Conceptual derivation of (classical mechanical) energy?

In summary: I was trying to do.In summary, both the traditional and the modern way of introducing energy seem forced and pedagogically unappealing to the non-expert. A more natural way of introducing the concept may be needed.
  • #1
RoyLB
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I have a pedagogical question, and a philosophical question, both involving energy:

1) All the derivations I’ve ever seen of kinetic energy in both elementary and advanced texts (or in Physics Forum searches) either simply define T=1/2mv^2 or start by taking the dot product of force and distance. Once either of these steps are done, it’s just a matter of mathematics to get to the work energy theorem. However, pedagogically speaking, both approaches seem forced (if you’ll pardon the pun). Do you know of a more natural way to introduce and motivate the idea of (mechanical) energy? I assume it is natural to start from F=ma, since the non-expert can grasp the concepts of forces, masses, and accelerations pretty easily, especially after some simple experiments.

2) What exactly is energy, anyway? Since work involves a dot product, can it be considered the component of something? If so, what? I suspect that one might need to resort to relativity and/or thermodynamics to get the true picture of what energy is, not unlike how Least Action in classical physics can be “explained” by resorting to
quantum physical considerations
(see http://www.eftaylor.com/pub/QMtoNewtonsLaws.pdf)

Direct answers or pointers to relevant references would be appreciated.

Thanks!
Roy
 
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  • #2
Energy (and work) is a scalar so can't be a component of anything.
They are both physical concepts.
The dot product is a mathematical concept that results in a scalar.

In traditional mechanical education energy is defined as the capacity to do work. The concept is introduced after work has been defined in terms of forces and distances. Both these entities are subject to relativistic transformations.

So where are you coming from?
 
  • #3
Here is a way I've discovered. The outline is:
All of our assumptions are
  1. conservation of momentum p(v)
  2. all forces are inverse square forces (or more generally [itex]\oint \vec{F}\cdot d\vec{r}=0[/itex] or [itex]F=-\nabla V(\vec{r})[/itex])
I make absolutely no assumption about the velocity dependence of the momentum. Momentum is just "something" that is conserved as a total.
I also never use "mass". It is not needed, but whoever wishes can define m=p/v
In the end I derive purely mathematically from vector momentum conservation that a scalar quantity [itex]E=\int v\,dp[/itex] exists, which is conserved provided you take care of another new quantity that we can call potential energy.

[tex]\frac{d\vec{p}_i}{dt}=\sum_{\stackrel{j}{j\neq i}}\vec{F}_{ij}[/tex]
[tex]\frac{d\vec{p}_i}{dt}\cdot d\vec{r}_i&=\sum_{\stackrel{j}{j\neq i}}\vec{F}_{ij}\cdot d\vec{r}_i[/tex]
[tex]d\vec{p}_i\cdot\vec{v}_i&=\sum_{\stackrel{j}{j\neq i}}\vec{F}_{ij}\cdot d\vec{r}_i[/tex]
[tex]\sum_i \int \vec{v}_i\cdot d\vec{p}_i&=\sum_{\stackrel{i,j}{j\leq i}}\int\left(\vec{F}_{ij}\cdo d\vec{r}_i+\vec{F}_{ji}\cdot d\vec{r}_j\right)[/tex]
If we assume
[tex]\vec{F}_{ij}&=-\nabla_i V(\vec{r}_i,\vec{r}_j)+\vec{A}\times\frac{d\vec{r}_i}{dt}[/tex]
(conservative force plus any perpendicular part)
and define a new unassigned quantity
[tex]E_i= \int\vec{v}_i\cdot d\vec{p}_i[/tex]
then the RHS is integrable
[tex]\sum_i E_i+\sum_{\stackrel{i,j}{j\leq i}}V(\vec{r}_i,\vec{r}_j)&=\sum_i E_i(0)+\sum_{\stackrel{i,j}{j\leq i}}V_{ij}(0)=\text{const}[/tex]

You see that whenever we have only inverse square laws, then conservation of momentum (which is completely undefined yet), implys conservation of a scalar we will call kinetic energy. Note that we need to add a correction factor which we will call potential energy.

If I now combine [itex]E=\int v\, dp[/itex] with E=m (natural units) i.e. E=p/v, then I get all of the expressions for relativistic mechanics.

If on the other hand I unnaturally assume p/v=const=m, then I get classical mechanics.
 
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  • #4
So you see in my view energy is just an artificial number that happens to be conserved in addition to momentum conservation, since we only have inverse square law forces.

Without inverse square laws, maybe our world wouldn't conserve energy.

