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1. Introduction

Let $x = (x_{1}, x_{2}, \dots, x_{n}) \in R_{+}^{n} = {(0, \infty)}^{n}$ and $n \geq 2$ . Then, the arithmetic and geometric means of n positive numbers $x_{1}, x_{2}, \dots, x_{n}$ are defined by

$A (x) = \frac{1}{n} \sum_{i = 1}^{n} x_{i} and G (x) = {(\prod_{i = 1}^{n} x_{i})}^{1 / n} .$

In [1] (p. 208, 3.2.34), it was stated that

(1) $\prod_{i = 1}^{n} (x_{i} + 1) \geq {[G (x) + 1]}^{n} .$

In the paper [2], Wang and Chen established that the inequality

(2) $\prod_{i = 1}^{n} [{(x_{i} + 1)}^{p} - 1] \geq {[{(G (x) + 1)}^{p} - 1]}^{n}$

is valid for

p > 1

. In the paper [3], Wang extended Inequality (2) as follows:

if $p \geq 1$ , then Inequality (2) is valid;
if $0 < p \leq 1$ , then Inequality (2) is reversed;
if $p > 0$ , then
(3) $\prod_{i = 1}^{n} [{(x_{i} + 1)}^{p} + 1] \geq {[{(G (x) + 1)}^{p} + 1]}^{n};$
if $p < 0$ and $0 < x_{i} < \frac{1}{| p |}$ for $1 \leq i \leq n$ , then Inequality (3) is reversed.

In [4] (p. 11), it was proven that

(4) $\sqrt[n]{\prod_{k = 1}^{n} (a_{k} + b_{k})} \geq \sqrt[n]{\prod_{k = 1}^{n} a_{k}} + \sqrt[n]{\prod_{k = 1}^{n} b_{k}},$

where

a_{k}, b_{k} \geq 0

. When

a_{k} = x_{k}

and

b_{k} = 1

, Inequality (4) becomes (1). Inequality (4) is the Minkowski inequality of the product form.

We observe that the inequalities in (1)–(4) can be rearranged as

(5) $G (x + 1) \geq G (x) + 1, G ({(x + 1)}^{p} \pm 1) \geq {[G (x) + 1]}^{p} \pm 1$

and

(6) $G (a + b) > G (a) + G (b),$

where

$x + 1 = (x_{1} + 1, x_{2} + 1, \dots, x_{n} + 1)$

and

${(x + 1)}^{p} \pm 1 = ({(x_{1} + 1)}^{p} \pm 1, {(x_{2} + 1)}^{p} \pm 1, \dots, {(x_{n} + 1)}^{p} \pm 1) .$

Inequality (6) reveals that the geometric mean

G (x)

is sub-additive. For information about the sub-additivity, please refer to [5,6,7,8,9,10,11,12] and the closely related references therein. The sub-additive property of the geometric mean

G (x)

can also be derived from the property that the geometric mean

G (x)

is a Bernstein function; see [13,14,15,16,17,18,19] and the closely related references therein.

In this paper, by some methods in the theory of majorization, we will generalize the above inequalities in (1)–(3), (5), and (6).

2. Definitions and Lemmas

Now, we recall some definitions and lemmas.

It is well known that a function $f (x_{1}, x_{2}, \dots, x_{n})$ of n variables is said to be symmetric if its value is unchanged for any permutation of its n variables $x_{1}, x_{2}, \dots, x_{n}$ .

Definition 1

([20,21]). Let $x = (x_{1}, x_{2}, \dots, x_{n})$ and $y = (y_{1}, y_{2}, \dots, y_{n}) \in R^{n}$ .

1.
If
$\sum_{i = 1}^{k} x_{[i]} \leq \sum_{i = 1}^{k} y_{[i]} a n d \sum_{i = 1}^{n} x_{[i]} = \sum_{i = 1}^{n} y_{[i]}$
for $1 \leq k \leq n - 1$ , then $x$ is said to be majorized by $y$ (in symbol $x ≺ y$ ), where $x_{[1]} \geq x_{[2]} \geq \dots \geq x_{[n]}$ and $y_{[1]} \geq y_{[2]} \geq \dots \geq y_{[n]}$ are rearrangements of $x$ and $y$ in descending order.
2.
For $x, y \in Ω$ and $λ \in [0, 1]$ , if
$λ x + (1 - λ) y = (λ x_{1} + (1 - λ) y_{1}, λ x_{2} + (1 - λ) y_{2}, \dots, λ x_{n} + (1 - λ) y_{n}) \in Ω,$
then $Ω \subseteq R^{n}$ is said to be a convex set.

Definition 2

([20,21]). Let $Ω \subseteq R^{n}$ be a symmetric and convex set.

1.
If $x ≺ y$ on Ω implies $φ (x) \leq φ (y)$ , then we say that the function $φ : Ω \to R$ is Schur convex on Ω.
2.
If $- φ$ is a Schur convex function on Ω, then we say that φ is Schur concave on Ω.

Lemma 1

([20,21]). Let $Ω \subseteq R^{n}$ be a symmetric and convex set with nonempty interior $Ω °$ , and let $φ : Ω \to R$ be continuous on Ω and continuously differentiable on $Ω °$ . If and only if φ is symmetric on Ω and

$(x_{1} - x_{2}) (\frac{\partial φ}{\partial x_{1}} - \frac{\partial φ}{\partial x_{2}}) \geq 0, x \in Ω °,$

the function φ is Schur convex on Ω.

Definition 3

([22] (pp. 64 and 107)). Let $x, y \in Ω \subseteq R_{+}^{n}$ .

1.
If $(x_{1}^{λ} y_{1}^{1 - λ}, x_{2}^{λ} y_{2}^{1 - λ}, \dots, x_{n}^{λ} y_{n}^{1 - λ}) \in Ω$ for $x, y \in Ω$ and $λ \in [0, 1]$ , then Ω is called a geometrically-convex set.
2.
If Ω is a geometrically-convex set and
$(\ln x_{1}, ln x_{2}, \dots, ln x_{n}) ≺ (\ln y_{1}, ln y_{2}, \dots, ln y_{n})$
implies $φ (x) \leq φ (y)$ for any $x, y \in Ω$ , then $φ : Ω \to R_{+}$ is said to be a Schur geometrically-convex function on Ω.
3.
If $- φ$ is a Schur geometrically-convex function on Ω, then φ is said to be a Schur geometrically-concave function on Ω.

Lemma 2

([22] (p. 108)). Let $Ω \subseteq R_{+}^{n}$ be a symmetric and geometrically-convex set with a nonempty interior $Ω °$ , and let $φ : Ω \to R_{+}$ be continuous on Ω and differentiable in $Ω °$ . If and only if φ is symmetric on Ω and

$(ln x_{1} - ln x_{2}) (x_{1} \frac{\partial φ}{\partial x_{1}} - x_{2} \frac{\partial φ}{\partial x_{2}}) \geq 0, x \in Ω °,$

the function φ is Schur geometrically-convex on Ω.

