= ${\left[-\frac{5}{9}{\left(3x-4\right)}^{-3}\right]}_2^3$

= ${\left[-\frac{5}{9{\left(3x-4\right)}^3}\right]}_2^3$

$=$ $-\frac{5}{9{\left(3\cdot 3-4\right)}^3}+\frac{5}{9{\left(3\cdot 2-4\right)}^3}$

= $-\frac{5}{9{\left(9-4\right)}^3}+\frac{5}{9{\left(6-4\right)}^3}$

= $-\frac{5}{9\cdot 5^3}+\frac{5}{9\cdot 2^3}$

= $-\frac{5}{9}\cdot \left(\frac{1}{125}\right)+\frac{5}{9}\cdot \left(\frac{1}{8}\right)$

= $-\frac{1}{225}+\frac{5}{72}$

= $-\frac{8}{1800}+\frac{125}{1800}$

= $\frac{13}{200}$

= ${\left[6e^{x-3}\right]}_1^2$

$=$ $6e^{2-3}-6e^{1-3}$

= $6e^{-1}-6e^{-2}$

= ${\left[3e^{\mathrm{0,8}x-\mathrm{0,2}}\right]}_0^u$

$=$ $3e^{\mathrm{0,8}u-\mathrm{0,2}}-3e^{\mathrm{0,8}\cdot 0-\mathrm{0,2}}$

= $3e^{\mathrm{0,8}u-\mathrm{0,2}}-3e^{0-\mathrm{0,2}}$

= $3e^{\mathrm{0,8}u-\mathrm{0,2}}-3e^{-\mathrm{0,2}}$

Diese Integralfunktion soll ja den Wert $14$ annehmen, deswegen setzen wir sie gleich :

Wir berechnen den Mittelwert mit der üblichen Formel:

= $\frac{1}{\pi }$ ${\left[5\cdot \sin \left(x-\frac{3}{2}\pi \right)\right]}_{\frac{1}{2}\pi }^{\frac{3}{2}\pi }$

$=$ $\frac{1}{\pi }·\left(5\cdot \sin \left(\frac{3}{2}\pi -\frac{3}{2}\pi \right)-5\cdot \sin \left(\frac{1}{2}\pi -\frac{3}{2}\pi \right)\right)$

= $\frac{1}{\pi }·\left(5\cdot \sin \left(0\right)-5\cdot \sin (-\pi )\right)$

= $\frac{1}{\pi }·\left(5\cdot 0-5\cdot 0\right)$

= $\frac{1}{\pi }·\left(0+0\right)$

= $\frac{1}{\pi }·0$

= 0

= ${\left[-{\left(x-1\right)}^{-2}\right]}_u^2$

= ${\left[-\frac{1}{{\left(x-1\right)}^2}\right]}_u^2$

$=$ $-\frac{1}{{\left(2-1\right)}^2}+\frac{1}{{\left(u-1\right)}^2}$

= $-\frac{1}{1^2}+\frac{1}{{\left(u-1\right)}^2}$

= $-1+\frac{1}{{\left(u-1\right)}^2}$

= $\frac{1}{{\left(u-1\right)}^2}-1$

Für u → 1 (u>1, also von rechts) gilt: A(u) = $\frac{1}{{\left(u-1\right)}^2}-1$ → $\infty$