Hi everyone, thanks so much for your support! If you'd like to check out more Physics videos, here's one explaining the First Law of Thermodynamics: kzbin.info/www/bejne/aYKmiYmBis5qgZo Edit: to answer a question I've seen a few times now, the "q" in the Euler-Lagrange equation can be thought of as a generalised coordinate. So in this instance, we replace q with x, and q(dot) with x(dot). In a system showing motion in multiple different directions, we would get multiple equations for each of the relevant coordinates. So for example a system varying in both the x and y directions, would give us an equation with x and x(dot) in it, as well as another equation with y and y(dot) in it.

An even more interesting conversation is why this popped up in my recommended

Everybody gangsta until friction comes around

Parth Congratulations, your video has been added to MIT open Courser ware along with Walter Lewin lectures

Having studied this intimately in grad school, and applied the principles in my M.Sc. thesis, I find your explanation clear and concise. Well done!

I remember how amazed I was at how usefull Lagrangian mechanics are dealing with complicated mechanics problems, when I learnt about them.

This brings me back 50 years ago when first being introduced to the subject and walking back to the dorm knowing I must be the dumbest guy in the world. Thanks for bringing me back to those memories.

And there is our Andrew Dotson who solves Projectile motion with Lagrangian formalism.

This is what a master looks like when explaining something. Took you 10 minutes to explain what my professors took hours.

I came here from Walter Lewins playlist of classical mechanics . Your video was added in that playlist

Something really important to keep in mind with regards to Euler-Lagrange equation: partial derivative and derivative are not the same thing! In many places partial derivatives behave as they were plain derivatives but in E-L there is a good chance they do not!

I like the style of the video and the explanations. There's a rather relevant point missing around 5:55 : q and q-dot in L stand for generalized coordinates and their derivatives, and for the srping-mass system we chose q = x. This can also help emphasize the importance of point (3) around 7:40.

Where have u been for these many days, bro ur videos are a nerd's dream come true.

currently in a robotics major and lagrangian mechanics is probably the coolest thing i have learned

Last week, I got my M.Sc in physics. I wonder why I'm here after all the hard work :D Great content btw.

Surely this is one of the best explanations of the Lagrangian on KZbin. Although it’s not detailed it’s it’s coherent and it’s a great overview of what is really going on. I’ve tried for years to understand it now I feel like I’m actually getting it. Thank you!

The depth of content is so well-balanced for such a short video, really enjoyed it!

Sometimes KZbin's algorithms recommend videos from content creators that are actually quite good, such as this one by Parth G. Quick and concise , highlighting the most important questions that a student might ask, without dumbing anything down. Right up my alley, Mr. G.

Waited so long for this one! Can you do some problems from Lagrangian Mechanics?

I find it fascinating that although the L doesn't represent anything physical - at least not obviously so - it sort of hints at a much deeper underlying structure to what we perceive and analyse. Brilliant video Parth. Thanks for your work.

8:03 The blue and orange lamps in the back are a vibe

Another gem found in youtube.

Popped up in my recommendation and changed my life..thank you yt!

You have explained this very well, I understood it without having had very advanced calculus, only integration and derivatives. So good job!

Wow being an msc student this is easily the best introductory explanation i have heard . Keep going forward u r a great teacher 👍

Ayyyy! Thank for your video, man! Watched few videos about Langranian Mechanics every each of them gives different view of it. Thank you

This is more complex but much more efficient than the simple thing we've learned!

I would add that the Lagrangian really shines when you're dealing with a problem with constraints. For example, a particle constrained to ride along a curved track (like a rollercoaster). Or the double pendulum (one pendulum hanging from another), in which the coordinate of the bottom pendulum bob depends on the position of the upper one. In these sorts of problems, Newtonian mechanics gets bogged down in dealing with coordinate changes and interdependences, and also dealing with which forces are "constraint forces" like normal forces and tension which hold the particle(s) to travel along the allowed path. But the Lagrangian is much simpler to write down in both cases (since it only depends on the magnitudes of the velocities - directions don't matter! - and whatever functional dependence the potential energy has on position).

"...an ideal system" me: wait that's not a spherical cow?

