KE of system / different reference frames question

In summary, the conversation discusses the concept of using the ground as a source of energy for a moving object, such as in the case of KERS. It explains how the energy in a given frame of reference can be repartitioned and how this can be misunderstood if one is thinking too literally. The conversation also addresses the issue of where the energy for KERS comes from, with one person arguing that it comes from the car's fuel and another suggesting it comes from the kinetic energy of the car itself. Overall, the conversation highlights the importance of considering reference frames when discussing energy and its sources.
  • #106


my_wan said:
@RCP
The "cyber-strand" deserved the attention it got and not at all surprising. It also had some people willing to stick it out more than I was and they deserve more credit. I only found it worthwhile to support the claim and blow a few whistles because the physics was in their favor.

However, I also failed to recognize that I was debating one of the same people here, and on a physically related set of perceptions about Galilean relativity to boot. Probably not worth sticking it out under the circumstances.

It is not just about the cart, but those very ideas of Galilean Relativity. Haven't you noticed that every example, is a two object inertial case, or how that is somehow suspended, so that things can accelerate? The most trivial possible. Definitions are stretched to breaking point, and then used as a bludgeon.

Do you have a rebuttal to the problem of the F1 car on the belt? It completely falsifies the treadmill, and the Galilean notions that define it. Or how an ordinary domestic car, can be said to accelerate the massive Earth? That one, defies all experience of the physical world.
 
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  • #107
Humber said:
I have not conserved energy, but only momentum.
And didn't DaleSpam also point out that energy must also be conserved? Or do you not believe energy is conserved? Yet you have half the energy put in the battery as potential energy, half in removing the cars momentum relative to Earth yet your method wants a third half to account for the second half of the ke? The 50 kJ you want accounted for is in fact 50 kJ ke, not momentum. You can't spend 50 kJ to stop the car and put 50 kJ in the battery and still expect another 50 kJ out of that 100 total kJ.

Said quiet nicely here:
DaleSpam said:
Just as the Earth lost 100 kJ (50 kJ to the car's KE and 50 kJ to the battery), as the car went from 0 to 10 m/s the Earth will gain 100 kJ (50 kJ from the car's KE and 50 kJ from the battery) as the car goes from 10 to 0 m/s. There is no free lunch here.

I don't really see much else to add.
 
  • #108


Humber said:
Do you have a rebuttal to the problem of the F1 car on the belt?
I don't see any problem here. If both the belt and the F1 car are initially at rest (say from a ground frame of reference), and then the F1 uses it's engine to convert chemical potential energy from fuel into kinetic energy of the belt and F1 car, and assuming no losses to heat, then all of the energy winds up as an increase in KE of the belt and F1 car, with most of the KE going into the belt because the F1 car has much more mass than the belt.

Humber said:
It completely falsifies the treadmill.
Falsifies what?
 
  • #109
Humber said:
Momentum is conserved between the car and the Earth.
The car gains -p, and the Earth gains p, so in the above case, that is Δp.
From this response I understand that you agree with the proof of post 59 as it applies to a single body and that here you are correctly pointing out that in the KERS scenario I must use the formula twice, once for [itex]\Delta KE_e[/itex] and once for [itex]\Delta KE_c[/itex], with [itex]\Delta p_e=-\Delta p_c[/itex] in order to conserve momentum.

Is this a correct understanding of your position? If I am misunderstanding then can you please provide a clear yes/no answer to whether or not you agree with the proof of post 59.
 
  • #110


rcgldr said:
I don't see any problem here. If both the belt and the F1 car are initially at rest (say from a ground frame of reference), and then the F1 uses it's engine to convert chemical potential energy from fuel into kinetic energy of the belt and F1 car, and assuming no losses to heat, then all of the energy winds up as an increase in KE of the belt and F1 car, with most of the KE going into the belt because the F1 car has much more mass than the belt.

Falsifies what?

The amount of KE recoverable by the KERS is due only to the KE of wheels and the mechanism of the TM, and not related to the translational KE of the car, in any way.
 
