Mean Value Theorem of Electrostatics

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pmb_phy
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In "Classical Electrodynamics - 3rd Ed.," J.D. Jackson has an exercise, 1.10, to derive the mean value theorem of electrostatics. Does anyone know of a derivation which is located on the web?

Pete
 
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Yes, this one

"The average value of the potential over the spherical surface is

[tex]\bar{\Phi} =\frac{1}{4\pi R}\int \Phi \ dA[/tex]

If u imagine the surface of the sphere as discretized, u can rewrite the integral as an infinite sum

[tex]\frac{1}{a}\int \ dA =\Sigma_{area}[/tex]

Then, takin the derivative wrt to R

[tex]\frac{d\bar{\Phi}}{dR}=\frac{d}{dR}\Sigma \Phi=\Sigma \frac{d\Phi}{dR}[/tex]

Convert the infinite sum back to an integral & get

[tex]\frac{d\bar{\Phi}}{dR}=\frac{1}{4\pi R^{2}} \int \frac{d\Phi}{dR} \ dA[/tex]

Now, using that

[tex]\frac{d\Phi}{dR}=-E[/tex] and Gauss's law (no charge inside the sphere) that gives

[tex]\frac{d\bar{Phi}}{dR}=0 \Rightarrow \bar{\Phi}_{surface}=\Phi_{center}[/tex]

Q.E.D.


Daniel.
 
dextercioby said:
"The average value of the potential over the spherical surface is
[tex]\bar{\Phi} =\frac{1}{4\pi R}\int \Phi \ dA[/tex]
No. It isn't. Its
[tex]\bar{\Phi} =\frac{1}{A}\int d\Phi[/tex]
where A is the area of the sphere.

Pete
 
This isn't quite right either.

pmb_phy said:
No. It isn't. Its
[tex]\bar{\Phi} =\frac{1}{A}\int d\Phi[/tex]
where A is the area of the sphere.
Pete

It isn't clear what you mean by [itex]\int d\Phi[/itex]
since usually the integral of an exact differential
is just the function evaluated at the endpoints.

Or alternatively
[tex]\int d\Phi = \int \frac{\partial \Phi}{\partial x} dx +<br /> \int \frac{\partial \Phi}{\partial y} dy +<br /> \int \frac{\partial \Phi}{\partial z} dz[/tex]
which is, of course, a line integral (which isn't what we
want).


dextercobi said:
[tex]\bar{\Phi} =\frac{1}{4\pi R}\int \Phi \ dA[/tex]

This doesn't have the right dimensions. On the left
we have dimensions of [Phi]; and on the right we have
dimensions of [Phi]x[Area]/[Length].

I propose another formula:
[tex] \bar{\Phi} = \frac{1}{4 \pi R^2} \int_A \Phi dA [/tex]

This also has the advantage that if Phi is constant
on the sphere we have
[tex] \bar{\Phi} = \frac{1}{4 \pi R^2} \int_A \Phi dA = <br /> \frac{1}{4 \pi R^2} \Phi \int_A dA = <br /> \frac{1}{4 \pi R^2} \Phi ( 4 \pi R^2 ) =<br /> \Phi[/tex]
 
qbert said:
This isn't quite right either.
It isn't clear what you mean by [itex]\int d\Phi[/itex]
since usually the integral of an exact differential
is just the function evaluated at the endpoints.
That would be true if you were talking about a line integral rather than in this case where the integral is a surface integral. What [itex]d\Phi[/itex] is? Hmmm. Perhaps you're right. I can't say that is a small element of [itex]\Phi[/itex] since that makes no sense to me at the moment. Thanks.

Pete
 
qbert said:
I propose another formula:
[tex] \bar{\Phi} = \frac{1}{4 \pi R^2} \int_A \Phi dA [/tex]
May I propose a more [notationally] precise formula:
[tex] \bar{\Phi} = \frac{1}{A} \int_A \Phi dA [/tex]
or a more [conceptually] precise formula for this average:
[tex] \bar{\Phi} = \frac{ \int_A \Phi dA } {\int_A dA} [/tex]
 
Ah, pedantry, thou most noble virtue. You are, of course, correct. Now the next person (who reads this thread) who needs a 2-D average will know the correct generalization.
 
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qbert said:
Ah, pedantry, thou most noble virtue. You are, of course, correct. Now the next person (who reads this thread) who needs a 2-D average will know the correct generalization.
This is a Homework subforum... and, in my experience, my students appreciate seeing the general idea in a consistent memorable notation rather than a special case. After all, there was some confusion with this formula.

Although the notation "A" [implicitly] suggests an area average, it is certainly not necessarily so.
 
robphy said:
This is a Homework subforum... and, in my experience, my students appreciate seeing the general idea in a consistent memorable notation rather than a special case. After all, there was some confusion with this formula.
Although the notation "A" [implicitly] suggests an area average, it is certainly not necessarily so.
Hi Rob

Do you know where I can find a solution? Jackson seems to want the student to use Green's theorem to solve this.

Pete
 
Hope this link helps

http://faculty.cua.edu/sober/536/meanvalue.pdf
 
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You do realize that this post is coming onto 4 years old? That the original poster hasn't asked a question for well over a year?

There is usually no reason to resurrect threads that are more than 2 months old, let alone ones that are 4 years old.