(I haven't generalized my proof to non-instantaneous forces yet :( )
 
  • #5
Conservation of energy holds even with forces that do not follow an inverse square law!
(as in springs, which follow Hooke's law)
 
  • #6
@Acut: Think about it! Even springs are based in the inverse square law of electrostatics.
 
  • #7
Thanks eveyone for responding

@Studiot - I am an Aeronautical engineer specializing in control systems, so I am familiar with the points you made. I am trying to write a treatise that takes a reader from some exposure to physics and perhaps calculus to where he/she could understand some elementary automatic control theory. I think it would be useful to bring some energy methods to this treatment. However, I realized that I was unable to bridge the gap in a satisfactory way between F=ma and W=Fd or T=1/2mv^2.

@ Gerenuk - I think you've just showed that if all the forces are derivable from a potential function that conservation of energy holds. But that is just the condition for the forces to be conservative (although I'm not sure how A x dr/dt comes into the discussion). I think that 1/r^2 forces are just a subset of conservative forces. To be even more general, Noether's theorem indicates that as long as there's no explicit dependence on time that energy will be conserved.

But, having said all that, your second step is to take the dot product between the forces and the displacement. What motivated this step - except of course that you knew how the answer needed to come out in the end! As a student, I always felt I understood concepts better when all the steps in a derivation made sense and followed naturally from the step before.

- Roy
 
  • #8
The best definition I've seen for energy is the capacity to create an effect.

As for teaching it, I can't see a simpler image to grasp than force times distance. If you imagine a person pulling a sliding block by a cord, anyone can grasp the concept that the bigger the force, the more energy required and the longer the distance traveled, the more energy required. In fact, I think it's more obvious (intuitively) than the bigger is an acceleration, the bigger is the force in F=ma.
 
  • #9
RoyLB said:
@ Gerenuk - I think you've just showed that if all the forces are derivable from a potential function that conservation of energy holds. But that is just the condition for the forces to be conservative (although I'm not sure how A x dr/dt comes into the discussion).
Well, I actually derive that something like energy exists at all. Why do you think that [itex]F=-\nabla V[/itex] means anything? Don't forget that you have to imagine to be the first scientist on Earth and no-one has ever discovered something like energy.
I suppose if you were to start a proof, you would not only restrict yourself to static *external* potentials, but also you would define [itex]dE=Fds[/itex] for no apparent reason? I just made this proof more general and logical.

The "A x" term is merely to add an admissible degree of freedom without breaking the proof. And this term is needed to represent magnetism.

RoyLB said:
I think that 1/r^2 forces are just a subset of conservative forces.
I vaguely recall, that inverse square forces and zero gradient is equivalent in 3D (I guess provided forces should vanish at infinity).

RoyLB said:
To be even more general, Noether's theorem indicates that as long as there's no explicit dependence on time that energy will be conserved.
That energy conservation follows from Noether, is a myth. The Lagrangian formalism guesses an formalism that is already tailored to yield energy results. Noether for energy in a way states that if energy is time independent, then energy is conserved.

RoyLB said:
But, having said all that, your second step is to take the dot product between the forces and the displacement. What motivated this step - except of course that you knew how the answer needed to come out in the end!
With mathematical experience, one sees that one can exploit [itex]\int \nabla V\cdot d\vec{s}=\Delta V[/itex]. So I really could have been lead by mathematical simplification ideas only.
 
  • #10
jack action said:
The best definition I've seen for energy is the capacity to create an effect.

As for teaching it, I can't see a simpler image to grasp than force times distance. If you imagine a person pulling a sliding block by a cord, anyone can grasp the concept that the bigger the force, the more energy required and the longer the distance traveled, the more energy required. In fact, I think it's more obvious (intuitively) than the bigger is an acceleration, the bigger is the force in F=ma.

Jack,
You may have a point in that I certainly don't recall having this difficulty during my own undergraduate or even high school physics experience. Perhaps I am making too much of it.

But, as for my other philosophical question, why should force times distance be meaningful? Why is energy a scalar at all? Is energy just a mathematical fiction / convenience, like imaginary numbers (OK - perhaps I opened a can of worms with that statement :-) or is there some physical "reality" to it? I think it is real, in that the energy concept exists in thermodynamics apart from mechanics. Also, I think relativistic physics shows that energy is as real as mass and momentum - in fact they are all aspects of the same mass energy momentum 4-vector. Unfortunately, my understanding of physics is not yet sufficiently sophisticated to make sense of all these ideas.

