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Revision as of 09:58, 7 April 2008 editGeorge Smyth XI (talk | contribs)383 edits Showing that Ampère's circuital law is the curl of the Biot-Savart law← Previous edit Latest revision as of 21:16, 9 September 2024 edit undoRod57 (talk | contribs)Autopatrolled, Extended confirmed users, Pending changes reviewers32,790 edits External links modified: del per sourcecheck, checked=false 
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==Reset older version==
*] - text has nothing to do with the Biot-Savart law]] ] 23:18, 20 Feb 2004 (UTC)
**I've redirected it to ]. ] 23:42, 20 Feb 2004 (UTC)
**I switched them the other way, since the preferred usage is tends to be without the apostrophe. -- ] 08:57, 21 Feb 2004 (UTC)
**List on redirects for deletion as copy/paste move which needs to be fixed. ] 16:22, 21 Feb 2004 (UTC)


I reestablished the version of 12 May 2012
-- ] 21:08, 26 Feb 2004 (UTC)
because later versions where corrupted. It seems as if 151.135.188.206 was trying to edit the page, but he corrupted it.
(Lejarrag, May 20, 2012) <small><span class="autosigned">— Preceding ] comment added by ] (] • ]) 15:41, 20 May 2012 (UTC)</span></small><!-- Template:Unsigned --> <!--Autosigned by SineBot-->


:Nice, and thanks. Those IP's were fiddling around unecerssarily, and in cases blanking and obliterating. In addition I cleaned up the notation. <span style="font-family:'TW Cen MT';">] ] ]</span> 17:12, 20 May 2012 (UTC)
----
In fact, the use of the apostrophe is clearly wrong. It implies that there was a single person named 'Biot-Savart', whereas the two names in fact belong to two different people. I'm going to fix all pages that link to the bad spelling. --] 00:40, 15 Nov 2004 (UTC)


== Laplace's Law == ==edits all the way..==
I was looking for this version of Laplace's law: http://hyperphysics.phy-astr.gsu.edu/Hbase/ptens.html#lap
Can someone either fix the redirection, maybe add a disambiguation, or explain where this should correctly fit?


I have already just made some changes now. But...
== first sentence; more general form? ==


* To my despair this article is written in the corny 2nd person "To apply the equation, '''you''' choose a point in space at which '''you''' want to compute the magnetic field. Holding that point fixed, '''you''' integrate over the path of the current(s) to find the total magnetic field at that point." It will be removed.
:The Biot-Savart law describes the magnetic field set up by a steady current density.
* Right now there is no indication that the integrals are ''line integrals'' in the equations. I'll modify that now.
This is true, but as later noted in the article Biot-Savart is used extensively in aerodynamics. In fact it has been the lynchpin of all vortex models of flows around bodies for the past 70 years. Given its prominence in aerodynamics, shouldn't the first sentence of this article be changed to more generally describe application of Biot-Savart?
* Also there is a contradictory notion of the "magnetic constant", initially it says <i>μ</i><sub>0</sub> is the constant (]), but later says <math>K_m = \mu_0/4\pi</math> is the magnetic constant. I know I’m kicking up too much of a fuss for nothing, but is it actually a convention to use <i>K<sub>m</sub></i> in parallel with Coloumb's constant <math>k=1/4\pi\epsilon_0</math>? I've never seen it before... It will just be removed. If it is conventionally used then reinstate it (preferably with a referance so future pernickity editors like me will not go through this again).
Hope the edits are fine, and no one minds the fabulous colour boxes (] - if you are reading this you will be proud of you're most succesful WP creation. I have used this all over the place, including this article). =) --<span style="font-family:'Gill Sans MT'"> ](])</span> 00:30, 23 February 2012 (UTC)


* <s>BTW why arn't the integrals line integrals <math>\int</math> around a closed path <math>\oint</math> ?? If the integral is around the path of electric current: how can current flow around a path not closed?</s>
::I made an attempt to modify the intro as you suggested. Feel free to improve it, expand it, or revert and start over. -- ] 01:38, 27 December 2005 (UTC)
* And why is the constant <math>\mu_0/4\pi</math> ''inside'' many of the integrals? I pulled it out from each - there is no reason to have it inside.
* I'll also merge the 1st two sections - too much overlap.
--<span style="font-family:'Gill Sans MT'"> ](])</span> 01:11, 23 February 2012 (UTC)


