90. $\int_{0}^{\frac{\pi}{2}} \frac{sin(x)^3}{cos(x)^3 + sin(x)^3} dx$

try some.
$\begin{aligned} &\int_0^{\frac{\pi}{2}} \frac{sin(x)^3}{cos(x)^3 + sin(x)^3} dx\\ &cos^3x+sin^3x=(cos^2x+sin^2x)(cosx+sinx)-cosxsin^2x-cos^2xsinx\\ &=cosx+sinx-cosxsin^2x-cos^2sinx\\ &=cosx(1-sin^2x)+sinx(1-cos^2x) \\ & u = cos(x), du=-sin(x)dx\\ &=\int \frac{sinx(1-u^2)}{u^3+sinx(1-u^2)} (-\frac{1}{sinx})du\\ & u=cos^3x+sin^3x, du/dx=3cos^2x(-sinx)+3sin^2xcosx \\ &=\int \frac{sinx(1-cos^2x)}{cos^3x+sin^3x}dx \\ &=\int \frac{1}{cot^3x+1}dx \end{aligned}$
$\int \frac{sin^3x}{cos^3x+sin^3x} dx\\ (cosx+sinx)^3 = cos^3x+sin^3x+3cos^2xsinx+3cosxsin^2x\\ =cos^3x+sin^3x+3cosxsinx(cosx+sinx)\\ =\int \frac{1}{cot^3x+1}dx=\int \frac{1}{(1+cot^2)(cotx)-cotx+1}dx\\ =\int \frac{1}{csc^2xcotx-cotx+1}dx\\ =\int \frac{tan^3x}{1+tan^3x}dx (u=tan x, du=sec^2x dx)\\ =\int \frac{u^3}{1+u^3}\frac{1}{sec^2x}dx$

