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/sci/ - Science & Math

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>> No.7241538 [View]
File: 24 KB, 800x596, 800px-Maxwell'sEquations.svg.png [View same] [iqdb] [saucenao] [google]
7241538

>>7241470
mmhhkay

The first one

Step one draw 2 circles apart from each other. Connect them with lines.

Take another colour... draw a circle somewhere.
The circle can contain one or two of your previous circles.

The second one:
Here is a different kind of cirlce.
Draw an arrow, bend the arrow to a circle. Keep the Arrow head.

The third one:
Perpendicular to the Circle of the second law, you can draw other circles or lines.

The fourth one.
This is exactly like the second law + the third, but with other circles and lines, which are magically connected.


That is essentially it.

>> No.6398536 [View]
File: 24 KB, 800x596, 800px-Maxwell'sEquations.svg.png [View same] [iqdb] [saucenao] [google]
6398536

how do maxwell's equations hold under Lorentz transformations?

>> No.5839857 [View]
File: 24 KB, 800x596, MaxwellsEquations.svg_.png [View same] [iqdb] [saucenao] [google]
5839857

>>5839803

like this

>> No.5185908 [View]
File: 24 KB, 800x596, 800px-MaxwellsEquations.svg_.png [View same] [iqdb] [saucenao] [google]
5185908

What are some simple experiments that show Maxwell's equations?

I know faradays talks about a loop of wire and putting a magnet through it but what about the other laws?

And are there any good sights with simple explanations of each law?

>> No.5117513 [View]
File: 24 KB, 800x596, MaxwellsEquations.svg_.png [View same] [iqdb] [saucenao] [google]
5117513

Technically not just one law, but it's kind of hard to separate them.

>> No.3559629 [View]
File: 24 KB, 800x596, 800px-MaxwellsEquations.svg_.png [View same] [iqdb] [saucenao] [google]
3559629

Okay, this is going to look like a homework problem, but I don't actually study maths. I'm actually trying to teach myself vector calculus, and doing some problems, but I got stuck on this one particular question and was wondering if anyone could help? (:

<div class="math"> \frac{d\vec{E}}{dt} = \vec{E_{0}} + \vec{B} \times \vec{E_{0}} [\eqn]

<div class="math">\frac{d\vec{B}}{dt} = \vec{B_{0}} + \vec{E} \times \vec{B_{0}}[\eqn]

assuming that <span class="math">\vec{E_{0}}[\math] and <span class="math">\{B_{0}} are orthogonal (\vec{E_{0}} \cdot \vec{B_{0}} = 0[\math]), the problem asks me to solve for \vec{B}[\math] and \vec{E}.

I tried solving the system of 6 scalar differential equations using matrix methods, but that got a little messy and I kinda lost the will to live. am I missing anything? is there some simple observation I need to make that pretty much solves it for me?

sorry for bothering you with this, but I've been trying for days :/[/spoiler][/spoiler]</div></div>

>> No.3099027 [View]
File: 24 KB, 800x596, MaxwellsEquations.svg_.png [View same] [iqdb] [saucenao] [google]
3099027

I love this shit

>> No.3070711 [View]
File: 24 KB, 800x596, MaxwellsEquations.svg_.png [View same] [iqdb] [saucenao] [google]
3070711

>div B = 0 (?)

Any news in this field, /sci/?

>> No.2873246 [View]
File: 24 KB, 800x596, 800px-MaxwellsEquations.svg_[1].png [View same] [iqdb] [saucenao] [google]
2873246

You jelly nonmaths/physicsfags?

What does you're chosen field of study have that even comes close to this level of fundamental beauty and understanding?

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