Ableitung und Integration

\(\text{arctan}(x) + C\)

als Integral schreiben

\(\text{cosh}(x) + C\)

(sinh' = cosh; cosh' = sinh; ohne Vorzeichenänderung)

als Integral schreiben

\(\int \frac{-1}{\sqrt{1-x^2}} dx=-\text{arcsin}(x) + C_1 = \text{arccos}(x) + C_2\)

(  \(\text{arcsin}(x) = -\text{arccos}(x)+\frac{\pi}{2} \)  )

\((\ f(g(x))\ )' = f'(g(x)) \cdot g'(x)\)

\(\int f'(g(x)) \cdot g'(x) \ dx = f(g(x))\)

1.  Zu substituierenden Term bestimmen \(\longrightarrow g(x)=y \implies x = g^{-1}(y)\)
2. dx berechnen    \(\frac{dx}{dy}=\frac{d}{dy}g^{-1}(y) = (g^{-1})'(y) \ \ \implies\ \ dx = (g^{-1})'(y)\cdot dy\)
3. Neue Integrationsgrenzen bestimmen     \(a_y=g(a),\ b_y=g(b)\)
4. Integral ausrechnen und Rücksubstitution
   \(\int_{a_y}^{b_y} f(y) \cdot (g^{-1})'(y)\ dy = h(a_y,b_y) + C = h(g(a),g(b)) + C\)

\(\int \frac{1}{\text{log}(x)}\frac{1}{x} dx = \text{log(log}(x)) + C\)

(Kettenregel und  \(\frac{d}{dx}log(x) = \frac{1}{x}\) )

\(\int \text{tan}(x) dx = \int \frac{\text{sin}(x)}{\text{cos}(x)} dx = -\int \frac{-\text{sin}(x)}{\text{cos}(x)} dx = \\-\int \frac{1}{\text{cos}(x)}(-\text{sin}(x))\ dx =-\text{log(cos}(x)) +C\)

\(\underbrace{\int_{1}^{2} x^2 \text{log}(x) dx }_{[\frac{x^3}{3}\text{log}(x)]_1^2 - \int_{1}^{2} \frac{1}{3}x^3 \cdot \frac{1}{x} dx}+ \underbrace{\int_{1}^{2} 1 \text{log}(x) dx }_{[x\text{log}(x)]_1^2 - \int_1^2 x\frac{1}{x} dx}\)
\(= [\frac{x^3}{3}\text{log}(x)- \frac{x^3}{9}+ x\text{log}(x)- x]_1^2\)\(= [(\frac{x^3}{3}+x)\text{log}(x)- \frac{x^3}{9}- x]_1^2\)
\(\dots\)

\(\text{ln}(|f(x)|) + C\)