Need help understanding voltage

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In summary: The key point is that voltage is relative between two points. When you measure voltage, you are measuring the difference in energy concentration between those two points. So if you have a resistor, there will be a difference in energy concentration (voltage) between the two ends of it, but the total amount of energy per charge does not decrease. It's like a water slide - the water at the top has more potential energy (higher voltage) than the water at the bottom, but the total amount of water (charge) is the same. The resistor just decreases the voltage difference, not the total amount of energy per charge. Does that make more sense?In summary, voltage is a measure of the energy concentration per unit
  • #36
remedemic said:
Thanks for the help gentlemen, I can understand voltage alone now, however, I'm having a bit of trouble relating it to resistance at this point.

From what I am reading, a resistor decreases the amount of energy per charge (by converting it into heat or motion through friction), which seems that by definition, voltage would decrease after a resistor, but according to V=IR, and I being constant, voltage goes up?

Could someone clear this confusion up? Thanks again.

I re-read this and it seems you are confusing cause and effect. You need to split the problem into independent and dependent variables. If we're talking about PD (independent), then this is what we start with. Inserting different resistors (independent) across your supply will result in different values of Current (the dependent variable). When you say that increasing the resistance will increase the Voltage, that will only apply if we keep I constant (a different experiment - constant current supply, not constant PD). The way you state it would imply that the height of a (constant head) dam would increase as you take less power from the generators, in the analogous situation.
It is true that, for two resistors in series, the volts across one resistor will increase as its value increases - but only because the current through the circuit decreases and the added resistor gets a bigger share of the supply volts. 'The Potential Divider' is explained all over the place. I don't think anyone who comes across the potential divider will instantly get a feel for it. It becomes very clear, once you have done the simple sums associated with it though.
 
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  • #37
sophiecentaur said:
...they must settle down and learn their basics - by rote at first, if you like. You emerge the other side a lot wiser, more capable and less likely to make up and talk nonsense.


why i keep harping on preciseness in terminology:
"We think only through the medium of words. --Languages are true analytical methods. --Algebra, which is adapted to its purpose in every species of expression, in the most simple, most exact, and best manner possible, is at the same time a language and an analytical method. --The art of reasoning is nothing more than a language well arranged." -----Lavoisier

that's why he should spend time getting his units defined unambiguously in his mind.

My view on matters electrical is that you can't expect to 'understand' them. The best you can do is to follow the rules and, in the end, get so familiar with them that they are as much second nature as Newton's laws of motion.
The "why" becomes apparent as they become 'second nature' because one tosses them about in thought experiments, resolving apparent contradictions in his mind.
At least that's how i learned everything from algebra to ethics.
"What" before "Why".
That's why "New Math" was such a failure, it tried to reverse that sequence. I went through junior high school just a year before that stuff thank goodness.

On electrical units - i usually lead into a joke with that line... "I pity Mechanicals - their stuff is non-linear, "g" is not an integer, and they have to put up with entropy."

old jim
 
  • #38
jim hardy said:
The "why" becomes apparent as they become 'second nature' because one tosses them about in thought experiments, resolving apparent contradictions in his mind.
At least that's how i learned everything from algebra to ethics.
"What" before "Why".
I pretty much agree but I have to add that feeling that one has understood the 'why' thing is an illusion. When we feel we know 'why', it is because we have related enough of the new thing to our past experiences to accept it and have gone 'deep enough' to satisfy our conscious mind (your "second nature"). Every individual has their own level of a sufficient answer to the 'why' questions.
It disappoints me that so many of the questions on PF seem to assume that there exists some fundamental level of truth about the world and that they have a cat's chance in hell of getting there.
Very early on, I came to terms with my own limitations and I accept that even the sum of human understanding is never going to be complete knowledge. This is absolutely no problem at all, for me. Is that just the underlying uncertainty of the 60's hanging about in the back of my mind, perhaps? Probably the best legacy from that time, for me. (That and Mr Worthington's Maths classes).
 
  • #39
sophiecentaur,

What has that to do with the induced Electric Field?

Nothing, that is my point.

Not all electric fields are "Electrostatic".

Yes, they are. If you are talking about a field caused by putting a voltage across a dielectric (capacitor), that is known as a "electric field" or electrostatic field. If you are talking about a field caused by running a current throught a loop of wire, that is a magnetic field or "electromagnetic field". A magnetic field does not need electricity to exist, as in a permanent magnet. So when you talked about "electromagnetic induction" and "induced emf" in post #29, I assumed you meant an electromagnetic field.

