Kapitza's pendulum or Kapitza pendulum is a rigid pendulum in which the pivot point vibrates in a vertical direction, up and down. It is named after Russian Nobel laureate physicist Pyotr Kapitza, who in 1951 developed a theory which successfully explains some of its unusual properties.[1] The unique feature of the Kapitza pendulum is that the vibrating suspension can cause it to balance stably in an inverted position, with the bob above the suspension point. In the usual pendulum with a fixed suspension, the only stable equilibrium position is with the bob hanging below the suspension point; the inverted position is a point of unstable equilibrium, and the smallest perturbation moves the pendulum out of equilibrium. In nonlinear control theory the Kapitza pendulum is used as an example of a parametric oscillator that demonstrates the concept of "dynamic stabilization".
The pendulum was first described by A. Stephenson in 1908, who found that the upper vertical position of the pendulum might be stable when the driving frequency is fast.[2] Yet until the 1950s there was no explanation for this highly unusual and counterintuitive phenomenon. Pyotr Kapitza was the first to analyze it in 1951. He carried out a number of experimental studies and as well provided an analytical insight into the reasons of stability by splitting the motion into "fast" and "slow" variables and by introducing an effective potential. This innovative work created a new subject in physics – vibrational mechanics. Kapitza's method is used for description of periodic processes in atomic physics, plasma physics and cybernetical physics. The effective potential which describes the "slow" component of motion is described in "Mechanics" volume (§30) of Landau's Course of Theoretical Physics.[3]
Another interesting feature of the Kapitza pendulum system is that the bottom equilibrium position, with the pendulum hanging down below the pivot, is no longer stable. Any tiny deviation from the vertical increases in amplitude with time.[4] Parametric resonance can also occur in this position, and chaotic regimes can be realized in the system when strange attractors are present in the Poincaré section.[5]
Denote the vertical axis as
y
x
x
y
\nu
a
\omega0=\sqrt{g/l}
g
l
m
Denoting the angle between pendulum and downward direction as
\varphi
\begin{cases} x&=l\sin\varphi\\ y&=-l\cos\varphi-a\cos\nut \end{cases}
The potential energy of the pendulum is due to gravity and is defined by, in terms of the vertical position, as
EPOT=-mg(l\cos\varphi+a\cos\nut).
The kinetic energy in addition to the standard term
EKIN=ml2
| \varphi |
2/2
EKIN =
| ml2 | |
| 2 |
| \varphi |
2+mal\nu~\sin(\nut)\sin(\varphi)~
| \varphi |
+
| ma2\nu2 | |
| 2 |
\sin2(\nut) .
The total energy is given by the sum of the kinetic and potential energies
E=EKIN+EPOT
L=EKIN-EPOT
The total energy is conserved in a mathematical pendulum, so time
t
EPOT
EKIN
In the case of vibrating suspension the system is no longer a closed one and the total energy is no longer conserved. The kinetic energy is more sensitive to vibration compared to the potential one. The potential energy
EPOT=mgy
-mg(l+a)<EPOT<mg(l+a)
EKIN\ge0
\nu
Motion of pendulum satisfies Euler–Lagrange equations. The dependence of the phase
\varphi
| d | |
| dt |
| \partialL | ||||
|
=
| \partialL | |
| \partial\varphi |
,
where the Lagrangian
L
L=
| ml2 | |
| 2 |
| \varphi |
2+ml(g+a~\nu2\cos\nut)\cos\varphi,
up to irrelevant total time derivative terms. The differential equation
\ddot\varphi=-(g+a~\nu2\cos\nut)
| \sin\varphi | |
| l |
,
which describes the movement of the pendulum is nonlinear due to the
\sin\varphi
Kapitza's pendulum model is more general than the simple pendulum. The Kapitza model reduces to the latter in the limit
a=0
x2+y2=l2=constant
E>mgl
E<mgl
(x,y)=(0,-l)
When the suspension is vibrating with a small amplitude
a\lll
\nu\gg\omega0
\omega0
\varphi
\varphi=\varphi0+\xi
\varphi0
\xi
(a/l),(\omega0/\nu)\ll1
(a/l)(\nu/\omega0)
a\to0,\nu\toinfty
\xi
\xi=
| a | |
| l |
\sin\varphi0~\cos\nut.
