From: John Larkin on
On Thu, 5 Aug 2010 18:41:04 +0100, "markp" <map.nospam(a)f2s.com> wrote:

>
>"Charlie E." <edmondson(a)ieee.org> wrote in message
>news:6isl56tn6kicj23a8ej6g7hjaqk6tt3k9s(a)4ax.com...
>> On Thu, 5 Aug 2010 02:40:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>
>>>
>>>With all due respect, we don't, and shouldn't, say a capacitor 'stores
>>>charge'. The misconception comes from the use of the word charge when
>>>talking about putting energy into a capacitor, and more explictly the
>>>significant lack of clarification given on this when being taught. This is
>>>compounded by a confusion of the q=C*V equation which actually relates to
>>>the charge on the plates, but one of the plates is of the same value but
>>>opposite in polarity, so the sum of those is zero. This is an extremely
>>>popular misunderstanding unfortunately, and leads to conclusions that
>>>electrical charge is not conserved. In fact, in a closed system where no
>>>electrical charge can get in or out, within that system electrical charge
>>>*is* conserved, it's actually a fundamental law of physics (along with
>>>conservation of energy and momentum, again for closed systems).
>>>
>>>The same current flows in and out of a capacitor when it is being
>>>'charged'
>>>(I assume you are not going to deny that). Note I said the same current,
>>>but
>>>they are not made of the same electrons because those can't cross the
>>>plate
>>>barrier. The same amount of electrical charge that goes in comes right out
>>>again. How can the capacitor possibly end up with a net charge in it? If
>>>it
>>>can, where has the electrical charge come from? Have electrons just been
>>>conjured up out of nowhere?
>>>
>>>Mark.
>>>
>>
>> Well, theoretically, if the cap was say at ground potential on both
>> plates before being added to the circuit, but the circuit is designed
>> to run at some value above ground potential when running, it COULD get
>> a few extra electrons added, giving a net increase of charge... ;-)
>>
>> Charlie
>
>For there to be a net increase in charge one plate would have more
>electrical charge than the other (either positive or nagative). This would
>require more current going in than coming out (or vice versa). That doesn't
>happen in electrical circuits. I'm ignoring static electricity which is a
>different subject.
>

Why? are there two different kinds of electricity?

John

From: Jim Thompson on
On Thu, 05 Aug 2010 19:22:52 -0700, John Larkin
<jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote:

>On Thu, 5 Aug 2010 18:41:04 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>
>>
>>"Charlie E." <edmondson(a)ieee.org> wrote in message
>>news:6isl56tn6kicj23a8ej6g7hjaqk6tt3k9s(a)4ax.com...
>>> On Thu, 5 Aug 2010 02:40:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>
>>>>
>>>>With all due respect, we don't, and shouldn't, say a capacitor 'stores
>>>>charge'. The misconception comes from the use of the word charge when
>>>>talking about putting energy into a capacitor, and more explictly the
>>>>significant lack of clarification given on this when being taught. This is
>>>>compounded by a confusion of the q=C*V equation which actually relates to
>>>>the charge on the plates, but one of the plates is of the same value but
>>>>opposite in polarity, so the sum of those is zero. This is an extremely
>>>>popular misunderstanding unfortunately, and leads to conclusions that
>>>>electrical charge is not conserved. In fact, in a closed system where no
>>>>electrical charge can get in or out, within that system electrical charge
>>>>*is* conserved, it's actually a fundamental law of physics (along with
>>>>conservation of energy and momentum, again for closed systems).
>>>>
>>>>The same current flows in and out of a capacitor when it is being
>>>>'charged'
>>>>(I assume you are not going to deny that). Note I said the same current,
>>>>but
>>>>they are not made of the same electrons because those can't cross the
>>>>plate
>>>>barrier. The same amount of electrical charge that goes in comes right out
>>>>again. How can the capacitor possibly end up with a net charge in it? If
>>>>it
>>>>can, where has the electrical charge come from? Have electrons just been
>>>>conjured up out of nowhere?
>>>>
>>>>Mark.
>>>>
>>>
>>> Well, theoretically, if the cap was say at ground potential on both
>>> plates before being added to the circuit, but the circuit is designed
>>> to run at some value above ground potential when running, it COULD get
>>> a few extra electrons added, giving a net increase of charge... ;-)
>>>
>>> Charlie
>>
>>For there to be a net increase in charge one plate would have more
>>electrical charge than the other (either positive or nagative). This would
>>require more current going in than coming out (or vice versa). That doesn't
>>happen in electrical circuits. I'm ignoring static electricity which is a
>>different subject.
>>
>
>Why? are there two different kinds of electricity?
>
>John

Yep. That with charge conservation and that without :-)

...Jim Thompson
--
| James E.Thompson, CTO | mens |
| Analog Innovations, Inc. | et |
| Analog/Mixed-Signal ASIC's and Discrete Systems | manus |
| Phoenix, Arizona 85048 Skype: Contacts Only | |
| Voice:(480)460-2350 Fax: Available upon request | Brass Rat |
| E-mail Icon at http://www.analog-innovations.com | 1962 |

SED Has Crumbled to Below SEB Status
Populated Only by Bloviators and Pompous PhD's
From: markp on

