Three families of two-parameter means constructed by trigonometric functions

In this paper, we establish three families of trigonometric functions with two parameters and prove their monotonicity and bivariate log-convexity. Based on them, three two-parameter families of means involving trigonometric functions, which include Schwab-Borchardt mean, the first and second Seiffert means, Sándor’s mean and many other new means, are defined. Their properties are given and some new inequalities for these means are proved. Lastly, two families of two-parameter hyperbolic means, which similarly contain many new means, are also presented without proofs.

MSC: 26E60, 26D05, 33B10, 26A48.

Let ${\mathbb{R}}_{+}$ denote the set of positive real numbers and $a,b\in {\mathbb{R}}_{+}$. A two-variable continuous function $M:{\mathbb{R}}_{+}^2\to {\mathbb{R}}_{+}$ is called a mean on ${\mathbb{R}}_{+}$ if

holds. For convenience, however, we assume that $a\ne b$ in what follows unless otherwise stated.

There exist many elementary means. They can be divided into three classes according to main categories of basic elementary functions by their composition. The first class is mainly constructed by power functions, like the Stolarsky means [1] defined by

and Gini means [2] defined by

It is well known that the Stolarsky and Gini means are very important, they contain many famous means, for instance, $S_{1,0}(a,b)=L(a,b)$ - the logarithmic mean, $S_{1,1}(a,b)=I(a,b)$ - the identric (exponential) mean, $S_{2,1}(a,b)=G_{1,0}(a,b)=A(a,b)$, $S_{2p,p}(a,b)=G_{p,0}(a,b)=A^{1/p}(a^p,b^p)=A_p$ - the p-order power mean, $S_{p,0}(a,b)=L^{1/p}(a^p,b^p)=L_p$ - the p-order logarithmic mean, $S_{p,p}(a,b)=I^{1/p}(a^p,b^p)=I_p$ - the p-order identric (exponential) mean; $G_{2,0}(a,b)=Q(a,b)$ - the quadratic mean, $G_{1,1}(a,b)=Z(a,b)$ - the power-exponential mean, $G_{p,p}(a,b)=Z^{1/p}(a^p,b^p)=Z_p$ - the p-order power-exponential mean, etc. The second class is mainly made up of exponential and logarithmic functions, such as the second part of Schwab-Borchardt mean (see [3], [[4], Section 3, equation (2.3)], [5]) defined by

the logarithmic mean $L(a,b)$, the exponential mean defined by

given in [6] (also see [7, 8]) by Sándor and Toader, and the Neuman-Sándor mean defined in [5] by

It should be noted that NS is actually a Schwab-Borchardt mean since $NS(a,b)=SB(Q,A)$ mentioned by Neuman and Sándor in [5].

The third class is mainly composed of trigonometric functions and their inverses, for example, the first part of Schwab-Borchardt mean defined by (1.3), the first and second Seiffert means [9, 10] defined by

respectively, and the new mean presented recently by Sándor in [11, 12] defined as

where $A=(a+b)/2$, $G=\sqrt{ab}$, P is defined by (1.5). As Neuman and Sándor pointed out in [5], the first and second Seiffert means are generated by the Schwab-Borchardt mean, because $SB(G,A)=P(a,b)$, $SB(A,Q)=T(a,b)$.

From the published literature, the first and second classes have been focused on and investigated, and there are a lot of references (see [1, 13–24]). While the third class is relatively little known.

The aim of this paper is to define three families of two-parameter means constructed by trigonometric functions, which include the Schwab-Borchardt mean SB, the first and second Seiffert means P, T, and Sándor’s mean X.

The paper is organized as follows. In Section 2, some useful lemmas are given. Three families of trigonometric functions and means with two parameters and their properties are presented in Sections 3-5. In Section 6, we establish some new inequalities for two-parameter trigonometric means. In the last section, two families of two-parameter hyperbolic means are also presented in the same way without proofs.

For later use, we give the following lemmas.

