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Are there any ways of justifying Lagrangian mechanics as a foundation of classical physics, without referring to Newtonian mechanics? In other words, what is the deeper reason or intuition why $$\int_{t_0}^{t_1} T-V$$ must be minimal, beyond the fact that the equations it generates agree with Newtonian mechanics? Is there no deeper reason?

All the resources I've seen (class I took years ago, books, wikipedia, random pdfs) make essentially the same chain of reasoning: $$\substack{\text{observation}\\ \text{intuition}\\ \text{physical principles} } \implies \text{Newtonian mechanics} \Longleftrightarrow \text{Lagrangian mechanics}$$

This question is basically whether the chain of reasoning be swapped, as follows: $$\substack{\text{observation}\\ \text{intuition}\\ \text{physical principles} } \overset{?}{\Longrightarrow} \text{Lagrangian mechanics} \Longleftrightarrow \text{Newtonian mechanics}$$

Nick Alger
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    Intuition??? Intuition has nothing to do with scientific theories, it's ALL about the data. Does Lagrangian mechanics agree with all the data it is supposed to cover? Yes. Does Newtonian mechanics agree with the data that it needs to cover? Yes. Can Newtonian mechanics be derived from Lagrange? Yes, as far as conservative forces are concerned. Non-conservative forces are a kludge on top of either theory, anyway. The major difference is that Lagrange offers a much wider range of physical applications then Newton because the formalism extends into relativity and quantum mechanics. – CuriousOne May 18 '15 at 06:54
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    For the equivalence between Newtonian mechanics and Lagrangian mechanics, see e.g. http://physics.stackexchange.com/q/78138/2451 – Qmechanic May 18 '15 at 07:11
  • @DanielSank: It's not completely obvious where the scientific method takes the hardest hit, is it in the mind of the student or layman or is it in the way science gets presented in the media and in some of the books written by physicists? Sometimes "intuition" indeed seems to be more important than data, which is easy enough to believe... until one takes a look at the primary literature, that is. – CuriousOne May 18 '15 at 07:23
  • I'm being pedantic but the lagrangian does not always equal $T - U$, see the electromagnetic lagrangian – CStarAlgebra May 18 '15 at 14:40
  • @NoahSteinberg Of course. Good point. – DanielSank May 18 '15 at 15:18
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    I think that @CuriousOne's point is one that should be emphasized over and over and over again (three times just for Daniel's benefit, natch): that giving the right answer plus a degree of parsimony is all the justification that a scientific theory needs. Ever. At all. And while the OP may not be confused about that the current state of the title is just dreadful. – dmckee --- ex-moderator kitten May 18 '15 at 15:49
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    Can we please use these comments for a discussion of this question, rather than a general debate about the philosophy of science? – Nick Alger May 18 '15 at 21:40
  • Hello. I don't know if this is relevant to your question, but some while ago I was wondering if we can define the kinetic energy without the law of Newton. It seems to me that the definition of the kinetic energy as $T={1 \over 2}mu^2 $ comes from newtonian mechanics into lagrangian mechanics. But maybe I'm wrong, I'm still thinking it, but the thought seems to me correct. – Constantine Black May 22 '15 at 15:40
  • Are you still looking for something more than what's already been described in the answers? – DanielSank May 22 '15 at 17:19
  • @DanielSank NeuroFuzzy's comment is the answer that I was looking for, but it is a comment so I can't accept it. I appreciate your answer and comments as well, but it's not quite what I was looking for. – Nick Alger May 22 '15 at 21:04
  • The same argument can be made for Newton's laws. It's true that I can guess Lagrangians from symmetry principles, but I can also guess forces from the same principles. Of course, the Lagrangian is more general in the sense that it works for more kinds of symmetry, such as Lortentz invariance. – DanielSank May 23 '15 at 16:48
  • Also, see edit to my answer. – DanielSank May 23 '15 at 16:54

3 Answers3

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Since the Lagrangian results in exactly the same equations of motion as Newton's laws, I'd say that based on their agreement with experiment both are on equal footing.

Of course, to get the right equations of motion from Lagrange's equation you have to pick the right Lagrangian, so then you ask how we systematically pick the right Lagrangian. The recipe in mechanics is $$\mathcal{L} \equiv T -U \, ,$$ so then you ask how we systematically find $T$ and $U$. From a purely theoretical perspective, finding $T$ and $U$ is on the same level as picking the forms of various forces used in Newton's law. The practical difference is that force can be defined in a way that relates it to simple experiments, so pedagogically we start with force.