For more information on the Schur convexity and the Schur geometric convexity, please refer to the papers [23,24,25,26] and the monographs [20,22].

Lemma 3

(Bernoulli’s inequality [27,28]). For $0 \neq x > - 1$ , if $α \geq 1$ or $α < 0$ , then

(7) ${(1 + x)}^{α} \geq 1 + α x;$

if $0 < α < 1$ , then Inequality (7) is reversed.

Lemma 4.

For $p \in R \ {0}$ and $x \in R_{+}$ , define

$h_{1} (x) = \frac{p {(x + 1)}^{p - 1}}{{(x + 1)}^{p} + 1}, g_{1} (x) = \frac{p x {(x + 1)}^{p - 1}}{{(x + 1)}^{p} + 1}, h_{2} (x) = \frac{p {(x + 1)}^{p - 1}}{{(x + 1)}^{p} - 1}, g_{2} (x) = \frac{p x {(x + 1)}^{p - 1}}{{(x + 1)}^{p} - 1} .$

1.
If $p < 0$ , the function $h_{1} (x)$ is increasing on $R_{+}$ ; if $0 2$ , the function $h_{1} (x)$ is increasing on $(0, {(p - 1)}^{1 / p} - 1)$ and decreasing on $({(p - 1)}^{1 / p} - 1, \infty)$ .
2.
If $p > 0$ , the function $g_{1} (x)$ is increasing on $R$ ; if $p < 0$ , the function $g_{1} (x)$ is decreasing on $(0, \frac{1}{| p |}]$ and increasing on $[\frac{2}{| p |}, \infty)$ .
3.
For $p \neq 0$ , the function $h_{2} (x)$ is decreasing on $R_{+}$ .
4.
If $p \geq 1$ , the function $g_{2} (x)$ is increasing on $R_{+}$ ; if $p < 1$ and $p \neq 0$ , the function $g_{2} (x)$ is decreasing on $R_{+}$ .

Proof.

Straightforward computation gives

$\begin{matrix} {[h_{1} (x)]}^{'} = & \frac{p [p - 1 - {(x + 1)}^{p}]}{{[{(x + 1)}^{p} + 1]}^{2}} {(x + 1)}^{p - 2}, & {[g_{1} (x)]}^{'} & = \frac{p [1 + p x + {(x + 1)}^{p}]}{{[{(x + 1)}^{p} + 1]}^{2}} {(x + 1)}^{p - 2}, \\ [h_{2} {(x)]}^{'} = & \frac{p [1 - p - {(x + 1)}^{p}]}{{[{(x + 1)}^{p} - 1]}^{2}} {(x + 1)}^{p - 2}, & {[g_{2} (x)]}^{'} & = \frac{p [{(x + 1)}^{p} - 1 - p x]}{{[{(x + 1)}^{p} - 1]}^{2}} {(x + 1)}^{p - 2} . \end{matrix}$

If $p < 0$ and $x \in R_{+}$ or $p > 2$ and $0 < x \leq {(p - 1)}^{1 / p} - 1$ , we have ${[h_{1} (x)]}^{'} \geq 0$ ; if $0 2$ and ${(p - 1)}^{1 / p} - 1 < x$ , we obtain ${[h_{1} (x)]}^{'} \leq 0$ .

If $p > 0$ and $x \in R_{+}$ , we acquire ${[g_{1} (x)]}^{'} \geq 0$ ; if $p < 0$ and $0 < x \leq \frac{1}{| p |}$ , we have ${[g_{1} (x)]}^{'} \leq 0$ ; if $p < 0$ and $x \geq \frac{2}{| p |}$ , since ${(x + 1)}^{p} < 1$ and $1 + p x \leq - 1$ , we acquire ${[g_{1} (x)]}^{'} \geq 0$ .

If $p \in R \ {0}$ , we obtain ${[h_{2} (x)]}^{'} \leq 0$ for $x \in R_{+}$ .

For $x \in R_{+}$ , by Lemma 3, if $p \geq 1$ , we have ${(x + 1)}^{p} \geq 1 + p x$ , then ${[g_{2} (x)]}^{'} \geq 0$ ; if $0 < p \leq 1$ , we have ${(x + 1)}^{p} \leq 1 + p x$ , and so, ${[g_{2} (x)]}^{'} \leq 0$ ; if $p < 0$ , we obtain ${(x + 1)}^{p} \geq 1 + p x$ , hence ${[g_{2} (x)]}^{'} \leq 0$ . The proof of Lemma 4 is complete. □

Let $x = (x_{1}, x_{2}, \dots, x_{n}) \in R^{n}$ and $i_{1}, \dots, i_{k}$ be positive integers. The elementary symmetric functions are defined by $E_{0} (x) = 1$ ,

$E_{k} (x) = E_{k} (x_{1}, x_{2}, \dots, x_{n}) = \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} x_{i_{j}}, 1 \leq k \leq n,$

and

E_{k} (x) = 0

for

k < 0

k > n

Lemma 5

(Newton’s inequality [20] (p. 134)). For $x = (x_{1}, x_{2}, \dots, x_{n}) \in R_{+}^{n}$ and $n \geq 2$ , let ${\hat{F}}_{k} (x) = \frac{1}{(\binom{n}{k})} E_{k} (x)$ for $1 \leq k \leq n - 1$ . Then

${[{\hat{F}}_{k} (x)]}^{2} \geq {\hat{F}}_{k - 1} (x) {\hat{F}}_{k + 1} (x) .$

3. Main Results

In this section, we will make use of the Schur convexity of the symmetric function

$E_{k} ({(x + 1)}^{p} + ξ) = \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} + 1)}^{p} + ξ], 2 \leq k \leq n, n \geq 2$

to generalize the inequalities in (1)–(3), (5) and (6), where

x \in R_{+}^{n}

, the quantities

i_{1}, i_{2}, \dots, i_{k}

are positive integers,

ξ = 0, \pm 1

, and

ξ = 0, \pm 1

Our main results are Theorems 1–3 below.

Theorem 1.

Let $2 \leq k \leq n$ , $p \in R \ {0}$ , $i_{1}, \dots, i_{k} \in N$ , and $a = \frac{(n - k) (p - 1)}{k - 1}$ for $p > 1$ .