Id like to add, 1:15 "The Lagrangian is indeed defined as the kinetic energy minus potential energy" This isn't actually true General Definition of a Lagrangian For a given mechanical system with generalized coordinates q=q(q1,q2,...qn), a Lagrangian L is a function L(q1,...,qn,q1(dot),...,qn(dot),t) of the coordinates and velocities, such that the correct equations of motion for the system are the Lagrange equations dL/dqi = d/dt(dL/dqi(dot)) for [i=1,...,n] This definition is given in Classical Mechanics by John R. Taylor page 272. Notice that it does NOT define a unique Lagrangian. Of course the definition provided in this video for this case fits this definition, and for most cases T-V will satisfy this definition. The video may have been hinting at this for point number 2 but something I would also like to add is that one of the advantages of this REformulation of Newtonian mechanics is that it can bypass constraining forces. For example consider a block on a table connected by an inextensible rope and pulley to a block hanging over the edge of the table. To work out the equation of motion using Newtonian mechanics you'd have to consider the tension in the rope while looking at the forces on the individual blocks, and that is a constraining force. As for lagrangian mechanics you don't. Which as an aside means qualitatively you'd be missing out on the physics of the problem ( and other problems) so if you've already learned how to do this problem using Newtonian mechanics then by all means use Lagrangian mechanics. You can of course apply Lagrange multipliers to find the constraining force if you want but then you'd need to include a constraint equation. 1:38 The Hamiltonian is defined by that IF you have time independence it is NOT in general defined that way. As for deriving Lagranian mechanics, incase anyone is interested where this comes from, here are two ways you can do this. First is the 'differential method' of D'Alembert's principle where the principle of virtual work is used. the second would be an 'integral method' whereby you look at various line integrals. Lastly, some further reading if you're interested I don't talk about it in my comment however this is a crucial concept. The principle of stationary action. en.wikipedia.org/wiki/Principle_of_least_action For more on Lagrange mulitpliers see page 275 of Classical Mechanics by John R. Taylor "D'Alembert's principle where the principle of virtual work is used" One resource for this would be page 16 Classical Mechanics Third Edition by Goldstein, Poole & Safko This is a more advanced textbook though. 3:52 As a side point, I'd just like to also point out that the dot notation is not specifically for time derivative and its a notation that you might want defined before hand. For example, see page 36 Classical Mechanics Third Edition by Goldstein, Poole & Safko, being used to mean dy/dx=y(dot). dL/dqi - Generalized force dL/dqi(dot) - Generalized momentum q - Generalized coordinates q(dot) - generalized velocity Overall an excellent video

This video really helped push back my ignorance - mainly to show there is so much more I am ignorant of than I realised. A great video that helped make complex concepts approachable.

Great job! I am going to share this channel with all the college students. It took me weeks to get started with Lagrangian mechanics (a few decades ago). I wish we had an introduction like this. In a multibody connected dynamic system, e.g. Robots, machines, mechanisms, etc. if one starts with Newtonian formulations, many unknown joint/contact forces appear in the equations and it becomes difficult to solve for the motion. If one uses Euler-Lagrangian equation, it is much easier to solve for the motion.

Humble request need a video on symmetry of space and time and how it leads to conservation laws.

This is so absolutely mind-blowing and well explained. This is incredibly well explained! Bravo. Thanks for sharing this with us.

Congratulations on the clarity of your presentation! You have natural teaching skills.

You nailed it, you delivered exactly what I was looking for. If all your videos get to the point and are as clear as this one, I have here plenty of things to enjoy.

Glorious explanation. I can only dream of having professors this effective at my uni...

Really enjoyed this video, thanks Parth! I'd always heard of Lagrangians and Hamiltonians in the context of QM but never got around to learning what they actually represent. Your explanation and example definitely helped me get a better understanding of the concepts: a nonphysical but useful mathematical tool and the total energy of a system. I was exited to hear Noether's Theorem is based upon Lagrangians, too. I really wish more people knew of the brilliance of Emmy Noether, so I'm glad this may have introduced some to her work and name for the first time. If you've not already seen it, I really enjoy this message Einstein wrote to Hilbert upon receiving her work: Yesterday I received from Miss Noether a very interesting paper on invariants. I'm impressed that such things can be understood in such a general way. The old guard at Göttingen should take some lessons from Miss Noether! She seems to know her stuff.

L=T-U can be derived from D'Alembert's principle of virtual displacement or virtual work. Concerning the Euler-Lagrange equations, this is only applicable to systems where FRICTION is NOT involved. If there are systems with FRICTION then you have to add the Rayleigh dissipation function to the E-L equations.

Great video. I want to point out that definition of 'q' and 'q dot' is missing in the Euler-Lagrange equation. These are placeholders for 'position' and 'momentum' respectively for those wondering.

