Intro
对数均值不等式(Arithmetic-Logarithmic-Geometric mean inequalities,ALG不等式)
当a > 0, b > 0时有:
$\color{grey}{b>\sqrt{\dfrac{a^{2}+b^{2}}{2}}>}$$\dfrac{a+b}{2}>\dfrac{b-a}{\ln b-\ln a}>\sqrt{a b}$$\color{grey}{>\dfrac{2}{\dfrac{1}{a}+\dfrac{1}{b}}>a}$
其中$\dfrac{b-a}{\ln b-\ln a}$为对数均值。
证明
核心思路:令$t=\dfrac{a}{b}$,构造关于t的方程f(t).
证明右半边 : 当a > 0, b > 0, 且a ≠ b时 , 有$\sqrt{ab}< \dfrac{a-b}{ \ln a- \ln b}$.
证明:不妨设a > b, 上不等式⇔$\ln \dfrac{a}{b}< \dfrac{a-b}{ \sqrt{ab}}= \sqrt{ \dfrac{a}{b}}- \sqrt{ \dfrac{b}{a}}$.
令$t= \sqrt{ \dfrac{a}{b}}\in (1,+ \infty)$,
上不等式⇔ $2 \ln t < t - \dfrac{1}{t}$ ⇔ t2 + 2tln t > 1.
构造函数f(t) = t2 + 2tln t, 求导得 : f′(t) = 2t + 2ln t + 2.
当t ∈ (1, +∞)时 , f′(t) > 0恒成立, 即可知f(t)在(1, +∞)上单调递增 .
即有f(t) > f(1) = 1, 所以原不等式成立 .
左半边同理。
套路
- 证明ALG不等式;
- 根据f(x1) = f(x2) = a联立2个等式;
- 指数化对数,有a的相减消a;
- 得到关系,代入具体题目分析。
- *如有需要,方程组可以相加,以得到a与x1, x2的关系。
推论
全部导数:已知0 < b < a,
则: $\dfrac{1}{b}>\dfrac{\dfrac{1}{a}+\dfrac{1}{b}}{2}>\dfrac{1}{\sqrt{a b}}>\dfrac{\ln a-\ln b}{a-b}>\dfrac{2}{a+b}>\sqrt{\dfrac{2}{a^{2}+b^{2}}}>\dfrac{1}{a}$
推论1:
$\begin{array}{ll}x>1 \text { 时, } & 2 \dfrac{x-1}{x+1}<\ln x<\dfrac{1}{2}\left(x-\dfrac{1}{x}\right) \\ x \in(0,1) \text { 时, } & 2 \dfrac{x-1}{x+1}>\ln x>\dfrac{1}{2}\left(x-\dfrac{1}{x}\right)\end{array}$
推论2:
$\begin{array}{ll}x>1 \text { 时, } & \dfrac{x^{2}-1}{x^{2}+1}<\ln x<\sqrt{x}-\dfrac{1}{\sqrt{x}} \\ x \in(0,1) \text { 时 }, & \dfrac{x^{2}-1}{x^{2}+1}>\ln x>\sqrt{x}-\dfrac{1}{\sqrt{x}}\end{array}$
实战演练
小试牛刀
已知 f(x) = ln x − ax有两个零点x1, x2.
- 求a的取值范围; (答案:$a \in\left(0,\frac{1}{e}\right)$)
- 求证 x1 ⋅ x2 > e2.
解析
设2个零点为x1, x2. 则有
$\left\{\begin{array}{l}\ln x_{1}=a x_{1} \\ \ln x_{2}=a x_{2}\end{array}\right.$
ln x1 − ln x2 = a(x1 − x2)
$\dfrac{1}{a}=\dfrac{x_{1}-x_{2}}{\ln x_{1}-\ln x_{2}}<\dfrac{x_{1}+x_{2}}{2}$
$\therefore a >x_{1} \dfrac{2}{x_{1}+x_{2}}$
ln x1 + ln x2 = a(x1 + x2) $>\dfrac{2}{x_{1}+x_{2}} \left(x_{1}+x_{2}\right)=2$
∴ ln (x1x2) > 2,x1x2 > e2
证明: $x-\ln x>2 \dfrac{e^{x}-x}{e^{x}+x}$.