"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in message
news:u4sm56lncllfueedvo2ahi4ihr8j00gu3p(a)4ax.com...
> On Thu, 5 Aug 2010 18:43:28 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>
>>
>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>message
>>news:7tjl5615o4lklftqq34fncd86soc75forh(a)4ax.com...
>>> On Thu, 5 Aug 2010 13:20:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>
>>>>
>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>message
>>>>news:889k5654o0h9qfgs3cej7gfe99ahsg42am(a)4ax.com...
>>>>> On Thu, 5 Aug 2010 02:40:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>>>
>>>>>>
>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>>message
>>>>>>news:ci3k56d0kga1776gghosaq09q2e0i2ahhq(a)4ax.com...
>>>>>>> On Wed, 4 Aug 2010 16:55:16 +0100, "markp" <map.nospam(a)f2s.com>
>>>>>>> wrote:
>>>>>>>
>>>>>>>>
>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>>>>message
>>>>>>>>news:2vge46h4sragrk4jdn6sasde6hg2r52nos(a)4ax.com...
>>>>>>>>> On Wed, 21 Jul 2010 12:17:41 -0500, "George Jefferson"
>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote
>>>>>>>>>>in
>>>>>>>>>>message
>>>>>>>>>>news:dj7e465sga7fe3nq7hfl3f0uk601pvrem8(a)4ax.com...
>>>>>>>>>>> On Wed, 21 Jul 2010 11:19:31 -0500, "George Jefferson"
>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote
>>>>>>>>>>>>in
>>>>>>>>>>>>message
>>>>>>>>>>>>news:s43e46la1p1vt11527eg3ptl9ulm44dfrj(a)4ax.com...
>>>>>>>>>>>>> On Wed, 21 Jul 2010 07:54:03 -0500, "George Jefferson"
>>>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>>>
>>>>>>>>>>>>>>Suppose you have two capacitors connected as
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>--*--
>>>>>>>>>>>>>>| |
>>>>>>>>>>>>>>C1 C2
>>>>>>>>>>>>>>| |
>>>>>>>>>>>>>>-----
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>where * is a switch.
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>What is the total energy before and after the switch is
>>>>>>>>>>>>>>closed(in
>>>>>>>>>>>>>>general).
>>>>>>>>>>>>>
>>>>>>>>>>>>> Energy is conserved, so it's the same, if you account for all
>>>>>>>>>>>>> the
>>>>>>>>>>>>> manifestations of energy.
>>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>You didn't answer the question. I assume this because you don't
>>>>>>>>>>>>know.
>>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>> State the question unambiguously and I will.
>>>>>>>>>>>
>>>>>>>>>>> As I said, the puzzle is both ancient and trivial, so probably
>>>>>>>>>>> JT
>>>>>>>>>>> invented it. There are web sites and even academic papers
>>>>>>>>>>> devoted
>>>>>>>>>>> to
>>>>>>>>>>> it. Given all that, how could I not understand it?
>>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>Um you don't get it. Your ignorance in basic electronics amazes
>>>>>>>>>>me.
>>>>>>>>>
>>>>>>>>> That's funny. But people can choose to be amazed in all sorts of
>>>>>>>>> ways.
>>>>>>>>>
>>>>>>>>>
>>>>>>>>> Michael
>>>>>>>>>>got it(although he didn't explain where the energy went but I
>>>>>>>>>>think
>>>>>>>>>>gets
>>>>>>>>>>it).
>>>>>>>>>>
>>>>>>>>>>Assume the second cap is initially "uncharged" and has the same
>>>>>>>>>>capacitance
>>>>>>>>>>as the first.
>>>>>>>>>>
>>>>>>>>>>Then the initial energy is
>>>>>>>>>>
>>>>>>>>>>Wi = 1/2*C*V^2
>>>>>>>>>>Wf = 2*1/2*C*(V/2)^2 = 1/4*C*V^2 = 1/2*Wi
>>>>>>>>>>
>>>>>>>>>>Hence the final energy of the system 1/2 what we started with.
>>>>>>>>>
>>>>>>>>> Miraculous calculation. Yours and about 300 web sites that admire
>>>>>>>>> this
>>>>>>>>> puzzle.
>>>>>>>>>
>>>>>>>>> You didn't wxplain where the energy went - see those 300 web
>>>>>>>>> sites -
>>>>>>>>> but you are assuming losses. Another solution is that no energy is
>>>>>>>>> lost, and it rings forever, in which case the final state that you
>>>>>>>>> cite never happens. The exact waveforms are actually interesting.
>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>I'd really like to hear your explanation but I know thats
>>>>>>>>>>impossible(as
>>>>>>>>>>you'll steal someone elses). After all your the one that believes
>>>>>>>>>>charge
>>>>>>>>>>isn't conserved... heres your change to *prove* it.
>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>
>>>>>>>>> Check my previous posts. I noted the exact waveform across a
>>>>>>>>> resistive
>>>>>>>>> switch, for any values of C1 and C2, and an independent way to
>>>>>>>>> compute
>>>>>>>>> the energy lost in that switch.
>>>>>>>>>
>>>>>>>>> Given an inductor, one can move all the energy from one charged
>>>>>>>>> cap
>>>>>>>>> to
>>>>>>>>> another, uncharged one. If the C values are unequal, the C*V
>>>>>>>>> (charge)
>>>>>>>>> on the first cap obviously becomes a different C*V on the second
>>>>>>>>> one.
>>>>>>>>> I noted that here some weeks ago, too.
>>>>>>>>>
>>>>>>>>> This is all EE101 stuff.
>>>>>>>>>
>>>>>>>>> John
>>>>>>>>
>>>>>>>>Yes, Q=CV equation is somewhat misleading in this context. A
>>>>>>>>capacitor
>>>>>>>>doesn't store electrical charge, it stores energy. This is a very
>>>>>>>>common
>>>>>>>>misconception, when we say 'charge a capacitor' we don't mean put
>>>>>>>>electrical
>>>>>>>>charge into it, we mean put energy into it. The plates are equal and
>>>>>>>>opposite in electrical charge due to an abundance of electrons on
>>>>>>>>one
>>>>>>>>plate
>>>>>>>>and an equal and opposite charge on the other. The total stored
>>>>>>>>electrical
>>>>>>>>charge in a capacitor is zero, and the Q=CV equation relates to how
>>>>>>>>much
>>>>>>>>charge flowed *in and out* of the capacitor (in fact since electrons
>>>>>>>>can't
>>>>>>>>cross the barrier between the plates, it actually describes the
>>>>>>>>*modulus*
>>>>>>>>of