Great video for those who wish to have a primer/overview on Lagrangian mechanics! However, I would note that the title is a bit off. Lacking the appropriate context, saying LM is better than NM is short sighted. Don't get me wrong, having learned the topic myself in Uni I was wide-eyed in disbelief why this wasn't taught to me sooner. You alluded to the reason in your video so much props, and that is variational calculus. From a pedagogical standpoint, most people a physics professor will teach will be non-physics students. Newtonian mechanics can be summed up fairly "easily" with algebraic techniques (the much maligned Algebraic Physics), and extended quite significantly with the addition of basic uni-variate calculus (F = dp/dt for example). With these relatively low level mathematical techniques, one can solve a wide variety of problems, even challenging ones. Contrast this with the workhorse of LM, the E-L equation. Right out of the gates, we have partial derivatives (multivariate calculus), and, in the gorier forms, with respect to the "generalized coordinates" and "generalized momenta." This of course opens up the universe of possibilities to doing calculus on potentially horrendous coordinate systems (chaos/multi pendulum as a simple example), but hardly the highest priority for people who don't plan on doing physics in their eventual career. Needless to say, the mathematical overhead required to explain why this machinery works, is no trivial matter. Minimization of integrands, finding the variation about fixed points are fairly high level concepts that involve a pretty broad understanding of the topic of calculus. Usually this FOLLOWS a course in Real or even Complex Analysis. Maths majors know this isn't for the faint of heart. All this being said, which is better LM or NM? That is like asking which is better, a spoon fed GUI that allows point and click, or a command-line interface which a litany of abstract and esoteric commands. Better how? The GUI allows a much broader swath of the population access to the power of the computer, whereas the pro's find the command-line much more efficient and powerful (though not all and preference does play a role, imperfect analogy being what it is). LM is definitely more powerful, as the number of systems which can be analyzed drastically increases over NM. However NM has great utility in the problem solving domain, still even for pros, but has significantly less overhead for all your typical/simple problems. Generally it doesn't usually even come up until you have gone through a process of ever increasing difficulty culminating in, from my anecdotal experience, moving reference frames where the simple F=ma gives way to all sorts of additional "imaginary forces" that come about from the rotation, for instance, of a reference frame. This is where the topic can be introduced as a way to short circuit the otherwise gory mess of equations you would end up with using simple NM. Just my two cents. All this being said though, still like the video only had an issue with the title. Keep spreading the word and your passion for physics!

Thank you for this video. Bringing in the Hamiltonian explanation helps forming the picture in my "trying to catch up" head.

I agree that Lagrangian mechanics is great, especially if you are dealing with systems consisting of many variables. But what Newtons formulation handles way better is friction, just add a model of friction (eg. -v or -v^2), doing this with lagrangians is an absolute pain.

No matter what you do Newtonian mechanics is ever green as the basic of modern physics comes from his

Excellent video. Very interesting, informative and worthwhile video. Parth is a brilliant explainer.

Great video. One of my favourite modules in my physics degree. It's so refreshing after years of writing F=ma that they turn round to you in second year of uni and say 'well actually there's a better way'

sir you said that lagrangian doesn't have a physical significance but can we say it is just the excess amount of energy within the system to perform work , synonymous to the concept of gibbs free energy in thermodynamics .....

As a mathematician and a image processing specialist, Euler Lagrange equation is very important in minimazing energy functionals

Wow!! You explained it in the simplest way!! Hats off, man

This is very interesting, but I long for the hour long video that actually makes the case posed by the title instead of acting as an introduction so that a person could understand the title.

It really depends on the scenario. They're certain times when thinking of stuff vectorally allows you to make quick approximations

Lovely! Lovely!! Very well explained, Parth. I'd studied this long ago and was trying to recall what the Lagrangian was all about, and you explained it so well. Thank you!!

At 6:51 the term on left side is not the total force on the system but describes the acceleration of the system. In other words, it is Newton's Second law which relates acceleration to the total force on the system which appears on the right hand side. That was a great journey. Thank you

Parth,where would I be without you!