解析
$\dfrac{\ln e^{x}-\ln x}{e^{x}-x}>\dfrac{2}{e^{x}+x}$
$x-\ln x>2 \dfrac{e^{x}-x}{e^{x}+x}$
已知 $f(x)=\ln x-a\left(x-\dfrac{1}{x}\right)$,对于∀x ∈ (1, +∞)都有f(x) < 0恒成立,则正数a的取值范围是( ).
A.(0, 2] B.[2, +∞) C. $\left(0, \dfrac{1}{2}\right]\qquad$ D.$\left[\dfrac{1}{2},+\infty\right)$
解析
D. 解析:$x>1 , \ln x<\dfrac{1}{2}\left(x-\dfrac{1}{a}\right) \leq a\left(x-\dfrac{1}{x}\right)$ $\Rightarrow a \geqslant \dfrac{1}{2}$
已知 $f(x)=\ln (x+1)-\dfrac{a x}{x+a}$,对于∀x ∈ (0, +∞)都有f(x) > 0恒成立,则正数a的取值范围是( ).
A.(0, 2] B.[2, +∞) C.$\left(0, \dfrac{1}{2}\right]\qquad$D.$\left[\dfrac{1}{2},+\infty\right)$
解析
A. 解析:$\ln x>2 \dfrac{x-1}{x+1} \quad(x>1)$
把 x = x + 1 代入得:
x > 0时, $\ln (x+1)>2 \dfrac{x+1-1}{x+1+1}=\dfrac{2x}{x+2}$
$\ln (x+1)>\dfrac{2 x}{x+2} \geqslant \dfrac{ax}{x+a}$
2x + 2a ≥ ax + 2a
∴ a ≤ 2
大显身手
(2016全国课标Ⅰ卷理科21题)已知函数f(x) = (x − 2)ex + a(x − 1)有两个零点.
(Ⅰ) 求a的取值范围 ;
(Ⅱ) 设x1, x2是f(x)的两个零点 , 证明: x1 + x2 < 2.
解析
解析 : (Ⅰ) a ∈ (0, + ∞)
(Ⅱ) 由 (Ⅰ) 知a > 0, x1 < 1 < x2 < 2, f(x1) = f(x2) = 0,
所以$\begin{cases} a(x_{1}-1)^{2}=(2-x_{1})e^{x} \\ a(x_{2}-1)^{2}=(2-x_{2})e^{x_{2}} \end{cases}$
取对数可得$\begin{cases} \ln a+2 \ln (1-x_{1})= \ln (2-x_{1})+x_{1} \\ \ln a+2 \ln (x_{2}-1)= \ln (2-x_{2})+x_{2} \end{cases}$
相减可得$2 ( 1- x _1 ) -2 ( x _2-1 ) = ( 2- x _1 ) -( 2- x _2 ) + x _1- x _2 $,
即2ln (1 − x1) − 2ln (x2 − 1) = ln (2 − x1) − ln (2 − x2) − [(2 − x1) − (2 − x2)],
所以$\dfrac{2 \ln (1-x_{1})-2 \ln (x_{2}-1)}{ \ln (2-x_{1})- \ln (2-x_{2})}= 1- \dfrac{(2-x_{1})-(2-x_{2})}{ \ln (2-x_{1})- \ln (2-x_{2})}$,
若x1+x2 ≥ 2, 则1 − x1 ≤ x2 − 1,
所以$\dfrac{2 \ln (1-x_{1})-2 \ln (x_{2}-1)}{ \ln (2-x_{1})- \ln (2-x_{2})} \leqslant 0$,
所以$1 \leqslant \dfrac{(2-x_{1})-(2-x_{2})}{ \ln (2-x_{1})- \ln (2-x_{2})}<\dfrac{(2-x_{1})+(2-x_{2})}{2}$,
所以(2 − x1) + (2 − x2) > 2, 即x1 + x2 < 2, 这与x1 + x2 ≥ 2矛盾 , 所以x1 + x2 < 2.
