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Reference Reference
: ([Morrison 2016](#org32cff19)) : ([Morrison 2016](#orgce03fd3))
Author(s) Author(s)
: Morrison, R. : Morrison, R.
@ -43,10 +43,6 @@ This displacement current flows when charges are added or removed from the plate
### Introduction {#introduction} ### Introduction {#introduction}
<a id="org3d4e25f"></a>
{{< figure src="/ox-hugo/morrison16_field_conf.png" caption="Figure 1: Field configurations around a shieded conductor" >}}
### Charges and Electrons {#charges-and-electrons} ### Charges and Electrons {#charges-and-electrons}
@ -133,20 +129,72 @@ In a few elements, the atomic structure is such that atoms align to generate a n
The flow of electrons is another way to generate a magnetic field. The flow of electrons is another way to generate a magnetic field.
The letter \\(H\\) is reserved for the magnetic field generated by a current. The letter \\(H\\) is reserved for the magnetic field generated by a current.
Figure [1](#orgb846bd1) shows the shape of the \\(H\\) field around a long, straight conductor carrying a direct current \\(I\\).
<a id="org2e6452b"></a> <a id="orgb846bd1"></a>
{{< figure src="/ox-hugo/morrison16_H_field.svg" caption="Figure 2: The \\(H\\) field around a current-carrying conductor" >}} {{< figure src="/ox-hugo/morrison16_H_field.svg" caption="Figure 1: The \\(H\\) field around a current-carrying conductor" >}}
The magnetic field is a force field.
This force can only be exerted on another magnetic field.
The direction of the force, the direction of the current flow and the direction of the field lines are all perpendicular to each other.
### Ampere's law {#ampere-s-law} ### Ampere's law {#ampere-s-law}
Ampere's law states that the integral of the \\(H\\) field intensity in a closed-loop path is equal to the current threading that loop
\begin{equation} \label{eq:ampere\_law}
\oint H dl = I
\end{equation}
The simplest path to use for this integration is the one of the concentric circles in Figure [1](#orgb846bd1), where \\(H\\) is constant and \\(r\\) is the distance from the conductor.
Solving for \\(H\\), we obtain
\begin{equation}
H = \frac{I}{2 \pi r}
\end{equation}
And we see that \\(H\\) has units of amperes per meter.
### The solenoid {#the-solenoid} ### The solenoid {#the-solenoid}
The magnetic field of a solenoid is shown in Figure [2](#orgf50ca35).
The field intensity inside the solenoid is nearly constant, while outside its intensity falls of rapidly.
Using Ampere's law \eqref{eq:ampere_law}:
\begin{equation}
\oint H dl \approx n I l
\end{equation}
<a id="orgf50ca35"></a>
{{< figure src="/ox-hugo/morrison16_solenoid.svg" caption="Figure 2: The \\(H\\) field around a solenoid" >}}
### Faraday's law and the induction field {#faraday-s-law-and-the-induction-field} ### Faraday's law and the induction field {#faraday-s-law-and-the-induction-field}
When a conducting coil is moved through a magnetic field, a voltage appears at the open ends of the coil.
This is illustrated in Figure [3](#org686ffe9).
The voltage depends on the number of turns in the coil and the rate at which the flux is changing.
<a id="org686ffe9"></a>
{{< figure src="/ox-hugo/morrison16_voltage_moving_coil.svg" caption="Figure 3: A voltage induced into a moving coil" >}}
The magnetic field has two measured.
The \\(H\\) or magnetic field that is proportional to current flow.
The force field representation that induces voltage is called the \\(B\\) or induction field.
The relation between \\(B\\) and \\(H\\) fields is given by:
\begin{equation} \label{eq:relation\_B\_H}
\boxed{B = \mu\_R \mu\_0 H}
\end{equation}
where the factor \\(\mu\_0\\) is the permeability of free space and \\(\mu\_R\\) is the relative permeability of the medium.
### The definition of inductance {#the-definition-of-inductance} ### The definition of inductance {#the-definition-of-inductance}
@ -624,4 +672,4 @@ Methods for limiting field penetration into and out of a screen are offered.
## Bibliography {#bibliography} ## Bibliography {#bibliography}
<a id="org32cff19"></a>Morrison, Ralph. 2016. _Grounding and Shielding: Circuits and Interference_. John Wiley & Sons. <a id="orgce03fd3"></a>Morrison, Ralph. 2016. _Grounding and Shielding: Circuits and Interference_. John Wiley & Sons.

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