a) Ta có \(\log_32<\log_33=1=\log_22<\log_23\)

b) \(\log_23<\log_24=2=\log_39<\log_311\)

c) Đưa về cùng 1 lôgarit cơ số 10, ta có 

\(\frac{1}{2}+lg3=\frac{1}{2}lg10+lg3=lg3\sqrt{10}\)

\(lg19-lg2=lg\frac{19}{2}\)

So sánh 2 số \(3\sqrt{10}\) và \(\frac{19}{2}\) ta có :

\(\left(3\sqrt{10}\right)^2=9.10=90=\frac{360}{4}<\frac{361}{4}=\left(\frac{19}{2}\right)^2\)

Vì vậy : \(3\sqrt{10}<\frac{19}{2}\)

Từ đó suy ra \(\frac{1}{2}+lg3\)<\(lg19-lg2\)

d) Ta có : \(\frac{lg5+lg\sqrt{7}}{2}=lg\left(5\sqrt{7}\right)^{\frac{1}{2}}=lg\sqrt{5\sqrt{7}}\)

Ta so sánh 2 số : \(\sqrt{5\sqrt{7}}\) và \(\frac{5+\sqrt{7}}{2}\) 

Ta có :

\(\sqrt{5\sqrt{7}}^2=5\sqrt{7}\)

\(\left(\frac{5+\sqrt{7}}{2}\right)^2=\frac{32+10\sqrt{7}}{4}=8+\frac{5}{2}\sqrt{7}\)

\(8+\frac{5}{2}\sqrt{7}-5\sqrt{7}=8-\frac{5}{2}\sqrt{7}=\frac{16-5\sqrt{7}}{2}=\frac{\sqrt{256}-\sqrt{175}}{2}>0\)

Suy ra : \(8+\frac{5}{2}\sqrt{7}>5\sqrt{7}\)

Do đó : \(\frac{5+\sqrt{7}}{2}>\sqrt{5\sqrt{7}}\)

và \(lg\frac{5+\sqrt{7}}{2}>\frac{lg5+lg\sqrt{7}}{2}\)

a) \(A=\left[\left(\frac{1}{5}\right)^2\right]^{\frac{-3}{2}}-\left[2^{-3}\right]^{\frac{-2}{3}}=5^3-2^2=121\)

b) \(B=6^2+\left[\left(\frac{1}{5}\right)^{\frac{3}{4}}\right]^{-4}=6^2+5^3=161\)

c) \(C=\frac{a^{\sqrt{5}+3}.a^{\sqrt{5}\left(\sqrt{5}-1\right)}}{\left(a^{2\sqrt{2}-1}\right)^{2\sqrt{2}+1}}=\frac{a^{\sqrt{5}+3}.a^{5-\sqrt{5}}}{a^{\left(2\sqrt{2}\right)^2-1^2}}\)

                              \(=\frac{a^{\sqrt{5}+3+5-\sqrt{5}}}{a^{8-1}}=\frac{a^8}{a^7}=a\)

d) \(D=\left(a^{\frac{1}{2}}-b^{\frac{1}{2}}\right)^2:\left(b-2b\sqrt{\frac{b}{a}}+\frac{b^2}{a}\right)\)

        \(=\left(\sqrt{a}-\sqrt{b}\right)^2:b\left[1-2\sqrt{\frac{b}{a}}+\left(\sqrt{\frac{b}{a}}\right)^2\right]\)

        \(=\left(\sqrt{a}-\sqrt{b}\right)^2:b\left(1-\sqrt{b}a\right)^2\)

a) \(\sqrt[3]{10}=\sqrt[15]{10^5}>\sqrt[15]{20^3=\sqrt[5]{20}}\)

b) Vì \(\frac{1}{e}<1\) và \(\sqrt{8}-3<0\) nên \(\left(\frac{1}{e}\right)^{\sqrt{8}-3}>1\)

c) Vì \(\frac{1}{8}<1\) và \(\pi>3.14\) nên \(\left(\frac{1}{8}\right)^{\pi}<\left(\frac{1}{8}\right)^{3,14}\)

d)  Vì \(\frac{1}{\pi}<1\)  và \(1,4<\sqrt{2}\)  nên \(\left(\frac{1}{\pi}\right)^{1,4}>\pi^{-\sqrt{2}}\)

a. Ta có : \(\begin{cases}\left(0,01\right)^{-\sqrt{3}}=\left(10^{-2}\right)^{-\sqrt{3}}=\left(10\right)^{2\sqrt{3}};1000=10^3\\2\sqrt{3}>3\end{cases}\)

