}{l} \sum_{n = m + 1}^{\infty} g_{m} (n) & = \int_{m}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{m}^{\infty} + \int_{m}^{\infty} ρ_{1} (t) {g^{'}}_{m} (t) d t \\ = \int_{m}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{m}^{\infty} + \frac{λ_{1} - λ - 1}{12} m^{λ} ε_{1} t^{λ_{1} - λ - 2} |_{m}^{\infty} \\ < \int_{m}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{m}^{\infty} + {\frac{λ - λ_{1} + 1}{12 m^{2 - λ_{1}}}}^{} (λ_{1} < λ, 0 < ε_{1} < 1), \end{array}

and then one has

\begin{array}{l} \sum_{n = 1}^{\infty} g_{m} (n) & < \int_{1}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (1) + \frac{λ - λ_{1} + 1}{12 m^{2 - λ_{1}}} \\ = \int_{0}^{\infty} g_{m} (t) d t - h_{m} (λ, λ_{1}), \end{array}

where

h (λ_{1}) : = 12 - (7 + λ) λ_{1} + λ_{1}^{2}

and

\begin{matrix} h_{m} (λ, λ_{1}) : = \int_{0}^{1} g_{m} (t) d t - \frac{1}{2} g_{m} (1) - \frac{λ - λ_{1} + 1}{12 m^{2 - λ_{1}}} = \frac{1}{λ_{1}} - \frac{1}{2} - \frac{λ - λ_{1} + 1}{12 m^{2 - λ_{1}}} \geq \frac{1}{λ_{1}} - \frac{1}{2} - \frac{λ - λ_{1} + 1}{12} \\ = \frac{h (λ_{1})}{12 λ_{1}} . \end{matrix}

Since

h^{'} (λ_{1}) = - (7 + λ) + 2 λ_{1}^{} < 0^{} (λ_{1} \in (1, \frac{11}{8}], λ \in (0, \frac{34}{11}])

, it follows that

h_{m} (λ, λ_{1}) > \frac{h (λ_{1})}{12 λ_{1}} \geq \frac{12 - (7 + λ) \times (\frac{11}{8}) + {(\frac{11}{8})}^{2}}{12 λ_{1}} = \frac{273 - 88 λ}{768 λ_{1}} > 0^{} (λ \in (0, \frac{34}{11}])

Thus, we get

ϖ_{λ} (λ_{1}, m) = \frac{1}{m^{λ_{1}}} \sum_{n = 1}^{\infty} g_{m} (n) < \frac{1}{m^{λ_{1}}} \int_{0}^{\infty} g_{m} (t) d t = k_{λ} (λ_{1}) = \frac{λ}{λ_{1} (λ - λ_{1})} .

On the other hand, we have

\begin{array}{l} \sum_{n = 2}^{m} g_{m} (n) & = \int_{1}^{m} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{1}^{m} + (λ_{1} - 1) \frac{\tilde{ε}}{12} t^{λ_{1} - 2} |_{1}^{m} \\ \geq \int_{1}^{m} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{1}^{m} + \frac{λ_{1} - 1}{12} (m^{λ_{1} - 2} - 1), \end{array}

\begin{array}{l} \sum_{n = m + 1}^{\infty} g_{m} (n) & = \int_{m}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{m}^{\infty} + \frac{λ_{1} - λ - 1}{12} m^{λ} ε_{1} t^{λ_{1} - λ - 2} |_{m}^{\infty} \\ > \int_{m}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (t) |_{m}^{\infty}, \end{array}

and then by

\frac{1}{2} - \frac{λ_{1} - 1}{12} > \frac{1}{2} - \frac{1}{12} > 0^{} (λ_{1} < 2)

, we find

\begin{array}{l} \sum_{n = 1}^{\infty} g_{m} (n) & > \int_{1}^{\infty} g_{m} (t) d t + \frac{1}{2} g_{m} (1) + \frac{λ_{1} - 1}{12} (m^{λ_{1} - 2} - 1) \\ > \int_{1}^{\infty} g_{m} (t) d t + (\frac{1}{2} - \frac{λ_{1} - 1}{12}) > \int_{0}^{\infty} g_{m} (t) d t - \int_{0}^{1} g_{m} (t) d t . \end{array}

Hence, from the expression

g_{m} (t)

we deduce the inequalities in (7). The proof of Lemma 1 is thus complete. □

Next, we shall establish a new inequality of Hilbert type for positive homogeneous kernel.