- Roy
 
  • #11
Gerenuk said:
The Lagrangian formalism guesses an formalism that is already tailored to yield energy results.
I'm interested in knowing more about this.
Here is what I know or believe to be true: in some closed systems (where there's no dissipative force), there's a quantity that is invariant with respect to time translations, i.e. a constant. This number is called the total energy and we can as you know separate it as kinetic and potential energy which aren't necessarily constant. The derivation of the kinetic energy comes from the Lagrangian of the system. And if the Lagrangian doesn't depend explicitly on time, then the energy is conserved.
 
  • #12
fluidistic said:
[...]The derivation of the kinetic energy comes from the Lagrangian of the system. And if the Lagrangian doesn't depend explicitly on time, then the energy is conserved.
The point is: How do you write down the Lagrangian for a system? You put in your knowledge about kinetic energy or anything equivalent! So you already set up the stage to make it yield energy conservation at some point.

If you just say that there is some vector quantity momentum which is conserved, then your system could be any crazy world.

But as soon as you say, OK, and now I take it as a *new* law that the Lagrangian formalism holds and I will put in mv^2/2 in there, then you are already presupposing that eventually there will be something like a conserved energy.
 
  • #13
Gerenuk said:
The point is: How do you write down the Lagrangian for a system? You put in your knowledge about kinetic energy or anything equivalent! So you already set up the stage to make it yield energy conservation at some point.
I agree that I also found the expression of the Lagrangian of a system with 1 particle somehow artificial.
I don't know if you had a look at a thread of mine I started about a week ago: https://www.physicsforums.com/showthread.php?t=399993. It might be of interest for this part of the discussion.


If you just say that there is some vector quantity momentum which is conserved, then your system could be any crazy world.

But as soon as you say, OK, and now I take it as a *new* law that the Lagrangian formalism holds and I will put in mv^2/2 in there, then you are already presupposing that eventually there will be something like a conserved energy.
This requires a lot of hours for me to think in order to fully agree with this. :smile:
 
  • #14
Gerenuk said:
Well, I actually derive that something like energy exists at all. Why do you think that [itex]F=-\nabla V[/itex] means anything? Don't forget that you have to imagine to be the first scientist on Earth and no-one has ever discovered something like energy.
I suppose if you were to start a proof, you would not only restrict yourself to static *external* potentials, but also you would define [itex]dE=Fds[/itex] for no apparent reason? I just made this proof more general and logical.

The "A x" term is merely to add an admissible degree of freedom without breaking the proof. And this term is needed to represent magnetism.I vaguely recall, that inverse square forces and zero gradient is equivalent in 3D (I guess provided forces should vanish at infinity).That energy conservation follows from Noether, is a myth. The Lagrangian formalism guesses an formalism that is already tailored to yield energy results. Noether for energy in a way states that if energy is time independent, then energy is conserved.With mathematical experience, one sees that one can exploit [itex]\int \nabla V\cdot d\vec{s}=\Delta V[/itex]. So I really could have been lead by mathematical simplification ideas only.

@ Gerenuk

I originally asked 2 questions. The first is how to show the derivation of energy from simpler concepts, the second is about what energy actually is. In the first case, I don't need a rigorous proof, I just want each step to be understandable, even if it is purely heuristic. In my mind, taking F dot ds comes out of nowhere, but perhaps that's just me. I feel there ought to be a more elegant way to approach this argument. As for my second question, I don't think your proof really tells me what energy actually is - anymore than any other textbook argument, unless you think that energy really is a sort of convenient mathematical fiction. As I've said earlier, I don't think that this is the case.

I think your proof is probably fine from a mathematics standpoint (although I think you'd need to show where A x dr comes from more explicitly and I don't think you've shown that energy is a constant in this case - i.e. that dE/dt = 0). I think from a physics standpoint you'd have to show that forces are conservative (I'd accept F = dp/dt from experimental reasoning, or even just as a definition). I believe that physicists think that this is indeed the case for the fundamental forces. However, the mathematics and the physics of the conservation of energy still work for dissipative forces, as long as you consider heat to be a form of energy.

In fact I think that the (mass-) energy momentum 4 vector from relativity is the probably the more fundamental physical entity, and that "forces" being the rate of change of momentum can be likely derived from that principle. Its just that we humans can appreciate forces, masses, and accelerations from our everyday experience while energy is more abstract.

- Roy
 
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  • #15
fluidistic said:
I agree that I also found the expression of the Lagrangian of a system with 1 particle somehow artificial.
I don't know if you had a look at a thread of mine I started about a week ago: https://www.physicsforums.com/showthread.php?t=399993. It might be of interest for this part of the discussion.