  • #111
Humber said:
ΔKE(car)

= (−m u − p)2/2m − (−m u)2/2m

= (m2 u2 −2m u·p + p2)/2m − (m2 u2)/2m
Note, a slight math error marked in red. A negative times a negative is a positive, so that term should be +2m u·p


Humber said:
ΔKE(earth)
= u.p + p2/2M
So you clearly agree with my formula, [itex]\Delta KE = v_i \Delta p + \Delta p^2/2m [/itex], in the case where [itex]u=v_i[/itex] and [itex]p=\Delta p[/itex]. Is there any time that you do not agree with it?

Btw, it would really help if you were more careful about distinguishing your quantities. Ie. Is your p the change in momentum or is it the initial momentum? I follow the usual convention where [itex]\Delta p[/itex] is the change in momentum, [itex]p_i[/itex] is the initial momentum, and [itex]p_f=p_i+\Delta p[/itex] is the final momentum.
 
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  • #112
DaleSpam said:
From this response I understand that you agree with the proof of post 59 as it applies to a single body and that here you are correctly pointing out that in the KERS scenario I must use the formula twice, once for [itex]\Delta KE_e[/itex] and once for [itex]\Delta KE_c[/itex], with [itex]\Delta p_e=-\Delta p_c[/itex] in order to conserve momentum.

Is this a correct understanding of your position? If I am misunderstanding then can you please provide a clear yes/no answer to whether or not you agree with the proof of post 59.

Only the change in the car's momentum is of concern, so, [itex]\Delta p_e=-\Delta p_c[/itex] That is all there is. It is transferred to the Earth.
In the first case, the car's 50kJ, is transferred to the battery. So, the second case, which is a mirror, should see the energy come from the battery to the car. The total remains in each case at 50kJ.

In the example you gave, and in the first case, the energy to the ground is a result of a change of Earth's velocity, 1e-21m/s. That results in 5e-18J

In the other case, the change in Earth's velocity is Vcar*(Mearth - Mcar)/Mearth
Vcar =10m/s
Mearth = 1e25kg
Mcar =1e3kg

so the change in KE is related to (10 - 1e-21)m/s.
That , I think, accounts for the difference of relative velocities and energy.

The energy "transferred back to the car" should be Mearth/Mcar*5e-18J =50kJ
 
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  • #113
Humber said:
Only the change in the car's momentum is of concern, so, [itex]\Delta p_e=-\Delta p_c[/itex] That is all there is. It is transferred to the Earth.
In the first case, the car's 50kJ, is transferred to the battery. So, the second case, which is a mirror, should see the energy come from the battery to the car. The total remains in each case at 50kJ.

In the example you gave, and in the first case, the energy to the ground is a result of a change of Earth's velocity, 1e-21m/s. That results in 5e-18J

In the other case, the change in Earth's velocity is Vcar*(Mearth - Mcar)/Mearth
Vcar =10m/s
Mearth = 1e25kg
Mcar =1e3kg

so the change in KE is related to (10 - 1e-21)m/s.
That , I think, accounts for the difference of relative velocities and energy.
You are still dodging the question. Do you agree with the proof post 59 or not? Please be clear.
 
  • #114
DaleSpam said:
Note, a slight math error marked in red. A negative times a negative is a positive, so that term should be +2m u·p


So you clearly agree with my formula, [itex]\Delta KE = v_i \Delta p + \Delta p^2/2m [/itex], in the case where [itex]u=v_i[/itex] and [itex]p=\Delta p[/itex]. Is there any time that you do not agree with it?

Btw, it would really help if you were more careful about distinguishing your quantities. Ie. Is your p the change in momentum or is it the initial momentum? I follow the usual convention where [itex]\Delta p[/itex] is the change in momentum, [itex]p_i[/itex] is the initial momentum, and [itex]p_f=p_i+\Delta p[/itex] is the final momentum.

Momentum adds linearily, so there is no dependency on pi
p^2/2mcar is the KE of the car with momentum p
p^2/2mearth is the change in the Earth's KE when p is transferred to it.
 
  • #115
Humber said:
Momentum adds linearily, so there is no dependency on pi
This is an ambiguous statement. There is no dependency of what quantity on [itex]p_i[/itex]?

