[LECS/CM-02] From Newtonian Mechanics to Euler Lagrange Form of Dynamics

 Euler Lagrange equations are obtained using Newton's laws and D' Alembert's principle.

For systems for which the generalized forces can be derived from a generalized potential \(U\), the Lagrangian can be  defined as \(L=T-U\) and the Euler Lagrange equations take the form \[\begin{equation*} \frac{d}{dt}\frac{\partial{L}}{\partial\dot{q_k}}-\frac{\partial{L}}{\partial{ q_k}}=0. \end{equation*}\]

 Whenever the generalized force \(Q_k\) \[\begin{equation}\label{AB01} Q_k=\sum_\alpha F^\text{(e)}_\alpha \pp[\vec{x}_\alpha]{q_k}. \end{equation}\] can be written in the form \[\begin{equation}\label{AB02} Q_k = \dd{t}\Big(\pp[U]{\dot{q}_k}\Big)-\pp[U]{q_k} . \end{equation}\] the equations of motion take the Euler Lagrange form with \(L=T-U\). It is demonstrated that the Lorentz force,the force on a charged particle in e.m. fields, has the form as in \(\eqref{AB02}\). An expression for the generalized potential \(U\) is derived.

 If the Lagrangian does not depend on time explicitly, the Hamiltonian \(H=\sum_{k=1}\frac {\partial{L}}{\partial{\dot q_k}}\dot q_k-L\) is a constant of motion.  For conservative systems of many particles, the Hamiltonian coincides with the total energy. is conserved.

A generalized coordinate,\(q_k\), is called cyclic if the Lagrangian is independent of the coordinate \(q_k\). It is shown that the corresponding canonical momentum is a constant of motion. A simple example of cyclic coordinate is given. 

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.

Eliminating cyclic coordinates using Routh's procedure is presented.