>>>>>>>>the abundance of charge on each plate, one abundance is positive and
>>>>>>>>the
>>>>>>>>other is negative).
>>>>>>>>
>>>>>>>>Mark.
>>>>>>>>
>>>>>>>
>>>>>>> That's not what they taught us in college, and that's not the way we
>>>>>>> do engineering. We say that a capacitor stores charge, the amount
>>>>>>> being C*V in coulombs, and it works. My whole point, which has
>>>>>>> evoked
>>>>>>> such ranting, is that when you use this convention, be careful about
>>>>>>> designing using the concept that (this kind of) charge is always
>>>>>>> conserved.
>>>>>>>
>>>>>>> John
>>>>>>>
>>>>>>
>>>>>>With all due respect, we don't, and shouldn't, say a capacitor 'stores
>>>>>>charge'.
>>>>>
>>>>> What do you mean by "we"? Electronic design engineers do this all the
>>>>> time, with reference to capacitors and batteries. You pump X coulombs
>>>>> into a cap; it becomes stored, coincidentally as C*V. You can extract
>>>>> those coulombs later, and the accounting is correct. The math works.
>>>>> The gear works.
>>>>>
>>>>> The misconception comes from the use of the word charge when
>>>>>>talking about putting energy into a capacitor, and more explictly the
>>>>>>significant lack of clarification given on this when being taught.
>>>>>>This
>>>>>>is
>>>>>>compounded by a confusion of the q=C*V equation which actually relates
>>>>>>to
>>>>>>the charge on the plates, but one of the plates is of the same value
>>>>>>but
>>>>>>opposite in polarity, so the sum of those is zero. This is an
>>>>>>extremely
>>>>>>popular misunderstanding unfortunately, and leads to conclusions that
>>>>>>electrical charge is not conserved. In fact, in a closed system where
>>>>>>no
>>>>>>electrical charge can get in or out, within that system electrical
>>>>>>charge
>>>>>>*is* conserved, it's actually a fundamental law of physics (along with
>>>>>>conservation of energy and momentum, again for closed systems).
>>>>>>
>>>>>>The same current flows in and out of a capacitor when it is being
>>>>>>'charged'
>>>>>>(I assume you are not going to deny that). Note I said the same
>>>>>>current,
>>>>>>but
>>>>>>they are not made of the same electrons because those can't cross the
>>>>>>plate
>>>>>>barrier. The same amount of electrical charge that goes in comes right
>>>>>>out
>>>>>>again. How can the capacitor possibly end up with a net charge in it?
>>>>>>If
>>>>>>it
>>>>>>can, where has the electrical charge come from? Have electrons just
>>>>>>been
>>>>>>conjured up out of nowhere?
>>>>>
>>>>> It's a different convention. Words. But the units work and the numbers
>>>>> work, so we use it. Call our kind of charge "charge separation" or
>>>>> "plate charge differential" if it makes you happier.
>>>>>
>>>>> Do you design electronics? Do mosfet data sheets refer to stored gate
>>>>> energy, or stored gate charge?
>>>>>
>>>>> John
>>>>
>>>>Yes, I'm actually an electronics design consultant.
>>>>Take a look at this:
>>>>www.irf.com/technical-info/appnotes/mosfet.pdf
>>>>
>>>>Note the equivalent circuits, which show capacitance between the gate,
>>>>source and drain. They talk about 'gate charge' as being a conveient way
>>>>of
>>>>relating the capacitance charging and discharging (energy, not
>>>>electrical
>>>>charge) with current, and hence time. Again, confusion can arrise
>>>>because
>>>>they use the word 'charge' in two contexts.
>>>
>>> They use "charge", in many places, the same way most electronics
>>> engineers use the word, namely C*V.
>>>
>>>>
>>>>The fact is that since current flows in and out of these capacitors in
>>>>equal
>>>>amounts the net stored electrical charge on each one is zero. However
>>>>the
>>>>Q=CV equation relates to the magnitude of charge that each of the plates
>>>>of
>>>>these capacitances carries, but for each capacitor there is another
>>>>plate
>>>>with equal and opposite charge.
>>>
>>> Exactly. We say a cap is "charged" if C*V <> 0. In fact, C*V is the
>>> exact charge. We say that a cap integrates charge into voltage, and
>>> that it can return that same charge as we drain it down to zero volts.
>>> So it's handy to think that a cap can store that charge for us, which
>>> it actually does.
>>>
>>>>
>>>>Here is a good derivation of the elecrostatic forces between the plates
>>>>of
>>>>a
>>>>parallel plate capacitor. Note that the electrical charge on each plate
>>>>has
>>>>the same magnitude Q, but one is positive and the other negative. If you
>>>>think this is not correct maybe you should contact the University of
>>>>Pennsylvania and tell them :)
>>>>http://dept.physics.upenn.edu/~uglabs/lab_manual/electric_forces.pdf
>>>
>>> The plates need not gave the same absolute Q, because the overall cap
>>> can have a net charge, what we electronic guys would call an
>>> electrostatic charge. That ususlly doesn't matter to us, so we use the
>>> conviently short word "charge" to mean C*V, where V is the sort of
>>> potential difference we measure with a 2-terminal voltmeter. When we
>>> rarely refer to physics-type net charge, we say "electrostatic
>>> charge."
>>>
>>> To express the concept of "charge on a capacitor" any way other than
>>> the way we use it would be grammatically and numerically very messy.
>>>
>>> But when we use the term this way, we have to be careful to remember
>>> what it means to us, and we can't blindly say stuff like "charge is
>>> conserved" without thinking carefully. It's safe to say "energy is
>>> conserved."
>>>
>>> John
>>
>>I'm giving up. Your concept of charge is obviously not Coulombs!
>
> Q=C*V is coulombs. The units work. If a cap stores 5 coulombs, I can
> load it at 2.5 amps for 2 seconds, and then the charge is gone. It
> works.
>
> John

