Consider the motion of the following idealized pendulum: a bob of mass $m$ is attached to one end of a massless rigid rod. The other end of the rod is pivoted so that the mass may swing in a vertical plane. We neglect both the friction of the pivot and air drag.
The swinging of the pendulum is governed by
$$ \ddot{\theta}=-\frac{g}{L} \sin \theta $$
where $\theta$ is the angle between the rod and the downward vertical. This equation is derived in all textbooks of classical mechanics.Phase plane representation.
Let’s do the same trick as for the harmonic oscillator by representing the state of the pendulum as a point in the phase plane $x=\theta$, $y=\dot{\theta}$. This yields
$$ \begin{cases} \dot{x}= y\\ \dot{y}=-\omega^2 \sin x \end{cases} $$
where $\omega^2=\frac{g}{L}$. (Notice that $\omega$ has the dimension of a frequency.)Let’s draw the phase portrait!
We can now look at the trajectories of this system. In the following digital experiment, one can pull the mass away from its rest position, drop it (without speed) and see at once the resulting trajectory in the phase plane. One can also select a point in the phase plane and see at once the resulting motion of the pendulum. If one does not take a point on the $x$-axis, this means that one start with a nonzero velocity (we kick the mass).
Actually the equilibrium points are $(k\pi,0)$, where $k\in\mathbb{Z}$. The origin in the phase portrait corresponds to the stable equilibrium position of the pendulum hanging straight down. The points $(\pm k\pi,0)$, $k\in\mathbb{Z}\backslash \{0\}$, correspond to the unstable equilibrium position where the pendulum is straight up. Let’s restrict to the points $(-\pi,0)$, $(0,0)$, $(\pi,0)$, since the phase portrait is periodic in the $x$-direction (translating horizontally points of the phase portrait by a distance that is a multiple of $2\pi$ yields the same phase portrait).
We observe two generic behaviors which take place into two separate regions:
- closed trajectories encircling the origin, which describe the periodic motions of the pendulum swinging back and forth;
- non closed trajectories, which are periodic in the $x$-direction, and which describe motions where the mass whirls around the pivot endlessly.
These two kinds of trajectories are separated by a eye-like curve, called the separatrix. It can be (approximately) obtained by dropping the mass very close from its upside down rest position.
Notice that, mathematically, the true separatrix corresponds to a set of initial states that has area zero in the plane. It corresponds to exceptional motions such that the pendulum tends to the unstable equilibrium, which takes an infinite amount of time.
$$
\frac{\dot{\theta}^2}{2}-\omega^2(1-\cos\theta)=\text{const}
$$ $$
E(x,y)=\frac{y^2}{2}-\omega^2(1-\cos x).
$$
It is well-known that we have conservation of total energy (kinetic $+$ potential) because we neglect friction of the pivot and air resistance. As shown in any textbook of classical mechanics