Lemma 2.

The following Hilbert-type inequality holds true:

\begin{matrix} I = \sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m} b_{n} < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) \\ \times {[\sum_{m = 1}^{\infty} m^{p (1 + \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q}]}^{\frac{1}{q}} \end{matrix}

(8)

Proof.

Following the pattern in which the proof of Lemma 1 was obtained, for

n \in

N,

λ \in (0, \frac{34}{11}],

λ_{2} \in (0, \frac{11}{8}]

\cap (0, λ)

, we have the following inequality:

k_{λ} (λ_{2}) (1 - \frac{λ - λ_{2}}{λ n^{λ_{2}}}) < ω (λ_{2}, n) : = \frac{1}{n^{λ_{2}}} \sum_{m = 1}^{\infty} \frac{{(\min {m, n})}^{λ}}{m^{λ - λ_{2} + 1}} < k_{λ} (λ_{2}) .

(9)

Using the Hölder’s inequality (see [25]), we obtain

\begin{matrix} \begin{matrix} I & = \sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} [\frac{m^{(λ - λ_{2} + 1) / q}}{n^{(λ - λ_{1} + 1) / p}} a_{m}] [\frac{n^{(λ - λ_{1} + 1) / p}}{m^{(λ - λ_{2} + 1) / q}} b_{n}] \\ \leq {[\sum_{m = 1}^{\infty} \sum_{n = 1}^{\infty} {(\min {m, n})}^{λ} \frac{m^{(λ - λ_{2} + 1) (p - 1)}}{n^{λ - λ_{1} + 1}} a_{m}^{p}]}^{\frac{1}{p}} \end{matrix} \\ \times {[\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} \frac{n^{(λ - λ_{1} + 1) (q - 1)}}{m^{λ - λ_{2} + 1}} b_{n}^{q}]}^{\frac{1}{q}} \\ = {[\sum_{m = 1}^{\infty} ϖ (λ_{1}, m) m^{p (1 + \frac{λ {}_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} ω (λ {}_{2}, n) n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q}]}^{\frac{1}{q}} . \end{matrix}

Hence, by using the inequalities in (7) and (9), we derive inequality (8). This completes the proof of Lemma 2. □

As a consequence of Lemma 2, we can deduce the following Hilbert-type inequality for the positive homogeneous kernel.

Remark 1.

By inequality (8), for

λ_{1} + λ_{2} = λ \in (0, \frac{11}{4}] (\subset (0, \frac{34}{11}])

,

λ_{i} \in (0, \frac{11}{8}]

\cap {(0, λ)}^{} (i = 1, 2)

we obtain

0 < \sum_{m = 1}^{\infty} m^{p (1 + λ_{1}) - 1} a_{m}^{p} < \infty, 0 < \sum_{n = 1}^{\infty} n^{q (1 + λ_{2}) - 1} b_{n}^{q} < \infty

and the following inequality:

\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m} b_{n} < \frac{λ}{λ_{1} λ_{2}} {[\sum_{m = 1}^{\infty} m^{p (1 + λ_{1}) - 1} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 + λ_{2}) - 1} b_{n}^{q}]}^{\frac{1}{q}}

(10)

In Lemma 3 below, we show that the constant factor given in (10) is the best possible.

Lemma 3.