Lemma 2.1 [[25], p.26]

Let f be a differentiable function defined on an interval I. Then the divided differences function F defined on $I^2$ by

is increasing (decreasing) in both variables if and only if f is convex (concave).

Lemma 2.2 [[26], Theorem 1]

Let f be a differentiable function defined on an interval I, and let F be defined on $I^2$ by (2.1). Then the following statements are equivalent:

1. (i)

   $f^{\prime }$ is convex (concave) on I,

2. (ii)

   $F(x,y)\le (\ge )\frac{f^{\prime }(x)+f^{\prime }(y)}{2}$ for all $x,y\in I$,

3. (iii)

   F is bivariate convex (concave) on $I^2$.

Lemma 2.3 If $f:(-m,m)\to \mathbb{R}$ is a differentiable even function such that $f^{\prime }$ is convex in $(0,m)$, then the function $x\mapsto F(c+x,c-x)$ defined by (2.1) increases for positive x if $c\ge 0$ and decreases if $c\le 0$ provided $c+x,c-x\in (-m,m)$.

Proof Differentiation yields

Since f is an even and differentiable function, it is easy to verify that $g_c(-x)=g_c(x)$, $g_{-c}(x)=-g_c(x)$. From this we only need to prove that for $c\ge 0$, $F^{\prime }(c+x,c-x)>0$ for $x\in (0,m)$ provided $c+x,c-x\in (-m,m)$ if $f^{\prime }$ is convex on $(0,m)$.

To this end, we first show two facts. Firstly, application of Lemma 2.2 leads to

The second one states that if h is a continuous and odd function on $[-d,d]$ ($d>0$) and is convex on $[0,d]$, then, for $u,v\in (0,d]$ with $u>v$, the inequality

holds. Indeed, using the fact $h(0)=0$ and the property of a convex function, the second one easily follows.

Now we can prove the desired result. When $x\in (0,m)$, application of the two previous facts and notice that $f^{\prime }$ is odd on $(-m,m)$ lead to

Hence, $F^{\prime }(c+x,c-x)=x^{-1}{g}_c(x)>0$ for $c,x\ge 0$.

This completes the proof. □

Lemma 2.4 The following inequalities are true:

Proof Inequalities (2.2)-(2.5) easily follow by the elementary differential method, and we omit all details here. Inequality (2.6) can be derived from a well-known inequality given in [[27], p.238]) by Adamović and Mitrinović for $0<|x|<\pi /2$, while it is obviously true for $\pi /2\le |x|<\pi$. Inequality (2.7) can be found in [[28], Problem 5.11, 5.12]. This lemma is proved. □

Lemma 2.5 [[29], pp.227-229]

Let $0<|x|<\pi$. Then we have

where $B_n$ is the Bernoulli number.

3.1 Two-parameter sine functions

We begin with the form of hyperbolic functions of Stolarsky means defined by (1.1) to introduce the two-parameter sine functions. Let $t=ln\sqrt{b/a}$. Then the Stolarsky means can be expressed in hyperbolic functions as

where

We call $Sh(p,q,t)$ two-parameter hyperbolic sine functions. Accordingly, for suitable p, q, t, we can give the definition of sine versions of $Sh(p,q,t)$ as follows.

Definition 3.1 The function $\tilde{S}$ is called a sine function with parameters if $\tilde{S}$ is defined on ${[-2,2]}^2\times (0,\pi /2)$ by

$\tilde{S}$ is said to be a two-parameter sine function for short.

Now let us observe its properties.

Proposition 3.1 Let the two-parameter sine function $\tilde{S}$ be defined by (3.2). Then

1. (i)

   $\tilde{S}$ is decreasing in p, q on $[-2,2]$, and is log-concave in $(p,q)$ for $(p,q)\in {[0,2]}^2$ and log-convex for $(p,q)\in {[-2,0]}^2$;

2. (ii)

   $\tilde{S}$ is decreasing and log-concave in t on $(0,\pi /2)$ for $p+q>0$, and is increasing and log-convex for $p+q<0$.

