函数\(f(x)=\dfrac{e^x}{x}-a\)的图像与\(x\)轴的两交点为\(A(x_1,0),B(x_2,0)(x_2>x_1)\)
(1)令\(h(x)=f(x)-\ln x+x\),若\(h(x)\)有两个零点,求\(a\)的取值范围
(2)证明:\(x_1x_2<1\)
(3)证明:当\(a\geq 5\)时,以\(AB\)为直径的圆与直线\(y=\dfrac{\sqrt{3}}{4}(x+1)\)恒有公共点
(参考数据:$e^{0.25}\approx 1.3,e^{2.5}\approx 12.2 $)
解
(1)\(h(x)=\dfrac{e^x}{x}-a-\ln x+\ln e^x=\dfrac{e^x}{x}+\ln\dfrac{e^x}{x}-a\xlongequal[]{\frac{e^x}{x}=t}t+\ln t-a,t\in [e,+\infty)\)
因\(t+\ln t-a\)单调递增,则要使得\(h(x)\)有两个零点
则要有\(t+\ln t-a\)有一个零点即可
则要有\(e+\ln e-a<0\)即\(a>e+1\)
(2)由题\(\begin{cases} \dfrac{e^{x_1}}{x_1}=a\\ \dfrac{e^{x_2}}{x_2}=a \end{cases}\)即$ \dfrac{e^{x_1}}{x_1}= \dfrac{e^{x_2}}{x_2}$
即\(x_1-\ln x_1=x_2-\ln x_2\)
即\(\dfrac{x_1-x_2}{\ln x_1-\ln x_2}=1\)
由对数均值不等式:
\[\sqrt{ab}<\dfrac{a-b}{\ln a-\ln b}<\dfrac{a+2}{2} \]有\(1=\dfrac{x_1-x_2}{\ln x_1-\ln x_2}>\sqrt{x_1x_2}\)
即\(x_1x_2<1\)
如果不想使用对数均值不等式,可如下操作:
设\(\dfrac{x_2}{x_1}=t,t>1\)
则有\(x_2=tx_1\)
\(\begin{cases} \dfrac{e^{x_1}}{x_1}=a\\ \dfrac{e^{x_2}}{x_2}=a \end{cases}\),两式做比\(\dfrac{x_2}{x_1}e^{x_1-x_2}=1\)
即\(te^{x_1(1-t)}=1\),即\(\ln t+x_1(1-t)=0\)得\(x_1=\dfrac{\ln t}{t-1}\),则\(x_2=\dfrac{t\ln t}{t-1}\)
从而\(x_1x_2=\dfrac{t\ln^2t}{(t-1)^2}\),记\(\varphi(t)=\dfrac{t\ln^2t}{(t-1)^2}\)
\[\varphi^{\prime}(t)=\dfrac{(t-1)\ln t\left[-(t+1)\ln t+2t-2\right]}{(t-1)^4} \]\[=\dfrac{(t-1)(t+1)\ln t\left[-\ln t+\dfrac{2(t-1)}{t+1}\right]}{(t-1)^4} \]\[=\dfrac{(t-1)(t+1)\ln t\left[-\ln t+\dfrac{2(t+1-2)}{t+1}\right]}{(t-1)^4} \]\[=\dfrac{(t-1)(t+1)\ln t\left[-\ln t+2-\dfrac{4}{x+1}\right]}{(t-1)^4} \]记\(\gamma(t)=-\ln t+2-\dfrac{4}{x+1},\gamma^{\prime}(t)=\dfrac{-x^2+2x-1}{x(x+1)^2}<0\),则\(\gamma(t)<\gamma(1)=0\)
从而\(\varphi^{\prime}(t)<0\),则\(\varphi(t)<\varphi(1)=0\)
得证
(3)根据平面几何知识,则要使得其有两个交点,则有
\[\dfrac{\left|\dfrac{\sqrt{3}}{4}\cdot\dfrac{x_1+x_2}{2}+\dfrac{\sqrt{3}}{4}\right|}{\dfrac{\sqrt{19}}{4}}<\left|\dfrac{x_1-x_2}{2}\right| \]整理得
\[16(x_1+x_2)^2-12(x_1+x_2)76x_1x_2>16(x_1+x_2)^2-12(x_1+x_2)-88>0 \]再整理得
\[4\left[4(x_1+x_2)-11\right](x_1+x_2+2)>0 \]即证\((x_1+x_2)>\dfrac{11}{4}\)
由(2)的第二个操作,有\(x_1+x_2=\dfrac{\ln t}{t-1},x_2=\dfrac{t\ln t}{t-1}\)
则\(x_1+x_2=\dfrac{\ln t}{t-1}+\dfrac{t\ln t}{t-1}>\dfrac{11}{4}\)
即证:\((1+t)\dfrac{\ln t}{t-1}>\dfrac{11}{4}\)
记\(\zeta(t)=(1+t)\dfrac{\ln t}{t-1},\zeta^{\prime}(t)=\dfrac{-\left(2\ln t-t+\dfrac{1}{t}\right)}{(t-1)^2}\)
因\(\ln x<\dfrac{1}{2}\left(x-\dfrac{1}{x}\right)\)
则\(\zeta^{\prime}(t)>0\)
从而\(\zeta(t)\)单调递增
现在开始估算:
因\(a\)越大,\(x_1+x_2\)的值也越大
当\(a=5\),\(f\left(\dfrac{1}{4}\right)=4e^{0.25}-5>0,f(2.5)=-4e^{2.5}-5<0\)
则\(1>x_1>0.25,x_2>2.5\)
从而$x_1+x_2>\dfrac{11}{4} $
因而\(a\geq 5\)时,\(x_1+x_2>\dfrac{11}{4}\)
标签:11,right,导数,ln,dfrac,每日,sqrt,90,left From: https://www.cnblogs.com/manxinwu/p/18085640