== somebody damaged the sidebar thing, .... ==
Just thought someone should know, I searched on Laplace Law, and got the following link: http://en.wikipedia.org/Laplace%27s_Law however, the article i got was Biot-Savart Law... I see no obvious connection between them. //Wikipedia reader ;)


its not very nice now <span style="font-size: smaller;" class="autosigned">— Preceding ] comment added by ] (]) 23:13, 29 October 2012 (UTC)</span><!-- Template:Unsigned IP --> <!--Autosigned by SineBot-->
::Really, there are two different uses of the name "Biot-Savart law." One is the strict use in the E&M sense of finding the B field from a current, the other is the basic math of inverting a curl. Inverting the curl is all you are doing in finding B from J, and it's also all you are doing to find v given the vorticity in a fluid. You could also use it to find A (the vector potential) from B, up to gauge, or whatever. I think it makes more sense to separate out the core mathematical concept in the Biot-Savart law, somewhere on this page] 06:01, 8 September 2006 (UTC)


:It has been fixed :-) --] (]) 00:24, 30 October 2012 (UTC)
== pronunciation ==


== Change of variable convention ==
how to pronounce "Biot-Savart"?


I noticed that the variable for the point of application (<math>\mathbf r</math>), the parameter to <math>\mathbf B</math>, was written to be the same as the displacement vector from the line integral element <math>\mathbf l</math> to that parameter <math>\mathbf r</math>. So I introduced a new convention <math>\mathbf r' = \mathbf r - \mathbf l</math> similar to the original, to alter the content minimally.
-- As they are French, probably the correct is without trailing "t", but this is only a guess. The rest
I suppose is pronounced phonetically. -- ] 14:24, 4 May 2006 (UTC)


(I'd be happy to explain why it's the displacement vector and not the parameter vector that appears in the integrals and expressions, but the text already said this, it just wasn't reflected in the formulas.)
I tried doing phonetic but I can't get the unicode to print right. Bee-oh, followed by sa like sa in sand but a bit more like "ah" as in "ah I see", art like the English word art but without the t, and with the r pronounced like a French r - fricative, swallowed r on the roof of your mouth, not the front of your mouth. But that won't do for the entry, eh? I dunno how to do the French phonetic unicode.... :)] 06:24, 8 September 2006 (UTC)


However, <math>\mathbf r'</math> was already used in the proof section for the line integral element. Apart from conflicting with the new notation, this was already inconsistent with all formulas above, which used <math>\mathbf l</math>, so I changed this to use the existing convention, but maintain the explicit difference (<math>\mathbf r - \mathbf l</math>) which, I agree, is probably clearest (rather than using the displacement vector throughout).
==Factors of 2==
...are easily lost in this subject. I've 'corrected' to my understanding (Batchelor, 'Fluid Dynamics', eqn 2.6.4) - if you think I'm wrong, I'll need a reference. ] 13:20, 22 January 2007 (UTC)


If anyone has any concerns with this, please feel free to leave a reply (and to message me directly if I don't respond promptly).
== geneneral statement first? ==


--] (]) 17:08, 20 March 2015 (UTC)
Could we see a general statement of this law in terms of vector analysis first, and then its applications to electromagnetics and to aerodynamics afterwards? ] 02:12, 13 March 2007 (UTC)


:Excuse me, but authors and editors should stop acting as if the entire world has advanced math training and understands what they are saying. This article is just another example of articles that are too technical and not at all user-friendly.
== The Introduction ==
:For instance, what does the quantity "'''r'= r-1''' " even mean?. What exactly are you subtracting "'''1'''" for and from what and what does "'''1'''" represent? A specific unit? A meter? A centimeter? What does "'''r'''" exactly mean and what is its physical meaning? And how "'''r''''" fits in the equations? If anyone takes the time to answer, please consider that you are not addressing only professionals and that the answers to such questions may be self evident to you but not to everyone else, and that these things should be explained IN the article. Thanks. <!-- Template:Unsigned IP --><small class="autosigned">—&nbsp;Preceding ] comment added by ] (]) 20:13, 10 July 2017 (UTC)</small> <!--Autosigned by SineBot-->


