@@genet.2894 well yes the generalization theorem is calculus 3, but the generalization theorem its for differential manifolds or a course on manifolds: its a course for mathematicians or physicists, on calculus 3 isnt normal to see the generalization
@JoseMedina-ug6on However, it is covered in the book itself. What's more there's a difference between a course in Calc III, aimed at those majoring in the social sciences vs. a more rigorous treatment of the subject aimed at science and engineering majors, which will cover such topics for the benefit of those students. I recall at UCLA they taught from different Calculus text books depending on major. One was geared towards the liberal arts majors and the other towards science and engineering majors
On the subject of visualizing higher dimensional integrals, the textbook we used had a great line. Referring to triple integrals, it said something like, "You can think of this as the four dimensional volume under a three dimensional surface. This is not particularly helpful."
I taught myself Calculus III entirely using Professor Leonard's lectures on UA-cam and doing practice problems in my college's calculus textbook. Prof Leonard does a phenomenal job explaining the intuition behind many of these key ideas, so I came into this video understanding the ideas of each theorem pretty well and understood their relationships. However, it was the end of your video that blew my mind. I honestly did not expect to see a very generalized version of all these theorems, and to see that it could be summed up so simply was super cool. Thanks for informing me about the Generalized Stokes' Theorem. I will be taking Calculus III in a month at my college, and I feel even more prepared.
The only way I see a double major CS and Physics as being remotely possible as both are hard subjects in their own light is if you know or are extremely talented in one subject area thereby able to focus more on the other area - The subjects are so disparate
I swear these kind of videos should be watched at lessons in university. They explan so much better what we are studing instead of mechanically doing things and just memorizing theorems without actually understanding what they say. As an engineering student, I thank you and will show to my university mates
I don't know, I kind of think our professors want us to have these "holy shit" moments of our own volition. To go home and ponder as we fall asleep and wonder how the pieces fit.
You should know that professors don't care if you understand or not. To them this kind of math is too elementary that when you enroll in their class you are expected to take care of your self. BTW most of the good math programs in Universities want you to think not spoon feeding the students
In university I took a course about physics simulations. There reached a point where we needed to calculate the mass of an arbitrary polyhedron so we could model its forces properly. I was shown how you could use the divergence theorem to calculate the volume of a closed polyhedron by turning an integral over its volume into an integral over its surface. You could then assume constant density and use the volume to get your mass. I think that was coolest application of multi-variable calculus I've seen. Thank you for this video, it's such a good refresher!
This is so cool! I have taken multivariable calculus many years ago and you've taught me probably the coolest application of divergence theorem I never knew of.
Please continue making videos sir, you have immense potential for explaining complex things and more importantly for building connections and intuition, I really hope your project is recognised in the SoME3
i love watching calculus and physics videos, and this was by far the best multivariable calculus video i've ever seen!! simple and intuitive explanations of hard topics of high-level math. never have i seen such a clear explanation of the fundamental theorem of single variable calculus it was really astonishing my jaw dropped. the fact that you're from chemistry and still make this video with that passion and beauty makes me wanna learn more about new stuff. I absolute recomend this to who's starting calculus, this is some neat material
Great video. As a meteorologist I enjoyed your perspective and it brought a smile to my face as you simply explained the maths i enjoy analyzing when i look at the diverging wind fields, the upward movement caused by the curvature of winds, over the different surfaces at varying pressure levels of our troposphere.
Really great video dude! Just about to take my first multivariable calc course and this has got me all excited to unpack the levels of abstraction in more detail.
I'm studying mech engineering, but when I started first year, we could choose between learning "normal maths" or "advanced maths". My instinct told me to choose advanced maths, just cause why not. (very few people chose it because they thought that it's extra suffering for no benefits). It was one of the best descisions I've ever made. Our teachers were insanely good, and analysis 1 and 2 were some of my favourite classes I've ever taken. Sometimes I get the same feeling as you, finally properly understanding something that I couldn't grasp when we were studying it, and it's amazing. I hope that in some of my future semesters I'll have the time to retake at least one of these classes (with the same teachers hopefully!), but we'll see.