This requires a lot of hours for me to think in order to fully agree with this. :smile:

@fluidistic, Gerenuk

I tend to agree with you that the Lagrangian formulation seems contrived. If you check here: http://www.eftaylor.com/pub/QMtoNewtonsLaws.pdf you'll see that the "least action" formulation is better understood from quantum mechanical principles (although I think they've left out some key portions of the argument in that paper)

- Roy
 
  • #16
Thank you for your response Roy, I should have perhaps said, where are you going to, rather than where are you coming from, but you anticipated even that!

From what you say I can't see the point of mentioning dot products at all. You may not be aware that physicists and mathematicians work to a slightly different definition of both vectors and scalars. The physicists' one being more restrictive.

If you want to introduce physical concepts in a staged manner I wonder how you introduce the definition of a force?
I was appalled to learn that modern teaching in the UK introduces friction as the first force discussed.

I have found in my experience of gaining understanding of a subject that following the historic route usually suits the best. Historically new concepts mostly arose when the necessary ground had been laid and could be seen in the concept of that work and understanding.
So some development of mechanics preceeded development of what we now call classical thermodynamics and some development of electrical phenomenon was also stirring. So it became obvious that some equivalence of the mechanical work, heat, fluid and electrical energies was called for.

I think those whose educational development followed this route have less trouble with what I might call engineering physics than with say particle or sub particle physics.
 
  • #17
RoyLB said:
In my mind, taking F dot ds comes out of nowhere, but perhaps that's just me.
Yes, and that's why I explained to you why someone who has never heard of F dot ds would still perform this operation. It's purely mathematical logic and an obvious mathematical simplification step.

RoyLB said:
although I think you'd need to show where A x dr comes from more explicitly and I don't think you've shown that energy is a constant in this case - i.e. that dE/dt = 0.
I get the impression that you are not reading what I write. If you are really interested in answers please read carefully. With the A x dr terms I'm trying to express a more general function that still allows for my proof. I'm not assuming any knowledge about real world physics and the choice F=\nabla V+A x dr is motivated only by the mathematical form of the expression.
And dE/dt=0 follows if you look at the step carefully. The A x dr term just cancels.

RoyLB said:
I think from a physics standpoint you'd have to show that forces are conservative (I'd accept F = dp/dt from experimental reasoning, or even just as a definition).
Note that at no point I'm using force. Force is just flow of momentum. So it's not a question of experimental reasoning or definitions.

RoyLB said:
I believe that physicists think that this is indeed the case for the fundamental forces. However, the mathematics and the physics of the conservation of energy still work for dissipative forces, as long as you consider heat to be a form of energy.
What is heat? It's a macroscopical concept. On the microscopic level there are only bouncing billard balls, so you cannot speak about heat.

RoyLB said:
In fact I think that the (mass-) energy momentum 4 vector from relativity is the probably the more fundamental physical entity, and that "forces" being the rate of change of momentum can be likely derived from that principle.
The problem with the 4 vector philosophy is, that it is overdetermined and it's a miracle why it is consistent. Given that 3 components are conserved and our world has inverse square laws, my derivation shows that the 4th component is conserved.
It's much more ugly to postulate two laws which could potentially be conflicting. It's nicer if you show how to derivate one of the law from the other.
 
  • #18
Studiot said:
From what you say I can't see the point of mentioning dot products at all. You may not be aware that physicists and mathematicians work to a slightly different definition of both vectors and scalars. The physicists' one being more restrictive.

I need the dot product anyway, perhaps in both the mathematical and the physical senses. Since you can see I have trouble bringing in the F ds concept, you can imagine that I really have a problem with introductory Controls texts that simply introduce Laplace and Fourier transforms. I plan to use the idea of infinite dimensional "dot products" to motivate these transforms.

If you want to introduce physical concepts in a staged manner I wonder how you introduce the definition of a force?
I was appalled to learn that modern teaching in the UK introduces friction as the first force discussed.

I was planning just to use an archetypical spring-mass-damper system to introduce the "intuitive" concept of force. My main concern is not rigor, but elegance. Having said that, I don't want to sacrifice accuracy for simplicity.

I have found in my experience of gaining understanding of a subject that following the historic route usually suits the best. Historically new concepts mostly arose when the necessary ground had been laid and could be seen in the concept of that work and understanding.
So some development of mechanics preceeded development of what we now call classical thermodynamics and some development of electrical phenomenon was also stirring. So it became obvious that some equivalence of the mechanical work, heat, fluid and electrical energies was called for.

I think those whose educational development followed this route have less trouble with what I might call engineering physics than with say particle or sub particle physics.


I'm really focusing on control systems, so I'll only bring in as much physics and math as I need. I think the historical approach - while fascinating - will take too much time. I'll probably focus the treatise on the engineering physics path and bring in mathematics via hypertext links as appropriate. Perhaps if I am ambitious enough I will add historical sidebars to the text.

