Chọn đáp án B.

Đáp án A.

\(2log_2y=2+\dfrac{1}{2}log_2x\)

=>\(log_2y^2=log_22^2+log_2x^{\dfrac{1}{2}}\)

=>\(log_2y^2=log_2\left(2^2\cdot x^{\dfrac{1}{2}}\right)\)

=>\(y^2=4\cdot x^{\dfrac{1}{2}}=4\sqrt{x}\)

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

a, Hàm số \(y=log_{\dfrac{1}{2}}x\) có cơ số \(\dfrac{1}{2}< 1\) nên hàm số nghịch biến trên \(\left(0;+\infty\right)\)

Mà \(4,8< 5,2\Rightarrow log_{\dfrac{1}{2}}4,8>log_{\dfrac{1}{2}}5,2\)

b, Ta có: \(log_{\sqrt{5}}2=2log_52=log_54\)

Hàm số \(y=log_5x\) có cơ số 5 > 1 nên hàm số đồng biến trên \(\left(0;+\infty\right)\)

Do \(4>2\sqrt{2}\Rightarrow log_54>log_52\sqrt{2}\Rightarrow log_{\sqrt{5}}2>log_52\sqrt{2}\)

c, Ta có: \(-log_{\dfrac{1}{4}}2=-\dfrac{1}{2}log_{\dfrac{1}{2}}2=log_{\dfrac{1}{2}}\dfrac{1}{\sqrt{2}}\)

Hàm số \(y=log_{\dfrac{1}{2}}x\) có cơ số \(\dfrac{1}{2}< 1\) nên nghịch biến trên \(\left(0;+\infty\right)\)

Do \(\dfrac{1}{\sqrt{2}}>0,4\Rightarrow log_{\dfrac{1}{2}}\dfrac{1}{\sqrt{2}}< log_{\dfrac{1}{2}}0,4\Rightarrow-log_{\dfrac{1}{4}}2< log_{\dfrac{1}{2}}0,4\)

a: \(log_22^{-13}=-13\)

b: \(lne^{\sqrt{2}}=\sqrt{2}\)

c: \(log_816-log_82=log_8\left(\dfrac{16}{2}\right)=log_88=1\)

c: \(log_26\cdot log_68=log_28=3\)

a) \(log_69+log_64=log_636=2\)

b) \(log_52-log_550=log_5\left(2:50\right)=-2\)

c) \(log_3\sqrt{5}-\dfrac{1}{2}log_550=-1,0479\)

Lời giải:

Đặt \(\log_ab=x\Rightarrow \log_ba=\frac{1}{x}\)

a)

\(A=(x+\frac{1}{x}+2)(x-\frac{1}{x}).\frac{1}{x}\)

\(\Leftrightarrow A=(1+\frac{1}{x^2}+2x)(x-\frac{1}{x})=\left(1+\frac{1}{x}\right)^2(x-\frac{1}{x})\)

\(\Leftrightarrow A=(1+\log_ba)^2(\log_ab-\log_ba)\)

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b) Điều kiện: \(x>0\)

Có \(1=\log_{ab}b.\log_b(ab)=\log_{ab}b(\log_ba+\log_bb)=\log_{ab}b(\frac{1}{x}+1)\)

\(\Rightarrow \log_{ab}b=\frac{x}{x+1}\)

Như vậy:

\(B=\sqrt{x+\frac{1}{x}+2}(x-\frac{x}{x+1})\sqrt{x}\)

\(\Leftrightarrow B=\sqrt{x^2+1+2x}(x-\frac{x}{x+1})=|x+1|.\frac{x^2}{x+1}\)

\(=(x+1)\frac{x^2}{x+1}=x^2=\log_a^2b\) (do \(x>0)\)

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

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