已知函数 f(x) = 2ln x − x2 − ax.
求函数 f(x) 的单调区间;
如果函数 f(x) 有两个不同的零点 x1, x2,且x1 < x2,证明:$f'\left(\dfrac{x_{1}+x_{2}}{2}\right)<0$
解析
分析: (1) 单调递增区间为 $\left(0, \dfrac{-a+\sqrt{a^{2}+16}}{4}\right)$, 单调递减区间为 $\left(\dfrac{-a+\sqrt{a^{2}+16}}{4},+\infty\right)$
- 证: $\because f(x)=2 \ln x-x^{2}-a x(x>0) \therefore f^{\prime}(x)=\dfrac{2}{x}-2 x-a$,
由题意得:$\left\{\begin{array}{l}2 \ln x_{1}-x_{1}^{2}-a x_{1}=0 \\ 2 \ln x_{2}-x_{2}^{2}-a x_{2}=0\end{array}\right.$,
两式相减得 : 2(ln x1 − ln x2) − (x12 − x22) = a(x1 − x2)
$\Leftrightarrow\dfrac{2\left(\ln x_{1}-\ln x_{2}\right)-\left(x_{1}^{2}-x_{2}^{2}\right)}{x_{1}-x_{2}}=a$,
欲证 $: f^{\prime}\left(\dfrac{x_{1}+x_{2}}{2}\right)<0$
只需证 $: f^{\prime}\left(\dfrac{x_{1}+x_{2}}{2}\right)=\dfrac{4}{x_{1}+x_{2}}-\left(x_{1}+x_{2}\right)-a<0$,
只需证: $\dfrac{4}{x_{1}+x_{2}}-\left(x_{1}+x_2\right)<a$,
只需证: $\dfrac{4}{x_{1}+x_{2}}-\left(x_{1}+x_2\right)<\dfrac{2\left(\ln x_{1}-\ln x_{2}\right)-\left(x_{1}^{2}-x_{2}^{2}\right)}{x_{1}-x_{2}}$,
只需证:$\dfrac{2}{x_{1}+x_{2}}<\dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}$,
由对数均值不等式$\dfrac{x_{1}-x_{2}}{\ln x_{1}-\ln x_{2}}<\dfrac{x_{1}+x_{2}}{2}$可得$\dfrac{2}{x_{1}+x_{2}}<\dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}$,
从而命题得证.
(2014南通二模)设函数 f(x) = ex − ax + a (a ∈ R), 其图象与x轴交于A(x1, 0),B(x2, 0) 两点, 且 x1 < x2.