\(\Rightarrow\left(0,01\right)^{-\sqrt{3}}>1000\)

b. Ta có :

                   \(\frac{\pi}{2}>1\) và \(2\sqrt{2}< 3\)

               \(\Rightarrow\left(\frac{\pi}{2}\right)^{2\sqrt{2}}< \left(\frac{\pi}{2}\right)^3\)

a) \(A=\frac{a^{\frac{5}{2}}\left(a^{\frac{1}{2}}-a^{\frac{-3}{2}}\right)}{a^{\frac{1}{2}}\left(a^{\frac{-1}{2}}-a^{\frac{3}{2}}\right)}=\frac{a^3-a}{1-a^2}=-a\)

Do đó : \(A=-\left(\pi-3\sqrt{2}\right)=3\sqrt{2}-\pi\)

b) Rút gọn B ta có :

\(B=\left(a^{\frac{1}{3}}+b^{\frac{1}{3}}\right)\left[\left(a^{\frac{1}{3}}\right)^2+\left(b^{\frac{1}{3}}\right)^2\right]=\left(a^{\frac{1}{3}}\right)^3+\left(b^{\frac{1}{3}}\right)^3=a+b\)

Do đó :

\(B=\left(7-\sqrt{2}\right)+\left(\sqrt{2}+3\right)=10\)

d) So sánh :

\(\sqrt{3}+1\) và \(\sqrt{7}\), ta có :

\(\left(\sqrt{3}+1\right)^2-\left(\sqrt{7}\right)^2=3+1+2\sqrt{3}-7=2\sqrt{3}-3\)

Hơn nữa : 

\(\left(2\sqrt{3}\right)^2-3^2=4.3-9=9>0\)

Do đó 

\(\sqrt{3}+1>\sqrt{7}\)

Mà \(e^{\sqrt{3}+1}>e^{\sqrt{7}}\)

c) Ta có :

\(\left(\frac{\pi}{5}\right)^{\sqrt{10}-3}=\frac{\left(\frac{\pi}{5}\right)^{\sqrt{10}}}{\left(\frac{\pi}{5}\right)^3}\)

Lại có \(0<\pi<5\) nên \(0<\frac{\pi}{5}<1\) và \(\sqrt{10}>3\)

Do đó : \(\left(\frac{\pi}{5}\right)^{\sqrt{10}}<\left(\frac{\pi}{5}\right)^3\)

Mà \(\left(\frac{\pi}{5}\right)^3>0\) nên \(\left(\frac{\pi}{5}\right)^{\sqrt{10}-3}=\frac{\left(\frac{\pi}{5}\right)^{10}}{\left(\frac{\pi}{5}\right)^3}<1\)

\(T=\left(\sqrt[7]{\frac{a}{b}\sqrt[5]{\frac{b}{a}}}\right)^{\frac{35}{4}}=\left\{\left[\left(\frac{b}{a}\right)^{-1}\left(\frac{b}{a}\right)^{\frac{1}{5}}\right]^{\frac{1}{7}}\right\}^{\frac{35}{4}}=\left[\left(\frac{b}{a}\right)^{-\frac{4}{5}}\right]=\frac{a}{b}\)

\(T=\left(\sqrt[7]{\frac{a}{b}\sqrt[5]{\frac{b}{a}}}\right)^{\frac{35}{4}}=\sqrt[4]{\left(\sqrt[7]{\frac{a}{b}\sqrt[5]{\frac{b}{a}}}\right)^{35}}=\sqrt[4]{\left(\frac{a}{b}\sqrt[5]{\frac{b}{a}}\right)^5}\)

