Anderson function

The magnetic field from a magnetic dipole along a given line, and in any given direction can be described by the following basis functions:

$$

\frac{\theta^{~i-1}}{(\theta^2+1)^{\frac{5}{2}}}, \text{ for } i = 1,2,3

which are known as Anderson functions.{{cite journal |last1=Loane |first1=Edward P. |title=Speed and Depth Effects in Magnetic Anomaly Detection |date=12 October 1976 |url=https://apps.dtic.mil/docs/citations/ADA081329 |publisher=EPL ANALYSIS OLNEY MD |language=en}}

Definitions:

• $\backslash vec\{m\}$ is the dipole's strength and direction
• $\backslash vec\{B\}\_E$ is the projected direction (often the Earth's magnetic field in a region)
• $x$ is the position along the line
• $\backslash hat\{v\}$ points in the direction of the line
• $\backslash vec\{r\}$ is a vector from the dipole to the point of closest approach (CPA) of the line
• $\backslash theta\; =\; x/r$, a dimensionless quantity for simplification

The total magnetic field along the line is given by

$$

B(\theta) = \frac{\mu_0}{4\pi}\frac

m

{r^3}\left(\frac{A_1}{(\theta^2+1)^{\frac{5}{2}}} + \frac{A_2\theta^1}{(\theta^2+1)^{\frac{5}{2}}} + \frac{A_3\theta^2}{(\theta^2+1)^{\frac{5}{2}}} \right)

where $\backslash mu\_0$ is the magnetic constant, and $A\_\{1,2,3\}$ are the Anderson coefficients, which depend on the geometry of the system. These are{{cite book |last1=Baum |first1=Carl E. |title=Detection And Identification Of Visually Obscured Targets |date=1998 |publisher=CRC Press |isbn=9781560325338 |page=345 |url=https://books.google.com/books?id=hAK4YvSRIwwC&q=Detection+And+Identification+Of+Visually+Obscured+Targets |language=en}}

$$

\begin{align}

A_1 &= 3(\hat{m}\cdot\hat{r})(\hat{r}\cdot\hat{B}_E) -~~(\hat{m}\cdot\hat{B}_E) \\

A_2 &= 3(\hat{m}\cdot\hat{r})(\hat{v}\cdot\hat{B}_E) + 3(\hat{m}\cdot\hat{v})(\hat{r}\cdot\hat{B}_E) \\

A_3 &= 3(\hat{m}\cdot\hat{v})(\hat{v}\cdot\hat{B}_E) -~~(\hat{m}\cdot\hat{B}_E)

\end{align}

where $\backslash hat\{m\},\backslash hat\{r\},$ and $\backslash hat\{B\}\_E$ are unit vectors (given by $\backslash frac\{\backslash vec\{m\}\}$

\vec{m}

, \frac{\vec{r}}

\vec{r}

, and $\backslash frac\{\backslash vec\{B\}\_E\}$

\vec{B}_E

, respectively).

Note, the antisymmetric portion of the function is represented by the second function. Correspondingly, the sign of $A\_2$ depends on how $\backslash vec\{v\}$ is defined (e.g. direction is 'forward').

The total field measurement resulting from a dipole field $\backslash vec\{B\}\_D$ in the presence of a background field $\backslash vec\{B\}\_E$ (such as earth magnetic field) is

$$

\begin{align}

|B| &= \sqrt{(\vec{B}_D+\vec{B}_E)\cdot(\vec{B}_D+\vec{B}_E)} \\

&= |B_E|\sqrt{1+\frac{2\vec{B}_D\cdot\vec{B}_E}

B_E|^2}+\frac{\vec{B}_D^2}{|B_E|^2}} \\ &\approx |B_E|+\frac{\vec{B}_D\cdot\vec{B}_E}{|B_E

, &|B_E|\gg |B_D|.

\end{align}

The last line is an approximation that is accurate if the background field is much larger than contributions from the dipole. In such a case the total field reduces to the sum of the background field, and the projection of the dipole field onto the background field. This means that the total field can be accurately described as an Anderson function with an offset.

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Category:Functions and mappings