I am so much amazed how excited you are teaching this theorem. Wished to have teachers like you at uni too.

Every math teacher feels it is his duty to say that he is not a fancy artist or so when he draws some kind of diagram

These lectures are fantastic, thank you for taking the time to produce and share them for free.

At 20:25 Steve oversimplified by moving the time derivative inside the volume integral just like that. It can only be done if the volume being integrated wont change over time, invalid assumption in fluid dynamics. Taking this into account leads us to another beautiful theorem called Reynolds Transport Theorem (RTT), which interestingly naturally leads to the right-hand-side on Steve’s board (if F is a velocity field).

> I see a new video has been posted >> I put "like" >>> I watch the video

Outstanding lecture, professor. Defining first in words, providing an intuition and then releasing the math! Shock and Awe. Anyone can deliver the symbols. Gifted educators deliver intuition and genuine understanding.

There is something I seriously don't see starting at 10:00 to about 13:30 when talking about the little boxes filling the volume. The claim is that with an interior filled with boxes with positive divergences, only the boxes on the surface contribute to the surface integral, with the internal ones cancelling along their apposing surfaces with other adjacent boxes. This can't be true; here are two lines of reasoning which, for the sake of the first argument assume a constant, positive, divergence throughout the volume. One: Compare two cases that have the same surface, but different volumes. The integral of the divergence over the volume is proportional to the volume, but the surface integral of the flux would not increase to match if there was a cancellation of the field F at the apposing adjacent surfaces of the interior boxes. Two: Since the integrals are linear, the surface integral flux for a volume with a single box with positive divergence must be half of that with two interior boxes with the same positive divergence. But if they are adjacent, and something cancelled, it wouldn't be. I'm thinking of this a la Gauss's law for the electrical field at the surface as proportional to the enclosed charge. Am I missing something??

Watching this video, I remembered being totally fascinated (for the first time in my life) by theoretical electrical theory. Thanks for the passion you bring presenting this math.

This is a treasure worth 1M views. I learnt this in my college days. Understood 15 years later.

Before this I had no idea fluid mechanics can be so intuitive and interesting. Great work sir, Thank you so much for your effort.

Very excited to watch every update on this series！

ನಿಮಗೆ ಅನಂತ ಧನ್ಯವಾದಗಳು... ಗುರುಗಳೇ ಇದೊಂದು ಅದ್ಭುತ ಪ್ರದರ್ಶನ

just came here to say that while i'm currently not watching most of your videos as you upload them, i'm still very thankful because i'm 99% certain that i'll need them again at some point in the future

Great video. Excellent for showing the intuition of the volume built as a union of smaller volumes, for divergence theorem. Just few comments: - Divergence Thm has some assumptions. Broadly speaking, everything inside of the statement of the theorem must be meaningful, as an example if you write a divergence of F, that function F must be regular enough (differentiable) for the divergence to exist; REMEMBER that PDEs of Physics translate into "regular enough local regions" all the general Principles of Physics holding for all the physical systems, differentiable or not; - Mass equation example: > when you put time derivative inside the volume integral, you're doing right only if that volume does not change in time (i.e. you're implicitly considering a fixed control volume, otherwise that manipulation is WRONG). Anyway the conclusion you reach is right, but your derivation only holds for a steady volume for integration. Integral laws and then differential laws can be easily translated from the very statement of the Physical Principles if you firs consider Lagrangian volumes (i.e. those volumes moving with the continuum), and then transformed to fixed control volumes (some math required) > maybe I missed that, but the physical meaning of F is not explicit here. In order to have the right physical dimension, it must have the dimension of a velocity. Indeed, it is the velocity field of the continuum under investigation in most of cases (few times it's a bit more tricky, i.e. in diffusion problems that vector field contains both a local average - averaged on the species velocity, maybe - velocity contribution and a drift velocity, likely due to gradient in the specie concentration, see Fick's law for diffusion). Keep going. I'm very curious how this series evolves.

It is thanksgiving eve and I am learning some quality vector calc from these lectures. They are so greatly made!! Every detail is explained and is wrapped so elegantly together. A joy to watch.

I'm so grateful for living at this time, so I can learn this theorem in 25 minutes.

Great lecture again, you are treasure for mankind! I find the most interesting with the mass continuity equation is the physical interpretation that we can derive for div (F) by rewriting the continuity equation in terms of material derivatives

23:57 dro/dt - Density can't become smaller or be infinitesimally small - it's a constant property of a mater even idealized for the sake to keep the conversation theoretical and abstract.

What a difference a teacher makes!!! I only wished I had Steve Brunton for all my Calculus physics and chemistry classes. I passed with the ability to solve these equations BUT with a quick and partial explanation of why. Great job Steve!!! Unfortunately, too late for me. But that's how the cookie crumbles.😟

You have no idea how much gratitude i have towards you... Thank you soo much for uploading this...

