choclo.prism.magnetic_ee#
- choclo.prism.magnetic_ee(easting, northing, upward, prism_west, prism_east, prism_south, prism_north, prism_bottom, prism_top, magnetization_east, magnetization_north, magnetization_up)[source]#
Easting derivative of the easting component of the magnetic field.
Returns the easting derivative of the easting component of the magnetic field due to a single rectangular prism on a single computation point.
- Parameters:
- easting
float
Easting coordinate of the observation point. Must be in meters.
- northing
float
Northing coordinate of the observation point. Must be in meters.
- upward
float
Upward coordinate of the observation point. Must be in meters.
- prism_west
float
The West boundary of the prism. Must be in meters.
- prism_east
float
The East boundary of the prism. Must be in meters.
- prism_south
float
The South boundary of the prism. Must be in meters.
- prism_north
float
The North boundary of the prism. Must be in meters.
- prism_bottom
float
The bottom boundary of the prism. Must be in meters.
- prism_top
float
The top boundary of the prism. Must be in meters.
- magnetization_east
float
The East component of the magnetization vector of the prism. Must be in \(A m^{-1}\).
- magnetization_north
float
The North component of the magnetization vector of the prism. Must be in \(A m^{-1}\).
- magnetization_up
float
The upward component of the magnetization vector of the prism. Must be in \(A m^{-1}\).
- easting
- Returns:
- b_ee
float
Easting derivative of the easting component of the magnetic field generated by the prism on the observation point in \(\text{T}\). Return
numpy.nan
if the observation point falls in a singular point: prism vertices, prism edges or interior points.
- b_ee
See also
Notes
Computes the easting derivative of the easting component of the magnetic field \(\mathbf{B}(\mathbf{p})\) generated by a rectangular prism \(R\) with a magnetization vector \(M\) on the observation point \(\mathbf{p}\) as follows:
\[B_{xx}(\mathbf{p}) = \frac{\mu_0}{4\pi} \left( M_x u_{xxx} + M_y u_{xxy} + M_z u_{xxz} \right)\]Where \(u_{ijk}\) are:
\[u_{ijk} = \frac{\partial^3}{\partial i \partial j \partial k} \int\limits_R \frac{1}{\lVert \mathbf{p} - \mathbf{q} \rVert} dv\]with \(i,j,k \in \{x, y, z\}\).
References