This video took a huge amount of time and effort to produce, so if you want to and can afford to, support this channel on Patreon: www.patreon.com/mathemaniac The Google form is also linked here so that you don't have to read the description: forms.gle/QJ29hocF9uQAyZyH6 The next video will finally tackle the problem of average distance between two points in a unit disc analytically - no more simulations. I am quite proud of this video, and took almost certainly more time (I didn't keep track this time) than any other video on this channel, even though it might not perform as well in the KZbin algorithm, but whatever, I like what I made here :) Do leave a like, subscribe and leave a comment now, so that more people can watch this!

Came for the Jacobian, stayed because - almost by accident - _you gave an intuitive explanation of the chain rule!_

After 40 years of college, finally a good explanation .

I have BS/MS in math, MS in statistics, and next year I'm finishing a statistics PhD, and I've never seen vector calc presented this way. Thank you for the illumination.

I love how KZbin is now exploding with math channels

back in 2018 i spent some time learning how code animations using manim and realized how much work it requires. i became sad once i realized there was no way 3b1b was ever going to come close to animating all of maths. now i am very excited to see all of these channels coming out and tackling these concepts! thank you for your contribution to humanity

This managed to make more of an impression on me than my entire university linear algebra class. Most professors seem to just read off a PowerPoint.

This is the only time I truly understand the Jacobian geometrically, I wish I could've bumped into this video sooner. Great stuff!

I started learning calculus 7 years ago, and I’m still learning new perspectives of derivatives and integrals today. It’s such a fascinating subject. I actually had this intuition for 2d+ cases, but applying it back to 1d cases was what really made it click just now haha. This is very helpful for those of us who had trouble connecting u-substitution to using the Jacobians to change variables. It’s the same exact thing! Please do one for vector calculus 🙏

I will need to watch this again, perhaps many times, and take notes, but my mind has been expanded already. Thank you so much for your generous work. God bless you.

I have yet to learn multivariable calculus and area integrals, and this seems to make things a bit more digestible for me. Neat video, man!

This is one of the best, if not *the* best video on the Jacobian available on KZbin. Wonderful job here.

with a heavy heart I clicked this, having a physics degree and never knowing why we were even learning jacobians back in the day. Thanks lol

I was smiling with resentment the whole video.. after aquiring master degree in theoretical mathematics, I realized I never really understood the concepts I know how to calculate the minute I woke up. That goes to the quality of my university, professors (with some exceptions) and my own will to go to the bottom of rabbit hole.

I'm in last year of my Mathematics degree, and I feel I just started understanding determinants and Jacobians right now!! Thanks a lot

This is so well done. Covers a lot of intuition that many, many linear algebra classes leave out, leaving the students to decipher it on their own. Well made man, I really appreciate this video.

Teaching calculus & linear algebra through the lens of analytic geometry is greatest missed opportunity in the world of teaching. Thank you for presenting these ideas in an intuitive way

without exaggeration, this is the best explaining video on youtube i have ever watched. I have watched "Essense of linear algebra" playlist by 3blue1brown, but this is definetely more clear and understandable. I am very grateful for this masterpeace.

awesome intuitions on change of base in the context of calculus. I can see the 3b1b influence all over this content and i love that too

Well shit, here I was suffering through the Wikipedia definition for ages, when you come along and tell me that the Jacobian is just the best linear approximation for a function at a given point... So much more intuitive!! Thank you!

Every linear algebra class should have this video as a prerequisite! Wish I had this video when I was in high school learning about matrices. Please don't stop creating these videos around linear algebra and various matrix computations!

I had never even thought about where the extra r came from when converting integrals to polar. This video just tied all of it together fantastically

I was able to solve these questions mathematically as taught by college profs., but never actually got the intuition of how things are flowing geometrically. Thanks a lot for explaining in such an intuitive way!

This is crucial in understanding how to develop boundary fitted coordinate systems and grid transformation metrics in the field of computational fluid dynamics. When implementing a finite difference discretization on a non-rectangular physical grid it is necessary to transform the irregular physical grid to a rectangular grid in computational space. The transformations require the Jacobian! Excellent explanation ! Thank you

wanted to just learn jacobian, but learned about linear maps and integral region mapping along the way, so cool!

This is absolutely a work of art. It bridges the gap between intuition and practical notation with a splash of simple and beautiful.

As a bonus, your explanation at 19:00 also provides a nice demonstration of *why* the chain rule works. That is something I only truly figured out (beyond memorizing it and knowing *that* I had to use it) over the past year or so of casual thinking about math, after the end of my formal education!

Thank you. Really educational. I came to this because I was reviewing my vector calculus course and I'm very confused about why is the definition of line integral and so on. This video gives me insights about the essence of derivatives & integration.