求实数a 的取值范围;
证明:$f'(\sqrt{x_{1} x_{2}})<0 .$
解析
解:(1) a > e2 (过程略)
证:(2) ∵f(1) = e > 0,由(1)知1 < x1 < ln a < x2
由 题 意 得: $\left\{\begin{array}{l}e^{x_1} -a x_{1}+a=0\\ e^{x_2}-a x_{2}+a=0\end{array} \Leftrightarrow\left\{\begin{array}{l}e^{x_{1}}=a\left(x_{1}-1\right) \\ e^{x_{2}}=a\left(x_{2}-1\right)\end{array} \Leftrightarrow\left\{\begin{array}{l}x_{1}=\ln \left(x_{1}-1\right)+\ln a \\ x_{2}=\ln \left(x_{2}-1\right)+\ln a\end{array}\right.\right.\right.$
两 式 相 减 得 x1 − x2 = ln (x − 1) − ln (x2 − 1),
$\therefore \dfrac{x_{1}-x_{2}}{\ln \left(x_{1}-1\right)-\ln \left(x_{2}-1\right)}=$ $\dfrac{\left(x_{1}-1\right)-\left(x_{2}-1\right)}{\ln \left(x_{1}-1\right)-\ln \left(x_{2}-1\right)}=1$
由ALG不等式得: $\sqrt{\left(x_{1}-1\right)\left(x_{2}-1\right)}<\dfrac{\left(x_{1}-1\right)-\left(x_{2}-1\right)}{\ln \left(x_{1}-1\right)-\ln \left(x_{2}-1\right)}$
$\therefore \sqrt{\left(x_{1}-1\right)}\left(x_{2}-1\right)<1, \therefore\left(x_{1}-1\right)\left(x_{2}-1\right)<1$
由 $\left\{\begin{array}{l}x_{1}=\ln \left(x_{1}-1\right)+\ln a \\ x_{2}=\ln \left(x_{2}-1\right)+\ln a\end{array}\right.$
两式相加得:x1 + x2 = [ln (x1 − 1) + ln (x2 − 1)]+ 2ln a
即 (x1 + x2) − 2ln a = ln [(x1 − 1)(x2 − 1)],
∵(x1 − 1)(x2 − 1) < 1∴ ln [(x1 − 1)(x2 − 1)] < 0,
$\therefore\left(x_{1}+x_{2}\right)-2 \ln a<0 \therefore \dfrac{x_{1}+x_{2}}{2}<\ln a$,
又$\because \sqrt{x_{1} x_{2}}<\dfrac{x_{1}+x_{2}}{2} \therefore \sqrt{x_{1} x_{2}}<\ln a$ 由(1)知f(x)在 (−∞, ln α) 上单调递减,
$\therefore f^{\prime}\left(\sqrt{x_{1} x_{2}}\right)<f^{\prime}(\ln \alpha)=0$,
则 $f^{\prime}\left(\sqrt{x_{1} x_{2}}\right)<0$ 得证.
(2014陕西理21(3))设函数f(x) = ln (1 + x), g(x) = xf′(x)(x ≥ 0),其中f′(x)是f(x)的导函数. 设 n ∈ N+, 比较g(1) + g(2) + ⋯ + g(n)与 n − f(n) 的大小, 并加以证明.
解析
因为 $g(x)=\dfrac{x}{1+x}$,
所以 g(1) + g(2)+ ⋯ + g(n) $=\dfrac{1}{2}+\dfrac{2}{3}+\cdots+\dfrac{n}{n+1}$ $=n-\left(\dfrac{1}{2}+\dfrac{1}{3}+\cdots+\dfrac{1}{n+1}\right)$,
而 n − f(n) = n − ln (n + 1), 因此只需比较$\dfrac{1}{2}+\dfrac{1}{3}+\cdots+\dfrac{1}{n+1}$ 与 ln (n + 1) 的大小即可.
利用对数均值不等式: 当 b > a > 0 时,有$b>\dfrac{b-a}{\ln b-\ln a} \Rightarrow \ln b-\ln a>\dfrac{b-a}{b}$[注1],
故可命b = n + 1, a=n,
则 $\ln (n+1)-\ln n>\dfrac{1}{n+1}$,
故 $\ln 2-\ln 1>\dfrac{1}{2}$,$\ln 3-\ln 2>\dfrac{1}{3}, \cdots, \ln (n+1)-\ln n>\dfrac{1}{n+1},$
将以上各不等式左右两边分别相加得
$\ln (n+1)>\dfrac{1}{2}+\dfrac{1}{3}+\dfrac{1}{4}$$+\cdots+\dfrac{1}{n}+\dfrac{1}{n+1},$
即得 g(1) + g(2) + ⋯ + g(n)> n − f(n)
注1
【注1】这里如果用$b>\dfrac{b-a}{\ln b-\ln a}$可以很快推出$\ln (n+1)-\ln n>\dfrac{1}{n+1}$. 但是如果使用常规(常用)的ALG不等式也可以分步推出相同结论。
令b = n + 1, a=n,根据ALG不等式,有:
$\dfrac{(n+1)-n}{\ln(n+1)-\ln n}<\dfrac{n+1+n}{2}$ $\dfrac{1}{\ln (n+1)-\ln n}<\dfrac{2 n+1}{2}$ $\ln (n+1)-\ln n>\dfrac{2}{2 n+1}>\dfrac{2}{2 n+2}=\dfrac{1}{n+1}$
(2013 年全国大纲卷22II)设函数 $f(x)=\ln (1+x)-\dfrac{x(1+\lambda x)}{1+x}$. 设数列 {an} 的通项 $a_{n}=1+\dfrac{1}{2}+\dfrac{1}{3}+\cdots$ $+\dfrac{1}{n}$, 证明 $: a_{2 n}-a_{n}+\dfrac{1}{4 n}>\ln 2$.