The equation of motion for the "slow" component
\varphi0
\begin{align} \ddot\varphi0=\ddot\varphi-\ddot\xi&=-(g+a~\nu2\cos\nut)
| \sin\varphi | |
| l |
\\ &{} {}-
| a | |
| l |
\left(\ddot\varphi0\cos\varphi0~\cos\nut-
| \varphi |
| 2\sin\varphi | |
| 0 |
~\cos\nut-2\nu
| \varphi |
0\cos\varphi0~\sin\nut-\nu2\sin\varphi0~\cos\nut\right)\\[8pt]&=-
| g | |
| l |
\sin\varphi0-(g+a~\nu2\cos\nut)
| 1 | |
| l |
\left(\xi\cos\varphi0+O(\xi2)\right)\\ &{} {}-
| a | |
| l |
\left(\ddot\varphi0\cos\varphi0~\cos\nut-
| \varphi |
| 2\sin\varphi | |
| 0 |
~\cos\nut-2\nu
| \varphi |
0\cos\varphi0~\sin\nut\right). \end{align}
Time-averaging over the rapid
\nu
\ddot\varphi0=-
| g | |
| l |
\sin\varphi0-
| 1 | \left( | |
| 2 |
| a\nu | |
| l |
\right)2\sin\varphi0\cos\varphi0.
The "slow" equation of motion becomes
ml2\ddot\varphi0=-
| \partialVeff | |
| \partial\varphi0 |
,
by introducing an effective potential
Veff=-mgl\cos\varphi0+m\left(
| a\nu | |
| 2 |
\sin
| 2. | |
| \varphi | |
| 0\right) |
It turns out that the effective potential
Veff
(a\nu)2>2gl
(a/l)(\nu/\omega0)>\sqrt{2}
(x,y)=(0,-l)
(x,y)=(0,l)
For fixed forcing frequency
\nu
a
\varphi=\pi
\varphi=\pi
\nu/2
\propto\sqrt{a-ac}
ac
For even larger amplitude, the stable oscillation becomes unstable, and the pendulum would start rotating. At even larger amplitudes, the rotating mode is also destroyed, and a strange attractor appears by period-doubling cascade.[7] [8]
The rotating solutions of the Kapitza's pendulum occur when the pendulum rotates around the pivot point at the same frequency that the pivot point is driven. There are two rotating solutions, one for a rotation in each direction. We shift to the rotating reference frame using
\varphi → \varphi\prime\pm\nut
\varphi
\ddot\varphi\prime=-
| 1 | |
| l |
\left[
| 1 | |
| 2 |
a\nu2\sin(\varphi\prime)+g\sin(\varphi\prime\pm\nut)+
| 1 | |
| 2 |
a\nu2\sin(\varphi\prime\pm2\nut)\right] .
Again considering the limit in which
\nu
\omega0
\nu
| \prime | |
| \varphi | |
| 0 |
\ddot
| \prime | |
| \varphi | |
| 0 |
=-
| 1 | |
| 2l |
a\nu2
| \prime | |
| \sin\varphi | |
| 0 |
.
The effective potential is just that of a simple pendulum equation. There is a stable equilibrium at
| \prime | |
| \varphi | |
| 0 |
=0
| \prime | |
| \varphi | |
| 0 |
=\pi
Interesting phase portraits might be obtained in regimes which are not accessible within analytic descriptions, for example in the case of large amplitude of the suspension
a ≈ l
a=l/2
Further increase of the amplitude to
a ≈ l
a