There is a very beautiful connection between the "physical properties" and the Lagrangian. By performing a Legendre Transform from the variable "velocity" to its slope, called momentum p, we get the symmetry condition of the Legendre transform as \dot q = \dfrac{\partial H}{\partial p} just as the original defintion of the canonical momentum reads p := \dfrac{\partial L}{\partial \dot q}. Now comes the breakthough: With this "second" equation we can write the total time evolution of the Hamiltonian as \dot H = \dfrac{\partial H}{\partial t}+\dfrac{\partial H}{\partial q}\dot q+\dfrac{\partial H}{\partial p}\dot p and take the transformed Version of the Euler-Lagrange-equation of motion for \dot p and the Legendre-Transform for \dot q and have a closed form where q, p and t are the only variables, and even more: They appear in an anti-symmetric ararrangeemnt, commonly denoted by Poissons' bracket, a special case of the Lie-brackets (commutator of two operators) commonly used in Quantum mechanics. The point is: You cannot achieve this anti-symmetric closed arrangement with the Lagangian as by the very same calculus \dot L = \dfrac{\partial L}{\partial t}+\dfrac{\partial L}{\partial q}\dot q+\dfrac{\partial L}{\partial \dot q}\ddot q and the acceleration \ddot q does not appear in the general Euler-Lagrange equation (just take any coordinate frame other than carthesian and you will see that the acceleration in a coordinate is not necessarily easily extracted/isolated), so the only meaningful way we can make predictions on the time evolution of the Lagrangian (and therfore its physical meaning) is by using the Legendre Transform again, writing L = H - \dot q p and reasoning \dot L = \dfrac{\partial L}{\partial t} + \{H,\dot q p\}. In general, this is not an easy thing to do, but if 1) time symmetry holds and 2) the momentum is linear in velocity with some constant term p=\dot q/a, then the Lagrangian (plus a constant) is simply int \dot L dt = \int \{H,\dot q p\} dt = \int \{H, a p\} p + \{H, p\}\dot q dt = \int (a*\dot p+\dot p)\dot q dt which is, if you squint you eyes, the total change in momentum, called a force, integrated over a path of motion ds = \dot q dt, which is the classical Newtonian definition of Work. The classical Lagrangian is a multiple of the total work done in a physical process, and the principle of least action states that the total amount of work done within a certain time frame must be extreme (mostly minimized). There you go, classical mechanics is really just "The universe is lazy". And also, most of the facy commutators of quantum operators you learn in QM can be solved by calculating corresponting Poisson brackets; the underlying anti-symmetry of its arguments is transferred from one theory to the other, or as we call it: Algebra remains. :) ps sorry for typos :/

It is a real skill morphing the complicated into the comprehensible.

Nice introduction to LM ... An important point which was overlooked is the way in which LM can incorporate generalized forces (which would appear as extra terms in the E-L equation). Such forces must be taken into account when some physical forces acting on the system are not conservative (and therefore not expressible via potential energy). Such forces also are especially convenient/useful for assessing relevant constraint forces.

Excellent presentation and explanation. I have read and listened to number of presentations by others but none as understandable as yours. Thank you and keep it up.

I don't know about better, but an additional viewpoint is almost always informative. And yes, scalar quantities like energy are simpler than vectors. But it's also interesting to think directly in terms of forces, even though it's messier, and perhaps more error prone. On the other hand, one could argue that Hamilton's principle, or least action principles in general, are "best" in the sense of elegance and simplicity. Ultimately though, Feynman told us that it's useful (and interesting) to have a variety of different mathematical formulations available for any given theory. Maybe that is the approach that is "better."

Deriving the equations of motion for a double pendulum from a Lagrangian and Newtonian perspective is enlightening: it's pretty straight-forward from a Lagrangian perspective, but more challenging from a Newtonian perspective.

Squiggly L and H are usually used for Lagrangian and Hamiltonian densities which are slightly different from Lagrangians and Hamiltonians.

great content! simple and knowledgable! :)

It was amazing , thanks KZbin for recommending such an astonishing video 🙃

Very nice explanation. I do find it interesting that you stress so often that the Lagrangian isn't a physical quantity but rather a mathematically useful quantity when that is equally true of energy as well. We typically say that things 'have' energy, but energy is just as much a mathematically constructed quantity as the Lagrangian, useful only for its apparent conservation. Like the Lagrangian, energy cannot be measured; only calculated.

Hi Parth. I just found your channel and watched this very informative video on Lagrangian Mechanics. I dig your approach to physics and have just subscribed! I'm trying to catch up on math and physics since I'm now retired. I look forward to learning from you!

