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[NOTES/CM-02004] Integration of EOM by Quadratures

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We discuss an example of particle in two dimensions in  a potential independent of \(\theta\). By working in plane polar coordinates, we show how solution of  equations of motion   can be reduced to quadratures.

An example
The momentum conjugate to  cyclic coordinates is a constant of motion. This is very helpful in integrating the equations of motion. Consider the example discussed above in previous {\sf Lesson-A03}.  There we had a particle moving in two dimensions in a potential that depends only on the radial distance from the origin. Changing the variables to plane polar coordinates \((r,\theta)\) we  had obtained

\begin{eqnarray}
  \text{K.E.}   &=&  \frac{1}{2}{m\dot{x}^2} + \frac{1}{2}
{m\dot{y}^2}\nonumber \\
                &=& \frac{1}{2} {m\dot r}^2 + \frac{1}{2}m r^2 {\dot \theta}^2\\
   \therefore \qquad         L   &=& \frac{1}{2} {m\dot r}^2 + \frac{1}{2} m r^2
{\dot \theta}^2 -V(r)\label{EQ19}
\end{eqnarray}

Find all cyclic coordinates and conservation laws
 From the expression for Lagrangian in plane polar coordinates it is obvious that \(\theta\) is a cyclic coordinate. Hence the corresponding momentum \(p_\theta\) is conserved. Thus \begin{equation} p_\theta = \pp[L]{\dot{\theta}} = m r^2 {\dot{\theta}} =\text{constant}, \text{say}\,\ell. \label{EQ20} \end{equation} Since the total energy is also  a constant of motion, we have \begin{equation}\label{EQ21} E = \frac{1}{2} m {\dot{r}}^2 + \frac{1}{2} m r^2 {\dot \theta}^2 + V(r) \end{equation}

Solve for generalized velocities
Solving for \(\dot{\theta}\) in terms for \(\ell\) from \EqRef{EQ20} we get \begin{equation}\label{EQ22} \dot{\theta} = \frac{\ell}{mr^2} \end{equation} and substituting in \eqRef{EQ21} we get

\begin{eqnarray}
    E = \frac{1}{2} m {\dot{r}}^2 + \frac{\ell^2}{2m r^2}
                  + V(r)
\end{eqnarray}

This is a relation  between \(r,{\dot r}\) and can be solved for \(\dot{r}\). This gives \begin{equation} \dd[r]{t} = \sqrt{\frac{2}{m}\Big(E -\frac{\ell^2}{2m r^2} - V(r)}\Big) \end{equation}

Integrate the velocities
Integrating we get a relation between \(r\) and \(t\). \begin{equation} t = \int \frac{dr}{\sqrt{\dfrac{2}{m}\Big(E -\dfrac{\ell^2}{2m r^2} - V(r)\Big)}} + \text{const}. \end{equation} This relation can be inverted to give \(r\) as a function of  time, \(r= r(t)\). Substituting in \eqref{EQ22} and integrating  gives \begin{equation} \theta = \int \frac{\ell}{mr^2(t)}\, dt + \text{const}. \end{equation} On integration this equation can be used to get \(\theta\) as a function of \(t\). Thus we see that the conservation laws help in integrating the equations of motion. Sufficiently many conservation laws can reduce the complete solution to quadratures.

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