Also, clearly [itex]p_i[/itex] depends on [itex]p_i[/itex] even though momentum adds linearly, so adding linearly is not a justification for a lack of dependency in general. If you want to show that x doesn't depend on y because y adds linearly then you need to take the linearity property, use it in the expression for x, and show that y drops out algebraically.

Btw, I note that you still avoid the question.

Humber said:
p^2/2mcar is the KE of the car with momentum p
This is true in general.
Humber said:
p^2/2mearth is the change in the Earth's KE when p is transferred to it.
This is true only in the case where the initial velocity is 0. Note the word "change" in bold. The change of x is not the same thing as x except when x is initially 0.
 
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  • #116
DaleSpam said:
This is an ambiguous statement. There is no dependency of what quantity on pi?

Also, clearly pi depends on pi even though momentum adds linearly, so adding linearly is not a justification for a lack of dependency in general. If you want to show that x doesn't depend on y because y adds linearly then you need to take the linearity property, use it in the expression for x, and show that y drops out algebraically.


It does. The existing momentum is pi,e the total after the change is pi,e + pi,c, so the change is just pi,c
The change in KE for the car is pi,c^2/2mc and for the Earth pi,c^2/2me
Works both ways.
 
  • #117
Humber said:
It does. The existing momentum is pi,e the total after the change is pi,e + pi,c, so the change is just pi,c
The change in KE for the car is pi,c^2/2mc and for the Earth pi,c^2/2me
Works both ways.
Then it should be no problem to demonstrate it algebraically, this time using clear variable names to distinguish between initial, final, and change quantities.
 
  • #118
DaleSpam said:
Then it should be no problem to demonstrate it algebraically, this time using clear variable names to distinguish between initial, final, and change quantities.

The point is that it's not. The idea of the car accelerating the Earth to 10m/s is not physically realizable. In the real world, an F1 car is on the track. The KERS is applied. If viewed from the frame of the car, and from the frame of the ground at the same time, there will be no difference. To start with the Earth at 10m/s relative to the car, is a totally different physical situation. In the first case the calculation is done with the car having 50kJ, which after 10s, is transferred to the battery. In the second, it's already there, at t = 0.
Makes no sense.
 
  • #119
DaleSpam said:
Then it should be no problem to demonstrate it algebraically, this time using clear variable names to distinguish between initial, final, and change quantities.

It's your notation i = initial, c = car, e= earth. There is one transfer of 10000kg.m/s to the momentum, pi,e. It makes no difference what that is. The resultant KE depends on the Earth's mass.
 
  • #120
Humber said:
Momentum is frame independent, otherwise, there could be violations of conservation.
I figured this was your core error, you don't understand the meaning of conservation laws. Conservation laws don't mean that the quantities are fixed, regardless of frame. They mean that once you pick a frame, the total quantities will stay the same in that frame. If you change frames, the quantities change. That's how conservation laws work. Do you get this, or not?
If follows that changes are also frame independent.
Wrong, the changes are frame independent, but that doesn't "follow" from anything, that statement, and only that statement, is the conservation law. Think about this as long as it takes.
Total energy = p^2/2mcar + p^2/2mearth is correct.
No, not if you think that p is a change in momentum, which is how you are using it. Doesn't it concern you that you do not get the correct answers, and you conclude that all the experts are wrong, but when they tell you what you are doing wrong, you just claim you are right? I can tell you right now, you will never learn anything that way. Is it all right with you to never learn anything?

If the energy change of the car were the same as the change in the ground, p^2/2mcar - p^2/2mearth = 0, then obviously the KERS could not store any energy.
Notice where once again you associate p^2/2m with energy changes. Wrong.
 
  • #121
Humber said:
To start with the Earth at 10m/s relative to the car, is a totally different physical situation.
Here is where you are flat out wrong. It is merely a different (but equally valid) description of the same physical situation. You are denying the principle of relativity. This has been a cornerstone of physics since Galileo's time:
http://physics.ucr.edu/~wudka/Physics7/Notes_www/node47.html
You are literally centuries out of date in your thinking.

Humber said:
In the first case the calculation is done with the car having 50kJ, which after 10s, is transferred to the battery.
Yes.