For

λ_{1} + λ_{2} = λ \in (0, \frac{11}{4}], λ_{i} \subset (0, \frac{11}{8}] \cap {(0, λ)}^{}

(i = 1, 2)

, the constant factor

\frac{λ}{λ_{1} λ_{2}}

in (10) is the best possible.

Proof.

For any

0 < ε < q λ_{1}

, we set

{\tilde{a}}_{m} : = m^{- λ_{1} - \frac{ε}{p} - 1}, {\tilde{b}}_{n} : = n^{- λ_{2} - \frac{ε}{q} - 1}^{} (m, n \in N)

If there exists a constant

M \leq

\frac{λ}{λ_{1} λ_{2}}

such that (10) is valid when replacing

\frac{λ}{λ_{1} λ_{2}}

by

M

, then in particular, by substitution of

a_{m} = {\tilde{a}}_{m} a n d b_{n} = {\tilde{b}}_{n}

in (10), we have

\tilde{I} : = \sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} {\tilde{a}}_{m} {\tilde{b}}_{n} < M {[\sum_{m = 1}^{\infty} m^{p (1 + λ_{1}) - 1} {\tilde{a}}_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 + λ_{2}) - 1} {\tilde{b}}_{n}^{q}]}^{\frac{1}{q}}

(11)

In the following, we shall prove that

M \geq \frac{λ}{λ_{1} λ_{2}}

, which would reveal that

M = \frac{λ}{λ_{1} λ_{2}}

is the best possible constant factor in (10).

By inequality (11) and the decreasing property of the series, we obtain

\begin{array}{l} \tilde{I} & < M {[\sum_{m = 1}^{\infty} m^{p (1 + λ_{1}) - 1} m^{- p λ_{1} - ε - p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 + λ_{2}) - 1} n^{- q λ_{2} - ε - q}]}^{\frac{1}{q}} \\ = M {(1 + \sum_{m = 2}^{\infty} m^{- ε - 1})}^{\frac{1}{p}} {(1 + \sum_{n = 2}^{\infty} n^{- ε - 1})}^{\frac{1}{q}} \\ < M {(1 + \int_{1}^{\infty} x^{- ε - 1} d x)}^{\frac{1}{p}} {(1 + \int_{1}^{\infty} y^{- ε - 1} d y)}^{\frac{1}{q}} = \frac{M}{ε} (ε + 1) . \end{array}

By inequalities in (9) and setting

{\hat{λ}}_{1} = λ_{1} - \frac{ε}{q} \in (0, \frac{11}{8}) \cap {(0, λ)}^{} (0 < {\hat{λ}}_{2} = λ_{2} + \frac{ε}{q} = λ - {\hat{λ}}_{1} < λ),

we obtain

\begin{array}{l} \tilde{I} = \sum_{m = 1}^{\infty} [m^{- (λ_{1} - \frac{ε}{q})} \sum_{n = 1}^{\infty} {(\min {m, n})}^{λ} n^{- (λ_{2} + \frac{ε}{q}) - 1}] m^{- ε - 1} \\ = \sum_{m = 1}^{\infty} ϖ ({\hat{λ}}_{1}, m) m^{- ε - 1} > \frac{λ}{{\hat{λ}}_{1} {\hat{λ}}_{2}} \sum_{m = 1}^{\infty} (1 - \frac{{\hat{λ}}_{2}}{λ m^{{\hat{λ}}_{1}}}) m^{- ε - 1} \\ = & \frac{λ}{{\hat{λ}}_{1} {\hat{λ}}_{2}} (\sum_{m = 1}^{\infty} m^{- ε - 1} - \frac{{\hat{λ}}_{2}}{λ} \sum_{m = 1}^{\infty} \frac{1}{m^{λ_{1} + \frac{ε}{p} + 1}}) > \frac{λ}{{\hat{λ}}_{1}, {\hat{λ}}_{2}} (\int_{1}^{\infty} x^{- ε - 1} d x - O (1)) \\ = & \frac{λ}{ε {\hat{λ}}_{1} {\hat{λ}}_{2}} (1 - ε O (1)) . \end{array}

Then, we have

\frac{λ}{(λ_{1} - \frac{ε}{q}) (λ_{2} + \frac{ε}{q})} (1 - ε O (1)) < ε \tilde{I} < M (ε + 1) .

