In classical mechanics, Bertrand's theorem states that among central-force potentials with bound orbits, there are only two types of central-force (radial) scalar potentials with the property that all bound orbits are also closed orbits.[1] [2]
The first such potential is an inverse-square central force such as the gravitational or electrostatic potential:
V(r)=-
| k | |
| r |
f(r)=-
| dV | |
| dr |
=-
| k | |
| r2 |
The second is the radial harmonic oscillator potential:
V(r)=
| 1 | |
| 2 |
kr2
f(r)=-
| dV | |
| dr |
=-kr
The theorem is named after its discoverer, Joseph Bertrand.
All attractive central forces can produce circular orbits, which are naturally closed orbits. The only requirement is that the central force exactly equals the centripetal force, which determines the required angular velocity for a given circular radius. Non-central forces (i.e., those that depend on the angular variables as well as the radius) are ignored here, since they do not produce circular orbits in general.
The equation of motion for the radius
r
m
V(r)
| m | d2r |
| dt2 |
-mr\omega2=m
| d2r | |
| dt2 |
-
| L2 | |
| mr3 |
=-
| dV | |
| dr |
,
where
\omega\equiv
| d\theta | |
| dt |
L=mr2\omega
| dV | |
| dr |
mr2\omega
The definition of angular momentum allows a change of independent variable from
t
\theta
| d | |
| dt |
=
| L | |
| mr2 |
| d | |
| d\theta |
,
giving the new equation of motion that is independent of time:
| L | |
| r2 |
| d | |
| d\theta |
\left(
| L | |
| mr2 |
| dr | |
| d\theta |
\right)-
| L2 | |
| mr3 |
=-
| dV | |
| dr |
.
This equation becomes quasilinear on making the change of variables
u\equiv
| 1 | |
| r |
| mr2 | |
| L2 |
| d2u | |
| d\theta2 |
+u=-
| m | |
| L2 |
| d | V\left( | |
| du |
| 1 | |
| u |
\right).
As noted above, all central forces can produce circular orbits given an appropriate initial velocity. However, if some radial velocity is introduced, these orbits need not be stable (i.e., remain in orbit indefinitely) nor closed (repeatedly returning to exactly the same path). Here we show that a necessary condition for stable, exactly closed non-circular orbits is an inverse-square force or radial harmonic oscillator potential. In the following sections, we show that those two force laws produce stable, exactly closed orbits (a sufficient condition) [it is unclear to the reader exactly what is the sufficient condition].
Define
J(u)
| d2u | |
| d\theta2 |
+u= J(u)\equiv-
| m | |
| L2 |
| d | V\left( | |
| du |
| 1 | |
| u |
\right)= -
| m | f\left( | |
| L2u2 |
| 1 | |
| u |
\right),
where
f
r0
where
u0\equiv1/r0
The next step is to consider the equation for
u
η\equivu-u0
J
J(u) ≈ J(u0)+ηJ'(u0)+
| 1 | |
| 2 |
η2J''(u0)+
| 1 | |
| 6 |
η3J'''(u0)+ …
Substituting this expansion into the equation for
u
| d2η | |
| d\theta2 |
+η=ηJ'(u0)+
| 1 | |
| 2 |
η2J''(u0)+
| 1 | |
| 6 |
η3J'''(u0)+ … ,
which can be written as
where
\beta2\equiv1-J'(u0)
\beta2
\beta=0
η(\theta)=h1\cos(\beta\theta),
where the amplitude
h1
\beta
\beta
J
J'(u0)=
| 2 | \left[ | |
| u0 |
| m | f\left( | |||||||||||
|
| 1 | |
| u0 |
\right)\right]-\left[
| m | f\left( | |||||||||||
|
| 1 | \right)\right] | |
| u0 |
| 1 | ||||
|
| d | f\left( | |
| du0 |
| 1{u | |
| 0}\right) |
= -2+
| u0 | ||||
|
| d | f\left( | |
| du0 |
| 1{u | |
| 0}\right) |
= 1-\beta2.
Since this must hold for any value of
u0
| df | |
| dr |
=(\beta2-3)
| f | |
| r |
,
which implies that the force must follow a power law
f(r)=-
| k | ||||
|
.