1.
If $2 \leq k \leq n - 1$ , $0 1$ with $a < 1$ , and $x \in {(0, a^{- 1 / p} - 1]}^{n}$ , or if $k = n$ , $p > 0$ , and $x \in R_{+}^{n}$ , then
(8) $(\binom{n}{k}) {[G (x) + 1]}^{k p} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} {(x_{i_{j}} + 1)}^{p} \leq (\binom{n}{k}) {[A (x) + 1]}^{k p};$
if $p < 0$ and $x \in {(0, \frac{1}{| p |}]}^{n}$ or if $k = n$ , $p < 0$ , and $x \in R_{+}^{n}$ , then the double Inequality (8) is reversed.
2.
If $2 \leq k \leq n - 1$ , $p > 1$ with $a > 1$ , and $x \in {(0, a^{1 / p} - 1]}^{n}$ , then
$(\binom{n}{k}) {[A (x) + 1]}^{k p} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} {(x_{i_{j}} + 1)}^{p} .$
3.
If $2 \leq k \leq n - 1$ , $p > 0$ , and $x \in R_{+}^{n}$ , then
(9) $(\binom{n}{k}) {[G (x) + 1]}^{k p} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} {(x_{i_{j}} + 1)}^{p};$
if $p < 0$ and $x \in R_{+}^{n}$ , then Inequality (9) is reversed.

Proof.

When $k = n$ , we have

$\frac{\partial E_{n} ({(x + 1)}^{p})}{\partial x_{1}} = \frac{p}{(x_{1} + 1)} E_{n} ({(x + 1)}^{p}) .$

From this, we obtain

$(x_{1} - x_{2}) [\frac{\partial E_{n} ({(x + 1)}^{p})}{\partial x_{1}} - \frac{\partial E_{n} ({(x + 1)}^{p})}{\partial x_{2}}] = - \frac{p {(x_{1} - x_{2})}^{2}}{(x_{1} + 1) (x_{2} + 1)} E_{n} ({(x + 1)}^{p}) \{\begin{matrix} \leq 0, & p > 0; \\ \geq 0, & p < 0 \end{matrix}$

and

$(x_{1} - x_{2}) [x_{1} \frac{\partial E_{n} ({(x + 1)}^{p})}{\partial x_{1}} - x_{2} \frac{\partial E_{n} ({(x + 1)}^{p})}{\partial x_{2}}] = \frac{p {(x_{1} - x_{2})}^{2}}{(x_{1} + 1) (x_{2} + 1)} E_{n} ({(x + 1)}^{p}) \{\begin{matrix} \geq 0, & p > 0; \\ \leq 0, & p < 0 . \end{matrix}$

Using Lemmas 1 and 2, we arrive at

if $p > 0$ , then $E_{n} ({(x + 1)}^{p})$ is Schur concave on $R_{+}^{n}$ ;
if $p < 0$ , then $E_{n} ({(x + 1)}^{p})$ is Schur convex on $R_{+}^{n}$ ;
if $p > 0$ , then $E_{n} ({(x + 1)}^{p})$ is Schur geometrically convex on $R^{n}$ ;
if $p < 0$ , the $E_{n} ({(x + 1)}^{p})$ is Schur geometrically concave on $R^{n}$ .

Since

(10) $(A_{n} (x), A_{n} (x), \dots, A_{n} (x)) ≺ x$

and

(11) $(ln G_{n} (x), ln G_{n} (x), \dots, ln G_{n} (x)) ≺ ln x$

for

x \in R_{+}^{n}

, applying Definitions 2 and 3, we obtain the double Inequality (8) for

k = n

When $2 \leq k \leq n - 1$ , a direct differentiation yields

$\frac{\partial E_{k} ({(x + 1)}^{p})}{\partial x_{1}} = p {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p} E_{k - 2} ({(\hat{x} + 1)}^{p}) + p {(x_{1} + 1)}^{p - 1} E_{k - 1} ({(\hat{x} + 1)}^{p}),$

where

\hat{x} = (x_{3}, \dots, x_{n})

. We clearly see that

(12) $\begin{matrix} Δ_{A} (E_{k} ({(x + 1)}^{p})) & ≜ (x_{1} - x_{2}) [\frac{\partial E_{k} ({(x + 1)}^{p})}{\partial x_{1}} - \frac{\partial E_{k} ({(x + 1)}^{p})}{\partial x_{2}}] \\ = - p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) \\ + p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p}) \end{matrix}$

and

(13) $\begin{matrix} (ln x_{1} - ln x_{2}) [x_{1} \frac{\partial E_{k} ({(x + 1)}^{p})}{\partial x_{1}} - x_{2} \frac{\partial E_{k} ({(x + 1)}^{p})}{\partial x_{2}}] \\ = p (ln x_{1} - ln x_{2}) (x_{1} - x_{2}) {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) \\ + p (ln x_{1} - ln x_{2}) [x_{1} {(x_{1} + 1)}^{p - 1} - x_{2} {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p}) . \end{matrix}$

Using Equation (13) and Lemma 2, we obtain that

if $p > 0$ , then $E_{k} ({(x + 1)}^{p})$ is Schur geometrically convex on $R_{+}^{n}$ ;
if $p < 0$ , then $E_{k} ({(x + 1)}^{p})$ is Schur geometrically concave on ${(0, \frac{1}{| p |}]}^{n}$ .

By Equation (12) and Lemma 1, we reveal that

if $p < 0$ , then $E_{k} ({(x + 1)}^{p})$ is Schur convex on $R_{+}^{n}$ ;
if $0 < p \leq 1$ , then $E_{k} ({(x + 1)}^{p})$ is Schur concave on $R_{+}^{n}$ ;
if $p > 1$ and $x \in R_{+}^{n}$ ,
- (a). when $x_{1} = x_{2}$ , we have $Δ_{A} (E_{k} ({(x + 1)}^{p})) = 0$ ;
- (b). when $x_{1} \neq x_{2}$ ,
  - by Lagrange’s mean value theorem, we have
    (14) $\frac{1}{{(x_{2} + 1)}^{p - 1}} - \frac{1}{{(x_{1} + 1)}^{p - 1}} = \frac{(p - 1) (x_{1} - x_{2})}{{(ξ + 1)}^{p}}$
    for at least one interior point $ξ \in (min {x_{1}, x_{2}}, max {x_{1}, x_{2}})$ ;
  - from Newton’s inequality, we obtain
    (15) $\begin{matrix} \frac{(n - k) (n - 2)}{(k - 1) \sum_{i = 3}^{n} {(x_{i} + 1)}^{- p}} & = \frac{(n - k) {\hat{F}}_{n - 2} ({(\hat{x} + 1)}^{p})}{(k - 1) {\hat{F}}_{n - 3} ({(\hat{x} + 1)}^{p})} \leq \frac{E_{k - 1} ({(\hat{x} + 1)}^{p})}{E_{k - 2} ({(\hat{x} + 1)}^{p})} \\ \leq \frac{(n - k) {\hat{F}}_{1} ({(\hat{x} + 1)}^{p})}{(k - 1) {\hat{F}}_{0} ({(\hat{x} + 1)}^{p})} = \frac{n - k}{(k - 1) (n - 2)} \sum_{i = 3}^{n} {(x_{i} + 1)}^{p} . \end{matrix}$