::That's a lower-case L. Unfortunately it looks like a 1. I agree that we should avoid using lower-case L (l) for that reason.
While the application to aerodynamics is very interesting, it is not something that people expect to read in an introductory paragraph about the '''Biot-Savart law'''. A full section on the aerodynamics parallel and applications is nevertheless most welcome, but we should not overlook the fact that the law was first conceieved of in conjunction with electromagnetism and it is with electromagnetism that it is primarily associated.


::Maybe we should replace it with <math>\ell</math>? I just looked it up, and it does have a boldface: <math>\ell \text{ vs } \boldsymbol\ell</math>. Any objections to switching the article from '''l''' to <math>\boldsymbol\ell</math>?
The issue of the '''Biot-Savart Law''' being the inverse of the curl operator may be a matter of technical interest to mathematicians but it is hardly suitable material to include in the introductory paragraph. It's a bit like saying that a quantity is the product of two quotients. David Tombe 16th April 2007 (] 09:55, 16 April 2007 (UTC))


::Sorry if the article is too technical. Remember, the people reading your post are not necessarily the same people who wrote the article. We're all busy people, but we can improve it bit by bit. What you said is helpful, and if you say what else is especially confusing, we can try to fix that too! The more specific you are, the easier it will be for me or whoever tries to improve it. :-D --] (]) 21:38, 10 July 2017 (UTC)
== Coordinate Frame Origin ==


:::Whadup, changed the variable names from <math>l</math> to <math>\boldsymbol\ell \text{ and } \ell</math>. ] (]) 13:01, 10 December 2017 (UTC)
The Biot-Savart law contains the inverse square law of distance.


== An upgraded image you might wish to use ==
If we consider electromagnetic radiation deep in space, where do we fix the origin of the coordinate frame within which the inverse square term of the Biot-Savart law is measured? David Tombe 17th April 2007 (] 16:21, 17 April 2007 (UTC))


[[File:Magnetic field element (Biot-Savart Law).svg|thumb|100px|<s>Shown are the directions of
== Lorentz Transformation ==
<math>I d\boldsymbol\ell</math>, <math>\mathbf{\hat r}</math>, and the value of <math>|\mathbf{r}|</math> in the ] used to evaluate <math>\mathbf B = \int d\mathbf B</math></s>]]
This article might be too high-level for this image, but I just made it for Wikiversity formula sheet.--] (]) 00:21, 28 February 2018 (UTC)


:Nice! I'd be happy if you posted it. (But the caption should be written in English.) --] (]) 20:49, 28 February 2018 (UTC)
The Lorentz transformation acts on the full electromagnetic field tensor to produce the Biot-Savart law. See http://hepth.hanyang.ac.kr/~kst/lect/relativity/x850.htm
This tensor already contains the magnetic vector potential term '''A'''. If we remove '''A''' from the equation, we cannot obtain the Biot-Savart law. Therefore it is not true to say that the Biot-Savart law can be obtained by applying the Lorentz transformation to Coulomb's law. We need to have the full set of Maxwell's equations to begin with. (] 21:47, 9 July 2007 (UTC))


:The quantity in the denominator should be absolute value squared.] (]) 21:08, 28 February 2018 (UTC)
== ] vs ] ==


::Thanks for taking it. It's yours to edit as you please. I will get back to ].--] (]) 01:27, 1 March 2018 (UTC)
I have thought for a while that the electromagnetism template is too long. I feel it gives a better overview of the subject if all of the main topics can be seen together. I created a ] and gave an explanation on the old (i.e. current) template ], however I don't think many people are watching that page.