You have been asked the question by someone else now - with no answer. You response to the question was just to sidestep the issue instead of answering the implied question.

Who, where?

But you could clear this up with just a smidgin of Maths (if it's as simple as you say.). You are still avoiding it and just hand waving. You could, for example, start with Maxwell's Equations, (believed and respected by both of us, I hope), which would take you most of the way there. Just slip in your modification in a valid way, where appropriate and we'd be cooking on gas. Even I would believe you, then.

Start with Maxwell's equations? Along with the vector analysis concepts of divergence, gradient, and curl plus integral and differential calculus? Plus the difficulty of writing math in an ASCII format. Can't you instead imagine integrating Coulombs equation of force between two charges with respect to the distance to get the energy to takes to put two charges close together. That has been done a multitude of time in textbooks.

Perhaps you should ask your question again carefully and specifically so we can start over.

Ratch
 
  • #40
Very early on, I came to terms with my own limitations and I accept that even the sum of human understanding is never going to be complete knowledge. This is absolutely no problem at all, for me. Is that just the underlying uncertainty of the 60's hanging about in the back of my mind, perhaps? Probably the best legacy from that time, for me.

education teaches us how litle we know. perhaps wisdom is the acceptance, not just awareness, of one's abysmal ignorance.
i exist at a level appropriate to maintenance of machinery. That was my vocation. It's been a good and interesting life.
 
  • #41
@ratch
An "Electrostatic" field is, as the name suggests, "Static".
Maxwell considers non-static Electric fields (sloppy use of terms, I'm afraid). Where are the charges in space?

If it is important for you to be believed and understood then you need to present us with more that assurances that we could prove your ideas for ourselves. Plenty of people on PF present equations when they are relevant. I think you really need to 'put of or shut up' on this one. I don't have to "imagine" anything that you're not prepared to present explicitly. A string of buzzwords proves nothing. Where's the meat? (as LBJ once said, I believe).
The question has been asked 'explicitly' - it is just "How do you justify what you are saying and support it with evidence?" or "Give a definition of the Volt that involves the dimension of length?" How much more explicit can that be? You could even quote the particular passage in a textbook that has your definition explicity printed as a definition and not associated stuff which the definition leads to. I presume a scan and a pdf attachment is possible?
 
  • #42
sophiecentaur,

An "Electrostatic" field is, as the name suggests, "Static".
Maxwell considers non-static Electric fields (sloppy use of terms, I'm afraid).

Yes, I agree with the above.

Where are the charges in space?

Anywhere charge carriers like electrons or protons exist in free space.

If it is important for you to be believed and understood then you need to present us with more that assurances that we could prove your ideas for ourselves. Plenty of people on PF present equations when they are relevant.

It is not important to me whether people believe me or not. I presented a view along with the reasoning to support that view. Everyone can evaluate it for themselves. In the case of my view, equations are not relevant. If I were solving a textbook problem, then I probably would present some equations.

I think you really need to 'put of or shut up' on this one.

I believe that I have "put up" as you say.

I don't have to "imagine" anything that you're not prepared to present explicitly

I have presented my view and reasoning explicitly. You don't have to even read my view.

A string of buzzwords proves nothing. Where's the meat? (as LBJ once said, I believe).

Words like "charge", "energy", "density" are not buzzwords. They are used all the time in scientific discussion. LJB was a politician, not a person of science.

The question has been asked 'explicitly'

The question was vague and sloppy.

it is just "How do you justify what you are saying and support it with evidence?"

That was not the question you asked. You asked something about electric or magnetic fields. However, to answer your last question as I did before. Since voltage is measured in units of energy/charge, that represents an energy density with respect to charge. That is as simple as I can make it, and it is basically the same answer I gave before. So now it is up to you to pick it apart by reason and logic, not by meaningless unsubstatiated declaration.

"Give a definition of the Volt that involves the dimension of length?" How much more explicit can that be? You could even quote the particular passage in a textbook that has your definition explicity printed as a definition and not associated stuff which the definition leads to. I presume a scan and a pdf attachment is possible?

I never said that a definition of voltage involves length. I challenge you to find where I said that.

Ratch
 
  • #43
We're back to my original problem. You introduced the term "density" and you have not justified it as fitting into the definition of the Volt. When I say 'justified' I mean with a reference or some Maths (which is what PF would normally require, I think, for something as revolutionary as that.
I should not need to explain why "density" involves the dimension of length.