Great video sir I just completed my course in classical mechanics but Lagrangian and Hamiltonian mechanics were not included.. Now I will learn this from u❤️

For larger rigid body systems, iterative newtonian methods are actually numerically "BETTER" (require less computational time)

I look forward to learning more about lagrangian mechanics with you sir

Man your videos are good.. Keep up the good work👍🏻

Didn't understand a thing he said, but I'm still transfixed like a deer in headlights ... Here, take my money ... like taking all the potential from my kinetic ... and I'm wobbling my head up and down like the doll on the dashboard!!!

I enjoyed your video very much. You're concise and clear, and filter out irrelevant mathematical complexity to make an important point. Fantastic.

wow...just derived and used it ,,few days ago in the exam..❤️

Oh yes! this channel is a great find. Can't wait to see the video on Noether's theorem!

Fantastic video, really interesting because as an alevel physics student have never dealt with lagrangian only newtonian mechanical physics. Also, you have incredible head hair sir!

Great video! By the way, often the “curly” L represents the so called “density of Lagrangian” which is Lagrangian per unit of volume. The Lagrangian itself is represented by the capital L. Just a tiny detail!

Pure brilliance in your explanation.

It is probably understood, but just to state it explicitly, Lagrangian Mechanics and its successor, Hamiltonian Mechanics are both directly derived from principles of Newtonian Mechanics. For anyone interested in the details of this derivation, I recommend *Goldstein, “Classical Mechanics”, 3rd edition* (or the older 2nd edition) published by Addison Wesley. In the first chapter, sections 1-3 give a crash-course basic Newtonian Mechanics (this is only for those already reasonably versed in Newtonian Mechanics as a brief refresher). Sections 4-6 derive Lagrangian Mechanics starting from D'Alembert's Principle in section 4. Chapter 2 introduces Variational Calculus or Hamilton's Principle applied to the Lagrangian. For the more advanced curiosities among us, Hamiltonian Mechanics is introduced in chapters 8-10, Classical Chaos in chapter 11, and the foundations of Field Theory (including Noether's Theorem) in chapter 12.

this is the first video of you I saw, And your channel just got a new subscriber

Really great video!! 👏👏👏 You have the gift of communication.

Luv the way you tought sir .......extremely impressive .......if a person luv physics, then they surely start liking you to fr ur creative teaching😊 thnkuuu

Great Explanation. The point is you kept everything simple while still useful and let us see its potential, definitely subcribed

This was the best physics video I've watched in a while. Great video Parth

Just started learning about Lagrangian mechanics in my Mechanics I class... Really cool stuff! Great video :)

Hey parth Walter Lewin put your this video in his 8.01 playlist

Dealing with energies is much more easier than dealing with forces as force is a vector quantity ( it needs to be added using vector algebra) where as energy is a scalar one ( so we can get rid of the annoying vector algebra). That's why Lagrangian mechanics is more convenient than Newtonian one.

Very clear introduction ! Could you do the same for hamiltonians as they look so similar ?

Awesome! I learned that the Hamiltonian is the sum of KE and PE, I got more xposure to dot notation, and I should go back and rewatch the derivation of F = -kx. A question: why is "the difference between KE and PE" not physical? The difference between its actual energy and what it can do? I like my math to be physical

Just make it a goddam 40 min long video ill watch it in one go because of how interesting you made it

Nailed it, Langrangian way to go as an investigative math tool, hope to see more how does it unravel more 🤔:)

Marvellous! Now I want more details!

First time I've seen any of your videos Parth, and it's a straight up subscribe for me. I like people who can "really" explain, and enjoy what they do

In my view the lagrangian 'kind of' has a physical meaning. Its not anything formal, but T-V represents a desequilibrium, or difference, of the system. If T>V the lagrangian points towards a system that aims at increasing the potential energy and lower the kinetic energy, and viceversa.

Man, you look like a very empathic, spiritual and warm person, and the info you share are so well structured. It is good i found your chanel.

I really enjoy your content. I'm hoping to study Physics at a higher level and I find your videos useful 🙂

Subscribed! Amazing video, man.

Great presentation, everything is clear and elegant and surprising!

Parth G, Thank you so much for this wonderful video! Please make a series on Calculus of Variations.

In true internet fashion, I only clicked on this because I agree with the title.

I was right with you up to, "Now many of you have asked me to discuss............".

5:52 This a simple second order differential equation with solutions of either sine, cosine, or an exponential (power of e). This results in a cyclic sine or cosine curve (depending on where you place the origin) when position is graphed as a function of time. The fact that the acceleration has sign opposite to position makes this a restoring force, i.e., motion is constrained within boundaries.