Bài 1:

\(A=\log_380=\log_3(2^4.5)=\log_3(2^4)+\log_3(5)\)

\(=4\log_32+\log_35=4a+b\)

\(B=\log_3(37,5)=\log_3(2^{-1}.75)=\log_3(2^{-1}.3.5^2)\)

\(=\log_3(2^{-1})+\log_33+\log_3(5^2)=-\log_32+1+2\log_35\)

\(=-a+1+2b\)

Bài 2:

\(\log_{30}8=\frac{\log 8}{\log 30}=\frac{\log (2^3)}{\log (10.3)}=\frac{3\log2}{\log 10+\log 3}\)

\(=\frac{3\log (\frac{10}{5})}{1+\log 3}=\frac{3(\log 10-\log 5)}{1+\log 3}=\frac{3(1-b)}{1+a}\)

a: \(8^{log_25}=2^{3\cdot log_25}=5^3=125\)

b: \(\left(\dfrac{1}{10}\right)^{log81}=10^{-1\cdot log81}=81^{-1}=\dfrac{1}{81}\)

c: \(5^{log_{25}16}=5^{log_{5^2}16}=16^{-2}=\dfrac{1}{256}\)

Lời giải:

Đặt \(\left\{\begin{matrix} \log_ab=x\\ \log_bc=y\\ \log_ca=z\end{matrix}\right.\Rightarrow \left\{\begin{matrix} \log_ba=\frac{1}{x}\\ \log_cb=\frac{1}{y}\\ \log_ac=\frac{1}{z}\end{matrix}\right. \). và \(xyz=1\)

Do \(a,b,c>1\Rightarrow x,y,z>0\)

Ta có:

\(P=\log_a(bc)+\log_b(ac)+4\log_c(ab)\)

\(=\log_ab+\log_ac+\log_ba+\log_bc+4\log_ca+4\log_cb\)

\(=x+\frac{1}{z}+\frac{1}{x}+y+4z+\frac{4}{y}\)

Áp dụng BĐT Cô-si cho các số dương:

\(\left\{\begin{matrix} x+\frac{1}{x}\geq 2\sqrt{1}=2\\ y+\frac{4}{y}\geq 2\sqrt{4}=4\\ \frac{1}{z}+4z\geq 2\sqrt{4}=4\end{matrix}\right.\) \(\Rightarrow P\geq 2+4+4=10\)

\(\Rightarrow m=10\)

Dấu bằng xảy ra khi \(\left\{\begin{matrix} x=\frac{1}{x}\rightarrow x=1\\ y=\frac{4}{y}\rightarrow y=2\\ \frac{1}{z}=4z\rightarrow z=\frac{1}{2}\end{matrix}\right.\) (thỏa mãn)

Suy ra \(n=\log_bc=y=2\)

\(\Rightarrow m+n=12\)

\(log_a\left(a^3b^2\right)=log_aa^3+log_ab^2=3+2\cdot log_ab\)

=>B

a: \(log_49=\dfrac{log9}{log4}=\dfrac{log3^2}{log2^2}=\dfrac{2\cdot log3}{2\cdot log2}=\dfrac{log3}{log2}=\dfrac{b}{a}\)

b: \(log_612=\dfrac{log12}{log6}=\dfrac{log2^2+log3}{log2+log3}=\dfrac{2\cdot log2+log3}{log2+log3}\)

\(=\dfrac{2a+b}{a+b}\)

c: \(log_56=\dfrac{log6}{log5}=\dfrac{log\left(2\cdot3\right)}{log\left(\dfrac{10}{2}\right)}=\dfrac{log2+log3}{log10-log2}\)

\(=\dfrac{a+b}{1-a}\)

\(log_65=\dfrac{1}{log_56}=\dfrac{1}{log_52+log_53}=\dfrac{1}{a+b}\)

=>Chọn B

a) \(\log_a\left(a^2b\right)=\log_aa^2+\log_ab=2.\log_aa+\log_ab=2.1+2=4\)

b) \(\log_a\dfrac{a\sqrt{a}}{b\sqrt[3]{a}}=\log_a\left(a\sqrt{a}\right)-\log_a\left(b\sqrt[3]{b}\right)=\log_aa^{\dfrac{3}{2}}-\log_ab^{\dfrac{4}{3}}=\dfrac{3}{2}.\log_aa-\dfrac{4}{3}\log_ab=\dfrac{3}{2}.1-\dfrac{4}{3}.2=-\dfrac{7}{6}\)

c) \(\log_a\left(2b\right)+\log_a\left(\dfrac{b^2}{2}\right)=\log_a2+\log_ab+\log_ab^2-\log_a2=\log_ab+2\log_ab=3\log_ab=3.2=6\)

a: \(=log_aa^2+log_ab=2+2=4\)

b: \(log_a\left(\dfrac{a\sqrt{a}}{b\sqrt[3]{b}}\right)=log_aa^{\dfrac{3}{2}}-log_ab^{\dfrac{4}{3}}\)

=3/2-4/3*2

=3/2-8/3

=9/6-16/6=-7/6

c: \(log_a\left(2b\right)+log_a\left(\dfrac{b^2}{2}\right)\)

\(=log_a\left(2b\cdot\dfrac{b^2}{2}\right)=log_a\left(b^3\right)=3\cdot2=6\)

\(a,A=log_23\cdot log_34\cdot log_45\cdot log_56\cdot log_67\cdot log_78\\ =log_28\\ =log_22^3\\ =3\\ b,B=log_22\cdot log_24...log_22^n\\ =log_22\cdot log_22^2...log_22^n\\ =1\cdot2\cdot...\cdot n\\ =n!\)

a)    \({\log _c}b = {\log _a}b.{\log _c}a \Leftrightarrow {a^{{{\log }_c}b}} = {a^{{{\log }_a}b.{{\log }_c}a}} \Leftrightarrow {c^{{{\log }_c}b}} = {\left( {{c^{{{\log }_c}a}}} \right)^{{{\log }_a}b}} \Leftrightarrow b = {a^{{{\log }_a}b}} \Leftrightarrow b = b\) (luôn đúng)

Vậy \({\log _c}b = {\log _a}b.{\log _c}a\)

b)    Từ \({\log _c}b = {\log _a}b.{\log _c}a \Leftrightarrow {\log _a}b = \frac{{{{\log }_c}b}}{{{{\log }_c}a}}\)