I'm going into my second year of undergrad in a few weeks. I can almost guarantee I will be referring back to this video once I get into the weeds of my courses. Thank you for making such digestible (and entertaining) videos, dude!

Thanks for the time spent in creating and sharing this video with meaningful insights of linear algebra, calculus, etc. Math is amazing and I’m glad we’re living in the time where deep math concepts can be explained clearly with aid of animations. Cannot judge all math professors for not having these tools decades ago and have to explain these concepts. But man , it really does a big difference.

One word.amazing！ I come from China.And I major in math.I feel you just did a great job！❤❤❤

I wish we had these videos during our physics undergrad 4 years ago

This makes so much more sense then 2 first years on my faculty through mathematics 1,2 and strength of materials. These transformations are very important in engineering science and using a dull textbook is not hettinf it close to students. I only came to understand at 28 through little trial and error at work what i was learning with no reference at 22. Only then it made sense and i was lucky to have come across it again.

Before this video I only knew Jacobin and Jacobean. Now I also know Jacobian!

This is a brilliant visualisation and analysis of matrix transformations

Your video series on complex calculus and this one has now given me an amazing visual understanding of derivation and integration and the connection between complex and real derivatives. THANK YOU

I'm so happy that 3b1b created manim as it's put to good use by many

I love watch those type of videos. I remember when I took Calculus II in my undergrad in Statistics and had to use these jacobians to change the coordinates. This link with linear map was awesome!

Lots of good intuition here. I would have never learn this without KZbin.

That last section of the video blew my mind. I always understood the concept behind polar coordinates, especially their necessity for easing problems. But I don't think my college classes ever delved into the linear algebra explanation for it. Really cool stuff!

I did a course called dynamical systems and chaos in my second year of undergrad, and the ideas were extremely impactful but I had very few opportunities too apply them through the rest of a pure maths degree. In particular, linear approximations of non-linear approximations to inspect critical points for stability, bifurcation etc. This was the the method though

You made a few things clicks in my head, you're a really good teacher

This is such a nice way of thinking about u-substitution. I only knew the usual proof using the product rule, but that barely gives any geometric insight. Thank you for this visual intuition for something I thought was a purely analytic concept!

Best explanation of the Jacobian I've ever seen. Great animation along with it too.

That's a lot of information and a lot of great insights for under 30minutes of video. With this high density, you can easily map this video to 50 pages worth of algebra textbook :-) Well done and thanks!

INTEGRALS AS MASS MAKES SO MUCH SENSE, I’VE NEVER THOUGHT OF IT THAT WAY. YOU ARE A GENIUSSS Also thank you so much for this vid, Jacobians have been tripping me up

derivative is scaling factor near f(x), then how the scaling factor was written to be 3 when derivative at 3 for f(x)=x^2=>f'(x)=2x=6

哇，太棒了，虽然没有完全解释所有东西，但给了我最最重要的灵感。我刚好被这个问题折磨好多天了。

This is amazing man. thanks for making this. you're another 3blue1brown, Zach star in the making.

i love when i found great math channels, i'm definitely subscribing.

Thank you for the amazing content. Channels like yours have been an eye-opener for me in mathematics

thank you for what you do. I started college with a biochemistry major, but added on math because I fell in love with calculus.

KZbin's algo is getting good lately. This was a term/topic that has been coming up in other studies of mine recently and your explanation was thorough and illuminating. I can think of many applications for this new knowledge. Thank you!

I never really understood determinant until I watched your video. This is amazing. Why can't schools teach it this way? Nobody mentions that determinant is the scaling factor in linear maps!

Clear, concise, and well-done. I wish I had this 20 years ago!

Top notch quality right here, extremely underrated amazing job on this video.

This is a fantastic lecture with neat demonstration

You are a math maniac! I will support the channel its amazing your work. Thanks!

The video recalls my university life of almost 50 years ago.

I just finished up Vector Calculus, and this is video has very much expanded my understanding!

I feel that about 11 min in, the material rushes forward more rapidly than the preceding material. I stopped the video there and will return to it at a future time. I guess I missed the part where why I would want to think about this as a map.

Thanks ...from 🇦🇷....your efforts will be remembered always...

I remember when you first made the announcement that you were starting a channel on Quora. I had been reading you for a while then so I’m very happy that you are getting some attention now :)

Although most professors should know about the materials, they didn't have the (animation) tool or the time to explain the Jacobian matrix in detail in class. This is an excellent video. Thanks!

Thank you to much for this setting :It helps me to have a good representation of the concept of jacobian and now i understand it deeply!Thousands thanks again !