I brought it back. r and r-hat need to be r' and r'-hat to agree with the text.
I have modified this article to demonstrate the new template and I would appreciate people's thoughts on it: constructive criticism, arguments for or against the change, suggestions for different layouts, etc.


[[File:Magnetic field element (Biot-Savart Law) PRIME.svg|thumb|180px|Shown are the directions of
To see an example of a similar template style, check out ]. This example expands the sublist associated with the main topic article currently being viewed, then has a separate template for each main topic once you are viewing articles within that topic. My personal preference (at least for electromagnetism) would be to remain with just one template and expand the main topic sublist for all articles associated with that topic.--] 16:46, 6 November 2007 (UTC)
<math>I d\boldsymbol\ell</math>, <math>\mathbf{\hat r'}</math>, and the value of <math>|\mathbf{r'}|</math> ]]


] (]) 01:40, 1 March 2018 (UTC)
== Undefined constant ==


:I need the vector arrow symbols for . Also, it would not be easy to create bold-faced symbols on Inkscape. But I can place a variation of the image with primes on commons for this article. Would adding primes but keeping the vector symbols be OK? --] (]) 02:32, 1 March 2018 (UTC)
A constant <math>K_m</math> begins to appear half way down page without any definition nor word of explanation. <small>—Preceding ] comment added by ] (]) 18:14, 15 January 2008 (UTC)</small><!-- Template:UnsignedIP --> <!--Autosigned by SineBot-->


::Not sure what you mean about the vector symbols, but I think they are OK, if you mean what I think you mean.] (]) 02:40, 1 March 2018 (UTC)
== Showing that Ampère's circuital law is the curl of the Biot-Savart law ==


:::{{ping|Constant314}} is this better?
Take the curl of,


No prime on the l or the B. ] (]) 03:39, 1 March 2018 (UTC)
:<math>
\mathbf{B} = \mathbf{v}\times \frac{1}{c^2}\mathbf{E}
</math>


{{done}}--] (]) 04:21, 1 March 2018 (UTC)
This expands into four terms under the product rule. The two '''v''' terms vanish since '''v''' is a vector and not a vector field. The two terms left are '''v'''(div '''E''') and ('''v'''.grad)'''E'''.


I see that you went with underscores instead of arrows. Its definitely not standard. The arrows are optional, but the underscores are a problem. Can you remove them? ] (]) 04:56, 1 March 2018 (UTC)
The former is equal to ρ'''v''' which equals '''J'''. the latter is the convective term which we ignore at stationary points in space.
:When doing calculations by hand the underscores are great because they are quicker and take less space. They also let you write rank-2 tensors by using two underscores. But I will remove them.--] (]) 06:15, 1 March 2018 (UTC)
::I just discovered that there is a way to boldface the ell. It is a unicode character that Inkscape can render as an object that can have a border.---] (]) 06:43, 1 March 2018 (UTC)
:::I believe that's it. I'll look at it again tomorrow. ] (]) 07:07, 1 March 2018 (UTC)


== Formulation of Biot-Savart law for vortex segments of finite length unclear, probably wrong ==
Hence curl '''B''' = '''J'''. This is Ampère's circuital law.] (]) 06:18, 5 April 2008 (UTC)


I believe that this remark "where A and B are the (signed) angles between the line and the two ends of the segment" is not correct. A and B should be the (signed) angles between the (vortex) line segment and the connection lines from the segment ends to the point (at which the induced velocity is calculated). This is not what is now stated. I recommend to check this. <!-- Template:Unsigned --><small class="autosigned">—&nbsp;Preceding ] comment added by ] (] • ]) 07:14, 7 November 2018 (UTC)</small> <!--Autosigned by SineBot-->
:If you're suggesting that the "derivation" of Ampere from Biot-Savart be put in, it seems reasonable and topical enough. It would probably be better to use a derivation that starts from the common form of the Biot-Savart law, instead of starting from the unconventional form in terms of E. See Jackson p178-9 for this derivation, for example. We can also put in the "derivation" of Gauss's law for magnetism while we're at it, see Jackson p179. Maybe we can use show/hide boxes to not clutter up the article with vector manipulations? --] (]) 17:33, 5 April 2008 (UTC)