Substituting (14) and (15) into Inequality (12) yields

(16) $\begin{matrix} Δ_{A} (E_{k} ({(x + 1)}^{p})) = - p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) \\ + p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p}) \\ = p (x_{1} - x_{2}) {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) \\ \times [- (x_{1} - x_{2}) + (\frac{1}{{(x_{2} + 1)}^{p - 1}} - \frac{1}{{(x_{1} + 1)}^{p - 1}}) \frac{E_{k - 1} ({(\hat{x} + 1)}^{p})}{E_{k - 2} ({(\hat{x} + 1)}^{p})}] \\ = p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) [\frac{p - 1}{{(ξ + 1)}^{p}} \frac{E_{k - 1} ({(\hat{x} + 1)}^{p})}{E_{k - 2} ({(\hat{x} + 1)}^{p})} - 1] . \end{matrix}$

If $a > 1$ and $x \in {(0, a^{1 / p} - 1]}^{n}$ , using $min {x_{1}, x_{2}} < ξ < max {x_{1}, x_{2}}$ , we have

$\frac{n - 2}{\sum_{i = 3}^{n} {(x_{i} + 1)}^{- p}} > \frac{n - 2}{\sum_{i = 3}^{n} {(0 + 1)}^{- p}} = 1$

and

(17) $\frac{1}{{(ξ + 1)}^{p}} \geq \frac{k - 1}{(n - k) (p - 1)} .$

Consequently, the inequalities from (16)–(17) imply

Δ (E_{k} ({(x + 1)}^{p})) \geq 0

for

x \in {(0, a^{1 / p} - 1]}^{n}

If $a < 1$ and $x \in {(0, a^{- 1 / p} - 1]}^{n}$ , we obtain

$\begin{matrix} Δ_{A} (E_{k} ({(x + 1)}^{p})) = p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) \\ \times [- 1 + \frac{p - 1}{{(ξ + 1)}^{p}} \frac{E_{k - 1} ({(\hat{x} + 1)}^{p})}{E_{k - 2} ({(\hat{x} + 1)}^{p})}] \\ \leq p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) [- 1 + \frac{(n - k) (p - 1)}{(k - 1) (n - 2) {(ξ + 1)}^{p}} \sum_{i = 3}^{n} {(x_{i} + 1)}^{p}] \\ \leq p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) \\ \times \{- 1 + \frac{(n - k) (p - 1)}{(k - 1) {(ξ + 1)}^{p}} {[({(\frac{k - 1}{(n - k) (p - 1)})}^{1 / p} - 1) + 1]}^{p}\} \\ = p {(x_{1} - x_{2})}^{2} {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} E_{k - 2} ({(\hat{x} + 1)}^{p}) [\frac{1}{{(ξ + 1)}^{p}} - 1] < 0 . \end{matrix}$

It is easy to obtain that, if

p > 1

and

a > 1

, then

E_{k} ({(x + 1)}^{p})

is Schur convex on

{(0, a^{1 / p} - 1]}^{n}

; if

p > 1

and

a < 1

, then

E_{k} ({(x + 1)}^{p})

is Schur concave on

{(0, a^{- 1 / p} - 1]}^{n}

Using (10) and by Definitions 2 and 3, the inequalities in (8) and (9) hold. The proof of Theorem 1 is complete. □

Theorem 2.

Let $2 \leq k \leq n$ and $p \in R \ {0}$ , $i_{1}, \dots, i_{k} \in N$ , and

$b = {[\frac{1}{2} (\sqrt{\frac{4 (4 n - 3 k - 1) (p - 1)}{k - 1} + 1} - 1)]}^{1 / p}, 1 < p \leq 2 .$

1.
If $k = n$ , $0 2$ , and $x \in {({(p - 1)}^{1 / p} - 1, \infty)}^{n}$ , or if $2 \leq k \leq n - 1$ , $0 < p \leq 1$ , and $x \in R_{+}^{n}$ , then
(18) $(\binom{n}{k}) {[{(G (x) + 1)}^{p} + 1]}^{k} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} + 1)}^{p} + 1] \leq (\binom{n}{k}) {[{(A (x) + 1)}^{p} + 1]}^{k} .$
If $2 \leq k \leq n$ , $p < 0$ , and $x \in {(0, \frac{1}{| p |}]}^{n}$ , then the double Inequality (18) is reversed.
2.
If $2 \leq k \leq n$ , $p > 2$ , and $x \in {(0, {(p - 1)}^{1 / p} - 1]}^{n}$ , or if $2 \leq k \leq n - 1$ , $1 < p \leq 2$ , and $x \in {(0, b]}^{n}$ , or if $2 \leq k \leq n$ , $p < 0$ , and $x \in R_{+}^{n}$ , then
(19) $(\binom{n}{k}) {[{(A (x) + 1)}^{p} + 1]}^{k} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} + 1)}^{p} + 1] .$
3.
If $2 \leq k \leq n - 1$ , $p > 0$ , and $x \in R_{+}^{n}$ or if $2 \leq k \leq n$ , $p < 0$ , and $x \in {[\frac{2}{| p |}, \infty)}^{n}$ , then
(20) $(\binom{n}{k}) {[{(G (x) + 1)}^{p} + 1]}^{k} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} + 1)}^{p} + 1] .$
4.
If $k = n$ , $p > 2$ , and $x \in R_{+}^{n}$ , then
(21) ${[{(G (x) + 1)}^{p} + 1]}^{n} \leq \prod_{i = 1}^{n} [{(x_{i} + 1)}^{p} + 1] .$

Proof.

When $k = n$ , a direct differentiation yields

(22) $\begin{matrix} \frac{\partial E_{n} ({(x + 1)}^{p} + 1)}{\partial x_{1}} = & \frac{p {(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} E_{n} ({(x + 1)}^{p} + 1) . \end{matrix}$

From Lemma 4, it follows that

$\begin{matrix} (x_{1} - x_{2}) [\frac{\partial E_{n} ({(x + 1)}^{p} + 1)}{\partial x_{1}} - \frac{\partial E_{n} ({(x + 1)}^{p} + 1)}{\partial x_{2}}] \\ = p (x_{1} - x_{2}) [\frac{{(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} - \frac{{(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} + 1}] E_{n} ({(x + 1)}^{p} + 1) \\ \{\begin{matrix} \leq 0, & 0 2, x \in {(0, {(p - 1)}^{1 / p} - 1]}^{n}; \\ \leq 0, & p > 2, x \in {({(p - 1)}^{1 / p} - 1, \infty)}^{n}; \\ \geq 0, & p < 0, x \in R_{+}^{n} \end{matrix} \end{matrix}$

and

$\begin{matrix} (ln x_{1} - ln x_{2}) [x_{1} \frac{\partial E_{n} ({(x + 1)}^{p} + 1)}{\partial x_{1}} - x_{2} \frac{\partial E_{n} ({(x + 1)}^{p} + 1)}{\partial x_{2}}] \\ = p (ln x_{1} - ln x_{2}) [\frac{x_{1} {(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} - \frac{x_{2} {(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} + 1}] E_{n} ({(x + 1)}^{p} + 1) \\ \{\begin{matrix} \geq 0, & p > 0, x \in R_{+}^{n}, \\ \leq 0, & p < 0, x \in {(0, \frac{1}{| p |}]}^{n}, \\ \geq 0, & p < 0, x \in {[\frac{2}{| p |}, \infty)}^{n} . \end{matrix} \end{matrix}$