Actually the capacitor stores + 5 Coulombs on one plate, and -5 Coulombs on
the other plate. When you 'load it at 2.5 Amps for 2.5 seconds' the
negatively charged electrons move from the negatively charged plate, through
the external circuit, and into the positively charged plate. At the end
there are zero Coulombs stored on both plates. This is why the maths works,
at no point does the capacitor as a whole ever have net stored charge, the
sum of the charges of both plates is always zero. In your system of stored
charge you cannot explain why, if the same current is flowing in and out of
the capacitor, it doesn't violate the Law of Conservation of Charge.

Mark.


From: John Larkin on
On Fri, 6 Aug 2010 15:05:38 +0100, "markp" <map.nospam(a)f2s.com> wrote:

>
>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in message
>news:u4sm56lncllfueedvo2ahi4ihr8j00gu3p(a)4ax.com...
>> On Thu, 5 Aug 2010 18:43:28 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>
>>>
>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>message
>>>news:7tjl5615o4lklftqq34fncd86soc75forh(a)4ax.com...
>>>> On Thu, 5 Aug 2010 13:20:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>>
>>>>>
>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>message
>>>>>news:889k5654o0h9qfgs3cej7gfe99ahsg42am(a)4ax.com...
>>>>>> On Thu, 5 Aug 2010 02:40:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>>>>
>>>>>>>
>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>>>message
>>>>>>>news:ci3k56d0kga1776gghosaq09q2e0i2ahhq(a)4ax.com...
>>>>>>>> On Wed, 4 Aug 2010 16:55:16 +0100, "markp" <map.nospam(a)f2s.com>
>>>>>>>> wrote:
>>>>>>>>
>>>>>>>>>
>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>>>>>message
>>>>>>>>>news:2vge46h4sragrk4jdn6sasde6hg2r52nos(a)4ax.com...
>>>>>>>>>> On Wed, 21 Jul 2010 12:17:41 -0500, "George Jefferson"
>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote
>>>>>>>>>>>in
>>>>>>>>>>>message
>>>>>>>>>>>news:dj7e465sga7fe3nq7hfl3f0uk601pvrem8(a)4ax.com...
>>>>>>>>>>>> On Wed, 21 Jul 2010 11:19:31 -0500, "George Jefferson"
>>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>>
>>>>>>>>>>>>>
>>>>>>>>>>>>>
>>>>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote
>>>>>>>>>>>>>in
>>>>>>>>>>>>>message
>>>>>>>>>>>>>news:s43e46la1p1vt11527eg3ptl9ulm44dfrj(a)4ax.com...
>>>>>>>>>>>>>> On Wed, 21 Jul 2010 07:54:03 -0500, "George Jefferson"
>>>>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>Suppose you have two capacitors connected as
>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>--*--
>>>>>>>>>>>>>>>| |
>>>>>>>>>>>>>>>C1 C2
>>>>>>>>>>>>>>>| |
>>>>>>>>>>>>>>>-----
>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>where * is a switch.
>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>What is the total energy before and after the switch is
>>>>>>>>>>>>>>>closed(in
>>>>>>>>>>>>>>>general).
>>>>>>>>>>>>>>
>>>>>>>>>>>>>> Energy is conserved, so it's the same, if you account for all
>>>>>>>>>>>>>> the
>>>>>>>>>>>>>> manifestations of energy.
>>>>>>>>>>>>>>
>>>>>>>>>>>>>
>>>>>>>>>>>>>You didn't answer the question. I assume this because you don't
>>>>>>>>>>>>>know.
>>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>> State the question unambiguously and I will.
>>>>>>>>>>>>
>>>>>>>>>>>> As I said, the puzzle is both ancient and trivial, so probably
>>>>>>>>>>>> JT
>>>>>>>>>>>> invented it. There are web sites and even academic papers
>>>>>>>>>>>> devoted
>>>>>>>>>>>> to
>>>>>>>>>>>> it. Given all that, how could I not understand it?
>>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>>Um you don't get it. Your ignorance in basic electronics amazes
>>>>>>>>>>>me.
>>>>>>>>>>
>>>>>>>>>> That's funny. But people can choose to be amazed in all sorts of
>>>>>>>>>> ways.
>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>> Michael
>>>>>>>>>>>got it(although he didn't explain where the energy went but I
>>>>>>>>>>>think
>>>>>>>>>>>gets
>>>>>>>>>>>it).
>>>>>>>>>>>
>>>>>>>>>>>Assume the second cap is initially "uncharged" and has the same
>>>>>>>>>>>capacitance
>>>>>>>>>>>as the first.
>>>>>>>>>>>
>>>>>>>>>>>Then the initial energy is
>>>>>>>>>>>
>>>>>>>>>>>Wi = 1/2*C*V^2
>>>>>>>>>>>Wf = 2*1/2*C*(V/2)^2 = 1/4*C*V^2 = 1/2*Wi
>>>>>>>>>>>
>>>>>>>>>>>Hence the final energy of the system 1/2 what we started with.
>>>>>>>>>>
>>>>>>>>>> Miraculous calculation. Yours and about 300 web sites that admire
>>>>>>>>>> this
>>>>>>>>>> puzzle.
>>>>>>>>>>
>>>>>>>>>> You didn't wxplain where the energy went - see those 300 web
>>>>>>>>>> sites -
>>>>>>>>>> but you are assuming losses. Another solution is that no energy is
>>>>>>>>>> lost, and it rings forever, in which case the final state that you
>>>>>>>>>> cite never happens. The exact waveforms are actually interesting.
>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>>I'd really like to hear your explanation but I know thats
>>>>>>>>>>>impossible(as
>>>>>>>>>>>you'll steal someone elses). After all your the one that believes
>>>>>>>>>>>charge
>>>>>>>>>>>isn't conserved... heres your change to *prove* it.
>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>> Check my previous posts. I noted the exact waveform across a
>>>>>>>>>> resistive
>>>>>>>>>> switch, for any values of C1 and C2, and an independent way to
>>>>>>>>>> compute
>>>>>>>>>> the energy lost in that switch.
>>>>>>>>>>
>>>>>>>>>> Given an inductor, one can move all the energy from one charged
>>>>>>>>>> cap
>>>>>>>>>> to
>>>>>>>>>> another, uncharged one. If the C values are unequal, the C*V
>>>>>>>>>> (charge)
>>>>>>>>>> on the first cap obviously becomes a different C*V on the second
>>>>>>>>>> one.
>>>>>>>>>> I noted that here some weeks ago, too.
>>>>>>>>>>
>>>>>>>>>> This is all EE101 stuff.
>>>>>>>>>>
>>>>>>>>>> John
>>>>>>>>>
>>>>>>>>>Yes, Q=CV equation is somewhat misleading in this context. A
>>>>>>>>>capacitor
>>>>>>>>>doesn't store electrical charge, it stores energy. This is a very
>>>>>>>>>common
>>>>>>>>>misconception, when we say 'charge a capacitor' we don't mean put
>>>>>>>>>electrical
>>>>>>>>>charge into it, we mean put energy into it. The plates are equal and
>>>>>>>>>opposite in electrical charge due to an abundance of electrons on
>>>>>>>>>one
>>>>>>>>>plate
>>>>>>>>>and an equal and opposite charge on the other. The total stored
>>>>>>>>>electrical
>>>>>>>>>charge in a capacitor is zero, and the Q=CV equation relates to how
>>>>>>>>>much
>>>>>>>>>charge flowed *in and out* of the capacitor (in fact since electrons
>>>>>>>>>can't
>>>>>>>>>cross the barrier between the plates, it actually describes the