== Alternate Representation ==
Steve, you asked for a citation for the above expression. That is hardly necessary. It follows directly from the previous section. Anyway, here is web link which backs it up. it's at about equation (19). http://hepth.hanyang.ac.kr/~kst/lect/relativity/x850.htm ] (]) 08:02, 6 April 2008 (UTC)


The Biot-Savart law presented here is an integral. But the way I learned it, the integral was derived from a simpler expression of the law in its differential form:
:Well everything I've seen, including that link, indicate that this is the formula for the magnetic field of a point charge moving at constant velocity (changing neither direction nor speed). The section itself makes it sound more general than that, so I rewrote and resectioned accordingly. I'd still like to see a citation for any expression in that section being called "the Biot-Savart law", as opposed to "the formula for the magnetic field of a point charge moving at constant velocity" :-) --] (]) 18:04, 6 April 2008 (UTC)
<math> d\mathbf{B}(\mathbf{r}) = \frac{\mu_0}{4\pi} \frac{I \, d\boldsymbol \ell\times\mathbf{r'}}{|\mathbf{r'}|^3}</math>


(Actually, the professor didn't express it in vector form, so it was more like this:
Steve, I'm happy enough if you put in the derivation of Ampère's circuital law from the Biot-Savart law. Try it for a few days. If it appears too cluttered then you can always side link it.
<math> dB (r) = \frac{\mu_0}{4\pi} \frac{dI}{r^2}</math>
I think he did it this way so it looked more like a familiar inverse square law. So I'm guessing I got the vector form right.)


When you look at that derivation, you will notice that the inverse square law aspect of Biot-Savart plays no role in obtaining the current density term. ] (]) 09:58, 7 April 2008 (UTC) I wonder if it would make sense to present the differential form first, then show what the derived integral looks like. If not, I think it still makes sense to present the differential form somewhere. ] (]) 11:11, 23 June 2020 (UTC)

== Right hand rule - direction of field ==

Is the field direction, shown in the image of a right hand, implied by the equations ? or does the image add information ? The text does not seem to refer to the image. - ] (]) 21:15, 9 September 2024 (UTC)

Latest revision as of 21:16, 9 September 2024

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Reset older version

I reestablished the version of 12 May 2012 because later versions where corrupted. It seems as if 151.135.188.206 was trying to edit the page, but he corrupted it. (Lejarrag, May 20, 2012) — Preceding unsigned comment added by Lejarrag (talkcontribs) 15:41, 20 May 2012 (UTC)

Nice, and thanks. Those IP's were fiddling around unecerssarily, and in cases blanking and obliterating. In addition I cleaned up the notation. F = q(E+v×B) ⇄ ∑ici 17:12, 20 May 2012 (UTC)

edits all the way..

I have already just made some changes now. But...

  • To my despair this article is written in the corny 2nd person "To apply the equation, you choose a point in space at which you want to compute the magnetic field. Holding that point fixed, you integrate over the path of the current(s) to find the total magnetic field at that point." It will be removed.
  • Right now there is no indication that the integrals are line integrals in the equations. I'll modify that now.
  • Also there is a contradictory notion of the "magnetic constant", initially it says μ0 is the constant (permeability of free space), but later says K m = μ 0 / 4 π {\displaystyle K_{m}=\mu _{0}/4\pi } is the magnetic constant. I know I’m kicking up too much of a fuss for nothing, but is it actually a convention to use Km in parallel with Coloumb's constant k = 1 / 4 π ϵ 0 {\displaystyle k=1/4\pi \epsilon _{0}} ? I've never seen it before... It will just be removed. If it is conventionally used then reinstate it (preferably with a referance so future pernickity editors like me will not go through this again).

