Câu nào mình biết thì mình làm nha.

1) Đổi thành \(\dfrac{y^4}{4}+y^3-2y\) rồi thế số.KQ là \(\dfrac{-3}{4}\)

2) Biến đổi thành \(\dfrac{t^2}{2}+2\sqrt{t}+\dfrac{1}{t}\) và thế số.KQ là \(\dfrac{35}{4}\)

3) Biến đổi thành 2sinx + cos(2x)/2 và thế số.KQ là 1

a) =

=

b) = =

=

c)=

d)=

=

e)=

=

g)Ta có f(x) = sin3xcos5x là hàm số lẻ.

Vì f(-x) = sin(-3x)cos(-5x) = -sin3xcos5x = f(-x) nên:

\(\int\limits^{\dfrac{\pi}{2}}_0sinxdx=cosx|^{\dfrac{\pi}{2}}_0=-1\)

\(\left\{{}\begin{matrix}u=x^2\\dv=cos2xdx\end{matrix}\right.\) \(\Rightarrow\left\{{}\begin{matrix}du=2xdx\\v=\dfrac{1}{2}sin2x\end{matrix}\right.\)

\(\Rightarrow I=\dfrac{1}{2}x^2sin2x|^{\pi}_0-\int\limits^{\pi}_0x.sin2xdx\)

a.

\(f'\left(x\right)=\dfrac{10}{\left(x+3\right)^2}>0\Rightarrow f\left(x\right)\) đồng biến

\(\Rightarrow\min\limits_{\left[-2;5\right]}f\left(x\right)=f\left(-2\right)=-7\)

\(\max\limits_{\left[-2;5\right]}f\left(x\right)=f\left(5\right)=\dfrac{7}{4}\)

b.

Đặt \(\left\{{}\begin{matrix}u=2x-3\\dv=cosxdx\end{matrix}\right.\) \(\Rightarrow\left\{{}\begin{matrix}du=2dx\\v=sinx\end{matrix}\right.\)

\(\Rightarrow I=\left(2x-3\right)sinx|^{\pi}_0-2\int\limits^{\pi}_0sinxdx=-2\int\limits^{\pi}_0sinxdx=-4\)

a.

Đặt \(\left\{{}\begin{matrix}u=2-x\\dv=sinxdx\end{matrix}\right.\) \(\Rightarrow\left\{{}\begin{matrix}du=-dx\\v=-cosx\end{matrix}\right.\)

\(\Rightarrow I=\left(x-2\right).cosx|^{\dfrac{\pi}{2}}_0-\int\limits^{\dfrac{\pi}{2}}_0cosx.dx=2-1=1\)

b. Đặt \(cos2x=t\Rightarrow-2sin2x.dx=dt\Rightarrow sin2xdx=-\dfrac{1}{2}dt\)

\(\left\{{}\begin{matrix}x=0\Rightarrow t=1\\x=\pi\Rightarrow t=1\end{matrix}\right.\)

\(\Rightarrow I=\int\limits^1_1-\dfrac{1}{2}.t^2dt=0\) (hai cận bằng nhau thì tích phân bằng 0 khỏi tính dài dòng)

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

\(I=x.e^x|^1_0-\int\limits^1_0e^xdx=\left(x.e^x-e^x\right)|^1_0=1\)

a)

Ta có \(A=\int ^{\frac{\pi}{4}}_{0}\cos 2x\cos^2xdx=\frac{1}{4}\int ^{\frac{\pi}{4}}_{0}\cos 2x(\cos 2x+1)d(2x)\)

\(\Leftrightarrow A=\frac{1}{4}\int ^{\frac{\pi}{2}}_{0}\cos x(\cos x+1)dx=\frac{1}{4}\int ^{\frac{\pi}{2}}_{0}\cos xdx+\frac{1}{8}\int ^{\frac{\pi}{2}}_{0}(\cos 2x+1)dx\)

\(\Leftrightarrow A=\frac{1}{4}\left.\begin{matrix} \frac{\pi}{2}\\ 0\end{matrix}\right|\sin x+\frac{1}{16}\left.\begin{matrix} \frac{\pi}{2}\\ 0\end{matrix}\right|\sin 2x+\frac{1}{8}\left.\begin{matrix} \frac{\pi}{2}\\ 0\end{matrix}\right|x=\frac{1}{4}+\frac{\pi}{16}\)

b)

\(B=\int ^{1}_{\frac{1}{2}}\frac{e^x}{e^{2x}-1}dx=\frac{1}{2}\int ^{1}_{\frac{1}{2}}\left ( \frac{1}{e^x-1}-\frac{1}{e^x+1} \right )d(e^x)\)

\(\Leftrightarrow B=\frac{1}{2}\left.\begin{matrix} 1\\ \frac{1}{2}\end{matrix}\right|\left | \frac{e^x-1}{e^x+1} \right |\approx 0.317\)

c)

Có \(C=\int ^{1}_{0}\frac{(x+2)\ln(x+1)}{(x+1)^2}d(x+1)\).

Đặt \(x+1=t\)

\(\Rightarrow C=\int ^{2}_{1}\frac{(t+1)\ln t}{t^2}dt=\int ^{2}_{1}\frac{\ln t}{t}dt+\int ^{2}_{1}\frac{\ln t}{t^2}dt\)

\(=\int ^{2}_{1}\ln td(\ln t)+\int ^{2}_{1}\frac{\ln t}{t^2}dt=\frac{\ln ^22}{2}+\int ^{2}_{1}\frac{\ln t}{t^2}dt\)

Đặt \(\left\{\begin{matrix} u=\ln t\\ dv=\frac{dt}{t^2}\end{matrix}\right.\Rightarrow \left\{\begin{matrix} du=\frac{dt}{t}\\ v=\frac{-1}{t}\end{matrix}\right.\Rightarrow \int ^{2}_{1}\frac{\ln t}{t^2}dt=\left.\begin{matrix} 2\\ 1\end{matrix}\right|-\frac{\ln t+1}{t}=\frac{1}{2}-\frac{\ln 2 }{2}\)

\(\Rightarrow C=\frac{1}{2}-\frac{\ln 2}{2}+\frac{\ln ^22}{2}\)