Proof We have

where

1. (i)

   We prove that $\tilde{S}$ is decreasing in p, q on $[-2,2]$, and is log-concave in $(p,q)$ for $(p,q)\in {[0,2]}^2$ and log-convex for $(p,q)\in {[-2,0]}^2$. By Lemmas 2.1 and 2.2, it suffices to check that f is concave in $p,q\in [-2,2]$ and that $f^{\prime }$ is concave for $p,q\in [0,2]$ and convex for $p,q\in [-2,0]$.

Differentiation and employing (2.2), (2.6) yield that for $t\in (0,\pi /2)$,

which prove part one.

1. (ii)

   Now we show that $\tilde{S}$ is decreasing and log-concave in t on $(0,\pi /2)$ for $p+q>0$, and increasing and log-convex for $p+q<0$. It is easy to verify that $f^{\prime }$ is an odd function on $[-2,2]$, and so $ln\tilde{S}(p,q,t)$ can be written in the form of integral as

   $$ln\tilde{S}(p,q,t)=\frac{1}{p-q}{\int }_q^p{f}^{\prime }(x)dx=\frac{p+q}{|p|+|q|}\frac{1}{|p|-|q|}{\int }_{|q|}^{|p|}{f}^{\prime }(x)dx.$$

   (3.7)

Differentiation and application of (2.2) and (2.3) give

It follows from (3.7) that

which proves part two and, consequently, the proof is completed. □

From the proof of Proposition 3.1, we see that f defined by (3.3) is an even function and $f^{‴}(x)<0$ for $x\in [0,2]$ given by (3.6). Let $m=2$ and $c-x=p\in (-2,2)$. Then by Lemma 2.3 we immediately obtain the following.

Proposition 3.2 For fixed $c\in (-2,2)$, let $-min(2,2-2c)\le p\le min(2,2c+2)$ and $t\in (0,\pi /2)$, and let $\tilde{S}(p,q,t)$ be defined by (3.2). Then the function $p\mapsto \tilde{S}(p,2c-p,t)$ is decreasing on $[-2,c)$ and increasing on $(c,2c+2]$ for $c\in (-2,0]$, and is increasing on $[2c-2,c)$ and decreasing on $(c,2]$ for $c\in (0,2)$.

By Propositions 3.1 and 3.2 we can obtain some new inequalities for trigonometric functions.

Corollary 3.1 For $t\in (0,\pi /2)$, we have

Proof (i) By Proposition 3.2, $\tilde{S}(p,2-p,t)$ is increasing in p on $[0,1)$ and decreasing on $[1,2]$, we have

Due to $\tilde{S}(1,q,t)$ is decreasing in q on $[-2,2]$, we get

Simplifying leads to (3.8).

1. (ii)

   Similarly, since $p\mapsto \tilde{S}(p,1-p,t)$ is increasing on $[-1,1/2)$ and decreasing on $(1/2,2]$, we get

   $$\begin{array}{rcl}\tilde{S}(2,-1,t)& <& \tilde{S}(\frac{3}{2},-\frac{1}{2},t)<\tilde{S}(\frac{4}{3},-\frac{1}{3},t)<\tilde{S}(1,0,t)\\ <& \tilde{S}(\frac{4}{5},\frac{1}{5},t)<\tilde{S}(\frac{3}{4},\frac{1}{4},t)<\tilde{S}(\frac{2}{3},\frac{1}{3},t)<\tilde{S}(\frac{1}{2},\frac{1}{2},t),\end{array}$$

while $\tilde{S}(\frac{1}{2},\frac{1}{2},t)<\tilde{S}(\frac{1}{2},\frac{1}{4},t)$ follows by the monotonicity of $\tilde{S}(1/2,q,t)$ in q on $[-2,2]$. Simplifying yields inequalities (3.9). □

3.2 Definition of two-parameter sine means and examples

Being equipped with Propositions 3.1, 3.2, we can easily establish a family of means generated by (3.2). To this end, we have to prove the following statement.