Taking

ε \to 0^{+}

, we deduce that

\frac{λ}{λ_{1} λ_{2}} \leq M

. Hence,

M = \frac{λ}{λ_{1}, λ_{2}}

is the best possible constant factor in (10). Lemma 3 is thus proven. □

Setting

{\tilde{λ}}_{1} : = \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}, {\tilde{λ}}_{2} : = \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}

, we find

{\tilde{λ}}_{1} + {\tilde{λ}}_{2} = λ,

and then we can reduce inequality (8) to the following:

\begin{matrix} I = & \sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m} b_{n} < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) \\ \times {[\sum_{m = 1}^{\infty} m^{p (1 + {\tilde{λ}}_{1}) - 1} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 + {\tilde{λ}}_{2}) - 1} b_{n}^{q}]}^{\frac{1}{q}} \end{matrix}

(12)

It is worth noting that inequality (12) is an analogue of the Hilbert-type inequality (8). In the following lemma, we present a relation between the parameters

λ, λ_{1}

and

λ_{2}

on the best possible constant factor in inequality (12).

Lemma 4.

If inequality (12) has the best possible constant factor

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

for various parameters, then

λ = λ_{1} + λ_{2} .

Proof.

From the assumption conditions of inequality (12), it follows that

{\tilde{λ}}_{1} = \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q} > 0, {\tilde{λ}}_{1} < \frac{λ}{p} + \frac{λ}{q} = λ, 0 < {\tilde{λ}}_{2} = λ - {\tilde{λ}}_{1} < λ .

Hence, we have

k_{λ} ({\tilde{λ}}_{1}) = \frac{λ}{{\tilde{λ}}_{1} (λ - {\tilde{λ}}_{1})} = \frac{λ}{{\tilde{λ}}_{1} {\tilde{λ}}_{2}} \in R_{+} = (0, \infty)

If the constant factor

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

in (12) is the best possible, then in view of inequality (10), we have

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) \leq k_{λ} ({\tilde{λ}}_{1})

By Hölder’s inequality with weight, we find

\begin{matrix} k_{λ} ({\tilde{λ}}_{1}) = k_{λ} (\frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) \\ \begin{array}{l} = \int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- (\frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} d u = \int_{0}^{\infty} {(\min {1, u})}^{λ} (u^{\frac{- λ_{1} - 1}{p}}) (u^{\frac{- λ + λ_{2} - 1}{q}}) d u \\ \leq {[\int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- λ_{1} - 1} d u]}^{\frac{1}{p}} {[\int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- λ + λ_{2} - 1} d u]}^{\frac{1}{q}} \\ = {[\int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- λ_{1} - 1} d u]}^{\frac{1}{p}} {[\int_{0}^{\infty} {(\min {1, v})}^{λ} v^{- λ_{2} - 1} d v]}^{\frac{1}{q}} \end{array} \\ = k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) . \end{matrix}

(13)

It follows that

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) =

k_{λ} ({\tilde{λ}}_{1})

, and thus (13) keeps the form of equality.

It is easy to see that (13) keeps the form of equality if, and only if, there exist constants

A

and

B

(not all zero) such that (c.f. [25])

A u^{- λ_{1} - 1} = B u^{- (λ - λ_{2}) - 1}^{} a . e . in R_{+} .

Assuming that

A \neq 0

, we have

u^{λ - λ_{2} - λ_{1}} = {\frac{B}{A}}^{} a . e .

in

R_{+}

, and this yields

λ - λ_{2} - λ_{1} = 0

, hence

λ = λ_{1} + λ_{2}

. The proof of Lemma 4 is thus complete. □

3. Main Results and Some Particular Cases

Theorem 1.