I probably don't even really need energy that all that much. After I explain the spring mass damper EOM via the force picture, I want to just mention that it can also be explained by energy transfer, from potential to kinetic to dissipative. This opens the door to more sophisticated methods (I prefer Kane's method to Lagrange, but that's what I studied in grad school)

- Roy
 
  • #19
Well, I can think of a perhaps more natural way of introducing energy.

Begin with Torricelli:

v^2 = vo^2 + 2*a*delta s

Apply it to free fall

v^2 = vo^2 + 2g(ho - h)

Rearrange:

v^2 + 2gh = vo ^2 + 2gho

You can see that it's a beginning: you have isolated on each side of the equation terms that only relate to the beginning and terms that only relate to the end.
Dividing both sides by 2 is just a mathematical operation. Multiplying it by m and getting the "right" expressions for kinetic and gravitational potential energy is a bit more tricky: use the spring-mass system and show you can do something similar (one side having only information about the past and one side having only information about future) with it. Then it becomes quite a natural thing to multiply the one-half-v^2 term by the mass of the object.

Now, this derivation follows from F=ma (so that you know the object's acceleration, which Torricelli demands) and only some very basic knowledge of kinematics. I think it's a nice way of showing how the concept of energy arises if you will not show them much physics. However, such derivations would hardly convince most physicists.

About "what is energy", notice that there's no universal definition of it. My books usually define it as "the capacity to do work" or, as jack action said "to produce a effect". Those definitions are unacceptable, however. You may have a lot of energy, but if you are in thermodynamical equilibrium, you can't do any useful work with it. I prefer thinking of it as a number which -as far as we know- is conserved with time.

@Gerenuk: Although the internal mechanism of springs is based on electrostatics, it isn't a requirement for energy to conserve. All we need is curl F = 0, and quite a lot of forces and force fields satisfy it.
 
  • #20
Acut said:
@Gerenuk: Although the internal mechanism of springs is based on electrostatics, it isn't a requirement for energy to conserve. All we need is curl F = 0, and quite a lot of forces and force fields satisfy it.
OK, tell me one example, but it should be one where the force vanishes at infinity. Our world is made up of particles and it's natural to assume that fundamental forces should not depend on particles an infinite distance away. So which type of force between point objects is possible, which isn't inverse square?
I have the feeling curl F=0 is equivalent to inverse square in 3D.

Btw: Springs are objects that change shape. This doesn't count. We are talking about forces on test particles, which do not change any of the enviroment.
 
  • #21
RoyLB said:
But, having said all that, your second step is to take the dot product between the forces and the displacement. What motivated this step - except of course that you knew how the answer needed to come out in the end!
They did try to explain this already, but let me try another way of saying it: what motivated that step (the first time anyone did it) was the realization that it was a useful thing to do. That's it. There need not be any deeper/larger meaning than that. People realized the mathematical relation was useful and gave it a name. That's it.
 
  • #22
I need the dot product anyway, perhaps in both the mathematical and the physical senses. Since you can see I have trouble bringing in the F ds concept, you can imagine that I really have a problem with introductory Controls texts that simply introduce Laplace and Fourier transforms. I plan to use the idea of infinite dimensional "dot products" to motivate these transforms.

What I don't understand is the level of knowledge of the course attendees. Presumably this course has prerequisites?

You express the need to 'introduce' force and energy to students in a course that will be using significant calculus.

Why would anyone attending this course and presumably having enough calculus to study Laplace transforms not have enough physics/ applied maths to understand force and energy?
 
  • #23
RoyLB said:
@ Gerenuk
I originally asked 2 questions. The first is how to show the derivation of energy from simpler concepts, the second is about what energy actually is. In the first case, I don't need a rigorous proof, I just want each step to be understandable, even if it is purely heuristic. In my mind, taking F dot ds comes out of nowhere, but perhaps that's just me.
- Roy

Intuitively, defining work as W=Fd makes sense. Imagine a giant spring that you have to compress. The work that you have to "invest" depends on the force F and the distance d.

F dot d (where F and d are vectors) is useful when the direction of force and path are different
 
  • #24
RoyLB said:
[...]
Do you know of a more natural way to introduce and motivate the idea of (mechanical) energy?
[...]

(I may duplicate something that is already posted; I tend to like writing more than reading.)

Is there a way to get from F=ma to mechanical energy, in intuitive steps?
I assume the following:
- Assumption: when an object falls down, gravity is doing work, increasing the mechanical energy of the object.
- I assume the existence of gravitational potential energy.
- Assumption: when I lift and object I am doing work, increasing the gravitational potential energy of the object. The potential energy is defined to be proportional to the height.