>>>>>>>>>*modulus*
>>>>>>>>>of
>>>>>>>>>the abundance of charge on each plate, one abundance is positive and
>>>>>>>>>the
>>>>>>>>>other is negative).
>>>>>>>>>
>>>>>>>>>Mark.
>>>>>>>>>
>>>>>>>>
>>>>>>>> That's not what they taught us in college, and that's not the way we
>>>>>>>> do engineering. We say that a capacitor stores charge, the amount
>>>>>>>> being C*V in coulombs, and it works. My whole point, which has
>>>>>>>> evoked
>>>>>>>> such ranting, is that when you use this convention, be careful about
>>>>>>>> designing using the concept that (this kind of) charge is always
>>>>>>>> conserved.
>>>>>>>>
>>>>>>>> John
>>>>>>>>
>>>>>>>
>>>>>>>With all due respect, we don't, and shouldn't, say a capacitor 'stores
>>>>>>>charge'.
>>>>>>
>>>>>> What do you mean by "we"? Electronic design engineers do this all the
>>>>>> time, with reference to capacitors and batteries. You pump X coulombs
>>>>>> into a cap; it becomes stored, coincidentally as C*V. You can extract
>>>>>> those coulombs later, and the accounting is correct. The math works.
>>>>>> The gear works.
>>>>>>
>>>>>> The misconception comes from the use of the word charge when
>>>>>>>talking about putting energy into a capacitor, and more explictly the
>>>>>>>significant lack of clarification given on this when being taught.
>>>>>>>This
>>>>>>>is
>>>>>>>compounded by a confusion of the q=C*V equation which actually relates
>>>>>>>to
>>>>>>>the charge on the plates, but one of the plates is of the same value
>>>>>>>but
>>>>>>>opposite in polarity, so the sum of those is zero. This is an
>>>>>>>extremely
>>>>>>>popular misunderstanding unfortunately, and leads to conclusions that
>>>>>>>electrical charge is not conserved. In fact, in a closed system where
>>>>>>>no
>>>>>>>electrical charge can get in or out, within that system electrical
>>>>>>>charge
>>>>>>>*is* conserved, it's actually a fundamental law of physics (along with
>>>>>>>conservation of energy and momentum, again for closed systems).
>>>>>>>
>>>>>>>The same current flows in and out of a capacitor when it is being
>>>>>>>'charged'
>>>>>>>(I assume you are not going to deny that). Note I said the same
>>>>>>>current,
>>>>>>>but
>>>>>>>they are not made of the same electrons because those can't cross the
>>>>>>>plate
>>>>>>>barrier. The same amount of electrical charge that goes in comes right
>>>>>>>out
>>>>>>>again. How can the capacitor possibly end up with a net charge in it?
>>>>>>>If
>>>>>>>it
>>>>>>>can, where has the electrical charge come from? Have electrons just
>>>>>>>been
>>>>>>>conjured up out of nowhere?
>>>>>>
>>>>>> It's a different convention. Words. But the units work and the numbers
>>>>>> work, so we use it. Call our kind of charge "charge separation" or
>>>>>> "plate charge differential" if it makes you happier.
>>>>>>
>>>>>> Do you design electronics? Do mosfet data sheets refer to stored gate
>>>>>> energy, or stored gate charge?
>>>>>>
>>>>>> John
>>>>>
>>>>>Yes, I'm actually an electronics design consultant.
>>>>>Take a look at this:
>>>>>www.irf.com/technical-info/appnotes/mosfet.pdf
>>>>>
>>>>>Note the equivalent circuits, which show capacitance between the gate,
>>>>>source and drain. They talk about 'gate charge' as being a conveient way
>>>>>of
>>>>>relating the capacitance charging and discharging (energy, not
>>>>>electrical
>>>>>charge) with current, and hence time. Again, confusion can arrise
>>>>>because
>>>>>they use the word 'charge' in two contexts.
>>>>
>>>> They use "charge", in many places, the same way most electronics
>>>> engineers use the word, namely C*V.
>>>>
>>>>>
>>>>>The fact is that since current flows in and out of these capacitors in
>>>>>equal
>>>>>amounts the net stored electrical charge on each one is zero. However
>>>>>the
>>>>>Q=CV equation relates to the magnitude of charge that each of the plates
>>>>>of
>>>>>these capacitances carries, but for each capacitor there is another
>>>>>plate
>>>>>with equal and opposite charge.
>>>>
>>>> Exactly. We say a cap is "charged" if C*V <> 0. In fact, C*V is the
>>>> exact charge. We say that a cap integrates charge into voltage, and
>>>> that it can return that same charge as we drain it down to zero volts.
>>>> So it's handy to think that a cap can store that charge for us, which
>>>> it actually does.
>>>>
>>>>>
>>>>>Here is a good derivation of the elecrostatic forces between the plates
>>>>>of
>>>>>a
>>>>>parallel plate capacitor. Note that the electrical charge on each plate
>>>>>has
>>>>>the same magnitude Q, but one is positive and the other negative. If you
>>>>>think this is not correct maybe you should contact the University of
>>>>>Pennsylvania and tell them :)
>>>>>http://dept.physics.upenn.edu/~uglabs/lab_manual/electric_forces.pdf
>>>>
>>>> The plates need not gave the same absolute Q, because the overall cap
>>>> can have a net charge, what we electronic guys would call an
>>>> electrostatic charge. That ususlly doesn't matter to us, so we use the
>>>> conviently short word "charge" to mean C*V, where V is the sort of
>>>> potential difference we measure with a 2-terminal voltmeter. When we
>>>> rarely refer to physics-type net charge, we say "electrostatic
>>>> charge."
>>>>
>>>> To express the concept of "charge on a capacitor" any way other than
>>>> the way we use it would be grammatically and numerically very messy.
>>>>
>>>> But when we use the term this way, we have to be careful to remember
>>>> what it means to us, and we can't blindly say stuff like "charge is
>>>> conserved" without thinking carefully. It's safe to say "energy is
>>>> conserved."
>>>>
>>>> John
>>>
>>>I'm giving up. Your concept of charge is obviously not Coulombs!
>>
>> Q=C*V is coulombs. The units work. If a cap stores 5 coulombs, I can
>> load it at 2.5 amps for 2 seconds, and then the charge is gone. It
>> works.
>>
>> John
>
>Actually the capacitor stores + 5 Coulombs on one plate, and -5 Coulombs on
>the other plate. When you 'load it at 2.5 Amps for 2.5 seconds' the
>negatively charged electrons move from the negatively charged plate, through
>the external circuit, and into the positively charged plate. At the end
>there are zero Coulombs stored on both plates. This is why the maths works,
>at no point does the capacitor as a whole ever have net stored charge, the
>sum of the charges of both plates is always zero. In your system of stored
>charge you cannot explain why, if the same current is flowing in and out of
>the capacitor, it doesn't violate the Law of Conservation of Charge.
>
>