Theorem 3.1 Let $p,q\in [-2,2]$, and let $\tilde{S}(p,q,t)$ be defined by (3.2). Then, for all $a,b>0$, ${\mathcal{S}}_{p,q}(a,b)$ defined by

is a mean of a and b if and only if $0\le p+q\le 3$.

Proof Without lost of generality, we assume that $0<a\le b$. Let $t=arccos(a/b)$. Then the statement in question is equivalent to that the inequalities

hold for $t\in (0,\pi /2)$ if and only if $0\le p+q\le 3$, where $\tilde{S}(p,q,t)$ is defined by (3.2).

Necessity. We prove that the condition $0\le p+q\le 3$ is necessary. If (3.11) holds, then we have

Using power series extension gives

Hence we have

which implies that $0\le p+q\le 3$.

Sufficiency. We show that the condition $0\le p+q\le 3$ is sufficient. Clearly, $max(p,q)\ge 0$. Now we distinguish two cases to prove (3.11).

Case 1: $p,q\ge 0$ and $p+q\le 3$. This case can be divided into two subcases. In the first subcase of $(p,q)\in [0,2]\times [0,1]$ or $[0,1]\times [0,2]$, by the monotonicity of $\tilde{S}(p,q,t)$ in p, q on $[-2,2]$, we get

In the second subcase of $(p,q)\in {[1,2]}^2$ and $p+q\le 3$, it is derived that

From Proposition 3.2 it is seen that $\tilde{S}(p,3-p,t)$ is increasing on $[1,3/2]$ and decreasing on $[3/2,2]$, which reveals that $\tilde{S}(p,3-p,t)>\tilde{S}(2,1,t)=cost$, that is, the desired result.

Case 2: $p\ge 0$, $q\le 0$ or $p\le 0$, $q\ge 0$ and $p+q\le 3$. Because of the symmetry of p and q, we assume that $p\ge q$. Then $p\ge 0$, $q\le 0$. Due to $p\in [0,2]$ and $p+q\le 3$, we have $p\le min(3-q,2)=2$. Using the monotonicity of $\tilde{S}(p,q,t)$ in p, q on $[-2,2]$ again leads us to

On the other hand, from $p+q\ge 0$, that is, $p\ge -q$, it is acquired that

which proves Case 2 and the sufficiency is complete. □

Now we can give the definition of the two-parameter sine means as follows.

Definition 3.2 Let $a,b>0$ and $p,q\in [-2,2]$ such that $0\le p+q\le 3$, and let $\tilde{S}(p,q,t)$ be defined by (3.2). Then ${\mathcal{S}}_{p,q}(a,b)$ defined by (3.10) is called a two-parameter sine mean of a and b.

As a family of means, the two-parameter sine means contain many known and new means.

Example 3.1 Clearly, for $0<a<b$, all the following

are means of a and b, where $SB(a,b)$ is the Schwab-Borchardt mean defined by (1.3).

To generate more means involving a two-parameter sine function, we need to note a simple fact: If $M_1$, $M_2$, M are means of distinct positive numbers x and y with $M_1<M_2$, then $M(M_1,M_2)$ is also a mean and satisfies inequalities

Applying the fact to Definition 3.2, we can obtain more means involving a two-parameter sine function, in which, as mentioned in Section 1, G, A and Q denote the geometric, arithmetic and quadratic means, respectively, and we have $G<A<Q$.

Example 3.2 Let $(a,b)\to (G,A)$. Then both the following

are means of a and b, where $P=P(a,b)$ is the first Seiffert mean defined by (1.5) and $X(a,b)$ is Sándor’s mean defined by (1.7). Also, they lie between G and A.

Example 3.3 Let $(a,b)\to (G,Q)$. Then both the following

are means of a and b, and between G and Q.

It is interesting that the new mean $U(a,b)$ is somewhat similar to the second Seiffert mean $T(a,b)$.