Therefore, from Lemmas 1 and 2, we acquire

if $0 < p \leq 2$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur concave on $R_{+}^{n}$ ;
if $p > 2$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur convex on ${(0, {(p - 1)}^{1 / p} - 1]}^{n}$ ;
if $p > 2$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur concave on ${({(p - 1)}^{1 / p} - 1, \infty)}^{n}$ ;
if $p < 0$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur convex on $R_{+}^{n}$ ;
if $p > 0$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur geometrically convex on $R_{+}^{n}$ ;
if $p < 0$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur geometrically concave on ${(0, \frac{1}{| p |}]}^{n}$ ;
if $p < 0$ , then $E_{n} ({(x + 1)}^{p} + 1)$ is Schur geometrically convex on ${[\frac{2}{| p |}, \infty)}^{n}$ .

From Relations (10) and (11), employing Definitions 2 and 3, we conclude that inequalities in (18)–(21) for

k = n

If $2 \leq k \leq n - 1$ , since

$\begin{matrix} \frac{\partial E_{k} ({(x + 1)}^{p} + 1)}{\partial x_{1}} = p {(x_{1} + 1)}^{p - 1} [{(x_{2} + 1)}^{p} + 1] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ + p {(x_{1} + 1)}^{p - 1} E_{k - 1} ({(\hat{x} + 1)}^{p} + 1) . \end{matrix}$

Therefore, we have

(23) $\begin{matrix} Δ_{A} (E_{k} ({(x + 1)}^{p} + 1)) ≜ (x_{1} - x_{2}) [\frac{\partial E_{k} ({(x + 1)}^{p} + 1)}{\partial x_{1}} - \frac{\partial E_{k} ({(x + 1)}^{p} + 1)}{\partial x_{2}}] \\ = p (x_{1} - x_{2}) [\frac{{(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} - \frac{{(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} + 1}] \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} + 1] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ + p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} + 1) . \end{matrix}$

By Equation (23) and Lemma 1, it is easy to obtain that

if $p < 0$ , then $E_{k} ({(x + 1)}^{p} + 1)$ is Schur convex on $R_{+}^{n}$ ;
if $0 < p \leq 1$ , then $E_{k} ({(x + 1)}^{p} + 1)$ is Schur concave on $R_{+}^{n}$ ;
if $p > 1$ and $x \in R_{+}^{n}$ ,
- (a). when $x_{1} = x_{2}$ , we have $Δ_{A} (E_{k} ({(x + 1)}^{p} + 1) = 0$ ;
- (b). when $x_{1} \neq x_{2}$ , using Cauchy’s mean value theorem, we have
  $\begin{matrix} \frac{\frac{{(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} - \frac{{(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} + 1}}{{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}} = \frac{p - 1 - {(ξ + 1)}^{p}}{(p - 1) {[{(ξ + 1)}^{p} + 1]}^{2}} \end{matrix}$
  for some point $ξ \in (min {x_{1}, x_{2}}, max {x_{1}, x_{2}})$ such that
  $\begin{matrix} Δ_{A} (E_{k} ({(x + 1)}^{p} + 1)) = p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{\frac{\frac{{(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} - \frac{{(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} + 1}}{{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}} \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} + 1] + \frac{E_{k - 1} ({(\hat{x} + 1)}^{p} + 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} + 1)}\} \\ = p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{\frac{p - 1 - {(ξ + 1)}^{p}}{(p - 1) {[{(ξ + 1)}^{p} + 1]}^{2}} \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} + 1] + \frac{E_{k - 1} ({(\hat{x} + 1)}^{p} + 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} + 1)}\} . \end{matrix}$

If $p > 2$ and $x \in (0, {(p - 1)}^{1 / p} - 1]$ , then $p - 1 - {(x + 1)}^{p} \geq 0$ , so $Δ_{A} (E_{k} ({(x + 1)}^{p} + 1)) \geq 0$ for $x \in {(0, {(p - 1)}^{1 / p} - 1]}^{n}$ .

If $1 < p \leq 2$ and $x \in (0, b]$ , we derive $p - 1 - {(x + 1)}^{p} \leq 0$ . Using

${(min {x_{1}, x_{2}} + 1)}^{p} + 1 < {(ξ + 1)}^{p} + 1 < {(max {x_{1}, x_{2}} + 1)}^{p} + 1$

and Newton’s inequality leads to

$\begin{matrix} Δ_{A} (E_{k} ({(x + 1)}^{p} + 1)) = p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{\frac{p - 1 - {(ξ + 1)}^{p}}{(p - 1) {[{(ξ + 1)}^{p} + 1]}^{2}} \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} + 1] + \frac{E_{k - 1} ({(\hat{x} + 1)}^{p} + 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} + 1)}\} \\ \geq p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{\frac{p - 1 - {(ξ + 1)}^{p}}{(p - 1) {[{(ξ + 1)}^{p} + 1]}^{2}} \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} + 1] + \frac{n - k}{k - 1} \frac{n - 2}{\sum_{i = 3}^{n} {[{(x_{i} + 1)}^{p} + 1]}^{- 1}}\} \\ \geq p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{\frac{p - 1 - {(ξ + 1)}^{p}}{(p - 1) [{(ξ + 1)}^{p} + 1]} [{(max {x_{1}, x_{2}} + 1)}^{p} + 1] + \frac{n - k}{k - 1} \frac{n - 2}{\sum_{i = 3}^{n} {[{(x_{i} + 1)}^{p} + 1]}^{- 1}}\} \\ \geq p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{\frac{p - 1 - {(b + 1)}^{p}}{2 (p - 1)} [{(b + 1)}^{p} + 1] + \frac{2 (n - k)}{k - 1}\} \\ = \frac{p}{2 (p - 1)} (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ \times \{- {(b + 1)}^{p} [{(b + 1)}^{p} + 1] + \frac{(4 n - 3 k - 1) (p - 1)}{k - 1}\} \geq 0 . \end{matrix}$