解析
证明: 当 b > a > 0 时,有 $\dfrac{b-a}{\ln b-\ln a}>\dfrac{2}{\dfrac{1}{a}+\dfrac{1}{b}}$ (利用对数均值不等式),
即 ln b $-\ln a<\dfrac{1}{2}\left(\dfrac{1}{a}+\dfrac{1}{b}\right)(b-a)$,
令 a = n, b = n + 1, 则 $\ln (n+1)-\ln n<\dfrac{1}{2}\left(\dfrac{1}{n}+\dfrac{1}{n+1}\right),$
所以 ln (n + 1) $-\ln n<\dfrac{1}{2}\left(\dfrac{1}{n}+\dfrac{1}{n+1}\right)$
ln (n + 2) − ln (n + 1)$<\dfrac{1}{2}\left(\dfrac{1}{n+1}+\dfrac{1}{n+2}\right)$
ln (n + 3) − ln (n + 2)< $\dfrac{1}{2}\left(\dfrac{1}{n+2}+\dfrac{1}{n+3}\right), \cdots,$
ln (2n) − ln (2n − 1)< $\dfrac{1}{2}\left(\dfrac{1}{2 n-1}+\dfrac{1}{2 n}\right)$,
将上式相加可得
ln 2n − ln n< $\dfrac{1}{2}\left(\dfrac{1}{n}+\dfrac{2}{n+1}+\dfrac{2}{n+2}+\dfrac{2}{n+3}+\cdots+\dfrac{2}{2 n-1}+\dfrac{1}{2 n}\right)$ $\ln 2<\dfrac{1}{2 n}+\left(\dfrac{1}{n+1}+\dfrac{1}{n+2}+\dfrac{1}{n+3}+\cdots+\dfrac{1}{2 n-1}\right)$ $+\dfrac{1}{4 n},$
故 $: \dfrac{1}{n+1}+\dfrac{1}{n+2}+\dfrac{1}{n+3}+\cdots+\dfrac{1}{2 n-1}+\dfrac{1}{2 n}+$ $\dfrac{1}{4 n}>\ln 2,$
所以得证 $a_{2 n}-a_{n}+\dfrac{1}{4 n}>\ln 2$
(2010天津理科21题) 已知函数f(x) = xe−x(x ∈ R). 如果x1 ≠ x2, 且f(x1) = f(x2), 证明x1+ x2 > 2.
解析
由 f(x1) = f(x2), 得x1e−x1 = x2e−x2,
化简得 $e^{x_{2}-x_{1}}=\dfrac{x_{2}}{x_{1}}$,
两边同时取以 e 为底的对数, 得
x2 − x1 $=\ln \dfrac{x_{2}}{x_{1}}=\ln x_{2}-\ln x_{1},$也即$\dfrac{\ln x_{2}-\ln x_{1}}{x_{2}-x_{1}}=1,$
利用ALG不等式得 $1=\dfrac{x_{1}-x_{2}}{\ln x_{1}-\ln x_{2}}<\dfrac{x_{1}+x_{2}}{2},$
即证得x1 + x2 > 2.
(2018全国I卷21) 已知函数 $f(x)=\dfrac{1}{x}-x+$ aln x. 若f(x)存在两个极值点 x1, x2, 证明: $\dfrac{f\left(x_{1}\right)-f\left(x_{2}\right)}{x_{1}-x_{2}}<a-2$.
