2.

\(I=\int e^{3x}.3^xdx\)

Đặt \(\left\{{}\begin{matrix}u=3^x\\dv=e^{3x}dx\end{matrix}\right.\) \(\Rightarrow\left\{{}\begin{matrix}du=3^xln3dx\\v=\dfrac{1}{3}e^{3x}\end{matrix}\right.\)

\(\Rightarrow I=\dfrac{1}{3}e^{3x}.3^x-\dfrac{ln3}{3}\int e^{3x}.3^xdx=\dfrac{1}{3}e^{3x}.3^x-\dfrac{ln3}{3}.I\)

\(\Rightarrow\left(1+\dfrac{ln3}{3}\right)I=\dfrac{1}{3}e^{3x}.3^x\)

\(\Rightarrow I=\dfrac{1}{3+ln3}.e^{3x}.3^x+C\)

1.

\(I=\int\left(2x-1\right)e^{\dfrac{1}{x}}dx=\int2x.e^{\dfrac{1}{x}}dx-\int e^{\dfrac{1}{x}}dx\)

Xét \(J=\int2x.e^{\dfrac{1}{x}}dx\)

Đặt \(\left\{{}\begin{matrix}u=e^{\dfrac{1}{x}}\\dv=2xdx\end{matrix}\right.\) \(\Rightarrow\left\{{}\begin{matrix}du=-\dfrac{e^{\dfrac{1}{x}}}{x^2}dx\\v=x^2\end{matrix}\right.\)

\(\Rightarrow J=x^2.e^{\dfrac{1}{x}}+\int e^{\dfrac{1}{x}}dx\)

\(\Rightarrow I=x^2.e^{\dfrac{1}{x}}+C\)

Lời giải:
\(x\in [-\sqrt{2}; \sqrt{2}]\Rightarrow x^2\leq 2\Rightarrow \sqrt{x^2+1}\leq \sqrt{3}\)

\(y=\frac{x+1}{\sqrt{x^2+1}}\geq \frac{x+1}{\sqrt{3}}\geq \frac{-\sqrt{2}+1}{\sqrt{3}}\)

Vậy $y_{\min}=\frac{-\sqrt{2}+1}{\sqrt{3}}$ khi $x=-\sqrt{2}$

$y^2=\frac{x^2+2x+1}{x^2+1}=1+\frac{2x}{x^2+1}$

$y^2=2+\frac{2x-x^2-1}{x^2+1}=2-\frac{(x-1)^2}{x^2+1}\leq 2$

$\Rightarrow y\leq \sqrt{2}$

Vậy $y_{\max}=\sqrt{2}$ khi $x=1$

a) Đk:\(x\in R\)

TH1:Xét \(x\in\left(3;+\infty\right)\)

Lấy \(x_1;x_2\in\left(3;+\infty\right)\) thỏa mãn \(x_1\ne x_2\)

Xét \(I=\dfrac{f\left(x_1\right)-f\left(x_2\right)}{x_1-x_2}=\dfrac{2x_1^2-4x_1+3-\left(2x_2^2-4x_2+3\right)}{x_1-x_2}\)\(=2\left(x_1+x_2\right)-4\)

Do \(x_1;x_2\in\left(3;+\infty\right)\)\(\Rightarrow2\left(x_1+x_2\right)>12\Leftrightarrow2\left(x_1+x_2\right)-4>8>0\)

\(\Rightarrow I>0\)

Hàm đồng biến trên \(\left(3;+\infty\right)\)

TH2:Xét \(x\in\left(-10;1\right)\)

Lấy \(x_1;x_2\in\left(-10;1\right):x_1\ne x_2\)

Xét \(I=2\left(x_1+x_2\right)-4\)

Do \(x_1< 1;x_2< 1\Rightarrow2\left(x_1+x_2\right)< 4\Rightarrow I=2\left(x_1+x_2\right)-4< 0\)

Hàm nb trên khoảng \(\left(-10;1\right)\)

b)Làm tương tự,hàm nb trên \(\left(1;+\infty\right)\) và đb trên \(\left(-10;-2\right)\)

c)Đk: \(x\in R\backslash\left\{2\right\}\)

=>Hàm số xác định trên \(\left(-\infty;2\right)\)

Lấy \(x_1;x_2\in\left(-\infty;2\right):x_1\ne x_2\)

Xét \(I=\dfrac{f\left(x_1\right)-f\left(x_2\right)}{x_1-x_2}=\dfrac{\dfrac{x_1}{x_1-2}-\dfrac{x_2}{x_2-2}}{x_1-x_2}=\dfrac{-2}{\left(x_1-2\right)\left(x_2-2\right)}\)

Do \(x_1;x_2< 2\Rightarrow\left(x_1-2\right)\left(x_2-2\right)>0\)

\(\Rightarrow I=-\dfrac{2}{\left(x_1-2\right)\left(x_2-2\right)}< 0\)

Hàm nb trên ​\(\left(-\infty;2\right)\)​

d)\(I=\dfrac{1}{\left(x_1+1\right)\left(x_2+1\right)}\)

Hàm đb trên \(\left(-1;+\infty\right)\) ; \(\left(-3;-2\right)\)

e)TXĐ:D=R

Lấy \(x_1;x_2\in\left(0;+\infty\right):x_1< x_2\)

​​\(T=f\left(x_1\right)-f\left(x_2\right)=x_1^{2020}+x_1^2-3-x_2^{2020}-x_2^2+3=x_1^{2020}-x_2^{2020}+x_1^2-x_2^2\)

Do \(x_1< x_2\Rightarrow x_1^{2020}< x_2^{2020};x_1^2< x_2^2\)

​\(\Rightarrow T=x_1^{2020}-x_2^{2020}+x_1^2-x_2^2< 0\)​

Hàm đb trên \(\left(0;+\infty\right)\)

Khi \(x\ne1\) thì \(f\left(x\right)=\dfrac{3x^2-3x}{x-1}=\dfrac{3x\left(x-1\right)}{x-1}=3x\) hoàn toàn xác định

nên f(x) liên tục trên các khoảng \(\left(-\infty;1\right);\left(1;+\infty\right)\)(1)

\(\lim\limits_{x\rightarrow1}f\left(x\right)=\lim\limits_{x\rightarrow1}\dfrac{3x^2-3x}{x-1}\)

\(=\lim\limits_{x\rightarrow1}\dfrac{3x\left(x-1\right)}{x-1}=\lim\limits_{x\rightarrow1}3x=3\cdot1=3\)

\(f\left(1\right)=m\cdot1+1=m+1\)

Để hàm số liên tục trên R thì hàm số cần liên tục trên các khoảng sau: \(\left(-\infty;1\right);\left(1;+\infty\right)\) và liên tục luôn tại x=1(2)

Từ (1),(2) suy ra để hàm số liên tục trên R thì hàm số cần liên tục tại x=1

=>\(f\left(1\right)=\lim\limits_{x\rightarrow1}f\left(x\right)\)

=>m+1=3

=>m=2

Chọn B

B