Example 3.4 Let $(a,b)\to (A,Q)$. Then both the following

are means of a and b, where $T=T(a,b)$ is the second Seiffert mean defined by (1.6). Moreover, they are between A and Q.

3.3 Properties of two-parameter sine means

From Propositions 3.1, 3.2 and Theorem 3.1, we easily obtain the properties of two-parameter sine means.

Property 3.1 The two-parameter sine means ${\mathcal{S}}_{p,q}(a,b)$ are symmetric with respect to parameters p and q.

Property 3.2 The two-parameter sine means ${\mathcal{S}}_{p,q}(a,b)$ are decreasing in p and q.

Property 3.3 The two-parameter sine means ${\mathcal{S}}_{p,q}(a,b)$ are log-concave in $(p,q)$ for $p,q>0$.

Property 3.4 The two-parameter sine means ${\mathcal{S}}_{p,q}(a,b)$ are homogeneous and symmetric with respect to a and b.

Now we prove the monotonicity of two-parameter sine means in a and b.

Property 3.5 Suppose that $0<a<b$. Then, for fixed $b>0$, the two-parameter sine means ${\mathcal{S}}_{p,q}(a,b)$ are increasing in a on $(0,b)$. For fixed $a>0$, they are increasing in b on $(a,\mathrm{\infty })$.

Proof (i) Let $t=arccos(a/b)$. Then $ln{\mathcal{S}}_{p,q}(a,b):=lnb+ln\tilde{S}(p,q,t)$. Differentiation yields

which, by part two of Proposition 3.1, reveals that $\partial (ln{\mathcal{S}}_{p,q}(a,b))/\partial a>0$, that is, ${\mathcal{S}}_{p,q}(a,b)$ is increasing in a on $(0,b)$.

(ii) Now we prove the monotonicity of ${\mathcal{S}}_{p,q}(a,b)$ in b. We have $ln{\mathcal{S}}_{p,q}(a,b):=lna-lncost+ln\tilde{S}(p,q,t)$. Differentiation leads to

where

here

is an even function on $[-2,2]$. Hence, to prove $\partial (ln{\mathcal{S}}_{p,q}(a,b))/\partial b>0$, it suffices to prove that for $p,q\in [-2,2]$ with $0\le p+q\le 3$, the inequality $H(p,q)+tant>0$ is valid for $t\in (0,\pi /2)$. Differentiation again gives

It follows by Lemmas 2.1 and 2.3 that $H(p,q)$ is decreasing in p and q on $[-2,2]$ and $H(p,3-p)$ is increasing on $[1,3/2)$ and decreasing on $(3/2,2]$.

Next we distinguish two cases to prove $H(p,q)>0$ for $p,q\in [-2,2]$ with $0\le p+q\le 3$.

Case 1: $p,q\ge 0$ and $p+q\le 3$. This case can be divided into two subcases. In the first subcase of $(p,q)\in [0,2]\times [0,1]$ or $[0,1]\times [0,2]$, by the monotonicity of $H(p,q)$ in p, q on $[-2,2]$, we have

In the second subcase of $(p,q)\in {[1,2]}^2$ and $p+q\le 3$, it is derived from the monotonicities of $H(p,q)$ and $H(p,3-p)$ that

Case 2: $p\ge 0$, $q\le 0$ or $p\le 0$, $q\ge 0$ and $p+q\le 3$. Because of the symmetry of p and q, we assume that $p\ge q$. Then $p\ge 0$, $q\le 0$. This together with $p,q\in [-2,2]$ with $p+q\le 3$ gives $p\le min(3-q,2)=2$. Therefore, we have

which proves the monotonicity of ${\mathcal{S}}_{p,q}(a,b)$ in b on $(a,\mathrm{\infty })$ and the proof is complete. □

Remark 3.1 Suppose that $0<a<b$. Then, by the monotonicity of ${\mathcal{S}}_{p,q}(a,b)$ in a and b, we see that

which implies that

Similarly, we have

4.1 Two-parameter cosine functions

In the same way, the Gini means defined by (1.2) can be expressed in hyperbolic functions by letting $t=ln\sqrt{b/a}$:

where

We call $Ch(p,q,t)$ two-parameter hyperbolic cosine functions. Analogously, we can define the two-parameter cosine functions as follows.