Because circuit designers use "charge" in a somewhat different way
than physicists. Call it "charge separation" of "differential charge"
if you want to. We call it "charge" and measure it as CV = time
integral of I. If you actually design electronics, you probably do
too. I doubt you design timers or integrators entirely in terms of
stored joules.

John

From: markp on

"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in message
news:258o56l0k2k1id6bm27oevicacm6ifd5ft(a)4ax.com...
> On Fri, 6 Aug 2010 15:05:38 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>
>>
>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>message
>>news:u4sm56lncllfueedvo2ahi4ihr8j00gu3p(a)4ax.com...
>>> On Thu, 5 Aug 2010 18:43:28 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>
>>>>
>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>message
>>>>news:7tjl5615o4lklftqq34fncd86soc75forh(a)4ax.com...
>>>>> On Thu, 5 Aug 2010 13:20:12 +0100, "markp" <map.nospam(a)f2s.com> wrote:
>>>>>
>>>>>>
>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>>message
>>>>>>news:889k5654o0h9qfgs3cej7gfe99ahsg42am(a)4ax.com...
>>>>>>> On Thu, 5 Aug 2010 02:40:12 +0100, "markp" <map.nospam(a)f2s.com>
>>>>>>> wrote:
>>>>>>>
>>>>>>>>
>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote in
>>>>>>>>message
>>>>>>>>news:ci3k56d0kga1776gghosaq09q2e0i2ahhq(a)4ax.com...
>>>>>>>>> On Wed, 4 Aug 2010 16:55:16 +0100, "markp" <map.nospam(a)f2s.com>
>>>>>>>>> wrote:
>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote
>>>>>>>>>>in
>>>>>>>>>>message
>>>>>>>>>>news:2vge46h4sragrk4jdn6sasde6hg2r52nos(a)4ax.com...
>>>>>>>>>>> On Wed, 21 Jul 2010 12:17:41 -0500, "George Jefferson"
>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com> wrote
>>>>>>>>>>>>in
>>>>>>>>>>>>message
>>>>>>>>>>>>news:dj7e465sga7fe3nq7hfl3f0uk601pvrem8(a)4ax.com...
>>>>>>>>>>>>> On Wed, 21 Jul 2010 11:19:31 -0500, "George Jefferson"
>>>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>>>
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>"John Larkin" <jjlarkin(a)highNOTlandTHIStechnologyPART.com>
>>>>>>>>>>>>>>wrote
>>>>>>>>>>>>>>in
>>>>>>>>>>>>>>message
>>>>>>>>>>>>>>news:s43e46la1p1vt11527eg3ptl9ulm44dfrj(a)4ax.com...
>>>>>>>>>>>>>>> On Wed, 21 Jul 2010 07:54:03 -0500, "George Jefferson"
>>>>>>>>>>>>>>> <phreon111(a)gmail.com> wrote:
>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>Suppose you have two capacitors connected as
>>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>--*--
>>>>>>>>>>>>>>>>| |
>>>>>>>>>>>>>>>>C1 C2
>>>>>>>>>>>>>>>>| |
>>>>>>>>>>>>>>>>-----
>>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>where * is a switch.
>>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>>>What is the total energy before and after the switch is
>>>>>>>>>>>>>>>>closed(in
>>>>>>>>>>>>>>>>general).
>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>> Energy is conserved, so it's the same, if you account for
>>>>>>>>>>>>>>> all
>>>>>>>>>>>>>>> the
>>>>>>>>>>>>>>> manifestations of energy.
>>>>>>>>>>>>>>>
>>>>>>>>>>>>>>
>>>>>>>>>>>>>>You didn't answer the question. I assume this because you
>>>>>>>>>>>>>>don't
>>>>>>>>>>>>>>know.
>>>>>>>>>>>>>>
>>>>>>>>>>>>>
>>>>>>>>>>>>> State the question unambiguously and I will.
>>>>>>>>>>>>>
>>>>>>>>>>>>> As I said, the puzzle is both ancient and trivial, so probably
>>>>>>>>>>>>> JT
>>>>>>>>>>>>> invented it. There are web sites and even academic papers
>>>>>>>>>>>>> devoted
>>>>>>>>>>>>> to
>>>>>>>>>>>>> it. Given all that, how could I not understand it?
>>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>Um you don't get it. Your ignorance in basic electronics amazes
>>>>>>>>>>>>me.
>>>>>>>>>>>
>>>>>>>>>>> That's funny. But people can choose to be amazed in all sorts of
>>>>>>>>>>> ways.
>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>> Michael
>>>>>>>>>>>>got it(although he didn't explain where the energy went but I
>>>>>>>>>>>>think
>>>>>>>>>>>>gets
>>>>>>>>>>>>it).
>>>>>>>>>>>>
>>>>>>>>>>>>Assume the second cap is initially "uncharged" and has the same
>>>>>>>>>>>>capacitance
>>>>>>>>>>>>as the first.
>>>>>>>>>>>>
>>>>>>>>>>>>Then the initial energy is
>>>>>>>>>>>>
>>>>>>>>>>>>Wi = 1/2*C*V^2
>>>>>>>>>>>>Wf = 2*1/2*C*(V/2)^2 = 1/4*C*V^2 = 1/2*Wi
>>>>>>>>>>>>
>>>>>>>>>>>>Hence the final energy of the system 1/2 what we started with.
>>>>>>>>>>>
>>>>>>>>>>> Miraculous calculation. Yours and about 300 web sites that
>>>>>>>>>>> admire
>>>>>>>>>>> this
>>>>>>>>>>> puzzle.
>>>>>>>>>>>
>>>>>>>>>>> You didn't wxplain where the energy went - see those 300 web
>>>>>>>>>>> sites -
>>>>>>>>>>> but you are assuming losses. Another solution is that no energy
>>>>>>>>>>> is
>>>>>>>>>>> lost, and it rings forever, in which case the final state that
>>>>>>>>>>> you
>>>>>>>>>>> cite never happens. The exact waveforms are actually
>>>>>>>>>>> interesting.
>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>I'd really like to hear your explanation but I know thats
>>>>>>>>>>>>impossible(as
>>>>>>>>>>>>you'll steal someone elses). After all your the one that