What an outstanding explanation! I'm so surprised that my Calc textbook left out the Mass Continuity Equation when going over the Divergence Theorem. It's really motivating to hear how powerful this equation is in applied math and physics. I love hearing the real-world applications.

Life saving videos for students. Awesome. Thank you so much.

This is the best explanation of the Gauss's Divergence theorem I have heard till now. ☺ Thanks, Steve.

Great visualized explanation of Gauss's Divergence theorem

I can't thank you enough, this playlist alone made taking the first step to start serious mathematics and physics for me so damn easy!!

Great lecture, professor! As always, very enlightening!

I'm so lucky to have discoverd your channel while self-learning multi-variable calc! Abosolutely recommend to anyone (even non-math majors who hasn't touched calculus in 4 years).

Such great explanations and a highly quality channel. Great for building a strong intuition of concepts rarely explained in a straightforward manner.

woow!cool explanation ! integral sum of dV finally make sense! Thanks!

Thank you so much Dr Brunton for making such high quality content freely available. I have recently left work to return to uni and without this channel I would be seriously underprepared. Your ability to take a difficult subject and make it seem almost like common sense in incredible. I hope that my lecturers will have half of your passion and skill.

Great explanation! Gauss truly was a super genius for figuring this out.

Makes a complicated subject clear and attractive.

The lecture is very well organized and superbly delivered!

He has 4k quality lectures, my eyes are so comfortable watching it.

What a great lecture!! I am truly looking forward to more videos from Professor Brunton.

Excellent lecture, thank you for posting!

非常感谢！这个讲解让人印象深刻，过目难忘！这是我见过的向量微积分原理最好的讲解，再次感谢

MVP....Most Valuable Professor of the year.

I am a fluid dynamics researcher at IIT Bombay. I want to do my Ph.D. at WashU. Now I am modeling fluid vortex around a Mobius Theorem.

I was wondering how good can be someone in explaining complex subjects in an easy way.

Thank you sir...I needed these explanations!! Respect💯

I like how you write in mirror texts along with teaching.

Dr. Brunton, you used "Gauss's Divergence Theorem"(GDT) to derive the conservation of mass(CVM). Could you show how GDT relates to the "Reynolds Transport Theorem"(RTT) & also derive the CVM using RTT? Thank you! Dr. Brunton, for taking the time to teach all of us.

Beautiful content, professor. Brilliant channel, thank you.

26:39 Rho can't be continuously varying even if that term adheres to us looking how mass enters end exits particular volume. Maybe I collide density with hardness together, yet still...

Such a good video! Love your teaching style! Keep up the good work, I’m such a fan of it!

Awesome explanation!🙏

Your lectures are so inspiring! 😊

Best explanation ever. hugely thanks.

11:15 Why do divergences in neighboring cells cancel out? I can see why fluxes would cancel, but isn't that different from divergence? Wouldn't neighboring divergences work in the same direction?

Remembering in such a good way...thank you so much

Sir explain why divergence of electric field line is positive,,and negative,plse

Thank you so much! I don't even know what to say. You did an amazing job explaining this!

At mis 81years l'm fascinated by grate young teachers

Great , very neat, clear and didactical explanation Professor Steve of Gauss´s Divergence Theorem. I really enjoy it !! I am following You on the networks and also in the University of Washigton UW Internet Sites. I am thinking about going back to Graduate School [second round from 58 to 100 !!] and besides the quality of the university I believe the Advisor is crucial. Not only that He has abroad knowledge and background on the subject matters but also his ability to motivate. Your lessons are highly motivational.

I'm not disrespecting my professor, but I wish I had you teaching vector calculus concepts to me. I enjoyed your machine learning series. I'm looking forward to your next videos

Thanks for this excellent lecture , I pray For you to be happy and long live.

Thats a brilliant intuitive explanation

I am sooooooo grateful for this video!!!

One issue with this theorem is that we have to define how much flows through the surface at the same time. That mans that we integrate over the surface for one moment in time. After completion we can see how that result evolves over time, but we can't use the left part of the surface values of one time moment and add that to the right part of the surface for a later time moment. But this means that we have to know what simultaneity means in that case. Thanks!

Brilliant explanation , thank you

Nice video but I do not understand the concept of the divergence in the volume, how they cancel out and how there was a surface without a divergence

That was really interesting. Thanks for such a fascinating lecture.

In this equation I see that units do not match: ∫∫_S ρF • n dS = ∫∫∫_V div(ρF ) dv on the LHS: [kg/m^3][m/s][m^2] = [kg/s] on the RHS: [kg/m^3][m/s][m^3] = [kg m / s] Please let me know what I am missing.

Hi Steve, I have to say the tiny boxes analogy is a bit confusing. Because when you integrate over the volumn, you are integrate the divergence, so at each point the integrand is positive since each point is a source, which does not reflect any 'cancellation'. (If it does, then at the points in central region the integrand should become 0 since they are 'cancelled'.) Whilist the 'cancellation' happens between the vector field F itself. So it might not be the right intuition for the theorem.