Inequality (8) is equivalent to the following inequality:

\begin{array}{l} J : & = {\sum_{n = 1}^{\infty} n^{- p (\frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} {[\sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m}]}^{p}}^{\frac{1}{p}} \\ < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) {[\sum_{m = 1}^{\infty} m^{p (1 + \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} a_{m}^{p}]}^{\frac{1}{p}} . \end{array}

(14)

If the constant factor in (8) is the best possible, then so is the constant factor in (14).

Proof.

Suppose that inequality (14) is valid. By Hölder’s inequality (c.f. [25]), we have

I = \sum_{n = 1}^{\infty} [n^{\frac{- 1}{p} - \frac{λ_{2}}{q} - \frac{λ - λ_{1}}{p})} \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m}] [n^{\frac{1}{p} + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}} b_{n}] \leq J {[\sum_{n = 1}^{\infty} n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q}]}^{\frac{1}{q}}

(15)

Then, by using inequality (14), we obtain inequality (8).

On the other hand, assuming that inequality (8) is valid, we set

b_{n} : = n^{- p (\frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} {[\sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m}]}^{p - 1}, n \in N

If

J = 0

, then inequality (14) is naturally valid; if

J = \infty

, then it is impossible to make inequality (14) valid, which implies

J < \infty

. Suppose that

0 < J < \infty

. By inequality (8), we have

\begin{matrix} \sum_{n = 1}^{\infty} n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q} = J^{p} = I < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) \times {[\sum_{m = 1}^{\infty} m^{p (1 + \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} a_{m}^{p}]}^{\frac{1}{p}} \\ {[\sum_{n = 1}^{\infty} n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q}]}^{\frac{1}{q}}, \end{matrix}

J = {[\sum_{n = 1}^{\infty} n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1} b_{n}^{q}]}^{\frac{1}{p}} < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) {[\sum_{m = 1}^{\infty} m^{p (1 + \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1} a_{m}^{p}]}^{\frac{1}{p}}

Thus, inequality (14) follows, and we conclude that inequality (8) is equivalent to inequality (14).

Furthermore, we show that if the constant factor in (8) is the best possible, then the constant factor in (14) is also the best possible. Otherwise, from inequality (15) we would reach a contradiction, namely that the constant factor in (8) is not the best possible. The proof of Theorem 1 is thus completed. □

In the following theorem, we give some equivalent statements of the best possible constant factor related to several parameters.

Theorem 2.

The statements (i), (ii), (iii) and (iv) below are equivalent:

(i)

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

is independent of

p, q

;

(ii)

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

is expressible as a single integral

k_{λ} ({\hat{λ}}_{1}) = \int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- {\hat{λ}}_{1} - 1} d u^{} (0 < {\hat{λ}}_{1} < λ)

(iii)

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

in (8) is the best possible constant factor;

(iv)

λ = λ_{1} + λ_{2}^{} (\in (0, \frac{11}{4}]) .

If the statement (iv) is valid, namely,

λ = λ_{1} + λ_{2} \in (0, \frac{11}{4}]

, then we have inequality (10) and the following equivalent inequality with the best possible constant factor

\frac{λ}{λ_{1} λ_{2}}

:

{\sum_{n = 1}^{\infty} \frac{1}{n^{p λ_{2} + 1}} {[\sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m}]}^{p}}^{\frac{1}{p}} < \frac{λ}{λ_{1} λ_{2}} {[\sum_{m = 1}^{\infty} m^{p (1 + λ_{1}) - 1} a_{m}^{p}]}^{\frac{1}{p}}

(16)

Proof.

(i)

\Rightarrow

(ii). By (i), we have

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) = \lim_{p \to 1^{+}} \lim_{q \to \infty} k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) = k_{λ} (λ_{1}) .