>>>>>>>>>>>>believes
>>>>>>>>>>>>charge
>>>>>>>>>>>>isn't conserved... heres your change to *prove* it.
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>> Check my previous posts. I noted the exact waveform across a
>>>>>>>>>>> resistive
>>>>>>>>>>> switch, for any values of C1 and C2, and an independent way to
>>>>>>>>>>> compute
>>>>>>>>>>> the energy lost in that switch.
>>>>>>>>>>>
>>>>>>>>>>> Given an inductor, one can move all the energy from one charged
>>>>>>>>>>> cap
>>>>>>>>>>> to
>>>>>>>>>>> another, uncharged one. If the C values are unequal, the C*V
>>>>>>>>>>> (charge)
>>>>>>>>>>> on the first cap obviously becomes a different C*V on the second
>>>>>>>>>>> one.
>>>>>>>>>>> I noted that here some weeks ago, too.
>>>>>>>>>>>
>>>>>>>>>>> This is all EE101 stuff.
>>>>>>>>>>>
>>>>>>>>>>> John
>>>>>>>>>>
>>>>>>>>>>Yes, Q=CV equation is somewhat misleading in this context. A
>>>>>>>>>>capacitor
>>>>>>>>>>doesn't store electrical charge, it stores energy. This is a very
>>>>>>>>>>common
>>>>>>>>>>misconception, when we say 'charge a capacitor' we don't mean put
>>>>>>>>>>electrical
>>>>>>>>>>charge into it, we mean put energy into it. The plates are equal
>>>>>>>>>>and
>>>>>>>>>>opposite in electrical charge due to an abundance of electrons on
>>>>>>>>>>one
>>>>>>>>>>plate
>>>>>>>>>>and an equal and opposite charge on the other. The total stored
>>>>>>>>>>electrical
>>>>>>>>>>charge in a capacitor is zero, and the Q=CV equation relates to
>>>>>>>>>>how
>>>>>>>>>>much
>>>>>>>>>>charge flowed *in and out* of the capacitor (in fact since
>>>>>>>>>>electrons
>>>>>>>>>>can't
>>>>>>>>>>cross the barrier between the plates, it actually describes the
>>>>>>>>>>*modulus*
>>>>>>>>>>of
>>>>>>>>>>the abundance of charge on each plate, one abundance is positive
>>>>>>>>>>and
>>>>>>>>>>the
>>>>>>>>>>other is negative).
>>>>>>>>>>
>>>>>>>>>>Mark.
>>>>>>>>>>
>>>>>>>>>
>>>>>>>>> That's not what they taught us in college, and that's not the way
>>>>>>>>> we
>>>>>>>>> do engineering. We say that a capacitor stores charge, the amount
>>>>>>>>> being C*V in coulombs, and it works. My whole point, which has
>>>>>>>>> evoked
>>>>>>>>> such ranting, is that when you use this convention, be careful
>>>>>>>>> about
>>>>>>>>> designing using the concept that (this kind of) charge is always
>>>>>>>>> conserved.
>>>>>>>>>
>>>>>>>>> John
>>>>>>>>>
>>>>>>>>
>>>>>>>>With all due respect, we don't, and shouldn't, say a capacitor
>>>>>>>>'stores
>>>>>>>>charge'.
>>>>>>>
>>>>>>> What do you mean by "we"? Electronic design engineers do this all
>>>>>>> the
>>>>>>> time, with reference to capacitors and batteries. You pump X
>>>>>>> coulombs
>>>>>>> into a cap; it becomes stored, coincidentally as C*V. You can
>>>>>>> extract
>>>>>>> those coulombs later, and the accounting is correct. The math works.
>>>>>>> The gear works.
>>>>>>>
>>>>>>> The misconception comes from the use of the word charge when
>>>>>>>>talking about putting energy into a capacitor, and more explictly
>>>>>>>>the
>>>>>>>>significant lack of clarification given on this when being taught.
>>>>>>>>This
>>>>>>>>is
>>>>>>>>compounded by a confusion of the q=C*V equation which actually
>>>>>>>>relates
>>>>>>>>to
>>>>>>>>the charge on the plates, but one of the plates is of the same value
>>>>>>>>but
>>>>>>>>opposite in polarity, so the sum of those is zero. This is an
>>>>>>>>extremely
>>>>>>>>popular misunderstanding unfortunately, and leads to conclusions
>>>>>>>>that
>>>>>>>>electrical charge is not conserved. In fact, in a closed system
>>>>>>>>where
>>>>>>>>no
>>>>>>>>electrical charge can get in or out, within that system electrical
>>>>>>>>charge
>>>>>>>>*is* conserved, it's actually a fundamental law of physics (along
>>>>>>>>with
>>>>>>>>conservation of energy and momentum, again for closed systems).
>>>>>>>>
>>>>>>>>The same current flows in and out of a capacitor when it is being
>>>>>>>>'charged'
>>>>>>>>(I assume you are not going to deny that). Note I said the same
>>>>>>>>current,
>>>>>>>>but
>>>>>>>>they are not made of the same electrons because those can't cross
>>>>>>>>the
>>>>>>>>plate
>>>>>>>>barrier. The same amount of electrical charge that goes in comes
>>>>>>>>right
>>>>>>>>out
>>>>>>>>again. How can the capacitor possibly end up with a net charge in
>>>>>>>>it?
>>>>>>>>If
>>>>>>>>it
>>>>>>>>can, where has the electrical charge come from? Have electrons just
>>>>>>>>been
>>>>>>>>conjured up out of nowhere?
>>>>>>>
>>>>>>> It's a different convention. Words. But the units work and the
>>>>>>> numbers
>>>>>>> work, so we use it. Call our kind of charge "charge separation" or
>>>>>>> "plate charge differential" if it makes you happier.
>>>>>>>
>>>>>>> Do you design electronics? Do mosfet data sheets refer to stored
>>>>>>> gate
>>>>>>> energy, or stored gate charge?
>>>>>>>
>>>>>>> John
>>>>>>
>>>>>>Yes, I'm actually an electronics design consultant.
>>>>>>Take a look at this:
>>>>>>www.irf.com/technical-info/appnotes/mosfet.pdf
>>>>>>
>>>>>>Note the equivalent circuits, which show capacitance between the gate,
