Sharp inequalities related to the constant e

The aim of this work is to extend the results obtained by Batir and Cancan in (Int. J. Math. Educ. Sci. Technol. 40(8):1101-1109, 2009).

MSC:26A09, 33B10, 26D99.

Batir and Cancan [[1], Theorem 2.5] presented the following sharp inequalities:

where $c=\frac{1}{\sqrt{2-ln4}}-1=0.27649\cdots$ and $d=\frac{1}{3}$. The proof is based on the fact that the function

is strictly increasing on $(0,\mathrm{\infty })$, while inequalities (1) follow from $\omega (1)\le \omega (n)<\omega (\mathrm{\infty })$. Such an approach of the problem does not offer good results in the left-hand side inequality (1), when n approaches infinity. As we wish to see (1) as an accurate approximation of the form

we are interested in finding $\delta (n)$ which gives the best such approximation for large values of n. Moreover, numerical computations show us that for large values of n, the expression ${(1+1/n)}^n$ gets closer to the right-hand side of (1). This fact suggests us that the best approximation (2) is obtained when $\delta (n)$ tends to $1/3$, as $n\to \mathrm{\infty }$. For $\delta (n)=1/3$, we deduce

but a better result is

The rigorous argument is the following theorem, which is also an improvement of the Batir and Cancan inequality (1).

Theorem 1 For every real number $x\ge 1$, we have

Proof Let

and

We have $f(1)=\frac{17}{25}-ln2=-0.013\cdots <0$, $g(1)=\frac{85,351}{121,801}-ln2=0.0075\cdots >0$ and

where

Evidently, f is concave, g is convex on $[1,\mathrm{\infty })$, with $f(\mathrm{\infty })=g(\mathrm{\infty })=0$, so $f<0$ and $g>0$ on $[1,\mathrm{\infty })$. The proof is completed. □

The same remarks we make on Batir and Cancan’s assertion [[1], Theorem 2.6], which is proven to have some computation errors, since the expression ${(1+1/n)}^{n+1}$ can be approximated for large values of n as

but a better result is

as we can see from the following.

Theorem 2 For every real number $x\ge 1$, we have

Proof Let

We have $u(1)=\frac{113}{81}-2ln2=0.00876\cdots >0$, $v(1)=\frac{8,448,529}{6,115,729}-2ln2=-0.00485\cdots <0$ and

where

Evidently, v is concave, u is convex, with $u(\mathrm{\infty })=v(\mathrm{\infty })=0$, so $v<0$ and $u>0$ on $[1,\mathrm{\infty })$. The proof is completed. □

In this section we discuss the problem of approximating ${(1+1/n)}^{n+a}$, $a\in [0,1]$, in the form

More precisely, we propose as an open problem the following approximation formula:

Particular values $a=0$ and $a=1$ in (5) lead again to (3) and (4).

The special case $a=1/2$ is treated at the final part of this section.

By now, we proved the approximation formula (5) for

where $\theta =0.82462\cdots$ is the unique real root of $558a-1,098a^2+675a^3-92$.

This assertion is sustained by the following three theorems.

Theorem 3 Let $a\in [0,\frac{4-\sqrt{2}}{7})$. Then there exists $x_1>0$ (depending on a) such that for every real number $x\ge x_1$, the following inequalities hold true:

Theorem 4 Let $a\in (\frac{1}{2},\frac{4+\sqrt{2}}{7})$. Then there exists $x_2>0$ (depending on a) such that, for every real number $x\ge x_2$, the following inequalities hold true:

Theorem 5 Let $a\in (\theta ,1]$. Then there exists $x_3>0$ (depending on a) such that, for every real number $x\ge x_3$, the following inequalities hold true:

Inequalities (6)-(8) are closely related to the functions

and

We have

where

and

where

Proofs of Theorems 3 and 4 For $a\in [0,\frac{4-\sqrt{2}}{7})\cup (\frac{1}{2},\frac{4+\sqrt{2}}{7})$, the leading coefficients of the polynomials P and Q are negative. We are in a position to consider $j>0$ (depending on a) such that $P(x)<0$ and $Q(x)<0$, for every $x\in [j,\mathrm{\infty })$. By (9) and (10), s is concave and t is convex. But $s(\mathrm{\infty })=t(\mathrm{\infty })=0$, so $s<0$ and $t>0$ on $[j,\mathrm{\infty })$.

Now inequalities $s(x)<0$ and $t(x)>0$, for every $x\in [j,\mathrm{\infty })$ are (6) and (7) and we are done. □

Proof of Theorem 5 For $a\in (\theta ,1]$, the leading coefficients of polynomials P and Q are positive. We are in a position to consider $l>0$ (depending on a) such that $P(x)>0$ and $Q(x)>0$, for every $x\in [l,\mathrm{\infty })$. By (9) and (10), now s is convex and t is concave. But $s(\mathrm{\infty })=t(\mathrm{\infty })=0$, so $s>0$ and $t<0$ on $[l,\mathrm{\infty })$.

Now inequalities $s(x)>0$ and $t(x)<0$, for every $x\in [l,\mathrm{\infty })$ are (6) and (7) and we are done. □

The special case $a=1/2$ provides the approximation formula

It is sustained by the following.

Theorem 6 For every real number $x\ge 1$, the following inequalities hold:

Proof Let us define the functions

and

We have

and

where

Evidently, b is concave, c is convex, with $b(\mathrm{\infty })=c(\mathrm{\infty })=0$, so $b<0$ and $c>0$ on $[1,\mathrm{\infty })$. The proof is completed. □

In case $a=1/2$, the entire asymptotic representation

can be constructed. In this sense, we write (12) as

where

By using the Maclaurin expansion of $ln(1+t)$, with $t=x^{-1}$, we deduce that

Now the coefficients $a_j$ in (12) can be inductively obtained by equating the following relation:

The first coefficients are $a_0=\frac{1}{3}$, $a_1=-\frac{7}{90}$ (see (11)), then $a_2=\frac{16}{405}$, $a_3=-\frac{2,141}{85,050}$, ….

Further research in the problem of approximating the constant e can be found in [1–4].

Finally, we leave as an open problem the approximation formula (5) for values of $a\in [0,1]$ other than those discussed in this paper.

The authors would like to thank the Editor and the referees for the comments that improved the initial form of this manuscript. The work of Cristinel Mortici was supported by a grant of the Romanian National Authority for Scientific Research, CNCS-UEFISCDI project number PN-II-ID-PCE-2011-3-0087. Cristinel Mortici contributed to this work during his visit at National Technical University of Athens, Greece. He would like to thank Prof. Themistocles M Rassias for hospitality.

Authors and Affiliations

1. College of Mathematics and Informatics, Henan Polytechnic University, Jiaozuo, 454003, China

   Yue Hu

2. Valahia University of Târgovişte, Bd. Unirii 18, Târgovişte, 130082, Romania

   Cristinel Mortici

3. Academy of Romanian Scientists, Splaiul Independenţei 54, Bucharest, 050094, Romania

   Cristinel Mortici

Corresponding author

Correspondence to Yue Hu.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

The paper is a joint work of all the authors who contributed equally to the final version of the paper. All authors read and approved the final manuscript.

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