解析
对函数 f(x) 求导得: $f^{\prime}(x)=\dfrac{a}{x}-\dfrac{1}{x^{2}}-1$ $=\dfrac{-x^{2}+a x-1}{x^{2}}$.
f(x)存在两个极值点 x1, x2⇔ −x2 + ax − 1 = 0在(0, +∞)上有两个解x1, x2.
由韦达定理可得: x1 ⋅ x2 = 1, x1 + x2 = a.
$\left\{\begin{array}{l}f\left(x_{1}\right)=\dfrac{1}{x_{1}}-x_{1}+a \ln x_{1} \\ f\left(x_{2}\right)=\dfrac{1}{x_{2}}-x_{2}+a \ln x_{2}\end{array}\right.$
两式相减得: $f(x_1)-f\left(x_{2}\right)=\dfrac{x_{2}-x_{1}}{x_{2} x_{1}}+x_{2}-x_{1}+a\left(\ln x_{1}-\ln x_{2}\right) .$
结合韦达定理得: $\dfrac{f\left(x_{1}\right)-f\left(x_{2}\right)}{x_{1}-x_{2}}=-\dfrac{1}{x_{2} x_{1}}-1+$ $a \dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}$ $=a \dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}-2,$
利用ALG不等式可得:$\dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}<\dfrac{1}{\sqrt{x_{1} x_{2}}}=1,$
所以 $\dfrac{f\left(x_{1}\right)-f\left(x_{2}\right)}{x_{1}-x_{2}}<a-2$ 成立.
(2016湖南高联预15) 已知函数 $f(x)=x \ln x-\dfrac{1}{2} m x^{2}-x, m \in \mathbb{R}$. 若 f(x) 有两个极值点 x1, x2, 且 x1 < x2, 求证: x1x2 > e2.
解析
对 f(x) 求导得: f′(x) = ln x − mx.
因为 x1, x2为f(x)的两个极值点,
所以 $\left\{\begin{array}{l}f^{\prime}\left(x_{1}\right)=\ln x_{1}-m x_{1}=0 \\ f^{\prime}\left(x_{2}\right)=\ln x_{2}-m x_{2}=0\end{array} \Rightarrow\left\{\begin{array}{l}\ln x_{1}=m x_{1} \quad (1)\\ \ln x_{2}=m x_{2}\quad (2)\end{array}\right.\right.$
由(1)-(2)得: $\dfrac{x_{1}-x_{2}}{\ln x_{1}-\ln x_{2}}=\dfrac{1}{m}$.
根据对数均值不等式得: $$\dfrac{1}{m}=\dfrac{x_{1}-x_{2}}{\ln x_{1}-\ln x_{2}}<\dfrac{x_{1}+x_{2}}{2} \Rightarrow x_{1}+x_{2}>\dfrac{2}{m}.\quad(3)$$
由(1)+(2)得:
ln (x1 ⋅ x2) = m(x1 + x2) (4)
将(3)式带入(4)式得: $\ln \left(x_{1} \cdot x_{2}\right)>m \cdot \dfrac{2}{m}=2$ ⇒ x1x2 > e2成立。
(2018福建高联预14) 已知f(x) = ex − mx.若x1, x2是函数f(x) 的两个零点, 求证:x1 + x2 > 2.
解析
因为 x1, x2是函数f(x) 的两个零点,
所以$\left\{\begin{array}{l}f\left(x_{1}\right)=e^{x_{1}}-m x_{1}=0 \\ f\left(x_{2}\right)=e^{x_{2}}-m x_{2}=0\end{array}\right.$成立.
移项可得:$\left\{\begin{array}{l}e^{x_{1}}=m x_{1} \\ e^{x_{2}}=m x_{2}\end{array}\right.$
两边分别取对数可得: $\left\{\begin{array}{l}x_{1}=\ln m+\ln x_{1} \\ x_{2}=\ln m+\ln x_{2}\end{array} \quad\right.$
上式相减可得: $\dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}=1$ 利用ALG不等式 $\dfrac{2}{x_{1}+x_{2}}<\dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}=1$即可得:x1 + x2 > 2 成立.
