====== Block 16 - Ampère's Law and Magnetomotive Force (MMF) ======

===== Learning objectives =====
<callout>
After this 90-minute block, you can
  * ...
</callout>

===== Preparation at Home =====

Well, again 
  * read through the present chapter and write down anything you did not understand.
  * Also here, there are some clips for more clarification under 'Embedded resources' (check the text above/below, sometimes only part of the clip is interesting). 

For checking your understanding please do the following exercises:
  * ...

===== 90-minute plan =====
  - Warm-up (x min): 
    - .... 
  - Core concepts & derivations (x min):
    - ...
  - Practice (x min): ...
  - Wrap-up (x min): Summary box; common pitfalls checklist.

===== Conceptual overview =====
<callout icon="fa fa-lightbulb-o" color="blue">
  - ...
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===== Core content =====

===== Generalization of the Magnetic Field Strength =====

So far, only the rotational symmetric problem of a single wire was considered in formula. I.e a current $I$ and the length $s$ of a magnetic field line around the wire was given to calculate the magnetic field strength $H$:

\begin{align*}
 \quad  H_\varphi  ={I\over{s}} = {{I}\over{2 \cdot \pi \cdot r}}  \quad  \Leftrightarrow  \quad I = H_\varphi \cdot {s}  \quad \quad \quad | \quad \text{applies only to the long, straight conductor}
\end{align*}

Now, this shall be generalized. For this purpose, we will look back at the electric field. \\
For the electric field strength $E$ of a capacitor with two plates at a distance of $s$ and the potential difference $U$ holds:

\begin{align*}
U = E \cdot s \quad \quad | \quad \text{applies to plate capacitor only}
\end{align*}

In words: The potential difference is given by adding up the field strength along the path of a probe from one plate to the other. \\ 
This was extended to the vltage between to points $1$ and $2$. Additionally, we know by Kirchhoff's voltage law that the voltage on a closed path is "0".

\begin{align*}
U_{12} &= \int_1^2 \vec{E} \; {\rm d}\vec{s} \\

U &= \oint \vec{E} \; {\rm d}\vec{s} =0 \\

\end{align*}

We can now try to look for similarities. Also for the magnetic field, the magnitude of the field strength is summed up along a path to arrive at another field-describing quantity. \\
Because of the similarity the so-called **magnetic potential difference $V_m$** between point $1$ and $2$ is introduced:

\begin{align*}
V_m &= H \cdot s \quad \quad | \quad \text{applies to rotational symmetric problems only} \\
\end{align*}

\begin{align*}
\boxed{ V_m = V_{m, 12} = \int_1^2 \vec{H} \; {\rm d}\vec{s} \\
 V_m = \oint \vec{H} {\rm d}\vec{s} = \theta }
\end{align*}

We need to take a loser look here. Any closed path in the static electric field leads to a potential difference of $U = \oint \vec{E} \; {\rm d}\vec{s} =0$. \\
BUT: closed paths in the static magnetic field leads to a magnetic potential difference which is **not mandatorily** $0$! $ V_m = \oint \vec{H} {\rm d}\vec{s} = \theta$ \\ \\
Another new quantity is introduced: the **magnetic voltage $\theta$**:
  - The magnetic voltage $\theta$ is the magnetic potential difference on a closed path.
  - Since the magnetic voltage $\theta$ is valid for exactly __one turn__ along our single wire, $\theta$ is also equal to the current through the wire: \\ \begin{align*} \theta = H \cdot s = I  \quad \quad | \quad \text{applies only to the long, straight conductor} \end{align*} 
  - The  magnetic potential difference can take a fraction or a multiple of one turn and is therefore  **not mandatorily** equal to $I$.
  - The magnetic voltage is generalized in the following box.
<callout icon="fa fa-exclamation" color="red" title="Notice:">

The path integral of the magnetic field strength along an arbitrary closed path is equal to the free currents (= current density) through the surface enclosed by the path.

The magnetic voltage $\theta$ (and therefore the current) is the cause of the magnetic field strength. \\

This leads to the **{{wp>Ampere's Circuital Law}}**

|  \begin{align*} \boxed{\oint_{s} \vec{H} {\rm d} \vec{s} = \theta } \end{align*}| The magnetic voltage $\theta$ can be given as \\ (nbsp)(nbsp) •  $\theta = I \quad \quad \quad \ $ for a single conductor \\  (nbsp)(nbsp) • $\theta = N \cdot I \quad \:\; \, $ for a coil\\  (nbsp)(nbsp) • $\theta = \sum_n \cdot I_n \quad$ for multiple conductors\\  (nbsp)(nbsp) • $\theta = \iint_A \; \vec{S} {\rm d}\vec{A}$ for any spatial distribution (see [[block15]])|

The unit of the magnetic voltage $\theta$ is **Ampere** (or **Ampere-turns**). 

In the english literature the magnetic voltage is called **{{wp>Magnetomotive force}}**

</callout>
<callout icon="fa fa-exclamation" color="red" title="Notice:">
${\rm d}\vec{s}$ and ${\rm d}\vec{A}$ in $\oint_{s} \vec{H} {\rm d} \vec{s} = \theta = \iint_A \; \vec{S} {\rm d}\vec{A}$ build a right-hand system. \\ 
  - Once the thumb of the right hand is pointing along ${\rm d}\vec{A}$, the fingers of the right hand show the correct direction for ${\rm d}\vec{s}$ for positive $\vec{H}$ and $\vec{S}$
  - Currents into the direction of the right hand's thumb count positive. Currents antiparallel to it count negative.