fail… very hard…

$\begin{aligned} &\text{Hint: tan x, x=arctan subs... }\\ &\int \frac{sin^3x}{cos^3x+sin^3x} dx \\ &=\int \frac{tan^3x}{1+tan^3x}dx, \quad (x=tan^{-1}y, dx=\frac{1}{1+y^2}dy)\\ &=\int \frac{y^3}{1+y^3}\frac{1}{1+y^2}dy \\ &=\int \frac{y^3+1-1}{(1+y^2)(1+y^3)}dy \\ &=\int \frac{1}{(1+y^2)}-\int \frac{1}{(1+y^2)(1+y^3)}dy \\ &=arctan(y)-\int \frac{ay+b}{1+y^2}+\frac{cy^2+dy+e}{1+y^3} dy\\ & a+c=0, b+d=0, c+e=0, d+a=0, b+e=1\\ &=a=-c, b=-d, c=-e, d-c=0, -c+-c=1, c=d=-b=-a, \\ &c=d=-(1/2), a=b=e=(1/2)\\ &\frac{(1/2)y+(1/2)}{1+y^2}+\frac{-(1/2)y^2+(-1/2)y+(1/2)}{1+y^3}\\ &=arctan(y)-\int \frac{(1/2)y+(1/2)}{1+y^2}+\frac{-(1/2)y^2+(-1/2)y+(1/2)}{1+y^3} dy\\ &=arctan(y)-\frac 1 2\int \frac{1+y}{1+y^2}dy+\frac 1 2 \int \frac{y^2+y-1}{1+y^3} dy\\ &\int \frac{1+y}{1+y^2}dy =\int \frac 1 {1+y^2}dy+\int \frac y {1+y^2}dy\\ &=arctan (y)+\frac 1 2 ln|1+y^2|\\ &R=\int \frac{y^2+y-1}{1+y^3}=\int \frac {y^2}{1+y^3}dy+\int \frac {y-1}{1+y^3}dy\\ &\int \frac {y^2}{1+y^3}dy=\frac 1 3 ln(1+y^3)\\ &y^3+1=(y+1)(y^2-y+1)\\ &\int \frac {y-1}{1+y^3}dy=\int \frac{ay+b}{y^2-y+1}+\frac{c}{y+1}dy\\ &a+c=0, b-c+a=0, b+c=1, a=-c, b=2c\\ &c=1/3, b=2/3, a=-1/3\\ &\int \frac {y-1}{1+y^3}dy=\int \frac{(-1/3)y+2/3}{y^2-y+1}+\frac{1/3}{y+1}dy\\ &=-\frac 1 3 \int \frac{y-2}{y^2-y+1}dy+\frac 1 3 \int \frac{1}{y+1}dy\\ &=-\frac 2 3 \int \frac{y-\frac 1 2-\frac 3 2 }{y^2-y+1}dy+\frac 1 3 ln|y+1|\\ &\int \frac{y-\frac 1 2-\frac 3 2 }{y^2-y+1}dy=\int \frac{y-\frac 1 2}{y^2-y+1}dy-\frac 3 2 \int \frac{1}{y^2-y+1}dy \\ &=\frac 1 2 ln(y^2-y+1) -\frac 3 2 \int \frac{1}{y^2-y+1}dy \\ &\int \frac{1}{y^2-y+1}dy=\int \frac {1}{tan^2x+1-tanx}sec^2xdx\\ &=\int \frac {sec^2x}{sec^2x-tanx}dx=\int \frac {\frac 1 {cos^2x}}{\frac{1-cosxsinx}{cos^2x}}dx=\int \frac 1 {1-cosxsinx}dx\\ &=\int \frac{2}{2- sin2x}dx\\ &\frac{1}{y^2-y+1}=c\frac {(ay+b)'}{1+(ay+b)^2}=\frac{ac}{a^2y^2+2aby+b^2+1}\\ &a/c=1, 2b/c=-1, (b^2+1)/ac=1, a=c=-2b\\ &(b^2+1)=(4b^2), 3b^2=1, b=\pm \frac 1 {\sqrt{3}} \\ &b=-\frac 1 {\sqrt 3}, a=c=\frac 2 {\sqrt 3}\\ &\frac{1}{y^2-y+1}=\frac 2 {\sqrt 3}\frac{\frac 2 {\sqrt 3}}{1+(\frac 2 {\sqrt 3}y-\frac 1 {\sqrt 3})^2}\\ &\int \frac{1}{y^2-y+1}dy=\frac 2 {\sqrt 3}\int \frac{\frac 2 {\sqrt 3}}{1+(\frac 2 {\sqrt 3}y-\frac 1 {\sqrt 3})^2} dy\\ &=\frac 2 {\sqrt 3}arctan(\frac 2 {\sqrt 3}y-\frac 1 {\sqrt 3})\\ & R=\int \frac{y^2+y-1}{1+y^3} dy = \frac1 3 ln(1+y^3)-\frac 2 3 ( \frac 1 2 ln(y^2-y+1)-\sqrt 3 arctan(\frac 2 {\sqrt 3} y-\frac 1 {\sqrt 3}) ) +\frac 1 3 ln(y+1)\\ &R=\frac 2 3 ln (y+1)+\frac 2 {\sqrt 3} arctan( \frac{2y-1}{\sqrt 3})\\ & \therefore Q=arctan(y)-\frac 1 2\int \frac{1+y}{1+y^2}dy+\frac 1 2 \int \frac{y^2+y-1}{1+y^3} dy \\ &=arctan(y)-\frac 1 2 ( arctan (y)+\frac 1 2 ln|1+y^2|)\\ &+\frac 1 2 ( \int \frac{y^2+y-1}{1+y^3} dy )\\ &=\frac 1 2 x-\frac 1 4 ln|1+tan^2x|+\frac 1 2 R\\ &=\frac 1 2 x-\frac 1 4 ln|1+tan^2x|+\frac{1}{3}ln|1+tanx|+\frac 1 {\sqrt 3}arctan(\frac {2tanx-1}{\sqrt 3}) \end{aligned}\\$
이렇게라도 해봤는데… 답이 안나옴…
답은 pi/4 라고 하니, 알아서 도전바람…
끈기 있게 다시 시도…

