Gelöste Aufgaben/Bike: Unterschied zwischen den Versionen

Version vom 10. März 2025, 11:09 Uhr

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Lorem Ipsum ....

\underline{\tilde{Q}} = (\begin{array}{c} W_{0} \\ Φ_{0} \\ W_{1} \\ Φ_{1} \\ W_{2} \\ Φ_{2}, \\ Ψ_{1}, \\ Ψ_{2} \end{array})

\underline{δ \tilde{Q}} = (\begin{array}{c} δ W_{0} \\ δ Φ_{0} \\ δ W_{1} \\ δ Φ_{1} \\ δ W_{2} \\ δ Φ_{2}, \\ δ Ψ_{1}, \\ δ Ψ_{2} \end{array})

\underline{Y} = [\begin{array}{c} \underline{Q} \\ \underline{\dot{Q}} \end{array}]

\begin{array}{ll} \underline{\dot{Y}} & = \underline{f} (\underline{Y}) \\ = [\begin{array}{l} \underline{\dot{Q}} \\ - {\underline{\underline{M}}}^{- 1} \cdot \underline{\underline{K}} \cdot \underline{Q} + {\underline{\underline{M}}}^{- 1} \cdot \underline{P} \end{array}] \end{array}

\underline{\underline{M}} \cdot \underline{\ddot{Q}} + \underline{\underline{K}} \cdot \underline{Q} = \underline{P} (\underline{Q}, \underline{\dot{Q}})

\begin{array}{lcc} δ W & = & δ W^{a} - δ Π \\ \overset{!}{=} & 0 \end{array}

δ Π = δ Π_{G} + δ Π_{S}

δ Π_{S} = K_{S} \cdot (Ψ_{2} - Ψ_{1}) \cdot (δ Ψ_{2} - δ Ψ_{1})

δ Π_{G} = δ Π_{G 1} + δ Π_{G 2}

δ Π_{G i} = \int_{0}^{ℓ_{i}} M_{i} (x) \cdot δ {w_{i}}^{″} (x) d x

M_{i} (x) = E \cdot I (x) \cdot {w_{i}}^{″} (x)

w_{i} (x) = {\underline{Q}}_{i}^{T} \cdot \underline{φ}

\underline{φ} = [\begin{array}{c} (ξ - 1)^{2} \cdot (2 \cdot ξ + 1) \\ ℓ_{i} \cdot ξ \cdot (ξ - 1)^{2} \\ - ξ^{2} \cdot (2 ξ - 3) \\ ℓ_{i} \cdot ξ^{2} \cdot (ξ - 1) \end{array}]

{\underline{\tilde{Q}}}_{i} = (\begin{array}{c} W_{i - 1} \\ Φ_{i - q} \\ W_{i} \\ Φ_{i} \end{array})

δ Π_{G i} = \int_{0}^{ℓ_{i}} E \cdot I_{i} (x) \cdot (W_{i - 1} {φ_{1}}^{″} \cdot δ W_{i - 1} {φ_{1}}^{″} + Φ_{i - 1} {φ_{2}}^{″} \cdot δ W_{i - 1} {φ_{1}}^{″} + W_{i} {φ_{3}}^{″} \cdot δ W_{i - 1} {φ_{1}}^{″} + \dots + Φ_{i} {φ_{4}}^{″} \cdot δ Φ_{i} {φ_{4}}^{″})

(.) : = \frac{d (.)}{d x}

δ Π_{G i} = δ Q_{i}^{T} \cdot {\underline{\underline{K}}}_{i} \cdot Q_{i}

k_{i, j k} = \int_{0}^{ℓ_{i}} E \cdot I_{i} (x) {φ_{j}}^{″} \cdot {φ_{k}}^{″} d x

I_{i} (x) = \frac{π}{64} (D_{i} (x)^{4} - d_{i} (x)^{4})

\begin{array}{ccccc} D_{i} (x) & = & D_{i - 1} \cdot (ξ_{1} - 1) & + & D_{i} \cdot ξ_{1} \\ d_{i} (x) & = & d_{i - 1} \cdot (ξ_{1} - 1) & + & d_{i} \cdot ξ_{1} \end{array}