Definition 4.1 The function $\tilde{C}$ is called a two-parameter cosine function if $\tilde{C}$ is defined on ${[-1,1]}^2\times (0,\pi /2)$ by

Similar to the proofs of Propositions 3.1 and 3.2, we give the following assertions without proofs.

Proposition 4.1 Let the two-parameter cosine function $\tilde{C}$ be defined by (4.2). Then

1. (i)

   $\tilde{C}$ is decreasing in p, q on $[-1,1]$, and is log-concave in $(p,q)$ for $(p,q)\in {[0,1]}^2$ and log-convex for $(p,q)\in {[-1,0]}^2$;

2. (ii)

   $\tilde{C}$ is decreasing and log-concave in t on $(0,\pi /2)$ for $p+q>0$, and is increasing and log-convex for $p+q<0$.

Proposition 4.2 For fixed $c\in (-1,1)$, let $-min(1,1-2c)\le p\le min(1,1+2c)$ and $t\in (0,\pi /2)$, and let $\tilde{C}(p,q,t)$ be defined by (4.2). Then the function $p\mapsto \mathcal{C}(p,2c-p,t)$ is decreasing on $[-1,c)$ and increasing on $(c,2c+1]$ for $c\in (-1,0]$, and is increasing on $[2c-1,c)$ and decreasing on $(c,1]$ for $c\in (0,1)$.

Propositions 4.1 and 4.2 also contain some new inequalities for trigonometric functions, as shown in the following corollary.

Corollary 4.1 For $t\in (0,\pi /2)$, we have

Proof By Propositions 4.1 and 4.2, we see that $\tilde{C}(1/2,q,t)$ is decreasing in q on $[-1,1]$ and $\tilde{C}(p,1-p,t)$ is decreasing in p on $[0,1/2)$. It is obtained that

which by some simplifications yields the desired inequalities. □

4.2 Definition of two-parameter cosine means and examples

Similarly, by Propositions 4.1, 4.2, we can easily present a family of means generated by (4.2). Of course, we need to prove the following theorem.

Theorem 4.1 Let $p,q\in [-1,1]$, and let $\tilde{C}(p,q,t)$ be defined by (4.2). Then, for all $a,b>0$, ${\mathcal{C}}_{p,q}(a,b)$ defined by

is a mean of a and b if and only if $0\le p+q\le 1$.

Proof We assume that $0<a\le b$ and let $t=arccos(a/b)$. Then the desired assertion is equivalent to the inequalities

hold for $t\in (0,\pi /2)$ if and only if $0\le p+q\le 1$, where $\tilde{C}(p,q,t)$ is defined by (4.2).

Necessity. If (4.5) holds, then we have

Using power series extension gives

Hence we have

which yields $0\le p+q\le 1$.

Sufficiency. We show that the condition $0\le p+q\le 1$ is sufficient. Clearly, $max(p,q)\ge 0$. Now we distinguish two cases to prove (4.5).

Case 1: $p,q\ge 0$ and $p+q\le 1$. By Proposition 4.1 it is obtained that

From Proposition 4.2 it is seen that $\tilde{C}(p,1-p,t)$ is increasing on $[0,1/2]$ and decreasing on $[1/2,1]$, which yields $\tilde{C}(p,1-p,t)>\tilde{C}(1,0,t)=cost$, which proves Case 1.

Case 2: $p\ge 0$, $q\le 0$ or $p\le 0$, $q\ge 0$ and $p+q\le 1$. We assume that $p\ge q$. Then $p\ge 0$, $q\le 0$. Due to $p\in [0,1]$ and $p+q\le 1$, we have $p\le min(1-q,1)=1$. Using the monotonicity of $\tilde{C}(p,q,t)$ in p, q on $[-1,1]$ gives