By Lemma 1, if

1 < p \leq 2

, then

E_{k} ({(x + 1)}^{p} + 1)

is Schur convex with respect to

x \in {(0, b]}^{n}

; if

p > 2

, then

E_{k} ({(x + 1)}^{p} + 1)

is Schur convex on

{(0, {(p - 1)}^{1 / p} - 1]}^{n}

When $2 \leq k \leq n - 1$ , from (22), we obtain

(24) $\begin{matrix} (ln x_{1} - ln x_{2}) [x_{1} \frac{\partial E_{k} ({(x + 1)}^{p} + 1)}{\partial x_{1}} - x_{2} \frac{\partial E_{k} ({(x + 1)}^{p} + 1)}{\partial x_{2}}] = p (ln x_{1} - ln x_{2}) \\ \times [\frac{x_{1} {(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} + 1} - \frac{x_{2} {(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} + 1}] \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} + 1] E_{k - 2} ({(\hat{x} + 1)}^{p} + 1) \\ + p (x_{1} - x_{2}) [x_{1} {(x_{1} + 1)}^{p - 1} - x_{2} {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} + 1) . \end{matrix}$

Using Equation (24) and Lemma 2, we obtain that

if $p > 0$ , then $E_{k} ({(x + 1)}^{p} + 1)$ is Schur geometrically convex on $R_{+}^{n}$ ;
if $p < 0$ , then $E_{k} ({(x + 1)}^{p} + 1)$ is Schur geometrically concave on ${(0, \frac{1}{| p |}]}^{n}$ ;
if $p < 0$ , then $E_{k} ({(x + 1)}^{p} + 1)$ is Schur geometrically convex on ${[\frac{2}{| p |}, \infty)}^{n}$ .

By (10) and Lemmas 1 and 2, we arrive at Inequalities (18)–(21). The proof of Theorem 2 is complete. □

Theorem 3.

Let $2 \leq k \leq n$ , $p \in R \ {0}$ , $i_{1}, \dots, i_{k} \in N$ ,

$c = {[\frac{n - 1 + \sqrt{{(n - 1)}^{2} + 4 (n - k) (k - 1) / (p - 1)}}{2 (n - k)}]}^{1 / p} - 1, p > 1,$

and

$d = {(\frac{2 n + k - 3}{k - 1})}^{1 / p} - 1, 0 < p < 1 .$

1.
If $k = n$ , $p \geq 1$ , and $x \in R_{+}^{n}$ , or if $2 \leq k \leq n - 1$ , $p > 1$ , and $x \in {(0, c]}^{n}$ , or if $2 \leq k \leq n - 1$ , $p = 1$ , and $x \in R_{+}^{n}$ , then
(25) $(\binom{n}{k}) {[{(G (x) + 1)}^{p} - 1]}^{k} \leq \sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} + 1)}^{p} - 1] \leq (\binom{n}{k}) {[{(A (x) + 1)}^{p} - 1]}^{k} .$
2.
If $k = n$ , $0 < p < 1$ , and $x \in R_{+}^{n}$ or f $2 \leq k \leq n - 1$ , $0 < p < 1$ , and $x \in {(0, d]}^{n}$ , then
$\sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} - 1)}^{p} + 1] \leq (\binom{n}{k}) {[{(G (x) + 1)}^{p} - 1]}^{k} .$
3.
If $p < 0$ , $k = n$ is an even integer, and $x \in R_{+}^{n}$ , or if $2 \leq k \leq n - 1$ , k is an even integer, $p < 0$ , and $x \in {(0, \frac{1}{| p |}]}^{n}$ , then
(26) $\sum_{1 \leq i_{1} < \dots < i_{k} \leq n} \prod_{j = 1}^{k} [{(x_{i_{j}} - 1)}^{p} + 1] \leq (\binom{n}{k}) {[{(A (x) + 1)}^{p} - 1]}^{k} .$
If $p < 0$ , $k = n$ is an odd integer, and $x \in R_{+}^{n}$ , or if $2 \leq k \leq n - 1$ , k is an odd integer, $p < 0$ , and $x \in {(0, \frac{1}{| p |}]}^{n}$ , then Inequality (26) is reversed.

Proof.

The proof is divided into three cases.

Case 1. If $k = n$ , a direct differentiation yields

$\begin{matrix} \frac{\partial E_{n} ({(x + 1)}^{p} - 1)}{\partial x_{1}} = & \frac{p {(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} - 1} E_{n} ({(x + 1)}^{p} - 1) . \end{matrix}$

From Lemma 4, it follows that

$\begin{matrix} (x_{1} - x_{2}) [\frac{\partial E_{n} ({(x + 1)}^{p} - 1)}{\partial x_{1}} - \frac{\partial E_{n} ({(x + 1)}^{p} - 1)}{\partial x_{2}}] \\ = p (x_{1} - x_{2}) [\frac{{(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} - 1} - \frac{{(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} - 1}] E_{n} ({(x + 1)}^{p} - 1) \\ \{\begin{matrix} \leq 0, & if p > 0; \\ \leq 0, & if p < 0 and n is an even integer; \\ \geq 0, & if p < 0 and n is an odd integer \end{matrix} \end{matrix}$

and

$\begin{matrix} (ln x_{1} - ln x_{2}) [x_{1} \frac{\partial E_{n} ({(x + 1)}^{p} - 1)}{\partial x_{1}} - x_{2} \frac{\partial E_{n} ({(x + 1)}^{p} + 1)}{\partial x_{2}}] \\ = p (ln x_{1} - ln x_{2}) [\frac{x_{1} {(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} - 1} - \frac{x_{2} {(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} - 1}] E_{n} ({(x + 1)}^{p} - 1) \\ \{\begin{matrix} \geq 0, & if p \geq 1; \\ \leq 0, & if 0 < p < 1; \\ \leq 0, & if p < 0 and n is an even integer; \\ \geq 0, & if p < 0 and n is an odd integer . \end{matrix} \end{matrix}$

Therefore, from Lemmas 1 and 2, we have

if $p > 0$ , then $E_{n} ({(x + 1)}^{p} - 1)$ is Schur concave on $R_{+}^{n}$ ; if $p < 0$ and n is an even (or odd, respectively) integer, then $E_{n} ({(x + 1)}^{p} - 1)$ is Schur concave (or Schur convex, respectively) on $R_{+}^{n}$ ;
if $p \geq 1$ , then $E_{n} ({(x + 1)}^{p} - 1)$ is Schur geometrically convex on $R_{+}^{n}$ ; if $0 < p < 1$ , then $E_{n} ({(x + 1)}^{p} - 1)$ is Schur geometrically concave on $R_{+}^{n}$ ; if $p < 0$ and n is an even (or odd, respectively) integer, then $E_{n} ({(x + 1)}^{p} - 1)$ is Schur geometrically concave (or convex, respectively) on $R_{+}^{n}$ .

For

k = n

, by Relations (10) and (11) and by Definitions 2 and 3, the inequalities in (25) and (26) hold.

