Wiki-Quellcode von Lösung Lineare Algebra
Verstecke letzte Bearbeiter
| author | version | line-number | content |
|---|---|---|---|
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1.1 | 1 | === Teilaufgabe a) === |
| 2 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
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7.1 | 3 | [[image:B3.1Lösunga).png||width="450" style="display:block;margin-left:auto;margin-right:auto"]] |
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1.1 | 4 | {{/detail}} |
| 5 | |||
| 6 | |||
| 7 | === Teilaufgabe b) === | ||
| 8 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
| 9 | {{formula}}D(0|0|0),E(5|0|2),H(0|0|2){{/formula}} | ||
| 10 | <br> | ||
| 11 | {{formula}}A_{BCGF}=5\cdot 2=10{{/formula}} | ||
| 12 | <br> | ||
| 13 | {{formula}}A_{ABFE}=2\cdot 2=4{{/formula}} | ||
| 14 | <br> | ||
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7.1 | 15 | {{formula}}A_{EFI}=\frac{1}{2}\cdot 0,5\cdot 2=0,5{{/formula}} |
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1.1 | 16 | <br> |
| 17 | {{formula}}A_{FGJI}=5\cdot \sqrt{1^2+0,5^2}\approx 5,59 {{/formula}} | ||
| 18 | <br> | ||
| 19 | {{formula}}A =2\cdot (A_{BCGF}+A_{ABFE}+A_{EFI}+A_{FGJI} )=2\cdot (10+4+0,5+5,59)=40,18{{/formula}} | ||
| 20 | <br> | ||
| 21 | {{formula}}40,18\cdot 10=401,8{{/formula}} | ||
| 22 | <br> | ||
| 23 | Das benötigte Glas wiegt {{formula}}401,8\text{kg}{{/formula}}. | ||
| 24 | {{/detail}} | ||
| 25 | |||
| 26 | === Teilaufgabe c) === | ||
| 27 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
| 28 | {{formula}}\overrightarrow{JG}=\left(\begin{matrix}0\\1\\-0,5 \end{matrix}\right){{/formula}} | ||
| 29 | <br> | ||
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7.1 | 30 | {{formula}}cos(\alpha)=\frac{\left(\begin{matrix}0\\1\\-0,5 \end{matrix}\right)\cdot \left(\begin{matrix}0\\1\\0 \end{matrix}\right)}{\sqrt{1^2+(-0,5)^2}\cdot \sqrt{1^2}}=\frac{1}{\sqrt{1,25}} \approx 0,8944 \quad \ \ \alpha \approx 26,57^\circ{{/formula}} |
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1.1 | 31 | {{/detail}} |
| 32 | |||
| 33 | === Teilaufgabe d) === | ||
| 34 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
| 35 | Ebene {{formula}}E{{/formula}}, in der das Sonnensegel liegt: | ||
| 36 | <br> | ||
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7.1 | 37 | {{formula}}E: \vec{x}=\overrightarrow{OF}+r\cdot \overrightarrow{FG}+ s\cdot \overrightarrow{FS}=\left(\begin{matrix}5\\2\\2 \end{matrix}\right)+ r\cdot \left(\begin{matrix}-5\\0\\0 \end{matrix}\right)+ s\cdot \left(\begin{matrix}-2\\2\\-0,5 \end{matrix}\right) \quad \ \ r,s\in \mathbb{R}{{/formula}} |
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1.1 | 38 | <br> |
| 39 | {{formula}}2+2s=3 \ \Leftrightarrow \ s=0,5{{/formula}} | ||
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7.1 | 40 | <br> |
| 41 | {{formula}}x_3=2-0,5\cdot 0,5=1,75<1,8 \ \text{(m)}{{/formula}} (d. h. der Baumstumpf muss gekürzt werden) | ||
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1.1 | 42 | {{/detail}} |
| 43 | |||
| 44 | === Teilaufgabe e) === | ||
| 45 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
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7.1 | 46 | {{formula}}\overrightarrow{FS}= \left(\begin{matrix}-2\\2\\-0,5 \end{matrix}\right); \ \|\overrightarrow{FS}|=\sqrt{4+4+0,25}=\sqrt{8,25}{{/formula}} |
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1.1 | 47 | <br> |
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7.1 | 48 | {{formula}}\overrightarrow{GS}= \left(\begin{matrix}3\\2\\-0,5 \end{matrix}\right); \ \ |\overrightarrow{GS}|=\sqrt{9+4+0,25}=\sqrt{13,25}{{/formula}} |
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1.1 | 49 | <br> |
| 50 | {{formula}}|\overrightarrow{FG}|=5{{/formula}} | ||
| 51 | {{/detail}} | ||
| 52 | |||
| 53 | === Teilaufgabe f) === | ||
| 54 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
| 55 | {{formula}}\overrightarrow{FP_k}=\left(\begin{matrix}-2\\k-2\\-0,5 \end{matrix}\right){{/formula}} | ||
| 56 | <br> | ||
| 57 | {{formula}}|\overrightarrow{FP_k}|=|\overrightarrow{GF}| \ \Leftrightarrow \ 5=\sqrt{4,25+(k-2)^2 }{{/formula}} | ||
| 58 | <br> | ||
| 59 | {{formula}}0=k^2-4k-16,75{{/formula}} | ||
| 60 | <br> | ||
| 61 | {{formula}}k_1\approx 6,56; \ k_2\approx-2,56{{/formula}} | ||
| 62 | <br> | ||
| 63 | D. h. für {{formula}}k_1{{/formula}} ist {{formula}}FGP_k{{/formula}} gleichschenklig. | ||
| 64 | <br><p> | ||
| 65 | Die Lösung {{formula}}k_2{{/formula}} ist aufgrund des Sachzusammenhangs irrelevant. | ||
| 66 | </p> | ||
| 67 | Alternativ: Ansatz {{formula}}|\overrightarrow{GP_k}|=|\overrightarrow{GF}|{{/formula}} möglich mit {{formula}}k_1\approx5,97{{/formula}}. | ||
| 68 | {{/detail}} | ||
| 69 | |||
| 70 | === Teilaufgabe g) === | ||
| 71 | {{detail summary="Erwartungshorizont (offiziell)"}} | ||
| 72 | Mit dem Ansatz kann die {{formula}}x_1{{/formula}}-Koordinate des Punktes {{formula}}T(t|4|3){{/formula}}, der von den beiden Punkten {{formula}}B{{/formula}} und {{formula}}G{{/formula}} denselben Abstand hat, bestimmt werden. | ||
| 73 | {{/detail}} |