Namely,

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

is expressible as a single integral

k_{λ} (λ_{1}) = \int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- λ_{1} - 1} d u^{} (0 < λ_{1} < λ)

(ii)

\Rightarrow

(iv). If

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

is expressible as a single integral

k_{λ} ({\hat{λ}}_{1}) = \int_{0}^{\infty} {(\min {1, u})}^{λ} u^{- {\hat{λ}}_{1} - 1} d u^{} (0 < {\hat{λ}}_{1} < λ)

then for

{\hat{λ}}_{1} = {\tilde{λ}}_{1}^{} (\in (0, λ))

, (13) keeps the form of equality. In view of the proof of Lemma 4, it follows that

λ = λ_{1} + λ_{2}

.

(iv)

\Rightarrow

(i). If

λ = λ_{1} + λ_{2}

, then

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) = k_{λ} (λ_{1})

, which is independent of

p, q

. Thus, we deduce that (i)

\Leftrightarrow

(ii)

\Leftrightarrow

(iv).

(iii)

\Rightarrow

(iv). By Lemma 4, we get

λ = λ_{1} + λ_{2}

.

(iv)

\Rightarrow

(iii). By Lemma 3, for

λ = λ_{1} + λ_{2}

,

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} {(λ_{2})}^{} (= \frac{λ}{λ_{1} λ_{2}})

is the best possible constant factor in (8). It follows that (iii)

\Leftrightarrow

(iv).

Therefore, we assert that the statements (i), (ii), (iii) and (iv) are equivalent. This completes the proof of Theorem 2. □

Now, we discuss some particular cases of the inequalities obtained above, from which we will derive some interesting inequalities.

Remark 2.

(i) Putting

λ = 1,^{} λ_{1} = \frac{1}{q},^{} λ_{2} = \frac{1}{p}

in (10) and (16), we obtain the following equivalent inequalities with the best possible constant factor

p q

:

\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} \min {m, n} a_{m} b_{n} < p q {[\sum_{m = 1}^{\infty} m^{2 (p - 1)} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{2 (q - 1)} b_{n}^{q}]}^{\frac{1}{q}}

(17)

{[\sum_{n = 1}^{\infty} \frac{1}{n^{2}} {(\sum_{m = 1}^{\infty} \min {m, n} a_{m})}^{p}]}^{\frac{1}{p}} < p q {[\sum_{m = 1}^{\infty} m^{2 (p - 1)} a_{m}^{p}]}^{\frac{1}{p}}

(18)

(ii) Putting

λ = 1, λ_{1} = \frac{1}{p}, λ_{2} = \frac{1}{q}

in (10) and (16), we get the following equivalent inequalities with the best possible constant factor

p q

:

\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} \min {m, n} a_{m} b_{n} < p q {[\sum_{m = 1}^{\infty} (m a_{m}^{})}^{p}]^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} (n b_{n}^{})}^{q}]^{\frac{1}{q}}

(19)

{[\sum_{n = 1}^{\infty} {(\frac{1}{n} \sum_{m = 1}^{\infty} \min {m, n} a_{m})}^{p}]}^{\frac{1}{p}} < p q {[\sum_{m = 1}^{\infty} (m a_{m}^{})}^{p}]^{\frac{1}{p}}

(20)

(iii) Setting

p = q = 2,

both (17) and (19) reduce to the inequality:

\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} \min {m, n} a_{m} b_{n} < 4 {[\sum_{m = 1}^{\infty} (m a_{m}^{})}^{2} \sum_{n = 1}^{\infty} (n b_{n}^{})^{2}]^{\frac{1}{2}}

(21)

furthermore, both (18) and (20) reduce to the equivalent form of (21) as follows:

{[\sum_{n = 1}^{\infty} {(\frac{1}{n} \sum_{m = 1}^{\infty} \min {m, n} a_{m})}^{2}]}^{\frac{1}{2}} < 4 {[\sum_{m = 1}^{\infty} (m a_{m}^{})}^{2}]^{\frac{1}{2}}