Hope the edits are fine, and no one minds the fabulous colour boxes (Maschen - if you are reading this you will be proud of you're most succesful WP creation. I have used this all over the place, including this article). =) -- F = q(E + v × B) 00:30, 23 February 2012 (UTC)

  • BTW why arn't the integrals line integrals {\displaystyle \int } around a closed path {\displaystyle \oint }  ?? If the integral is around the path of electric current: how can current flow around a path not closed?
  • And why is the constant μ 0 / 4 π {\displaystyle \mu _{0}/4\pi } inside many of the integrals? I pulled it out from each - there is no reason to have it inside.
  • I'll also merge the 1st two sections - too much overlap.

-- F = q(E + v × B) 01:11, 23 February 2012 (UTC)

somebody damaged the sidebar thing, ....

its not very nice now — Preceding unsigned comment added by 83.134.175.203 (talk) 23:13, 29 October 2012 (UTC)

It has been fixed :-) --Steve (talk) 00:24, 30 October 2012 (UTC)

Change of variable convention

I noticed that the variable for the point of application ( r {\displaystyle \mathbf {r} } ), the parameter to B {\displaystyle \mathbf {B} } , was written to be the same as the displacement vector from the line integral element l {\displaystyle \mathbf {l} } to that parameter r {\displaystyle \mathbf {r} } . So I introduced a new convention r = r l {\displaystyle \mathbf {r} '=\mathbf {r} -\mathbf {l} } similar to the original, to alter the content minimally.

(I'd be happy to explain why it's the displacement vector and not the parameter vector that appears in the integrals and expressions, but the text already said this, it just wasn't reflected in the formulas.)

However, r {\displaystyle \mathbf {r} '} was already used in the proof section for the line integral element. Apart from conflicting with the new notation, this was already inconsistent with all formulas above, which used l {\displaystyle \mathbf {l} } , so I changed this to use the existing convention, but maintain the explicit difference ( r l {\displaystyle \mathbf {r} -\mathbf {l} } ) which, I agree, is probably clearest (rather than using the displacement vector throughout).

If anyone has any concerns with this, please feel free to leave a reply (and to message me directly if I don't respond promptly).

--RProgrammer (talk) 17:08, 20 March 2015 (UTC)

Excuse me, but authors and editors should stop acting as if the entire world has advanced math training and understands what they are saying. This article is just another example of articles that are too technical and not at all user-friendly.
For instance, what does the quantity "r'= r-1 " even mean?. What exactly are you subtracting "1" for and from what and what does "1" represent? A specific unit? A meter? A centimeter? What does "r" exactly mean and what is its physical meaning? And how "r'" fits in the equations? If anyone takes the time to answer, please consider that you are not addressing only professionals and that the answers to such questions may be self evident to you but not to everyone else, and that these things should be explained IN the article. Thanks. — Preceding unsigned comment added by 2A02:587:4507:1B00:BC0F:9D45:251:B361 (talk) 20:13, 10 July 2017 (UTC)
That's a lower-case L. Unfortunately it looks like a 1. I agree that we should avoid using lower-case L (l) for that reason.
Maybe we should replace it with {\displaystyle \ell } ? I just looked it up, and it does have a boldface:  vs  {\displaystyle \ell {\text{ vs }}{\boldsymbol {\ell }}} . Any objections to switching the article from l to {\displaystyle {\boldsymbol {\ell }}} ?
Sorry if the article is too technical. Remember, the people reading your post are not necessarily the same people who wrote the article. We're all busy people, but we can improve it bit by bit. What you said is helpful, and if you say what else is especially confusing, we can try to fix that too! The more specific you are, the easier it will be for me or whoever tries to improve it. :-D --Steve (talk) 21:38, 10 July 2017 (UTC)
Whadup, changed the variable names from l {\displaystyle l} to  and  {\displaystyle {\boldsymbol {\ell }}{\text{ and }}\ell } . Sebastian tilman (talk) 13:01, 10 December 2017 (UTC)

An upgraded image you might wish to use

Shown are the directions of I d {\displaystyle Id{\boldsymbol {\ell }}} , r ^ {\displaystyle \mathbf {\hat {r}} } , and the value of | r | {\displaystyle |\mathbf {r} |} in the integrand used to evaluate B = d B {\displaystyle \mathbf {B} =\int d\mathbf {B} }