\(=\sqrt[4]{\left(\frac{a}{b}\right)^5.\frac{b}{a}}=\sqrt[4]{\left(\frac{a}{b}\right)^4}=\frac{a}{b}\)

a) \(\left(\sqrt{17}\right)^6=\sqrt{\left(17^3\right)^2}=17^3=4913\)

\(\left(\sqrt[3]{28}\right)^6=\sqrt[3]{\left(28^2\right)^3}=28^2=784\)

=> \(\left(\sqrt{17}\right)^6>\left(\sqrt[3]{28}\right)^6\)

=> \(\sqrt{17}>\sqrt[3]{28}\)

b) \(\left(\sqrt[4]{13}\right)^{20}=13^5=371293\)

\(\left(\sqrt[5]{23}\right)^{20}=23^4=279841\)

=> \(\sqrt[4]{13}>\sqrt[5]{23}\)

a) Áp dụng bất đẳng thức Cauchy cho các số dương, ta có :

\(\log_23+\log_32>2\sqrt{\log_23.\log_32}=2\sqrt{1}=2\)

Không xảy ra dấu "=" vì \(\log_23\ne\log_32\)

Mặt khác, ta lại có :

\(\log_23+\log_32<\frac{5}{2}\Leftrightarrow\log_23+\frac{1}{\log_23}-\frac{5}{2}<0\)

                             \(\Leftrightarrow2\log^2_23-5\log_23+2<0\)

                            \(\Leftrightarrow\left(\log_23-1\right)\left(\log_23-2\right)<0\) (*)

Hơn nữa, \(2\log_23>2\log_22>1\) nên \(2\log_23-1>0\)

Mà \(\log_23<\log_24=2\Rightarrow\log_23-2<0\)

Từ đó suy ra (*) luôn đúng. Vậy \(2<\log_23+\log_32<\frac{5}{2}\)

b) Vì \(a,b\ge1\) nên \(\ln a,\ln b,\ln\frac{a+b}{2}\) không âm. 

Áp dụng bất đẳng thức Cauchy ta có

\(\ln a+\ln b\ge2\sqrt{\ln a.\ln b}\)

Suy ra 

\(2\left(\ln a+\ln b\right)\ge\ln a+\ln b+2\sqrt{\ln a\ln b}=\left(\sqrt{\ln a}+\sqrt{\ln b}\right)^2\)

Mặt khác :

\(\frac{a+b}{2}\ge\sqrt{ab}\Rightarrow\ln\frac{a+b}{2}\ge\frac{1}{2}\left(\ln a+\ln b\right)\)

Từ đó ta thu được :

\(\ln\frac{a+b}{2}\ge\frac{1}{4}\left(\sqrt{\ln a}+\sqrt{\ln b}\right)^2\)

hay \(\frac{\sqrt{\ln a}+\sqrt{\ln b}}{2}\le\sqrt{\ln\frac{a+b}{2}}\)

c) Ta chứng minh bài toán tổng quát :

\(\log_n\left(n+1\right)>\log_{n+1}\left(n+2\right)\) với mọi n >1

Thật vậy, 

\(\left(n+1\right)^2=n\left(n+2\right)+1>n\left(n+2\right)>1\) 

suy ra :

\(\log_{\left(n+1\right)^2}n\left(n+2\right)<1\Leftrightarrow\frac{1}{2}\log_{n+1}n\left(n+2\right)<1\)

                                  \(\Leftrightarrow\log_{n+1}n+\log_{\left(n+1\right)}n\left(n+2\right)<2\)

Áp dụng bất đẳng thức Cauchy ta có :

\(2>\log_{\left(n+1\right)}n+\log_{\left(n+1\right)}n\left(n+2\right)>2\sqrt{\log_{\left(n+1\right)}n.\log_{\left(n+1\right)}n\left(n+2\right)}\)

Do đó ta có :

\(1>\log_{\left(n+1\right)}n.\log_{\left(n+1\right)}n\left(n+2\right)\) và \(\log_n\left(n+1>\right)\log_{\left(n+1\right)}\left(n+2\right)\) với mọi n>1