(22)

(iv) Putting

λ = 2, λ_{1} = λ_{2} = 1

in (10) and (16), we have the following equivalent inequalities with the best possible constant factor

2

:

\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{2} a_{m} b_{n} < 2 {(\sum_{m = 1}^{\infty} m^{2 p - 1} a_{m}^{p})}^{\frac{1}{p}} {(\sum_{n = 1}^{\infty} n^{2 q - 1} b_{n}^{q})}^{\frac{1}{q}}

(23)

{\sum_{n = 1}^{\infty} \frac{1}{n^{p + 1}} {[\sum_{m = 1}^{\infty} {(\min {m, n})}^{2} a_{m}]}^{p}}^{\frac{1}{p}} < 2 {(\sum_{m = 1}^{\infty} m^{2 p - 1} a_{m}^{p})}^{\frac{1}{p}}

(24)

(v) Putting

λ = e^{} (< \frac{11}{4} = 2.75), λ_{1} = λ_{2} = \frac{e}{2}

in (10) and (16), we have the following equivalent inequalities with the best possible constant factor

\frac{4}{e}

:

\sum_{n = 1}^{\infty} \sum_{m = 1}^{\infty} {(\min {m, n})}^{e} a_{m} b_{n} < \frac{4}{e} {[\sum_{m = 1}^{\infty} m^{p (1 + \frac{e}{2}) - 1} a_{m}^{p}]}^{\frac{1}{p}} {[\sum_{n = 1}^{\infty} n^{q (1 + \frac{e}{2}) - 1} b_{n}^{q}]}^{\frac{1}{q}}

(25)

{\sum_{n = 1}^{\infty} \frac{1}{n^{\frac{e}{2} p + 1}} {[\sum_{m = 1}^{\infty} {(\min {m, n})}^{e} a_{m}]}^{p}}^{\frac{1}{p}} < \frac{4}{e} {[\sum_{m = 1}^{\infty} m^{p (1 + \frac{e}{2}) - 1} a_{m}^{p}]}^{\frac{1}{p}}

(26)

4. Operator Expressions

We choose the functions

ϕ (m) : = m^{p (1 + \frac{λ_{1}}{p} + \frac{λ - λ_{2}}{q}) - 1}, ψ (n) : = n^{q (1 + \frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1},

where from,

ψ^{1 - p} (n) = n^{- p (\frac{λ_{2}}{q} + \frac{λ - λ_{1}}{p}) - 1}^{} (m, n \in N)

We define the following real normed spaces:

\begin{array}{l} l_{p, ϕ} : = {a = {a_{m}}_{m = 1}^{\infty}; | | a | |_{p, ϕ} : = {(\sum_{m = 1}^{\infty} ϕ (m) | a_{m} |^{p})}^{\frac{1}{p}} < \infty}, \\ l_{q, ψ} : = {b = {b_{n}}_{n = 1}^{\infty}; | | b | |_{q, ψ} : = {(\sum_{n = 1}^{\infty} ψ (n) | b_{n} |^{q})}^{\frac{1}{q}} < \infty}, \\ l_{p, ψ^{1 - p}} : = {c = {c_{n}}_{n = 1}^{\infty}; | | c | |_{p, ψ^{1 - p}} : = {(\sum_{n = 1}^{\infty} ψ^{1 - p} (n) | c_{n} |^{p})}^{\frac{1}{p}} < \infty} . \end{array}

We let

a \in l_{p, ϕ}

, and set

c = {c_{n}}_{n = 1}^{\infty}, c_{n} : = \sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m}, n \in N .

Then, we can rewrite inequality (14) as follows:

| | c | |_{p, ψ^{1 - p}} < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) | | a | |_{p, ϕ} < \infty, that is c \in l_{p, ψ^{1 - p}} .

