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Binārssose2020/la/uebungen/la4.pdf
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Binārssose2020/theo/uebungen/theo5.pdf
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sose2020/la/uebungen/la4.pdf
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sose2020/la/uebungen/la4.tex
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| @@ -3,6 +3,8 @@ | |||
| \title{Lineare Algebra 2: Übungsblatt 4} | |||
| \author{Dominik Daniel, Christian Merten} | |||
| \usepackage[]{gauss} | |||
| \begin{document} | |||
| \punkte[16] | |||
| @@ -57,4 +59,155 @@ | |||
| \end{enumerate} | |||
| \end{aufgabe} | |||
| \begin{aufgabe} | |||
| \begin{enumerate}[(a)] | |||
| \item Kurze Rechung ergibt | |||
| \begin{align*} | |||
| P_A &= \begin{gmatrix}[p] t-10 & 11 & 11 & 32 \\ | |||
| 1 & t & 2 & - 4 \\ | |||
| -1 & 1 & t-1 & 4 \\ | |||
| -2 & 2 & 2 & t+6 | |||
| \rowops | |||
| \swap{0}{1} | |||
| \end{gmatrix} | |||
| \sim | |||
| \begin{gmatrix}[p] | |||
| 1 & t & 2 & - 4 \\ | |||
| t-10 & 11 & 11 & 32 \\ | |||
| -1 & 1 & t-1 & 4 \\ | |||
| -2 & 2 & 2 & t+6 | |||
| \rowops | |||
| \add[-(t-10)]{0}{1} | |||
| \add{0}{2} | |||
| \add[2]{0}{3} | |||
| \colops | |||
| \add[-t]{0}{1} | |||
| \add[-2]{0}{2} | |||
| \add[4]{0}{3} | |||
| \end{gmatrix} \\ | |||
| &\sim | |||
| \begin{gmatrix}[p] | |||
| 1 & 0 & 0 & 0 \\ | |||
| 0 & 11-t^2 + 10t & -8 + 4t \\ | |||
| 0 & t+1 & t+1 & 0 \\ | |||
| 0 & 2+2t & 6 & t-2 | |||
| \rowops | |||
| \swap{1}{3} | |||
| \colops | |||
| \swap{1}{2} | |||
| \end{gmatrix} | |||
| \sim | |||
| \begin{gmatrix}[p] | |||
| 1 & 0 & 0 & 0 \\ | |||
| 0 & 6 & 2+2t & t-2 \\ | |||
| 0 & t+1 & t+1 & 0 \\ | |||
| 0 & 31-2t & 11-t^2 + 10t & -8+4t | |||
| \rowops | |||
| \mult{1}{\cdot \frac{1}{6}} | |||
| \end{gmatrix} \\ | |||
| &\sim | |||
| \begin{gmatrix}[p] | |||
| 1 & 0 & 0 & 0 \\ | |||
| 0 & 1 & \frac{1}{3} + \frac{1}{3}t & \frac{1}{6}t - \frac{1}{3} \\ | |||
| 0 & t+1 & t+1 & 0 \\ | |||
| 0 & 31-2t & 11-t^2+10t & -8+4t | |||
| \rowops | |||
| \add[-(t+1)]{1}{2} | |||
| \add[-(31-2t)]{1}{3} | |||
| \colops | |||
| \add[-\left(\frac{1}{3} + \frac{1}{3}t \right)]{1}{2} | |||
| \add[-\left(\frac{1}{6}t - \frac{1}{3} \right)]{1}{3} | |||
| \end{gmatrix} | |||
| \sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & -\frac{1}{3} t^2+\frac{2}{3} + \frac{1}{3}t & -\frac{1}{6}t^2 + \frac{1}{6}t + \frac{1}{3} \\ | |||
| 0 & \frac{2}{3} + \frac{1}{3}t - \frac{1}{3}t^2 & \frac{1}{3}t^2 - \frac{11}{6}t + \frac{7}{3} | |||
| \rowops | |||
| \add[-1]{1}{2} | |||
| \colops | |||
| \add[-\frac{1}{2}]{1}{2} | |||
| \end{gmatrix} \\ | |||
| &\sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & -\frac{1}{3}t^2 + \frac{1}{3}t + \frac{2}{3} & 0 \\ | |||
| 0 & 0 & \frac{1}{2}t^2 - 2t + 2 | |||
| \rowops | |||
| \mult{1}{\cdot (-3)} | |||
| \mult{2}{\cdot 2} | |||
| \end{gmatrix} | |||
| \sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & (t+1)(t-2) & 0 \\ | |||
| 0 & 0 & (t-2)^2 | |||
| \rowops | |||
| \add{1}{2} | |||
