The dipole model of the Earth's magnetic field is a first order approximation of the rather complex true Earth's magnetic field. Due to effects of the interplanetary magnetic field (IMF), and the solar wind, the dipole model is particularly inaccurate at high L-shells (e.g., above L=3), but may be a good approximation for lower L-shells. For more precise work, or for any work at higher L-shells, a more accurate model that incorporates solar effects, such as the Tsyganenko magnetic field model, is recommended.
The following equations describe the dipole magnetic field.[1]
First, define
B0
| -5 | |
| B | |
| 0=3.12 x 10 |
rm{T}
Then, the radial and latitudinal fields can be described as
Br=
| -2B | ||||
|
\right)3\cos\theta
B\theta=
| -B | ||||
|
\right)3\sin\theta
|B|=
| B | ||||
|
\right)3\sqrt{1+3\cos2\theta}
where
RE
r
RE
\theta
It is sometimes more convenient to express the magnetic field in terms of magnetic latitude and distance in Earth radii. The magnetic latitude (MLAT), or geomagnetic latitude,
λ
\theta
λ=\pi/2-\theta
In this case, the radial and latitudinal components of the magnetic field (the latter still in the
\theta
Br=-
| 2B0 | |
| R3 |
\sinλ
B\theta=
| B0 | |
| R3 |
\cosλ
|B|=
| B0 | |
| R3 |
\sqrt{1+3\sin2λ}
where
R
R=r/RE
Invariant latitude is a parameter that describes where a particular magnetic field line touches the surface of the Earth. It is given by[2]
Λ=\arccos\left(\sqrt{1/L}\right)
or
L=1/\cos2\left(Λ\right)
where
Λ
L
On the surface of the earth, the invariant latitude (
Λ
λ