19 lines
910 B
Plaintext
19 lines
910 B
Plaintext
\def\xstrut{\vphantom{\frac{(A)^1}{(B)^1}}}
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\begin{pspicture}(-0.5,-0.5)(7,4)
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\rput[l](0.5,3.6){$\xstrut \bullet$\hspace{7mm}Die Menge hei{\ss}t $\xstrut \IR^3$ / $\IR^n$;}
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\rput[l](0.5,3.0){$\xstrut \bullet$\hspace{7mm}Dabei ist $ \xstrut n$ eine nat\"{u}rliche Zahl, $\xstrut n\in\IN$.}
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\rput[l](0.5,2.4){$\xstrut \bullet$\hspace{7mm}Also: $\xstrut \IR^3 = \left\{ {\left( {a_1 ,a_2 ,a_3 } \right)|a_1,a_2 ,a_3\in \left. \IR \right\}} \right.$}
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\rput[l](0.5,1.8){$\bullet$\hspace{7mm}$\IR^3=\left\{\rnode[t]{ae}{\psframebox*[fillcolor=darkyellow, linestyle=none]{ \left(a_1 , \ldots,a_n\right)}}|a_1 , \ldots a_n \in \IR\right\}$}
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\rput[l](1,1.2){\rnode{a}{n-Tupel}}%
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\nccurve[angleB=-90]{->}{a}{ae}
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% \IR^3 = \left\{ {\psframebox*[fillcolor=darkyellow, linestyle=none]{{\left( {a_1 , \ldots \rnode[t]{ae},a_n } \right)}}}
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%{|a_1 , \ldots a_n \in \IR} \right\}
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\end{pspicture}
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