$\begin{aligned} &\int \frac{sin^3x}{cos^3x+sin^3x} dx \\ &=\int \frac{tan^3x}{1+tan^3x}dx, \quad (x=tan^{-1}y, dx=\frac{1}{1+y^2}dy)\\ &=\int \frac{y^3}{1+y^3}\frac{1}{1+y^2}dy \\ &=\int \frac{y^3}{(1+y^2)(1+y^3)}dy =\int \frac{y^3}{(1+y)(1+y^2)(1-y+y^2)}dy\\ &\frac{a}{y+1}+\frac{by+c}{y^2+1}+\frac{dy+e}{y^2-y+1}=\frac{ (a+b)y^2+(b+c)y+(a+c) }{y^3+y^2+y+1}+\frac{dy+e}{y^2-y+1}\\ &y^4( a+b +d)=0, y^3(b+c-a-b+e+d=1), y^2(a+c-b-c+a+b+e+d)=0,\\ &y(-a-c+b+c+e+d)=0, a+c+e=0\\ &a+c+e=0, -a+b+e+d=0, 2a+e+d=0, -a+c+d+e=1, a+b+d=0\\ &b+d=-a, -2a+e=0, e=2a, c=-3a, d=-4a, -a-3a-4a+2a=1\\ &a=-1/6, c=1/2, e=-1/3, d=2/3, b=-1/2\\ &Q=\int \frac{-1/6}{y+1}+\frac{(-1/2)y+(1/2)}{y^2+1}+\frac{(2/3)y+(-1/3)}{y^2-y+1} dy\\ &=-\frac 1 6 ln(y+1)- \frac 1 2 \int \frac{y-1}{y^2+1}dy+\frac 1 3 \int \frac{2y-1}{y^2-y+1} dy\\ &=-\frac 1 6 ln(y+1)- \frac 1 2 \int \frac y {y^2+1}dy +\frac 1 2 \int \frac 1 {y^2+1}dy+\frac 1 3 ln(y^2-y+1) \\ &=-\frac 1 6 ln(y+1)-\frac 1 4 ln(y^2+1)+\frac 1 2 arctan(y)+\frac 1 3 ln(y^2-y+1) \\ &\text{x= 0 to pi/2 , y=0 to inf. y=tan(x)}\\ &=\frac 1 2 x +\frac 1 {12} ( 4ln(y^2-y+1)-2ln(y+1)-3ln(y^2+1) )\\ &=\frac 1 2 x +\frac 1 {12} ln ( \frac{ (y^2-y+1)^4}{(y+1)^2(y^2+1)^3} ) \\ & (x=0, then Q=0 ) \\ & (x=\pi/2, then Q= \pi/4 , ( \lim_{y\to\infty} ln \frac{O(y^8)}{O(y^8)}=ln1=0) )\\ & \therefore Q=\frac {\pi}{4}\\ &Q=\frac 1 2 x +\frac 1 {12} ln ( \frac{ (y^2-y+1)^4} {(y+1)^2(y^2+1)^3} )\\ &=\frac 1 2 x +\frac 1 {12} ln( \frac{(1+tan^2x-tanx)^4}{(1+tanx)^2(1+tan^2x)^3})\\ &=\frac 1 2 x +\frac 1 {12} ln( \frac{(sec^2x-tanx)^4}{(1+tanx)^2(secx)^6})\\ &=\frac 1 2 x +\frac 1 {6} ln( \frac{(sec^2x-tanx)^2}{(1+tanx)(secx)^3})\\ &=\frac 1 2 x +\frac 1 {3} ln(\frac{1-cosxsinx}{cos^2x})-\frac 1 6 ln(\frac{cosx+sinx}{cos^4x})\\ &=\frac 1 2 x + \frac 1 3 ln(1-cosxsinx)-\frac 2 3ln(cosx)-\frac 1 6 ln(cosx+sinx)+\frac 2 3 ln(cosx)\\ &=\frac 1 2 x +\frac 1 3 ln(1-cosxsinx)-\frac 1 6 ln(cosx+sinx)+C\\ \end{aligned}$

https://math.stackexchange.com/questions/198083/int-frac-sin3x-sin3x-cos3x

Author: crazyj7@gmail.com

51. $\int \sec^6x dx$

$\begin{aligned} &\int \sec^6x dx =\int \sec^2x sec^4 x dx\\ &(D( tanx ) \rightarrow sec^2x) \\ &=sec^4x tanx-\int 4sec^3xsecxtanxtanxdx\\ &=sec^4xtanx-4\int sec^4xtan^2x dx\\ &=sec^4xtanx-4\int sec^4xsec^2x-sec^4x dx\\ &=sec^4xtanx-4\int sec^6x dx+4\int sec^4x dx\\ &5\int sec^6x dx = sec^4xtanx+4\int sec^4 dx\\ &\int sec^4 dx=\int \sec^2x (1+\tan^2x) dx=\int sec^2x dx+\int sec^2xtan^2xdx\\ &=\tan{x}+\int sec^2xtan^2x dx\\ &\int sec^2xtan^2x dx (u=tan x, du= sec^2x dx)\\ &=\int u^2 du = \frac{1}{3}u^3=\frac{1}{3}\tan^3{x}\\ &5\int sec^6x dx = sec^4xtanx+4\int sec^4 dx\\ &=sec^4xtanx+4(tan x+\frac{1}{3}\tan^3{x})\\ &\therefore \int sec^6x dx=\frac{1}{5}sec^4xtanx +\frac{4}{5}tanx+\frac{4}{15}tan^3x +C\\ &=\frac{1}{5}(1+2tan^2x+tan^4x)tanx +\frac{4}{5}tanx+\frac{4}{15}tan^3x +C\\ &=\frac{1}{5}tan^5x+\frac{5}{5}tanx+\frac{10}{15}tan^3x +C\\ &=\frac{1}{5}tan^5x+\frac{2}{3}tan^3x+tan {x} +C\\ \end{aligned}$
Alternative