Humber said:
In the second, it's already there, at t = 0.
Makes no sense.
This is incorrect. In the second the Earth has a huge amount of KE, of which after 10s, 50 kJ is transferred to the battery and 50 kJ is transferred to the car's KE.

These are both correct descriptions of the same physical situation. Momentum and energy are conserved in both cases, and Newton's laws are obeyed in both cases.
 
  • #122
Humber said:
It's your notation i = initial, c = car, e= earth. There is one transfer of 10000kg.m/s to the momentum, pi,e. It makes no difference what that is. The resultant KE depends on the Earth's mass.
So prove it, mathematically. If you are going to make claims, then you should be able to back them up with clear and unambiguous derivations, as I have done.
 
  • #123
Ken G said:
I figured this was your core error, you don't understand the meaning of conservation laws. Conservation laws don't mean that the quantities are fixed, regardless of frame. They mean that once you pick a frame, the total quantities will stay the same in that frame.
And none can be created.

Ken G said:
If you change frames, the quantities change. That's how conservation laws work. Do you get this, or not?Wrong, the changes are frame independent, but that doesn't "follow" from anything, that statement, and only that statement, is the conservation law. Think about this as long as it takes.
Yes it does. There are two objects. The ground and the car. Momentum is conserved, so what one gains, the other loses, and that is entirely frame independent, as the total remains the same and pe - pc = 0 or p = -p

Ken G said:
No, not if you think that p is a change in momentum, which is how you are using it.
When all is transferred Δp is p. 100% of p is p.

Ken G said:
Doesn't it concern you that you do not get the correct answers, and you conclude that all the experts are wrong, but when they tell you what you are doing wrong, you just claim you are right? I can tell you right now, you will never learn anything that way. Is it all right with you to never learn anything?
Oh, right.

Ken G said:
Notice where once again you associate p^2/2m with energy changes. Wrong.
Oh right.

p= mv ( I assume you know that)

p2 = m2v2

p2/2m = m2v2/2m = 1/2mv2 = KE.
 
  • #124
Btw, I think that Huber's continued avoidance of the question is because he recognizes that the derivation is correct, but he feels that he would lose face to admit it.
 
  • #125
This nonsense has gone on long enough. Thread locked.
 
<h2>1. What is kinetic energy of a system?</h2><p>Kinetic energy is the energy an object possesses due to its motion. It is a scalar quantity that depends on the mass and velocity of the object.</p><h2>2. How is kinetic energy of a system calculated?</h2><p>The formula for calculating kinetic energy is KE = 1/2 * m * v^2, where m is the mass of the object and v is its velocity.</p><h2>3. Does the kinetic energy of a system change in different reference frames?</h2><p>Yes, the kinetic energy of a system can change in different reference frames. This is because the velocity of the object may be different in different frames of reference, resulting in a different value for kinetic energy.</p><h2>4. Can kinetic energy be negative?</h2><p>No, kinetic energy cannot be negative. It is always a positive quantity, as it represents the energy of an object in motion.</p><h2>5. How does the kinetic energy of a system affect its motion?</h2><p>The kinetic energy of a system is directly proportional to its velocity. As the kinetic energy increases, so does the velocity of the system. This means that a system with a higher kinetic energy will have a greater tendency to continue moving and will require more force to stop it.</p>

1. What is kinetic energy of a system?

Kinetic energy is the energy an object possesses due to its motion. It is a scalar quantity that depends on the mass and velocity of the object.

2. How is kinetic energy of a system calculated?

The formula for calculating kinetic energy is KE = 1/2 * m * v^2, where m is the mass of the object and v is its velocity.

3. Does the kinetic energy of a system change in different reference frames?

Yes, the kinetic energy of a system can change in different reference frames. This is because the velocity of the object may be different in different frames of reference, resulting in a different value for kinetic energy.

4. Can kinetic energy be negative?

No, kinetic energy cannot be negative. It is always a positive quantity, as it represents the energy of an object in motion.

5. How does the kinetic energy of a system affect its motion?

The kinetic energy of a system is directly proportional to its velocity. As the kinetic energy increases, so does the velocity of the system. This means that a system with a higher kinetic energy will have a greater tendency to continue moving and will require more force to stop it.

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