Case 2. When $2 \leq k \leq n - 1$ , since

(27) $\begin{matrix} \frac{\partial E_{k} ({(x + 1)}^{p} - 1)}{\partial x_{1}} = p {(x_{1} + 1)}^{p - 1} [{(x_{2} + 1)}^{p} - 1] E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ + p {(x_{1} + 1)}^{p - 1} E_{k - 1} ({(\hat{x} + 1)}^{p} - 1), \end{matrix}$

we have

(28) $\begin{matrix} Δ (E_{k} ({(x + 1)}^{p} - 1)) ≜ (x_{1} - x_{2}) [\frac{\partial E_{k} ({(x + 1)}^{p} - 1)}{\partial x_{1}} - \frac{\partial E_{k} ({(x + 1)}^{p} - 1)}{\partial x_{2}}] \\ = p (x_{1} - x_{2}) {{(x_{1} + 1)}^{p - 1} [{(x_{2} + 1)}^{p} - 1] - [{(x_{1} + 1)}^{p} - 1] {(x_{2} + 1)}^{p - 1}} \\ \times E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) + p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} - 1) \\ = p (x_{1} - x_{2}) [\frac{{(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} - 1} - \frac{{(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} - 1}] \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} - 1] E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ + p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} - 1) . \end{matrix}$

Utilizing the monotonicity of

p {(x + 1)}^{p - 1}

and Lemma 4, we obtain that

if $0 < p \leq 1$ , then $Δ (E_{k} ({(x + 1)}^{p} - 1)) \leq 0$ for $x \in R_{+}^{n}$ , so the function $E_{n} ({(x + 1)}^{p} - 1)$ is a Schur-concave function on $R_{+}^{n}$ ;
if $p < 0$ and k is an even (or odd, respectively) integer, then $Δ (E_{k} ({(x + 1)}^{p} - 1)) ⋚ 0$ for $x \in R_{+}^{n}$ . This shows from Lemma 1 that, if $p < 0$ and n is an even (or odd, respectively) integer, the function $E_{n} ({(x + 1)}^{p} - 1)$ is Schur concave (or Schur convex, respectively) on $R_{+}^{n}$ ;
if $p > 1$ and $x \in {(0, c]}^{n}$ , from (28), it follows that
(29) $\begin{matrix} Δ (E_{k} ({(x + 1)}^{p} - 1)) = p (x_{1} - x_{2}) {- (x_{1} - x_{2}) {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} \\ - [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}]} E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ + p (x_{1} - x_{2}) [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} - 1) \\ = p (x_{1} - x_{2}) E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) {- (x_{1} - x_{2}) {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} \\ + [{(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1}] [\frac{E_{k - 1} ({(\hat{x} + 1)}^{p} - 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} - 1)} - 1]} . \end{matrix}$

Suppose

x_{1} \neq x_{2}

and

x \in {(0, c]}^{n}

. By Lagrange’s mean value theorem, we have

(30) $\begin{matrix} {(x_{1} + 1)}^{p - 1} - {(x_{2} + 1)}^{p - 1} = (p - 1) (x_{1} - x_{2}) {(ξ + 1)}^{p - 2} \end{matrix}$

for some

ξ

in the open interval

(min {x_{1}, x_{2}}, max {x_{1}, x_{2}})

and

$\frac{{(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1}}{(p - 1) {(ξ + 1)}^{p - 2}} \geq \frac{1}{(p - 1) {(ξ + 1)}^{p}} \geq \frac{1}{(p - 1) {(c + 1)}^{p}} .$

For

k = 2, \dots, n

and

x \in {(0, c]}^{n}

, using Lemma 5 yields

(31) $\frac{E_{k - 1} ({(\hat{x} + 1)}^{p} - 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} - 1)} \leq \frac{(n - k) {\hat{F}}_{1} ({(\hat{x} + 1)}^{p} - 1)}{(k - 1) {\hat{F}}_{0} ({(\hat{x} + 1)}^{p} - 1)} \leq \frac{n - k}{k - 1} {(c + 1)}^{p} - \frac{n - k}{k - 1} .$

For

x \in {(0, c]}^{n}

, by Equation (29) and the inequalities in (30) and (31), we obtain

$\begin{matrix} Δ (E_{k} ({(x + 1)}^{p} - 1)) = p {(x_{1} - x_{2})}^{2} E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ \times \{- {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} + (p - 1) {(ξ + 1)}^{p - 2} [\frac{E_{k - 1} ({(\hat{x} + 1)}^{p} - 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} - 1)} - 1]\} \\ \leq p {(x_{1} - x_{2})}^{2} (p - 1) {(ξ + 1)}^{p - 2} E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ \times [- \frac{{(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1}}{(p - 1) {(ξ + 1)}^{p - 2}} + \frac{n - k}{(k - 1) (n - 2)} \sum_{i = 3}^{n} {(x_{i} + 1)}^{p} - \frac{n - 1}{k - 1}] \\ \leq p {(x_{1} - x_{2})}^{2} (p - 1) {(ξ + 1)}^{p - 2} E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ \times [- \frac{1}{(p - 1) {(c + 1)}^{p}} + \frac{n - k}{k - 1} {(c + 1)}^{p} - \frac{n - 1}{k - 1}] = 0 . \end{matrix}$

Therefore, if

p > 1

, then

Δ (E_{k} ({(x + 1)}^{p} - 1)) \leq 0

for

x \in {(0, c]}^{n}

. Therefore, from Lemma 1, it follows that

if $0 < p \leq 1$ , the function $E_{k} ({(x + 1)}^{p} - 1)$ is Schur concave on $R_{+}^{n}$ ;
if $p < 0$ and k is an even (or odd, respectively) integer, the function $E_{k} ({(x + 1)}^{p} - 1)$ is Schur concave (or Schur convex, respectively) on $R_{+}^{n}$ ;
if $p > 1$ , the function $E_{k} ({(x + 1)}^{p} - 1)$ is Schur concave on ${(0, c]}^{n}$ .