$\begin{aligned} &\int \sec^6x dx =\int (\sec^2x)^2 sec^2 x dx=\int (1+\tan^2x)^2 sec^2 x dx\\ &(u=tanx, du=sec^2x dx)\\ &=\int (1+u^2)^2 du = \int u^4+2u^2+1du=\frac{1}{5}u^5+\frac{2}{3}u^3+u\\ &=\frac{1}{5}tan^5x+\frac{2}{3}tan^3x+tan {x} +C\\ \end{aligned}$

52. $\int 1/(5x - 2)^4 dx$

$\begin{aligned} &\int \frac{1}{(5x - 2)^4}dx (u=5x-2, du=5dx)\\ &=\frac{1}{5}\int u^{-4}du=-\frac{1}{15}u^{-3}=-\frac{1}{15}(5x-2)^{-3}+C \end{aligned}$

53. $\int ln (1+x^2) dx$

$\begin{aligned} &\int ln (1+x^2)dx =\int 1*ln (1+x^2)dx \\ &=(ln|1+x^2|)(x)-\int \frac{2x^2}{1+x^2} dx\\ &=xln|1+x^2|-2\int \frac{x^2+1-1}{1+x^2} dx\\ &=xln|1+x^2|-2\int 1-\frac{1}{1+x^2} dx\\ &=xln|1+x^2|-2x+2\int\frac{1}{1+x^2} dx\\ &=xln|1+x^2|-2x+2 \arctan{x}+C\\ \end{aligned}$

54. $\int \frac{1}{x^4+x} dx$

$\begin{aligned} &\int \frac{1}{x^4+x} dx =\int \frac{1}{x(x^3+1)}dx \\ &=\int \frac{1}{x(x+1)(x^2-x+1)}dx \\ &=\int \frac{1}{x}+\frac{-\frac{1}{3}}{x+1}+\frac{-\frac{2}{3}x+\frac{1}{3}}{x^2-x+1}dx \\ &=ln|x|-\frac{1}{3}ln|x+1|-\frac{2}{3} \int \frac{x-\frac{1}{2}}{(x-\frac{1}{2})^2+\frac{3}{4}}dx\\ &=ln|x|-\frac{1}{3}ln|x+1|-\frac{1}{3} ln |x^2-x+1|+C\\ &=\frac{1}{3}ln|x^3|-\frac{1}{3}ln|x+1|-\frac{1}{3} ln |x^2-x+1|+C\\ &=\frac{1}{3}ln|x^3\frac{1}{(x+1)}\frac{1}{(x^2-x+1)}+C\\ &=\frac{1}{3}ln|\frac{x^3}{x^3+1}|+C=-\frac{1}{3}ln|\frac{x^3+1}{x^3}|+C\\ &=-\frac{1}{3}ln|1+x^{-3}|+C \end{aligned}$
Alternative (미분형태가 나오도록… 차수를 1차이나게…)
$\begin{aligned} &\int \frac{1}{x^4+x} dx =\int \frac{1}{x^4(1+x^{-3})}dx \\ &=\int \frac{x^{-4}}{1+x^{-3}}dx (u=1+x^{-3}, du=-3x^{-4}dx)\\ &=-\frac{1}{3}\int \frac{1}{u}dx=-\frac{1}{3}ln|u|=-\frac{1}{3}ln|1+x^{-3}|+C \end{aligned}$

55. $\int \frac{1-tan x }{1+tan x} dx$

$\begin{aligned} &\int \frac{1-tan x }{1+tan x} dx \\ &=\int \frac{cos x-sin x }{cos x+sin x} dx =\int \frac{cos^2 x-sin^2 x }{(cos x+sin x)^2} dx \\ Alt. &= ln|cosx+sinx|+C\\ &=\int \frac{cos (2x) }{1+sin(2x)} dx (u=1+sin(2x), du = 2cos(2x)dx)\\ &=\frac{1}{2}\int \frac{1}{u}du\\ &=\frac{1}{2}ln|1+sin(2x)|+C \end{aligned}$

$\frac{1}{2}ln|1+sin(2x)|=ln|\sqrt{1+2sinxcosx}|\\ =ln|\sqrt{cos^2x+sin^2x+2sinxcosx}|\\ =ln|cos x + sin x|$