Definition 1.

Define a Hilbert-type operator

T : l_{p, ϕ} \to l_{p, ψ^{1 - p}}

as follows: For any

a \in l_{p, ϕ},

there exists a unique representation

c \in l_{p, ψ^{1 - p}}

. Define the formal inner product of

T a

and

b \in l_{q, ψ}

, and the norm of

T

as follows:

(T a, b) : = \sum_{n = 1}^{\infty} [\sum_{m = 1}^{\infty} {(\min {m, n})}^{λ} a_{m}] b_{n}

| | T | | : = \sup_{a (\neq θ) \in l_{p, ϕ}} \frac{| | T a | |_{p, ψ^{1 - p}}}{| | a | |_{p, ϕ}}

Then, by Theorems 1 and 2, we obtain the operator expressions of inequalities (8) and (14) as follows:

Theorem 3.

If

a \in l_{p, ϕ}, b \in l_{q, ψ}, | | a | |_{p, ϕ}, | | b | |_{q, ψ} > 0,

then we have the following inequalities:

(T a, b) < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) | | a | |_{p, ϕ} | | b | |_{q, ψ},

(27)

| | T a | |_{p, ψ^{1 - p}} < k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2}) | | a | |_{p, ϕ}

(28)

Furthermore,

λ_{1} + λ_{2} = λ^{} (\in (0, \frac{11}{4}])

if, and only if, the constant factor

k_{λ}^{\frac{1}{p}} (λ_{1}) k_{λ}^{\frac{1}{q}} (λ_{2})

in (27) and (28) is the best possible, namely,

| | T | | = k_{λ} (λ_{1}) = {\frac{λ}{λ_{1} λ_{2}}}^{} (λ_{i} \in (0, \frac{11}{8}] \cap (0, λ), i = 1, 2)

(29)

5. Conclusions

In this paper, we give, with Lemma 2 and Theorem 1, respectively, a new inequality of the Hilbert-type containing positive homogeneous kernel and its equivalent forms. Based on the obtained Hilbert-type inequality, we discuss in Theorem 2 the equivalent statements of the best possible constant factor related to several parameters. As applications, the operator expressions of the obtained inequalities are given in Theorem 3, and some particular cases of the obtained inequalities (10) and (16) are considered in Remark 2. It is shown that the results obtained in Theorems 1 and 2 would generate more new inequalities of Hilbert-type.

Author Contributions

B.Y. carried out the mathematical studies and drafted the manuscript. S.W. and A.W. participated in the design of the study and performed the numerical analysis. All authors contributed equally and significantly in this paper. All authors have read and agreed to the published version of the manuscript.

Funding

This work is supported by the National Natural Science Foundation (No. 61772140), and the Science and Technology Planning Project Item of Guangzhou City (No. 201707010229).

Acknowledgments

The authors are grateful to the reviewers for their valuable comments and suggestions to improve the quality of the manuscript.

Conflicts of Interest

The authors declare that they have no competing interests.

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Yang, B.; Wu, S.; Wang, A. A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms. Symmetry 2020, 12, 342. https://doi.org/10.3390/sym12030342

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Yang B, Wu S, Wang A. A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms. Symmetry. 2020; 12(3):342. https://doi.org/10.3390/sym12030342

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Yang, Bicheng, Shanhe Wu, and Aizhen Wang. 2020. "A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms" Symmetry 12, no. 3: 342. https://doi.org/10.3390/sym12030342

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Yang, B., Wu, S., & Wang, A. (2020). A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms. Symmetry, 12(3), 342. https://doi.org/10.3390/sym12030342

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A New Hilbert-Type Inequality with Positive Homogeneous Kernel and Its Equivalent Forms

Abstract

1. Introduction

2. Some Lemmas

3. Main Results and Some Particular Cases

4. Operator Expressions

5. Conclusions

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

References

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