| \colops | |||
| \add[-1]{1}{2} | |||
| \end{gmatrix} \\ | |||
| &\sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & (t+1)(t-2) & -(t+1)(t-2) \\ | |||
| 0 & (t+1)(t-2) & -3t + 6 | |||
| \rowops | |||
| \swap{1}{2} | |||
| \colops | |||
| \swap{1}{2} | |||
| \end{gmatrix} | |||
| \sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & -3t + 6 & (t-2)(t+1) \\ | |||
| 0 & -(t-2)(t+1) & (t-2)(t+1) | |||
| \rowops | |||
| \mult{1}{\cdot \left( -\frac{1}{3} \right)} | |||
| \colops | |||
| \mult{2}{\cdot 3} | |||
| \end{gmatrix} \\ | |||
| &\sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & t - 2 & -(t-2)(t+1) \\ | |||
| 0 & -(t-2)(t+1) & 3(t-2)(t+1) | |||
| \rowops | |||
| \add[t+1]{1}{2} | |||
| \colops | |||
| \add[t+1]{1}{2} | |||
| \end{gmatrix} | |||
| \sim | |||
| \begin{gmatrix}[p] | |||
| E_2 & 0 & 0 \\ | |||
| 0 & t-2 & 0 \\ | |||
| 0 & 0 & (t-2)^2(t+1) | |||
| \end{gmatrix} | |||
| .\end{align*} | |||
| Damit folgen als Invariantenteiler: $c_1 = c_2 = 1$, $c_3 = t- 2$ und $c_4 = (t-2)^2(t+1)$. | |||
| Die Determinantenteiler sind damit $d_1 = 1$, $d_2 = 1$, $d_3 = t-2$ und $d_4 = (t-2)^{3}(t+1)$. | |||
| \item Hier ist sofort ersichtlich: | |||
| \begin{align*} | |||
| \text{det}(P_B) | |||
| = \begin{gmatrix}[v] | |||
| t+5 & 3 & -5 \\ | |||
| 0 & t-1 & 1 \\ | |||
| 8 & 4 & t-7 | |||
| \end{gmatrix} | |||
| = (t-1)^{3} | |||
| \neq | |||
| (t-2)(t-1)(t+1) | |||
| = | |||
| \begin{gmatrix}[v] | |||
| t+3 & -8 & -12 \\ | |||
| -1 & t+2 & 3 \\ | |||
| 2 & -4 & t-7 | |||
| \end{gmatrix} | |||
| = \text{det}(P_C) | |||
| .\end{align*} | |||
| Damit ist $d_3_{B} \neq d_3_{C}$, also sind nach Invariantenteilersatz | |||
| $B$ und $C$ nicht ähnlich. | |||
| \end{enumerate} | |||
| \end{aufgabe} | |||
| \end{document} | |||
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| @@ -36,7 +36,7 @@ | |||
| H &= \frac{p_{\vartheta}^2}{mR^2} - L \\ | |||
| &= \frac{p_{\vartheta}^2}{mR^2} | |||
| - \frac{1}{2} mR^2 (\dot{\vartheta}^2 + \omega^2\sin^2\vartheta) + mg R \cos\vartheta \\ | |||
| &= \frac{p_{\vartheta}^2}{2mR^2} - \frac{1}{2} \omega^2 \sin^2\vartheta + mgR\cos\vartheta | |||
| &= \frac{p_{\vartheta}^2}{2mR^2} - \frac{1}{2} R^2 \omega^2 \sin^2\vartheta + mgR\cos\vartheta | |||
| .\end{align*} | |||
| \item Es liegt hier zwar ein Potential vor, allerdings ist | |||
| die kinetische Energie des Systems gegeben als | |||
| @@ -47,8 +47,9 @@ | |||
| an der zeitabhängigen Zwangsbedingung. | |||
| Wegen $\frac{\partial H}{\partial t} = 0$ ist die Hamilton Funktion zeitlich | |||
| erhalten. Außerdem ist $\dot{w} = 0$, also ist das System | |||
| invariant gegenüber Zeittranslation. Damit folgt Energieerhaltung. | |||
| erhalten. Da die Zwangskräfte von der Zeit abhängen, ist das | |||
| System nicht invariant gegenüber Zeittranslation, also ist die Energie nicht | |||
| erhalten. | |||
| \item Für die kanonischen Gleichungen folgt | |||
| \begin{align*} | |||
| \frac{\partial H}{\partial p_{\vartheta}} &= \frac{2 p_{\vartheta}}{mR^2} - \frac{p_{\vartheta}}{mR^2} | |||