This article might be too high-level for this image, but I just made it for Wikiversity formula sheet.--Guy vandegrift (talk) 00:21, 28 February 2018 (UTC)

Nice! I'd be happy if you posted it. (But the caption should be written in English.) --Steve (talk) 20:49, 28 February 2018 (UTC)
The quantity in the denominator should be absolute value squared.Constant314 (talk) 21:08, 28 February 2018 (UTC)
Thanks for taking it. It's yours to edit as you please. I will get back to wikiversity:OpenStax equations/University physics/V2.--Guy vandegrift (talk) 01:27, 1 March 2018 (UTC)

I brought it back. r and r-hat need to be r' and r'-hat to agree with the text.

Shown are the directions of I d {\displaystyle Id{\boldsymbol {\ell }}} , r ^ {\displaystyle \mathbf {{\hat {r}}'} } , and the value of | r | {\displaystyle |\mathbf {r'} |}

Constant314 (talk) 01:40, 1 March 2018 (UTC)

I need the vector arrow symbols for OpenStax. Also, it would not be easy to create bold-faced symbols on Inkscape. But I can place a variation of the image with primes on commons for this article. Would adding primes but keeping the vector symbols be OK? --Guy vandegrift (talk) 02:32, 1 March 2018 (UTC)
Not sure what you mean about the vector symbols, but I think they are OK, if you mean what I think you mean.Constant314 (talk) 02:40, 1 March 2018 (UTC)
@Constant314: is this better?

No prime on the l or the B. Constant314 (talk) 03:39, 1 March 2018 (UTC)

 Done--Guy vandegrift (talk) 04:21, 1 March 2018 (UTC)

I see that you went with underscores instead of arrows. Its definitely not standard. The arrows are optional, but the underscores are a problem. Can you remove them? Constant314 (talk) 04:56, 1 March 2018 (UTC)

When doing calculations by hand the underscores are great because they are quicker and take less space. They also let you write rank-2 tensors by using two underscores. But I will remove them.--Guy vandegrift (talk) 06:15, 1 March 2018 (UTC)
I just discovered that there is a way to boldface the ell. It is a unicode character that Inkscape can render as an object that can have a border.---Guy vandegrift (talk) 06:43, 1 March 2018 (UTC)
I believe that's it. I'll look at it again tomorrow. Constant314 (talk) 07:07, 1 March 2018 (UTC)

Formulation of Biot-Savart law for vortex segments of finite length unclear, probably wrong

I believe that this remark "where A and B are the (signed) angles between the line and the two ends of the segment" is not correct. A and B should be the (signed) angles between the (vortex) line segment and the connection lines from the segment ends to the point (at which the induced velocity is calculated). This is not what is now stated. I recommend to check this. — Preceding unsigned comment added by Rschmehl (talkcontribs) 07:14, 7 November 2018 (UTC)

Alternate Representation

The Biot-Savart law presented here is an integral. But the way I learned it, the integral was derived from a simpler expression of the law in its differential form: d B ( r ) = μ 0 4 π I d × r | r | 3 {\displaystyle d\mathbf {B} (\mathbf {r} )={\frac {\mu _{0}}{4\pi }}{\frac {I\,d{\boldsymbol {\ell }}\times \mathbf {r'} }{|\mathbf {r'} |^{3}}}}

(Actually, the professor didn't express it in vector form, so it was more like this: d B ( r ) = μ 0 4 π d I r 2 {\displaystyle dB(r)={\frac {\mu _{0}}{4\pi }}{\frac {dI}{r^{2}}}} I think he did it this way so it looked more like a familiar inverse square law. So I'm guessing I got the vector form right.)

I wonder if it would make sense to present the differential form first, then show what the derived integral looks like. If not, I think it still makes sense to present the differential form somewhere. –MiguelMunoz (talk) 11:11, 23 June 2020 (UTC)

Right hand rule - direction of field

Is the field direction, shown in the image of a right hand, implied by the equations ? or does the image add information ? The text does not seem to refer to the image. - Rod57 (talk) 21:15, 9 September 2024 (UTC)

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