When acceleration is uniform then covered distance 's' as a function of elapsed time 't' is:

[tex] s = \frac{1}{2}at^2 [/tex] (1)

And instantaneous velocity as a function of time:

[tex] v = at [/tex] (2)

Adapting expression (1):

[tex] a*s = \frac{1}{2}a^2t^2 [/tex] (3)

Substituting according to expression (2)

[tex] a*s = \frac{1}{2}v^2 [/tex] (4)

Substituting:

[tex] \frac{F}{m}s = \frac{1}{2}v^2 [/tex] (5)

Moving the factor 'm' for mass to the other side:

[tex] F*s = \frac{1}{2}mv^2 [/tex] (6)

What does expression (6) mean?
I think it expresses something about velocity: I can isolate the velocity:

[tex] v = \sqrt{\frac{2Fs}{m} } [/tex] (7)

Let's say you're dropping an object from several heights. If you double the height you don't get double the velocity. To get double the velocity you have to quadruple the height. That's because once the falling object is going fast gravity has less time to accelerate it even more.
 
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  • #25
@Geranuk:
I think pretty much any function which obey 1/r^n , n being any real larger than one (in order to make F=0 at infinity) will have curl F = 0. But I haven't done the math. So curl F =0 does not imply an inverse square law.

I honestly can't see why you've restricted yourself to forces which go to 0 as distance approaches infinity. If I'm missing something, please explain. Perhaps you only wanted to avoid that I mentioned the spring potential again (why on Earth Physics shouldn't be concerned with springs? I really can't get your point). However, I'm happy to give you another example of curl F=0 force which does not obey inverse square law and which vanishes at infinity: the covalent bond in H2.

If you still find problems with my example above, since it is not "fundamental" or "between two point particles" (which also seem quite useless restrictions to me, please explain them!) the strong force does not follow inverse square law. An it is a fundamental force.

I'm puzzled by your views that everything should be reduced to fundamental inverse square law forces between two point particles. May I give you a suggestion? Show us how could you build a model of spring force using only inverse square laws that are fundamental and act only on point objects.

Have fun!
 
  • #26
@Edgardo
I disagree it's intuitive. It's very common to confuse "to do work" with "getting tired"
 
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  • #27
Acut said:
@Geranuk:
I think pretty much any function which obey 1/r^n , n being any real larger than one (in order to make F=0 at infinity) will have curl F = 0. But I haven't done the math. So curl F =0 does not imply an inverse square law.
Yes, true. I forgot why inverse square law was special. Maybe I can find that reasoning again.

Acut said:
I honestly can't see why you've restricted yourself to forces which go to 0 as distance approaches infinity. If I'm missing something, please explain.
Because I want to talk about real infinities, i.e. lightyears away. And of course we do not want a physics, where some object lightyears away influences what happens on earth.
Note that the spring potential does not belong to the forces we are considering here.
Here a force means, that a test particle experiences a force without the whole world changing depending on the particle position. However, if you are talking about spring forces, then you imply that you adjust the spring for whichever distance the test particle is. That's something completely difference and not related to fundamental forces between particles.

Acut said:
Show us how could you build a model of spring force using only inverse square laws that are fundamental and act only on point objects.
That should be doable. I mean in the end there is no other force, than electrostatics, right? I'll get back to that later.
 
  • #28
@Gerenuk

I'm wondering how to describe spring forces with more elemental, inverse square laws.
For inverse square laws go weaker with distance, on the opposite trend of spring forces.

I'm really curious now. If you find a solution, post it!


Inverse square law is special, since it's the only kind of forces that keep flux constant (which implies they obey some sort of Gauss' Law). This, aside from some minor curiosities, is the only reason why inverse square laws have a special place in Physics.

I've never studied quantum stuff very deeply, but I believe that I've read about a mechanism to influence particles very very very far away. So objects lightyears away may influence earth. In fact, some stars you see in the sky are lightyears away, and they indeed influence our eyes!
 
  • #29
Thanks everyone for the spirited discussion.

I think I am coming to the conclusion that, for "classical" or "engineering" physics, energy is just a convenient mathematical "fiction", in the same way that Hook's Law and Normal Friction "forces" are just ways to compartmentalize manifestations of the underlying more fundamental "real" forces. Which is, of course, what many of you were saying, either implicitly or explicitly.