The question specifically asks if observation, intuition, and physical principles naturally lead to the Lagrangian formulation. One perspective is that the principle of least action is the phsyical principle of the universe, so from that perspective the answer is "yes".

I wouldn't say intuition leads to the Lagrangian formulation, but I also wouldn't say that intuition leads to Newton's law. It is quite mind-bending when we first learn that an object uninterrupted by external forces moves at constant velocity. This is unsurprising given how long it took humanity to figure that out!

What about observation? Certainly the right observations lead naturally to Newton's law. Put a feather on top of a book and drop them and you'll see the feather fall just as fast as the book. Push harder on a cart and it speeds up faster. The Lagrangian formulation doesn't arise from every-day observations like those.

Still, in the end the Lagrangian formulation definitely can come before Newton's laws. There's nothing more arbitrary or unfounded in dictating the forms of $T$ and $U$ for various systems than there is in dictating the form of $F$ in those same systems, so the answer to the main question of whether the Lagrangian can be developed without talking about Newton's laws is a definite "yes". Pick any physical system and we most certainly can describe and analyze it with the principle of least action without ever talking about force or Newton's laws. In fact, there are lots of non-mechanical systems where Newton's laws don't work at all but the principle of least action works amazingly well (e.g. spin, circuits).

Summary: Dictating that physical systems minimize $\int T-U\,dt$ and dictating how write down $T$ and $U$ for each type of system is no more arbitrary than dictating that physical systems obey $F=ma$ and dictating how to write down $F$ for each type of system.

EDIT: As mentioned in the comments, it is possible (and typical in some settings) to guess the form of a Lagrangian for a system based almost entirely from symmetry principles. This works even for things like Lortentz invariance; you can derive Maxwell's equations from Lorentz invariance, conservation of charge, and some assumptions about the structure of space-time. This makes the Lagrangian arguably more general than Newton's laws. That said, it's also possible to guess the form of the Forces for a system from the same symmetry principles, so it's not always really true that the Lagrangian is really more fundamental.

DanielSank
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    It might also be worth mentioning what L&L do in the first book. IIRC they get pretty far just assuming the eqs of motion stem from an action principle & respect galilean invariance. –  May 18 '15 at 07:23
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    @NeuroFuzzy: I would give Landau and Lifshitz even more credit than that. Volume I is a beautiful example of scientific writing that summarizes the easily hidden assumptions behind classical physics along the way of its crystal clear mathematical deduction of Newtonian mechanics from an action principle. One can, of course, argue about its pedagogic value for students who don't know its contents in and out, already. – CuriousOne May 18 '15 at 07:29
  • @NeuroFuzzy I had trouble keeping my answer focused on what is actually asked in OP. Your point is well received; if you can work it into the answer without sacrificing clarity and focus, please make full use of the edit button :-) – DanielSank May 18 '15 at 08:18
  • @NeoruFuzzy If it's true, that is exactly the sort of thing I'm looking for (action principle + galilean invariance -> lagrangian mechanics). Would you be willing to write it up in an answer? – Nick Alger May 18 '15 at 17:56
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    @NickAlger if that's what you're looking for then the answer is a resounding "Yes!". You can write down Lagrangians based almost entirely on symmetry principles (i.e. invariance). From there you get equations of motion and everything is hunky-dory. – DanielSank May 18 '15 at 19:54
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With a strong grasp of Lie Algebra and Calculus of variations, "Invariante Variationsprobleme" should provide all the foundation one needs to build Newtonian Mechanics (and so much more). The deeper reason that we use either of these formalism is that they agree with experiment; that either formalism predicts the other is far less valuable than that they predict experimental outcomes.

From an intuition perspective, if you assume that the laws of physics must be the same at any given place, speed, orientation, etc..., you could 'derive' Lagrangian mechanics, but you'd need access to much higher mathematics than simply moving through the 'standard' physics track.

user121330
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Can Lagrangian Mechanics be justified without referring back to Newtonian Mechanics?

Sure; one can deduce Newtons Laws from it.

The question is should one?

By deducing Newtons Laws one is missing the crucial aspect of induction; the reverse procedure and in a sense more difficult; that is the discovery and invention of a theory that covers a wider range of phenomena.

The concepts that go into Lagrangian Mechanics are those that first appeared in an exact form in Newtonian Mechanics.

Mozibur Ullah
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