已知实数 a > 0, 函数 f(x) = ln x −ax2 + (2 − a)x. 若 y = f(x) 的图象与 x 轴交于 A, B 两点, 线段AB中点的横坐标为 x0, 证明: f′(x0) < 0.
解析
由 f(x1) = f(x2) = 0, 知 ln x1 − ax12 +(2 − a)x1 = ln x2 − ax22 + (2 − a)x2,
故$a=\dfrac{\ln x_{1}-\ln x_{2}+2\left(x_{1}-x_{2}\right)}{x_{1}^{2}-x_{2}^{2}+x_{1}-x_{2}}$
f′(x0) < 0
$\Leftrightarrow x_{0}=\dfrac{x_{1}+x_{2}}{2}>\dfrac{1}{a}$
$\Leftrightarrow \dfrac{x_{1}+x_{2}}{2}>\dfrac{x_{1}^{2}+x_{2}^{2}+x_{1}-x_{2}}{\ln x_{1}-\ln x_{2}+2\left(x_{1}-x_{2}\right)}$
$\Leftrightarrow \dfrac{x_{1}+x_{2}}{2}>\dfrac{x_{1}+x_{2}+1}{\frac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}+2}$
$\Leftrightarrow \dfrac{2}{x_{1}+x_{2}}<\dfrac{\ln x_{1}-\ln x_{2}}{x_{1}-x_{2}}$
总结
$\color{grey}{b>\sqrt{\dfrac{a^{2}+b^{2}}{2}}>}$$\dfrac{a+b}{2}>\dfrac{b-a}{\ln b-\ln a}>\sqrt{a b}$$\color{grey}{>\dfrac{2}{\dfrac{1}{a}+\dfrac{1}{b}}>a}$
| 题号/来源 | 所用的不等式 | 方程组处理 |
|---|---|---|
| 1/2016国一21 | $\dfrac{a+b}{2}>\dfrac{b-a}{\ln b-\ln a}$ | 相减、反证法 |
| 2 | $\dfrac{2}{a+b}<\dfrac{\ln a-\ln b}{a-b}$ | 相减 |
| 3/2014南通二模20 | $\dfrac{b-a}{\ln b-\ln a}>\sqrt{a b}$ $\dfrac{a+b}{2}>\sqrt{a b}$ | 取对、相减、相加 |
| 4/2014陕西21 | $\color{grey}{ b>\dfrac{b-a}{\ln b-\ln a}}$或$\dfrac{a+b}{2}>\dfrac{b-a}{\ln b-\ln a}$ | 命b = n + 1, a = n |
| 5/2013全国大纲卷22II | $\dfrac{b-a}{\ln b-\ln a}>\dfrac{2}{\dfrac{1}{a}+\dfrac{1}{b}}$ | 裂项 |
| 6/2010天津理21 | $\dfrac{a+b}{2}>\dfrac{b-a}{\ln b-\ln a}$ | 相减、取对 |
| 7/2018全国I卷21 | $\dfrac{\ln b-\ln a}{b-a}<\dfrac{1}{\sqrt{ab}}$ | 相减、韦达 |
| 8/2016湖南高联预15 | $\dfrac{a+b}{2}>\dfrac{b-a}{\ln b-\ln a}$ | 相减 |
| 9/2018福建高联预14 | $\dfrac{2}{a+b}<\dfrac{\ln a-\ln b}{a-b}$ | 取对、相减 |
| 10 |
参考资料
- 《利用对数均值不等式破解极值点偏移问题》陈友镇
- 《巧用对数均值不等式解高考压轴题》彭耿铃
- 《对数均值不等式在高考及竞赛中的运用》陈纪刚
- 《妙用对数均值不等式解题》徐春艳


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