>>>>>>source and drain. They talk about 'gate charge' as being a conveient
>>>>>>way
>>>>>>of
>>>>>>relating the capacitance charging and discharging (energy, not
>>>>>>electrical
>>>>>>charge) with current, and hence time. Again, confusion can arrise
>>>>>>because
>>>>>>they use the word 'charge' in two contexts.
>>>>>
>>>>> They use "charge", in many places, the same way most electronics
>>>>> engineers use the word, namely C*V.
>>>>>
>>>>>>
>>>>>>The fact is that since current flows in and out of these capacitors in
>>>>>>equal
>>>>>>amounts the net stored electrical charge on each one is zero. However
>>>>>>the
>>>>>>Q=CV equation relates to the magnitude of charge that each of the
>>>>>>plates
>>>>>>of
>>>>>>these capacitances carries, but for each capacitor there is another
>>>>>>plate
>>>>>>with equal and opposite charge.
>>>>>
>>>>> Exactly. We say a cap is "charged" if C*V <> 0. In fact, C*V is the
>>>>> exact charge. We say that a cap integrates charge into voltage, and
>>>>> that it can return that same charge as we drain it down to zero volts.
>>>>> So it's handy to think that a cap can store that charge for us, which
>>>>> it actually does.
>>>>>
>>>>>>
>>>>>>Here is a good derivation of the elecrostatic forces between the
>>>>>>plates
>>>>>>of
>>>>>>a
>>>>>>parallel plate capacitor. Note that the electrical charge on each
>>>>>>plate
>>>>>>has
>>>>>>the same magnitude Q, but one is positive and the other negative. If
>>>>>>you
>>>>>>think this is not correct maybe you should contact the University of
>>>>>>Pennsylvania and tell them :)
>>>>>>http://dept.physics.upenn.edu/~uglabs/lab_manual/electric_forces.pdf
>>>>>
>>>>> The plates need not gave the same absolute Q, because the overall cap
>>>>> can have a net charge, what we electronic guys would call an
>>>>> electrostatic charge. That ususlly doesn't matter to us, so we use the
>>>>> conviently short word "charge" to mean C*V, where V is the sort of
>>>>> potential difference we measure with a 2-terminal voltmeter. When we
>>>>> rarely refer to physics-type net charge, we say "electrostatic
>>>>> charge."
>>>>>
>>>>> To express the concept of "charge on a capacitor" any way other than
>>>>> the way we use it would be grammatically and numerically very messy.
>>>>>
>>>>> But when we use the term this way, we have to be careful to remember
>>>>> what it means to us, and we can't blindly say stuff like "charge is
>>>>> conserved" without thinking carefully. It's safe to say "energy is
>>>>> conserved."
>>>>>
>>>>> John
>>>>
>>>>I'm giving up. Your concept of charge is obviously not Coulombs!
>>>
>>> Q=C*V is coulombs. The units work. If a cap stores 5 coulombs, I can
>>> load it at 2.5 amps for 2 seconds, and then the charge is gone. It
>>> works.
>>>
>>> John
>>
>>Actually the capacitor stores + 5 Coulombs on one plate, and -5 Coulombs
>>on
>>the other plate. When you 'load it at 2.5 Amps for 2.5 seconds' the
>>negatively charged electrons move from the negatively charged plate,
>>through
>>the external circuit, and into the positively charged plate. At the end
>>there are zero Coulombs stored on both plates. This is why the maths
>>works,
>>at no point does the capacitor as a whole ever have net stored charge, the
>>sum of the charges of both plates is always zero. In your system of stored
>>charge you cannot explain why, if the same current is flowing in and out
>>of
>>the capacitor, it doesn't violate the Law of Conservation of Charge.
>>
>>
>
> Because circuit designers use "charge" in a somewhat different way
> than physicists. Call it "charge separation" of "differential charge"
> if you want to. We call it "charge" and measure it as CV = time
> integral of I. If you actually design electronics, you probably do
> too. I doubt you design timers or integrators entirely in terms of
> stored joules.
>
> John
>

As I said, I don't have to design timers or integrators by thinking in terms
of stored energy, I can use the Q=CV equation and it works, because it
relates the charges moving in and out of a capacitor to the voltage, and to
the current in and out of a capacitor at any point in time. I can design
anything you can using the same Q=CV equation, but I don't need to have any
special cases or violate any conservation law.

Coulombs of charge are Coulombs of charge. You have invoked a special case
of 'electrical charge' that doesn't seem to be conserved, and yet you still
relate it to the current (which consists of electrons or the lack of them)
by integration, and voltage. Are you saying that the engineer's view of what
makes a current is different to an physicist's view? Is the 'charge'
flowing per second for an engineer somehow a different, non-conserved charge
flow to the physicist's charge flow? If not, then explain why, if the same
current is flowing in and out of the capacitor, it doesn't violate the Law
of Conservation of Charge.

Engineers and circuit designers are simply people who apply the laws of
physics to create real world applications, they are bound by the same laws
of physics - no exceptions.

Mark.