Hence,
J
For more general deviations from circularity (i.e., when we cannot neglect the higher-order terms in the Taylor expansion of
J
η
η(\theta)=h0+h1\cos\beta\theta+h2\cos2\beta\theta+h3\cos3\beta\theta+ …
We substitute this into equation and equate the coefficients belonging to the same frequency, keeping only the lowest-order terms. As we show below,
h0
h2
h1
| 2 | |
| h | |
| 1 |
h3
| 3 | |
| h | |
| 1 |
h0,h2,h3,\ldots
h1
h0=
| 2 | |
| h | |
| 1 |
| J''(u0) | |
| 4\beta2 |
,
h2=
| 2 | |
| -h | |
| 1 |
| J''(u0) | |
| 12\beta2 |
,
h3=-
| 1 | |
| 8\beta2 |
\left[h1h2
| J''(u0) | |
| 2 |
+
| 3 | |
| h | |
| 1 |
| J'''(u0) | |
| 24 |
\right].
From the
\cos\beta\theta
0= (2h1h0+h1h2)
| J''(u0) | |
| 2 |
+
| 3 | |
| h | |
| 1 |
| J'''(u0) | |
| 8 |
=
| |||||||
| 24\beta2 |
\left(3\beta2J'''(u0)+5
| 2\right), | |
| J''(u | |
| 0) |
where in the last step we substituted in the values of
h0
h2
Using equations and, we can calculate the second and third derivatives of
J
u0
J''(u0)=-
| \beta2(1-\beta2) | |
| u0 |
,
J'''(u0)=
| \beta2(1-\beta2)(1+\beta2) | ||||||
|
.
Substituting these values into the last equation yields the main result of Bertrand's theorem:
\beta2(1-\beta2)(4-\beta2)=0.
Hence, the only potentials that can produce stable closed non-circular orbits are the inverse-square force law (
\beta=1
\beta=2
\beta=0
For an inverse-square force law such as the gravitational or electrostatic potential, the potential can be written
V(r)=
| -k | |
| r |
=-ku.
| d2u | |
| d\theta2 |
+u=-
| m | |
| L2 |
| d | V\left( | |
| du |
| 1 | |
| u |
\right)=
| km | |
| L2 |
,
whose solution is the constant
| km | |
| L2 |
u\equiv
| 1 | |
| r |
=
| km | |
| L2 |
[1+e\cos(\theta-\theta0)],
where e (the eccentricity), and θ0 (the phase offset) are constants of integration.
This is the general formula for a conic section that has one focus at the origin; e = 0 corresponds to a circle, 0 < e < 1 corresponds to an ellipse, e = 1 corresponds to a parabola, and e > 1 corresponds to a hyperbola. The eccentricity e is related to the total energy E (see Laplace–Runge–Lenz vector):
e=\sqrt{1+
| 2EL2 | |
| k2m |
Comparing these formulae shows that E < 0 corresponds to an ellipse, E = 0 corresponds to a parabola, and E > 0 corresponds to a hyperbola. In particular,
E=-
| k2m | |
| 2L2 |
To solve for the orbit under a radial harmonic-oscillator potential, it's easier to work in components r = (x, y, z). The potential can be written as
V(r)=
| 1 | |
| 2 |
kr2=
| 1 | |
| 2 |
k(x2+y2+z2).
The equation of motion for a particle of mass m is given by three independent Euler equations:
| d2x | |
| dt2 |
+
| 2 | |
| \omega | |
| 0 |
x=0,
| d2y | |
| dt2 |
+
| 2 | |
| \omega | |
| 0 |
y=0,
| d2z | |
| dt2 |
+
| 2 | |
| \omega | |
| 0 |
z=0,
where the constant
| 2 | |
| \omega | |
| 0 |
\equiv
| k | |
| m |
x=Ax\cos(\omega0t+\phix),
y=Ay\cos(\omega0t+\phiy),
z=Az\cos(\omega0t+\phiz),
where the positive constants Ax, Ay and Az represent the amplitudes of the oscillations, and the angles φx, φy and φz represent their phases. The resulting orbit r(t) = [''x''(''t''), ''y''(''y''), ''z''(''t'')] is closed because it repeats exactly after one period
T\equiv
| 2\pi | |
| \omega0 |
.
The system is also stable because small perturbations in the amplitudes and phases cause correspondingly small changes in the overall orbit.