Case 3. If $2 \leq k \leq n - 1$ , then from (27), it follows that

$\begin{matrix} Δ_{G} (E_{k} ({(x + 1)}^{p} - 1) ≜ (ln x_{1} - ln x_{2}) [x_{1} \frac{\partial E_{k} ({(x + 1)}^{p} - 1)}{\partial x_{1}} - x_{2} \frac{\partial E_{k} ({(x + 1)}^{p} - 1)}{\partial x_{2}}] \\ = p (ln x_{1} - ln x_{2}) [\frac{x_{1} {(x_{1} + 1)}^{p - 1}}{{(x_{1} + 1)}^{p} - 1} - \frac{x_{2} {(x_{2} + 1)}^{p - 1}}{{(x_{2} + 1)}^{p} - 1}] \prod_{i = 1}^{2} [{(x_{i} + 1)}^{p} - 1] E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ + p (ln x_{1} - ln x_{2}) [x_{1} {(x_{1} + 1)}^{p - 1} - x_{2} {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} - 1) . \end{matrix}$

Using the monotonicity of function

p x {(x + 1)}^{p - 1}

and Lemma 4 results in

if $p \geq 1$ , then $Δ (E_{k} ({(x + 1)}^{p} - 1) \geq 0$ for $x \in R_{+}^{n}$ ;
if $p < 0$ and k is an even (or odd, respectively) integer, then $Δ (E_{k} ({(x + 1)}^{p} - 1) ⋚ 0$ for $x \in {(0, \frac{1}{| p |}]}^{n}$ ;
if $0 < p < 1$ , then
(32) $\begin{matrix} Δ_{G} (E_{k} ({(x + 1)}^{p} - 1) = p (ln x_{1} - ln x_{2}) {x_{1} {(x_{1} + 1)}^{p - 1} [{(x_{2} + 1)}^{p} - 1] \\ - [{(x_{2} + 1)}^{p} - 1] x_{2} {(x_{2} + 1)}^{p - 1}} E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ + p (ln x_{1} - ln x_{2}) [x_{1} {(x_{1} + 1)}^{p - 1} - x_{2} {(x_{2} + 1)}^{p - 1}] E_{k - 1} ({(\hat{x} + 1)}^{p} - 1) \\ = p (ln x_{1} - ln x_{2}) E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) {(x_{1} - x_{2}) {(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} \\ + [x_{1} {(x_{1} + 1)}^{p - 1} - x_{2} {(x_{2} + 1)}^{p - 1}] [\frac{E_{k - 1} ({(\hat{x} + 1)}^{p} - 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} - 1)} - 1]} . \end{matrix}$

Suppose

x_{1} \neq x_{2}

, by Lagrange’s mean value theorem, we have

(33) $x_{1} {(x_{1} + 1)}^{p - 1} - x_{2} {(x_{2} + 1)}^{p - 1} = (x_{1} - x_{2}) {(ξ + 1)}^{p - 2} (1 + p ξ)$

for some

ξ \in (min {x_{1}, x_{2}}, max {x_{1}, x_{2}})

. Therefore, using Lemma 5 leads to

(34) $\frac{E_{k - 1} ({(\hat{x} + 1)}^{p} - 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} - 1)} \leq \frac{n - k}{(k - 1) (n - 2)} \sum_{i = 3}^{n} {(x_{i} + 1)}^{p} - \frac{n - k}{k - 1}, x \in R_{+}^{n} .$

For

x \in {(0, d]}^{n}

, substituting (33) and (34) into (32) yields

$\begin{matrix} Δ_{G} (E_{k} ({(x + 1)}^{p} - 1) = p (ln x_{1} - ln x_{2}) (x_{1} - x_{2}) E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ \times \{{(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} + {(ξ + 1)}^{p - 2} (1 + p ξ) [\frac{E_{k - 1} ({(\hat{x} + 1)}^{p} - 1)}{E_{k - 2} ({(\hat{x} + 1)}^{p} - 1)} - 1]\} \\ \leq p (ln x_{1} - ln x_{2}) (x_{1} - x_{2}) E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) {{(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1} \\ + {(ξ + 1)}^{p - 2} (1 + p ξ) [\frac{n - k}{(k - 1) (n - 2)} \sum_{i = 3}^{n} {(x_{i} + 1)}^{p} - \frac{n - 1}{k - 1}]} \\ = p (ln x_{1} - ln x_{2}) (x_{1} - x_{2}) {(ξ + 1)}^{p - 2} (1 + p ξ) E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ \times [\frac{{(x_{1} + 1)}^{p - 1} {(x_{2} + 1)}^{p - 1}}{{(ξ + 1)}^{p - 2} (1 + p ξ)} + \frac{n - k}{(k - 1) (n - 2)} \sum_{i = 3}^{n} {(x_{i} + 1)}^{p} - \frac{n - 1}{k - 1}] \\ \leq p (ln x_{1} - ln x_{2}) (x_{1} - x_{2}) {(ξ + 1)}^{p - 2} (1 + p ξ) E_{k - 2} ({(\hat{x} + 1)}^{p} - 1) \\ \times [{(d + 1)}^{2 p} + \frac{n - k}{k - 1} {(d + 1)}^{p} - \frac{n - 1}{k - 1}] = 0 . \end{matrix}$

Therefore, using Lemma 2, we obtain that

if $p \geq 1$ , the function $E_{k} ({(x + 1)}^{p} - 1)$ is Schur geometrically convex on $R_{+}^{n}$ ;
if $p < 0$ and k is an even (or odd, respectively) integer, the function $E_{k} ({(x + 1)}^{p} - 1)$ is a Schur geometrically-concave (or convex, respectively) function on ${(0, \frac{1}{| p |}]}^{n}$ ;
if $0 < p < 1$ , the function $E_{k} ({(x + 1)}^{p} - 1)$ is Schur geometrically concave on ${(0, d]}^{n}$ .

For

k = n

, by Relations (10) and (11) and by Definitions 2 and 3, the inequalities in (25) and (26) hold. Theorem 3 is thus proven. □

Remark 1.

This paper is a corrected and revised version of the preprint [29].

Author Contributions

The authors contributed equally to this work. The authors read and approved the final manuscript.

Funding

The authors Bo-Yan Xi, Ying Wu and Feng Qi were partially supported by the National Natural Science Foundation of China under Grant No. 11361038, by the Foundation of the Research Program of Science and Technology at Universities of Inner Mongolia Autonomous Region under Grant No. NJZZ18154, and by the Inner Mongolia Autonomous Region Natural Science Foundation Project under Grant No. 2018LH01002, China.

Acknowledgments

The authors are thankful to the anonymous referees for their careful corrections to and valuable comments on the original version of this paper.

Conflicts of Interest

The authors declare no conflict of interest.

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In the paper, by some methods in the theory of majorization, the authors generalize several inequalities related to multivariate geometric means.

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Title

Generalizations of Several Inequalities Related to Multivariate Geometric Means

Author

Bo-Yan, Xi¹

; Wu, Ying¹

; Huan-Nan Shi²

; Feng, Qi³

¹ College of Mathematics, Inner Mongolia University for Nationalities, Tongliao 028043, Inner Mongolia, China
² Department of Electronic Information, Teacher’s College, Beijing Union University, Beijing 100011, China
³ Institute of Mathematics, Henan Polytechnic University, Jiaozuo 454010, Henan, China; School of Mathematical Sciences, Tianjin Polytechnic University, Tianjin 300387, China

First page

552

Publication year

2019

Publication date

2019

Publisher

MDPI AG

e-ISSN

22277390

Source type

Scholarly Journal

Language of publication

English

DOI

https://doi.org/10.3390/math7060552

ProQuest document ID

2548636276

Generalizations of Several Inequalities Related to Multivariate Geometric Means

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