However, I still don't think "trust me on this; it works; I don't have time to review centuries of experiments and theories" is a very good teaching strategy, if a better approach exists. Here's the solution I propose: The mass bob of a two-dimensional pendulum is of course constrained to follow a circular arc. The force of gravity can therefore only cause motion in a direction perpendicular to the rigid rod of the pendulum. This naturally suggests investigating the component of gravity in that direction - that is taking the dot product of the force with the displacement or the velocity. The dot product of the gravity force with displacement yields the work, and that with the velocity yields power. From either one, its just a matter of mathematics to get to energy and all the rest. To me, that seems a little more elegant and natural than just taking the dot product for "no good reason". I think this approach could lead very nicely to an analytical mechanics discussion (Lagrange's or Kane's method)

- Roy
 
  • #30
Studiot said:
What I don't understand is the level of knowledge of the course attendees. Presumably this course has prerequisites?

You express the need to 'introduce' force and energy to students in a course that will be using significant calculus.

Why would anyone attending this course and presumably having enough calculus to study Laplace transforms not have enough physics/ applied maths to understand force and energy?

@Studiot,

I should take a step further back. This is not intended to be any sort of course. It will be more of a tutorial or treatise that lives on a web page somewhere. I am designing my own quadrotor control system. There is at least one guy (http://www.aeroquad.com/) who was able to cobble together a quadrotor control system based on bits and pieces he picked up on the web. But, he and his followers have no real understanding of closed loop feedback control systems. My intent is to give them sufficient background in the theory to understand how their PID control loops work. I think I can do this with the prerequisite of some exposure to calculus and physics.

I won't need Laplace transforms until much later. However, I have some ideas on how to introduce the Laplace and Fourier transforms that I think are more elegant and understandable than the way they are typically introduced in the controls curriculum. So, even though this project is initially geared toward non-specialists, I do think that as it expands it could eventually be of value to struggling EE, aero, or mech E undergraduates (or perhaps even grad students) who are studying control systems. I envision it to become a mostly self contained feedback control tutorial, that brings in the needed mathematics via hyperlinks as appropriate.

- Roy
 
  • #31
In the classical sense energy could be seen as an auxiliary invariant, but I haven't checked if energy is more fundamental in special relativity. Maybe someone can comment on this?
That I want to check soon.

And I've explained it a couple of times: a mathematician knows that if he sees a gradient, he wants to dot it and integrate. That's a very good reason to do that.
 
  • #32
In the book "Mathematical Aspects of Classical and Celestial Mechanics", 3rd edition, by Vladimir I. Arnold, Valery V. Kozlov, and Anatoly I. Neishtadt, this paragraph appears on page 19(!)
------------
Example 1.1. A natural mechanical system is a triplet (M, T, V ), where M is a smooth configuration manifold, T is a Riemannian metric on M (the kinetic energy of the system), V is a smooth function on M (the potential of the force field). A Riemannian metric is a smooth function on the tangent bundle that is a positive definite quadratic form on each tangent plane. The Lagrange function is L = T + V (the function V : M → R is lifted to a function from TM into R in the obvious way).
-----------

Now, to me, the idea of kinetic energy being a "metric" makes sense since it is (typically? always?) a quadratic function of the coordinates, just like the (square) of the distance between two points in Euclidean space. So, is that all energy is - a length in some space? The rest of the terms used here don't quite make sense to me yet, and I don't think they're defined in this book (at least not in the pages prior to page 19). Do you think this line of attack makes any sense? If so, do you know of any good references that will explain some of these terms (manifold, tangent bundle, etc.?)

- Roy
 
  • #33
Gerenuk said:
And I've explained it a couple of times: a mathematician knows that if he sees a gradient, he wants to dot it and integrate. That's a very good reason to do that.

Gerenuk,

I don't dispute that the dot product makes sense from a mathematical standpoint. I would have thought it was obvious from what I had posted several times now, but my intended audience is not mathematicians, physicists nor engineers.

- Roy
 
  • #34
RoyLB said:
[...]
Now, to me, the idea of kinetic energy being a "metric" makes sense since it is (typically? always?) a quadratic function of the coordinates, just like the (square) of the distance between two points in Euclidean space.
[...]

Well, angular momentum [tex] m r^2 \omega [/tex] is a quadratic function of 'r', but there does not seem to be a way of interpreting that as akin to a metric.
I agree that interpreting kinetic energy as related to a metric is tempting, but I think it's a dead end.The challenge is, I suppose, to capture in words the most general sense of the concept of Energy.

It appears that materials have a state of zero energy, and that energy is accumulated when the material is pushed away from this ground state.

When an elastic material is deformed it stores energy, which is released when the material relaxes again. In elastic deformation the molecules of the material do not slide along each other (when they do slide you have plastic deformation, which dissipates energy). In the case of elastic deformation you are deforming the very molecules away from their ground state.