ξ_{1} = \frac{x}{ℓ_{1}}

ξ_{2} = \frac{(x - H)}{ℓ_{2}}

\frac{d (.)}{d x} = \frac{d (.)}{d ξ_{i}} \cdot \frac{1}{ℓ_{i}}

\underline{\underline{K}} = (\begin{array}{cccccccc} k_{1, 11} & k_{1, 12} & k_{1, 13} & k_{1, 14} & 0 & 0 & 0 & 0 \\ k_{1, 12} & k_{1, 22} & k_{1, 23} & k_{1, 24} & 0 & 0 & 0 & 0 \\ k_{1, 13} & k_{1, 23} & k_{1, 33} + k_{2, 11} & k_{1, 34} + k_{2, 12} & k_{2, 13} & k_{2, 14} & 0 & 0 \\ k_{1, 14} & k_{1, 24} & k_{1, 34} + k_{2, 12} & k_{1, 44} + k_{2, 22} & k_{2, 23} & k_{2, 24} & 0 & 0 \\ 0 & 0 & k_{2, 13} & k_{2, 23} & k_{2, 33} & k_{2, 34} & 0 & 0 \\ 0 & 0 & k_{2, 14} & k_{2, 24} & k_{2, 34} & k_{2, 44} & 0 & 0 \\ 0 & 0 & 0 & 0 & 0 & 0 & K_{S} & - K_{S} \\ 0 & 0 & 0 & 0 & 0 & 0 & - K_{S} & K_{S} \end{array})

{\underline{r}}_{B, 1} = (\begin{array}{c} H - h - b \cdot \sin (Φ_{1} (t)) \\ - v_{0} t + W_{1} (t) + b \cdot \cos (Φ_{1} (t)) \end{array})

{\underline{r}}_{B, 2} = (\begin{array}{c} H - r_{2} \cdot \cos (Ω t + Ψ_{2} (t) + Θ_{2}) \\ - v_{0} t + W_{2} (t) - r_{2} \cdot \sin (Ω t + Ψ_{2} (t) + Θ_{2}) \end{array})

{\underline{r}}_{A} = (\begin{array}{c} H - R_{1} \cdot \cos (Ω t + Ψ_{1} (t) + Θ_{1}) \\ - v_{0} t + W_{1} (t) - R_{1} \cdot \sin (Ω t + Ψ_{1} (t) + Θ_{1}) \end{array})

{\underline{v}}_{B, r e l} = {\underline{\dot{r}}}_{B, 1} - {\underline{\dot{r}}}_{B, 2}

\begin{array}{lll} {\underline{v}}_{A, r e l} & = & {\underline{\dot{r}}}_{A} \\ = & (\begin{array}{c} 0 \\ - v_{0} + R_{1} \cdot (Ω + {\dot{Ψ}}_{1} (t)) + {\dot{W}}_{2} (t) \end{array}) \end{array}

\dot{(.)} : = \frac{d (.)}{d t}

δ W^{a} = δ W_{A}^{a} + δ W_{B}^{a} + δ W_{d^{'} A l e m b e r t}^{a}

δ {\underline{r}}_{B, 1} = (\begin{array}{c} - δ Φ_{1} b \\ δ W_{1} \end{array})

δ {\underline{r}}_{B 2} = (\begin{array}{c} r_{2} \cdot δ Ψ_{2} \sin (ψ) \\ δ W_{2} - r_{2} \cdot δ Ψ_{2} \cos (ψ) \end{array})

δ {\underline{r}}_{A} = (\begin{array}{c} 0 \\ δ W_{2} + R_{1} \cdot δ Ψ_{1} \end{array})

δ W_{A}^{a} = {\underline{F}}_{A}^{T} \cdot δ {\underline{r}}_{A}

δ W_{B}^{a} = {\underline{F}}_{B}^{T} \cdot δ {\underline{r}}_{B, 1} - {\underline{F}}_{B}^{T} \cdot δ {\underline{r}}_{B, 2}

{\underline{F}}_{B} = (\begin{array}{c} B_{x} \\ B_{z} \end{array})

{\underline{F}}_{A} = (\begin{array}{c} A_{V} \\ A_{H} \end{array})

δ W_{A}^{a} + δ W_{B}^{a} = B_{z} \cdot δ W_{1} - b \cdot B_{x} \cdot δ Φ_{1} + δ W_{2} \dot{(} A_{H} - B_{z}) + δ Ψ_{1} \cdot R_{1} \cdot A_{H} + δ Ψ_{2} \cdot (r_{2} \cdot B_{z} \cdot \cdot \cos (ψ) - r_{2} \cdot B_{x} \cdot \sin (ψ))

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@@ Zeile 183: / Zeile 183: @@
 </math>
+::<math>\underline{F}_{B} = \left(\begin{array}{c}
+                           B_x\\
+                           B_z \end{array}\right)
+</math>
+::<math>\underline{F}_{A} = \left(\begin{array}{c}
+                           A_V\\
+                           A_H \end{array}\right)
+</math>
+::<math>\delta W^a_{A}+\delta W^a_{B} =
+                B_z \cdot \delta W_1
+              - b \cdot B_x \cdot \delta\Phi_1
+              + \delta W_2 \dot (A_H - B_z)
+              + \delta \Psi_1 \cdot R_1 \cdot A_H
+              + \delta \Psi_2 \cdot (r_2 \cdot B_z \cdot \cdot \cos(\psi)-r_2 \cdot B_x \cdot \sin(\psi))
+</math>