Sharp bounds for Seiffert mean in terms of root mean square

We find the greatest value α and least value β in (1/ 2,1) such that the double inequality

holds for all a,b > 0 with a ≠ b. Here, T(a, b) = (a-b)/[2 arctan((a-b)/(a + b))] and S(a, b) = [(a² + b²)/2]^{1/ 2}are the Seiffert mean and root mean square of a and b, respectively.

2010 Mathematics Subject Classification: 26E60.

For a,b > 0 with a ≠ b the Seiffert mean T(a, b) and root mean square S(a, b) are defined by

and

respectively. Recently, both mean values have been the subject of intensive research. In particular, many remarkable inequalities and properties for T and S can be found in the literature [1–14].

Let $A\left(a,b\right)=\left(a+b\right)/2,G\left(a,b\right)=\sqrt{ab}$, and M _p (a, b) = ((a^p+b^p)/2)^1/p(p ≠ 0) and $M_0\left(a,b\right)=\sqrt{ab}$ be the arithmetic, geometric, and p th power means of two positive numbers a and b, respectively. Then it is well known that

for all a, b > 0 with a ≠ b.

Seiffert [1] proved that inequalities

hold for all a, b > 0 with a ≠ b.

Chu et al. [5] found the greatest value p₁ and least value p₂ such that the double inequality H_{p 1}(a,b) < T(a,b) < H_{p 2}(a,b) holds for all a,b > 0 with a ≠ b, where H _p (a, b) = ((a^p+ (ab)^p/2+b^p)/3)^1/p(p ≠ 0) and $H_0\left(a,b\right)=\sqrt{ab}$ is the p th power-type Heron mean of a and b.

In [6], Wang et al. answered the question: What are the best possible parameters λ and μ such that the double inequality L _λ (a,b) < T(a,b) < L _μ (a,b) holds for all a,b > 0 with a ≠ b? where L _r (a,b) = (a^r+1+ b^r+1)/(a^r+ b^r) is the r th Lehmer mean of a and b.

Chu et al. [7] proved that inequalities

hold for all a,b > 0 with a ≠ b if and only if p ≤ 3/5 and q ≥ π/4.

Hou and Chu [9] gave the best possible parameters α and β such that the double inequality

holds for all a, b > 0 with a ≠ b.

For fixed a, b > 0 with a ≠ b, let x ∈ [1/2,1] and

Then it is not difficult to verify that f(x) is continuous and strictly increasing in [1/2,1]. Note that f(1/2) = A(a,b) < T(a,b) and f(1) = S(a, b) > T(a, b). Therefore, it is natural to ask what are the greatest value α and least value β in (1/2,1) such that the double inequality

holds for all a, b > 0 with a ≠ b. The main purpose of this article is to answer these questions. Our main result is the following Theorem 1.1.

Theorem 1.1. If α, β ∈ (1/2,1), then the double inequality

holds for all a,b > 0 with a ≠ b if and only if $\alpha \le \left(1+\sqrt{16/{\pi }^2-1}\right)/2$ and $\beta \ge \left(3+\sqrt{6}\right)/6$.

Proof of Theorem 1.1. Let $\lambda =\left(1+\sqrt{16/{\pi }^2-1}\right)/2$ and $\mu =\left(3+\sqrt{6}\right)/6$.

We first proof that inequalities

and

hold for all a, b > 0 with a ≠ b.

From (1.1) and (1.2), we clearly see that both T(a, b) and S(a, b) are symmetric and homogenous of degree 1. Without loss of generality we assume that a > b. Let t = a/b > 1 and p ∈ (1/2,1), then from (1.1) and (1.2) one has

Let

then simple computations lead to

where

Note that

where

Let $g_2\left(t\right)=g_1^{\prime }\left(t\right)/4,g_3\left(t\right)=g_2^{\prime }\left(t\right),g_4\left(t\right)=g_3^{\prime }\left(t\right)/6$. Then simple computations lead to

We divide the proof into two cases.