In a molecular bond there is a distance between the atoms that is the state of least energy. I suppose the most fundamental level of description we currently have is the following: given the quantum physics of molecular orbitals there is a state (of the molecule) that is the most probable. When a molecule is deformed away from that most probable state then it tends to return to the most probable state.

Another aspect: is it possible to view gravitational potential energy as a deformation away from a state of lowest energy? I think so. According to GR gravitational interaction is mediated by deformation of spacetime. (In other words: spacetime curvature acts as mediator of gravitational interaction.) I infer that when two objects are pulled apart then there is a net increase in spacetime deformation.

Finally, kinetic energy.
When two objects have a velocity relative to each other then that two-object system has the potential to do work.
Example, a electric car that is designed for regenerative braking. When the car and the Earth have a velocity relative to each other then regenerative braking will recharge the batteries. The state of lowest energy is where the two objects have no relative velocity.

So in all I like to think of the relative velocity of the two objects in a two-object system as a form of potential energy.
I don't so much think of the quadratic form, I think of the potential to do work, expressed as force acting over a certain distance.
What is special of course is that in the case of kinetic energy this potential is realized only at the very instant in time that the two objects actually interact. When two objects interact with each other, and not with other surrounding objects (as in a collision) then they are in effect a two-object system.
 
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  • #35
RoyLB said:
[...]
I realized that I was unable to bridge the gap in a satisfactory way between F=ma and W=Fd or T=1/2mv^2.
[...]

Hi Roy,

I believe I did the very thing you requested: I bridged from F=ma to W=Fd, using just d=1/2*a*t2 and v=a*t. That was in https://www.physicsforums.com/showpost.php?p=2711586&postcount=24". I'm very curious what you think about that demonstration.

Cleonis
 
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<h2>1. What is the concept of energy in classical mechanics?</h2><p>The concept of energy in classical mechanics refers to the ability of a physical system to do work. It is a scalar quantity that is conserved, meaning it cannot be created or destroyed, but can be transferred or transformed into different forms.</p><h2>2. How is energy defined in classical mechanics?</h2><p>In classical mechanics, energy is defined as the sum of kinetic energy and potential energy. Kinetic energy is the energy an object possesses due to its motion, while potential energy is the energy an object possesses due to its position or state.</p><h2>3. What is the equation for calculating energy in classical mechanics?</h2><p>The equation for calculating energy in classical mechanics is E = K + U, where E is the total energy, K is the kinetic energy, and U is the potential energy. This equation is known as the Law of Conservation of Energy.</p><h2>4. How is energy transferred in classical mechanics?</h2><p>In classical mechanics, energy can be transferred through work, which is the product of force and displacement. When a force is applied to an object, work is done and energy is transferred to the object. Additionally, energy can also be transferred through heat and other forms of energy conversion.</p><h2>5. How does the concept of energy relate to the laws of motion in classical mechanics?</h2><p>The concept of energy is closely related to the laws of motion in classical mechanics. The First Law of Motion states that an object will remain at rest or in motion with constant velocity unless acted upon by a net external force. This means that energy must be transferred to change the motion of an object. The Second Law of Motion relates the net force acting on an object to its acceleration, which in turn affects its kinetic energy. The Third Law of Motion states that for every action, there is an equal and opposite reaction, which also involves the transfer of energy.</p>

1. What is the concept of energy in classical mechanics?

The concept of energy in classical mechanics refers to the ability of a physical system to do work. It is a scalar quantity that is conserved, meaning it cannot be created or destroyed, but can be transferred or transformed into different forms.

2. How is energy defined in classical mechanics?

In classical mechanics, energy is defined as the sum of kinetic energy and potential energy. Kinetic energy is the energy an object possesses due to its motion, while potential energy is the energy an object possesses due to its position or state.

3. What is the equation for calculating energy in classical mechanics?

The equation for calculating energy in classical mechanics is E = K + U, where E is the total energy, K is the kinetic energy, and U is the potential energy. This equation is known as the Law of Conservation of Energy.

4. How is energy transferred in classical mechanics?

In classical mechanics, energy can be transferred through work, which is the product of force and displacement. When a force is applied to an object, work is done and energy is transferred to the object. Additionally, energy can also be transferred through heat and other forms of energy conversion.

5. How does the concept of energy relate to the laws of motion in classical mechanics?

The concept of energy is closely related to the laws of motion in classical mechanics. The First Law of Motion states that an object will remain at rest or in motion with constant velocity unless acted upon by a net external force. This means that energy must be transferred to change the motion of an object. The Second Law of Motion relates the net force acting on an object to its acceleration, which in turn affects its kinetic energy. The Third Law of Motion states that for every action, there is an equal and opposite reaction, which also involves the transfer of energy.

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