56. $\int x·sec(x)·tan(x) dx$

$\begin{aligned} &\int x \sec{x} \tan{x} dx dx (D sec \rightarrow sec x tan x) \\ &=x sec x - \int sec x dx\\ &=x sec x - ln|sec x+tan x | + C\\ \end{aligned}$
Check…
$D(x \sec x - ln|\sec x+\tan x | ) \\ = \sec x+x(\sec x \tan x)-\frac{\sec x \tan x + \sec^2 x}{\sec x + \tan x } \\ = \sec x + x \sec x \tan x - \sec x = x \sec x \tan x$

57. $\int arcsec(x) dx$

$\begin{aligned} &\int arcsec(x) dx \\ &( y=arcsec(x), x=sec(y), dx=sec(y)tan(y)dy )\\ &=\int y sec(y) tan (y) dy = y sec(y) - \int sec(y) dy \\ &=y sec(y) - ln | sec(y)+tan(y) | \\ &(R.T angle=y, a=1, h=x, o=sqrt(x^2-1) )\\ &=x arcsec(x)-ln |x+tan(arcsec(x)) |+C \\ &=x arcsec(x)-ln |x+\sqrt{x^2-1} |+C \\ \end{aligned}$
Alt.

$D(\arcsin{x}) \\ ( y=arcsec(x), x=sec(y), dx=sec(y)tan(y)dy )\\ =\frac{dy}{dx} = \frac{1}{sec(y)tan(y)}=cos^2y \csc y\\ =(\frac{1}{x})^2 \frac{x}{\sqrt{x^2-1}}=\frac{1}{x\sqrt{x^2-1}}$

$\int arcsec(x) dx = arcsec(x)(x)-\int \frac{1}{x \sqrt{x^2-1}} x dx \\ =x arcsec(x)-\int \frac{1}{\sqrt{x^2-1}}dx$

$\int \frac{1}{\sqrt{x^2-1}}dx (x=sec\theta, dx=sec\theta tan\theta d \theta)\\ =\int \frac{1}{tan \theta} sec\theta tan\theta d \theta\\ =\int sec \theta d \theta =ln|sec \theta+tan \theta|$

$\int arcsec(x) dx =x arcsec(x)-ln | sec \theta+tan\theta| \\ (R.T angle=\theta, a=1, h=x, o=sqrt(x^2-1))\\ \int arcsec(x) dx =x arcsec(x)-ln | x+\sqrt{x^2-1}| +C$

58. $\int (1 - cos(x))/(1 + cos(x)) dx$

$\begin{aligned} &\int \frac{1 - cos(x)}{1 + cos(x)}dx \\ &=\int \frac{1-2cos(x)+cos^2x}{1-cos^2x} dx =\int \frac{1-2cos(x)+cos^2x}{sin^2x} dx \\ &=\int \frac{1}{sin^2x}dx-2\int \frac{cos x}{sin^2 x}dx+\int \frac{cos^2x}{sin^2x} dx \end{aligned}$

$\int \frac{1}{sin^2x} dx=\int \frac{cos^2x + sin^2x}{sin^2x}\\ =\int \frac{cos^2x}{sin^2x} dx +x = \int cot^2x dx +x\\ =\int csc^2x-1 dx+x =\int csc^2x dx = -cot x \\ \int \frac{cos x}{sin^2x} dx (u=sin x, du=cos x dx)\\ =\int \frac{du}{u^2} = -\frac{1}{u}=-csc x\\ \int \frac{cos^2x}{sin^2x} dx =\int cot^2x dx =\int csc^2x-1dx\\ =-cot x - x$

$=\int \frac{1}{sin^2x}dx-2\int \frac{cos x}{sin^2 x}dx+\int \frac{cos^2x}{sin^2x} dx \\ = -cot x +2 csc x -cot x - x\\ =2 csc x -2cot x -x +C =2 (csc x -cot x) -x +C\\ =2(\frac{1-cos x}{sin x})-x+C\\$

$=2(\frac{\frac{1-cosx}{2}}{\frac{sinx}{2}})-x+C\\ =2(\frac{sin^2\frac{x}{2}}{2sin\frac{x}{2}cos\frac{x}{2}/2} )-x+C\\ =2tan(\frac{x}{2})-x+C$

Alt.
$\begin{aligned} &\int \frac{1 - cos(x)}{1 + cos(x)}dx \\ &( sin^2(\frac{x}{2})=\frac{1-cosx}{2} , cos^2(\frac{x}{2})=\frac{1+cosx}{2} )\\ &=\int \frac{sin^2(\frac{x}{2})}{cos^2(\frac{x}{2})} dx =\int \frac{1-cos^2(\frac{x}{2})}{cos^2(\frac{x}{2})} dx \\ &=\int sec^2{\frac{x}{2}} dx-x \\ &=2tan(\frac{x}{2})-x+C \end{aligned}$