<WRAP>
<imgcaption BildNr1065 | Right hand rule>
</imgcaption> \\
{{drawio>Righthandrule.svg}} 
</WRAP>

</callout>

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==== Recap of the fieldline images ====

<WRAP group><WRAP half column>
=== longitudinal coil ===
<WRAP>
<imgcaption BildNr04 | Magnetic field in a longitudinal coil></imgcaption> \\
{{url>https://www.falstad.com/vector3dm/vector3dm.html?f=SolenoidField&d=streamlines&sl=none&st=3&ld=5&a1=21&a2=30&a3=100&rx=63&ry=1&rz=2&zm=2.396 700,450 noborder}}
</WRAP>

A longitudinal coil can be seen in <imgref BildNr04>. \\ 
The magnetic field in a toroidal coil is often considered as homogenious in the inner volume, when the length $l$ is much larger than the diameter: $l \gg d$. \\
With a given number $N$ of windings, the magnetic field strength $H$ is

\begin{align*}
\theta = H \cdot l = N \cdot I
\end{align*}
\begin{align*}
\boxed{H = {{N \cdot I}\over{l}}}  \biggr | _\text{longitudinal coil}
\end{align*}

</WRAP><WRAP half column>
=== toroidal coil ===
<WRAP>
<imgcaption BildNr05 | Magnetic field in a toroidal coil></imgcaption> \\
{{url>https://www.falstad.com/vector3dm/vector3dm.html?f=ToroidalSolenoidField&d=streamlines&sl=none&st=1&ld=8&a1=77&a2=26&a3=100&rx=0&ry=0&rz=0&zm=1.8 700,450 noborder}}
</WRAP>

A toroidal coil has a donut-like setup. This can be seen in <imgref BildNr05>. \\ 
The toroidal coil is often defined by: 
  * The minor radius $r$: The radius  of the circular cross-section of the coil.
  * The major radius $R$: The distance from the center of the entire toroid (the center of the hole) to the center of the circular cross-section of the coil.
For reasons of symmetry, it shall get clear that the field lines form concentric circles. \\
Also the magnetic field strength $H$ in a toroidal coil is often considered as homogenious, when $R \gg r$. With a given number $N$ of windings, the magnetic field strength $H$ is

\begin{align*}
\theta = H \cdot 2\pi R = N \cdot I 
\end{align*}
\begin{align*}
\boxed{H = {{N \cdot I}\over{2\pi R}}} \biggr | _\text{toroidal coil}
\end{align*}

</WRAP></WRAP>


===== Common pitfalls =====
  * ...

===== Exercises =====

<panel type="info" title="Task 3.2.3 Magnetic Potential Difference"> <WRAP group><WRAP column 2%>{{fa>pencil?32}}</WRAP><WRAP column 92%>

<WRAP>
<imgcaption BildNr05 | different trajectories around current-carrying conductors>
</imgcaption>
{{drawio>Task3MagneticFieldCurrentFlowingConductor.svg}} \\
</WRAP>

Given are the adjacent closed trajectories in the magnetic field of current-carrying conductors (see <imgref BildNr05>). Let $I_1 = 2~\rm A$ and $I_2 = 4.5~\rm A$ be valid.

In each case, the magnetic potential difference $V_{\rm m}$ along the drawn path is sought.


#@HiddenBegin_HTML~323100,Path~@#

  * The magnetic potential difference is given as the **sum of the current through the area within a closed path**.
  * The direction of the current and the path have to be considered with the righthand rule.

#@HiddenEnd_HTML~323100,Path~@#

#@HiddenBegin_HTML~323102,Result a)~@#
a) $V_{\rm m,a} = - I_1 = - 2~\rm A$ \\
#@HiddenEnd_HTML~323102,Result~@#

#@HiddenBegin_HTML~323103,Result b)~@#
b) $V_{\rm m,b} = - I_2 = - 4.5~\rm A$ \\
#@HiddenEnd_HTML~323103,Result~@#

#@HiddenBegin_HTML~323104,Result c)~@#
c) $V_{\rm m,c} = 0 $ \\
#@HiddenEnd_HTML~323104,Result~@#

#@HiddenBegin_HTML~323105,Result d)~@#
d) $V_{\rm m,d} = + I_1 - I_2 = 2~\rm A - 4.5~\rm A = - 2.5~\rm A$ \\
#@HiddenEnd_HTML~323105,Result~@#

#@HiddenBegin_HTML~323106,Result e)~@#
e) $V_{\rm m,e} = + I_1 = + 2~\rm A$ \\
#@HiddenEnd_HTML~323106,Result~@#

#@HiddenBegin_HTML~323107,Result f)~@#
f) $V_{\rm m,f} = 2 \cdot (- I_1) = - 4~\rm A$ \\
#@HiddenEnd_HTML~323107,Result~@#

</WRAP></WRAP></panel>

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===== Embedded resources =====
<WRAP column half>
Explanation (video): ...
</WRAP>

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