Great content. The concept of "linear map approximation" connects dots... now I know how to identify the "skeleton" of the linear map, which leads to the Jacobian... no more confusion on which indices run horizontal/vertical ... there are 4 possible combinations, and I was never able to remember it... Thanks!

I was taught to compute blindly all these nasty integrals, I feel these mysterious methods have been unlocked

These videos are a joy to watch. Thank you!

It cannot be overstated how the density of intuition is uniformly high over the course of this video.

Wonderful piece of explanation. I remember performing the computations in multivariable calculus at university without understanding the concept of the Jacobian. I guess content like this requires lots of preparation so thanks a lot

This is some _quality_ content! It indeed looks like a ton of effort went into making it.

i took linear algebra and never learned these geometrical intuitions for linear transformations. thank you very much

If you are still waiting for this to come out, you can drink something. stay hydrated... when you feel thirsty

Haven't needed this in over two years yet here I am watching this on a saturday

In Chapter 2, Derivatives in 1D, did you mean x^3 instead of x^2 if you want the scaling factor to be 3 ?

Really good explanation. Especially on that linear transformation part. Thank you. ✌️

In chapter 2, the scaling is 3. When the function is f(x)=x squared. Do the derivate is 2x. I couldn't figure out why the scaling is 3 instead of 2. It took reading a lot of comments to realise: 1) The red point is 0, so the test value is 3. So the derivative here is 6. 2) BUT The points are apparently only 0.5 apart, so the scaling is 3. Nope, I'm still not getting it. I'll come back after lunch.

As soon as the narrator started talking I knew some serious learning was about to go down

Vsauce music incoming in 1...2.....3...

Thank you for this masterpiece. I think that is the best maths video i've seen so far. The amount of understanding that you provided me with this video🤯. Keep doing this amazing work!

The derivative in XY(2D) plane can be seen as "slope" and in the XYZ(3D) plane it is seen as "area". The same analogy is applicable for integrals: XY plane represent "area" and in XYZ plane "volume".

This video reminds me to the Change of variables theorem. One of the longest theorems that it took to prove in my advanced calculus course. Really nice video, I like how you also slowly approach the notion of derivative in mathematical analysis and topoplogy.

Maybe I am only silly one here. Matrix (3) or scaler 3 came out from x^2? Doesn’t slope depend on 2x ? @7:22

T his is stunningly good. Really makes simple a sometime baffling subject. I found this very helpful. Thank you!

Amazing video!! I'm taking a Calculus III course right now. This surely is going to help :).

Best infographic and visuals in a maths video so exciting to watch keep up

Excellent work! Just curious, are you using 3B1B's graphics framework for your visualizations? Regardless, love your videos and can't wait to see more!

this seems way better than just reading the theory. thanks man it really helps a lot.

6:26 why does the Jacobian Matrix for f(x) = x^2 equal 3 instead of 2?

I'm not sure if it's a difference of usage, as I'm an engineer and not a mathematician, but that's exactly how we use Jacobian determinant all the time in finite element method calculations. To me, it's mostly just a factor of a tetrahedron (for example, or whatever the shape of the element is) that will tell me if the shape of the element will give me accurate results. Meaning, the factor describes the shape, which describes roughly the distribution of integral points, in which calculations will be performed.

I think you survey could be improved a lot. I don’t think I’m the only one who have learned a lot of math through the math community (for example by watching math videos like these instead of taking classes). Therefore, I can’t really tell which subjects I have mastered and which I have learned all the basics of (perhaps I’ve missed something crucial). You could perhaps ask about what terminology we are familiar with, which concept we understand, and what impression a problem gives us (easy, solvable or scary). It would be easier to interpret, more useful and fun. Thank you for the video! I’m eager to see the final of this series.

These were the last lectures on calculus at the Physics Department, 2nd year. This representation is a must for calculus.

Very good video! I had several years of calculus as an undergrad and learned all this stuff years ago, but I still like how you presented it. Linear maps are indeed a useful way to think about differentiation and integration, even in 1D.

Sir, you are a GENIUS. Thank you so much for your time and effort, this video clarifies many topics all at once. It was really a profound explanation that clarified many doubts regarding numerous topics. Thank you so much again for this video and keep up!!

I'm only going to say Amazing dude!, I'm an undergraduate student in maths and the books some times are really hard to digest, have a picture of the sightseen helps a lot in the abstraction. Thanks!

This is awesome. Two years of calculus summarized clearly in 30minutes

Just found this channel Great content (I loved the Vsauce music)

Thanks for the effort in creating these animated videos. They make math infinite times more enjoyable. I believe every math class should be like this. 👍

Thank you for the video and its subtitles!

This really is a great video. I am only understanding it now, on my third watch. I watched it the first two times in high school, and now I am watching it again after learning basic linear algebra, partial derivatives, directional derivatives etc.