Case 1. $p=\lambda =\left(1+\sqrt{16/{\pi }^2-1}\right)/2$. Then equations (2.6), (2.11), (2.13), (2.15), and (2.17) lead to

Note that

From (2.10), (2.12), (2.14), (2.16), and (2.23) we clearly see that

From equation (2.16) and inequality (2.23) we clearly see that g₄(t) is strictly increasing in [1, + ∞), then inequality (2.22) and equation (2.27) lead to the conclusion that there exists t₀ > 1 such that g₄(t) < 0 for t ∈ (1,t₀) and g₄(t) > 0 for t ∈ (t₀,+∞). Hence, g₃(t) is strictly decreasing in [1, t₀] and strictly increasing in [t₀, +∞).

It follows from (2.21) and (2.26) together with the piecewise monotonicity of g₃(t) that there exists t₁ > t₀ > 1 such that g₂(t) is strictly decreasing in [1,t₁] and strictly increasing in [t₁,+∞).

From (2.20) and (2.25) together with the piecewise monotonicity of g₂(t) we conclude that there exists t₂ > t₁ > 1 such that g₁(t) is strictly decreasing in [1,t₂] and strictly increasing in [t₂,+∞).

Equations (2.7)-(2.9), (2.19), and (2.24) together with the piecewise monotonicity of g₁(t) imply that there exists t₃ > t₂ > 1 such that f(t) is strictly decreasing in [1,t₃] and strictly increasing in [t₃, +∞).

Therefore, inequality (2.1) follows from equations (2.3)-(2.5) and (2.18) together with the piecewise monotonicity of f(t).

Case 2. $p=\mu =\left(3+\sqrt{6}\right)/6$. Then equation (2.10) becomes

for t > 1.

Equations (2.7)-(2.10) and inequality (2.28) lead to the conclusion that f(t) is strictly increasing in [1, +∞).

Therefore, inequality (2.2) follows from equations (2.3)-(2.5) and the monotonicity of f(t).

From the monotonicity of f(x) = S(xa + (1 - x)b, xb + (1- x)a) in [1/2,1] and inequalities (2.1) and (2.2) we know that inequality (1.3) holds for all $\alpha \le \left(1+\sqrt{16/{\pi }^2-1}\right)/2,\beta \ge \left(3+\sqrt{6}\right)/6$ and a, b > 0 with a ≠ b.

Next, we prove that $\lambda =\left(1+\sqrt{16/{\pi }^2-1}\right)/2$ is the best possible parameter in (1/2,1) such that inequality (2.1) holds for all a, b > 0 with a ≠ b.

For any $1>p>\lambda =\left(1+\sqrt{16/{\pi }^2-1}\right)/2$, from (2.6) one has

Equations (2.3) and (2.4) together with inequality (2.29) imply that for any $1>p>\lambda =\left(1+\sqrt{16/{\pi }^2-1}\right)/2$ there exists T₀ = T₀(p) > 1 such that

for a/b ∈ (T₀, + ∞).

Finally, we prove that $\mu =\left(3+\sqrt{6}\right)/6$ is the best possible parameter in (1/2,1) such that inequality (2.2) holds for all a, b > 0 with a ≠ b.

For any $1/2<p<\mu =\left(3+\sqrt{6}\right)/6$, from (2.11) one has

From inequality (2.30) and the continuity of g₁(t) we know that there exists δ = δ(p) > 0 such that

fort ∈ (1,1 + δ).

Equations (2.3)-(2.5) and (2.7)-(2.10) together with inequality (2.31) imply that for any $1/2<p<\mu =\left(3+\sqrt{6}\right)/6$ there exists δ = δ(p) > 0 such that

for a/b ∈ (1,1 + δ).

This research was supported by the Natural Science Foundation of China under Grant 11071069, the Natural Science Foundation of Hunan Province under Grant 09JJ6003 and the Innovation Team Foundation of the Department of Education of Zhejiang Province under Grant T200924.

Authors and Affiliations

1. Department of Mathematics and Computing Science, Hunan City University, Yiyang, 413000, China

   Yu-Ming Chu

2. Department of Mathematics, Hangzhou Normal University, Hangzhou, 310012, China

   Shou-Wei Hou & Zhong-Hua Shen

Corresponding author

Correspondence to Yu-Ming Chu.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

Y-MC provided the main idea in this article. S-WH carried out the proof of inequality (2.1) in this article. Z-HS carried out the proof of inequality (2.2) in this article. All authors read and approved the final manuscript.

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