I'm confused regarding a basic idea. If there are no sources in the volume, I don't understand why the flux as defined isn't always equal to zero. Where the field enters the volume the flux contribution F dot n would be negative and where the field exits the volume F dot n would be positive. So, the net flux would be zero.

Hi, I think there is some problem with the "explanation' of canceling off between fluxes in the video. The cancelling off takes place because the flux through an interfacial control surface will have different signs when taken in two adjacent control volumes.Anyone thought the same?

Can't wait to watch the next one.

Dear Sir, I cannot understand the part at 12:35 sec. If there is a perimeter which has continuous outward emerging arrows, then what about the arrows that are in +z direction (emerging in 3D), as flux F is coming/flowing out (not expanding).

Some thing I didn't understand is why we are assuming that each tiny boxes would work identically either as a source or sink. Isn't the divergence induced by the vector filed on the surface going to change from section to section

really broadened my mind . thanks !

Being slow to get it Will watch again A 3D simulation would be perfect for full visibility Cant thank you enough for the giant efforts

Perfect, please more calculus lectures.

I love this video God bless you teacher❤

I love your content. Your followers are brainy people. They love ur style. They are bored by Netflix, autodidacts. I love your lectures about Compressed Sensing.

this video is helping me a lot, thanks

wonderful explanation thank you.

At 21:35 or so, does anyone know how we formally justify changing the total derivative in respect to time with a partial derivative with respect to time when we move the derivative operator inside the triple integral? Also, in this particular exemple, I get the feeling that this could only be true if the volume is not a quantity that depends on time, but I know that conservation on mass is always true and does not rely on such assumptions... How can I convince myself that this is true no matter what happens to the volume? And this is closely related to my last question : what does happen if we consider that the volume does depend on time? Can we still switch the integral with the total derivative? Thank you Steve Brunton for these videos! It's been a long time since I saw these topics (if ever for some of them!) and I really appreciate your enthusiasm and the quality of your work :)

Fantastic lectures. Please increase microphone volume level next time.

Well, I wasn't expecting to have my entire outlook on the world around me changed today but it happened.

Sir love you I am immensely thankful to you you are great My teacher didn't give me any concept any amount of concept of that topic❤ Love from Pakistan 🇵🇰🇵🇰 may Allah bless you ❤

In terns of computation, which integral is more effective. The surface or the volume integral?

Watching this while waiting for my next flight. Thanks

what id really mass energy and momentum created then how will gauss divergence theorem work?

2:38 The generalized Stoke's theorem would like a talk.

So, it means that, thanks to this equivalence between what happend in a volume and its surface, we can intuitively feel what is the conept of continuity. It's not the coninuity of the mathematcians, but rather of the physicians. What is the continuity ? To check at every scale and at every shape, this equivalence. If this rule is true then it means that the medium is continous. It's very surprising that for knowing something locally, we need to look at globally.

@stevebrunton Is the gauss’s divergence theorem also relevant to transitions of chemical states? (Water turning to ice, dry ice to co2… etc? As it does flux mass to and from the volume through the surface area.)

Some facts about Gauss: Gauss could divide by 0 Gauss squared the circle He knew the last digit of pi He could construct lines with a compass and circles with a straight edge

Hi Steve [URGENT!] Shouldn’t F be the velocity field vector V in this case, I think that is intuitive from dimensional matching and have also seen it written in the standard text book instead of F. Please correct me if I am wrong. Otherwise awesome lecture. Thanks and Regards Vinayak

the name of the theorem is Gaus-Green Theorem

I just realized that if it can be said that the noise of a vacuum is 92 decibel, it's thanks to the Gauss's divergence theorem... As there is a kind of conservation law of the noise, and as the noise is given by a power, it's maybe, the conservation law of the energy which allows us to measure the sound of machines and equipments ...

Awesome lecture sir...🙏

gotta love this man

"If it's Gauss' Divergence Theorem, it's probably the best divergence theorem."

A good refresher. Could you also show contuinty eqn for deformable control volume (i.e. V=V(t))?

amaaaaazing

Sir you put d/dt inside integral but if volume is changing with time then also can we put d/dt inside integral

Hi Dr. Brunton. As obscure as this seems is it scientifically useful to somehow perturb Guass's Divergence Theorem with an arbitrary differentiable function to see what would happen if non-conservation were to ever take place, and the consequence on the derived PDE?

Rendering so beautiful to replace some of the MIT's teachers on its edX online teaching platform

Amazing video, sir. Any1..Correct me if I'm wrong : He was able to interchange the order of derivative and integral because of the following>>> derivative of an integral= integral of a derivative. Just thought it might help some1 like me cause i was wondering how twas possible for a couple of minutes.