You are being deliberately obtuse here, I can tell. You have done it before in threads where you didn't want to climb down. (Don't ask for a reference, they are dead an buried)

I never said that a definition of voltage involves length. I challenge you to find where I said that

All in the thread:

Sure, voltage is the electrical energy density of an amount of charge

So voltage is a measure of the energy concentration per unit of charge (joules/coulomb)

So if there is energy and charge together in a volume, that defines voltage.

Yes, a higher charge carrier or electron density will define a higher voltage

Do you know what the word "define" means in the context of Science?
 
  • #44
sophiecentaur,

...I should not need to explain why "density" involves the dimension of length...

Now I think we are getting somewhere. You seem to think that density only has meaning for spatial dimensions. That certainly the most common meaning, and the one everyone thinks of unless stated otherwise. Now, what if I said I was mixing 1 kg of salt with 100 kg of sugar. Would not that dry mixture have a particular density with respect to the weight of the salt? Could it not also be described as having a particular concentration with respect to the weight of the salt. Sure, there is volume involved, but that is not what defines density in this case. What if I mixed 1 kg of salt with 100 kg of flour? It would still have the same density and concentration with respect to the weight of the salt, but the volume would be greater. Therefore, volume is not part of the density definition in this case. If you know some other quantative word to call that mixture (percentage?), let me know and I will use that instead.

You can guess what comes next. We extrapolate using energy and charge. No need to go further in that direction, is there?

Do you know what the word "define" means in the context of Science?

Not just science, but elsewhere also.

Ratch
 
  • #45
OH boy, we're re-defining the meaning of density now.
It's not a poetry circle. It's a Physics Forum.
 
  • #46
Thread closed for a bit until I can sort things out...
 
  • #47
Unfortunately, Ratch has been banned for multiple misinformation violations. This thread has run its course, and will remain closed. Sorry that I didn't see the problems earlier in the thread -- please be sure to use the Report button when there are problematic posts in a thread, so the Mentors can head off the problems early. Thanks.
 
<h2>1. What is voltage?</h2><p>Voltage is a measure of the potential energy difference between two points in an electrical circuit. It is often referred to as "electrical pressure" and is measured in volts (V).</p><h2>2. How is voltage different from current?</h2><p>Voltage and current are two different characteristics of electricity. While voltage measures the potential energy difference, current measures the rate at which electricity is flowing. Voltage is analogous to the pressure of water in a pipe, while current is analogous to the flow rate of water through the pipe.</p><h2>3. What is the relationship between voltage and resistance?</h2><p>According to Ohm's Law, the relationship between voltage (V), current (I), and resistance (R) is V = I * R. This means that as the resistance increases, the voltage needed to maintain the same current also increases.</p><h2>4. How does voltage affect the performance of electronic devices?</h2><p>Voltage is a crucial factor in determining the performance of electronic devices. If the voltage is too low, the device may not function properly, and if the voltage is too high, it can cause damage to the device. Therefore, it is important to use the correct voltage for each electronic device.</p><h2>5. What are some common sources of voltage?</h2><p>There are many sources of voltage, including batteries, power outlets, generators, and solar panels. In most cases, voltage is created by converting some form of energy (such as chemical, mechanical, or solar energy) into electrical energy.</p>

1. What is voltage?

Voltage is a measure of the potential energy difference between two points in an electrical circuit. It is often referred to as "electrical pressure" and is measured in volts (V).

2. How is voltage different from current?

Voltage and current are two different characteristics of electricity. While voltage measures the potential energy difference, current measures the rate at which electricity is flowing. Voltage is analogous to the pressure of water in a pipe, while current is analogous to the flow rate of water through the pipe.

3. What is the relationship between voltage and resistance?

According to Ohm's Law, the relationship between voltage (V), current (I), and resistance (R) is V = I * R. This means that as the resistance increases, the voltage needed to maintain the same current also increases.

4. How does voltage affect the performance of electronic devices?

Voltage is a crucial factor in determining the performance of electronic devices. If the voltage is too low, the device may not function properly, and if the voltage is too high, it can cause damage to the device. Therefore, it is important to use the correct voltage for each electronic device.

5. What are some common sources of voltage?

There are many sources of voltage, including batteries, power outlets, generators, and solar panels. In most cases, voltage is created by converting some form of energy (such as chemical, mechanical, or solar energy) into electrical energy.

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