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3.7: Momentum Angular

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    Notación:

    • \(\textbf{L}_{C}\)= momento angular del sistema con respecto al centro de masa C.
    • \(\textbf{L}\)= momento angular del sistema relativo a algún otro origen O.
    • \(\overline{\textbf{r}}\)= vector de posición de C con respecto a O.
    • \(\textbf{P}\)= impulso lineal del sistema con respecto a O.
    • (El impulso lineal con respecto a C es, por supuesto, cero.)
    Teorema:

    \[ \textbf{L} = \textbf{L}_{C} + \overline{\textbf{r}} \times \textbf{P} \tag{3.7.1}\label{eq:3.7.1} \]

    Así:

    \[ \begin{align*} \textbf{L} &= \sum \textbf{r}_{i}\times \textbf{p}_{i} = \sum m_{i}(\textbf{r}_{i}\times \textbf{v}_{i}) = \sum m_{i}(\overline{\textbf{r}} + \textbf{r}_{i}^{\prime})\times(\overline{\textbf{v}} + \textbf{v}_{i}^{\prime}) \\[5pt] &=(\overline{\textbf{r}}\times \overline{\textbf{v}})\sum m_{i} + \overline{\textbf{r}}\times \sum m_{i}\textbf{v}_{i}^{\prime} + (\sum m_{i}\textbf{r}_{i}^{\prime}) \times \overline{\textbf{v}} + \sum \textbf{r}_{i}^{\prime} \times \textbf{p}_{i}^{\prime} \\[5pt] &=M(\overline{\textbf{r}}\times \overline{\textbf{v}}) +\overline{\textbf{r}}\times 0 + 0 \times \overline{\textbf{v}} + \textbf{L}_{C} \end{align*} \nonumber \]

    por lo tanto

    \[\qquad \textbf{L} =\textbf{L}_{C} + \overline{\textbf{r}} \times \textbf{P} \nonumber \]

    Ejemplo\(\PageIndex{1}\)

    Un aro de radio a rodando a lo largo del suelo (Figura III.6):


    alt

    El momento angular con respecto a C es L C =\(I_{C \omega}\) donde\( I_{C}\) está la inercia rotacional alrededor de C. El momento angular alrededor de O es por lo tanto

    \[ I = I_{C}\omega+M\overline{v}a=I_{C}\omega+Ma^{2}\omega=(I_{C}+Ma^{2})=I\omega \nonumber \]

    donde

    \[ I = I_{C}+Ma^{2} \nonumber \]

    es la inercia rotacional alrededor de O.


    This page titled 3.7: Momentum Angular is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by Jeremy Tatum via source content that was edited to the style and standards of the LibreTexts platform.