5:07 i got this proof on my channel lol. it was the first thing that came to my mind when i was trying to make sense of that fundamental theorem of calculus equation like years ago in high school...thanks for pointing out that it doesn't work in all cases.would need to learn more to know more about what's going there.
Awesome mesmerising superb. I completed my BSC in electrical and electronics engineering from most famous university in my country 23 years ago . Unfortunately I didn’t fathom anything regarding greens theorem during my fields and waves course in BSC. I wish I would have watched this video during my study. Thank awfully for this video
My favorite explanation of why the gradient is the max rate of ascent: the more something’s increasing your result, the more of it you do; the more something’s decreasing your result, the more you do the opposite
Incredible, incredible video. I took calculus 3 and absolutely loved it, and upon finishing it I had a vague sense that there was a connection between some of the theorems, but I never caught on to just how fundamental that connection was, and that it extended to not just between greens, stokes, and the divergence theorem, but to line integrals and the fundamental theorem of single variable calculus itself. Absolutely beautiful.
This was beautiful, reminds me of Poincaré’s quote “Mathematics is the art of giving the same name to different things” or in this case different names to the same thing. Thanks for sharing!
Thank you for sharing this extremely insightful simplification of an otherwise a highly complex topic (perception of complexity of multi-variable calculus). This simplified (geometric) image will likely stick in my mind for years to come. Human mind thinks differently and complex math can be translated into a human-mind-friendly format using these insightful changes in perspective.
man i can t believe you explained it so nicely, it s the first watching one of your video, i hope you have more. congrats on you explanations, i can t believe i understood so much while i am still struggling with my PDEs and A level pure maths, etc. very big appreciation for founding your video. lots of thanks
26:10 It took me 30 years 😭😭 to come to this understanding despite all the efforts spent accross the years, by a video (amazing and mind blowing 🤯) that I have landed on it by chance. Thank you ❤
Beautifully done!!! And very satisfying how it all comes together in the end!!! I was a Physics Major, studying Calculus (of course), nearly forty years ago, and these connections never occurred to me. Every minute of your video was compelling and clearly explained, and I could visualize it all (*especially* because of my familiarity with working with Maxwell's equations of Electromagnetism). I get the "spirit" of it.... the generalization... but there are still some subtleties I'll need to ponder in the coming days, which I think will put me on a firmer foundation of understanding. This video should be required viewing for every Calc-II student!
Very nice vid, one of my favorite submissions so far for #SoME3 I feel! To add to the discussion, you might be interested in what you might view as a possible "sequel" to this: at around the 9 min mark, you mention that we "can't multiply vectors". Tho, what if I told you that this is totally possible, and in a way where you don't have to resort to the math in general relativity, but can also take a lot of what you learned in vector calculus and extend it in higher dimensions? (you will need to drop the cross product and replace it with something else that reproduces its properties in 3D while letting it generalize in higher dimensions, called the wedge product. You'll also need to include more "directed objects" instead of restricting yourself to just directed lines, i.e. regular vectors. For instance: directed plane segments, directed volume segments, etc, modeled by multivectors, in the same way vectors modeled directed line segments geometrically). That subject is called Geometric/Clifford Algebra, and an associated calculus to it called 'Geometric Calculus' in a similar way vector calculus was to regular vector algebra. (There is a related area called "Clifford Analysis" that goes quite in depth with pure math formalism and rigor, but you won't need it just to extend vector calculus).
or alternatively u can just learn tensors and fibre bundles and do differential geometry like the rest of the world. They are more versatile and generalize to algebraic geometry via sheaves of O_X modules
I’m absolutely astonished. I’m a dunce when it comes to mathematics generally (a dunce who is at the same time is very interested in maths); yet now, having seen your video I’m really beginning to see that calculus is within range of my understanding it. I can’t tell you how excited I am about this leap forward! Thank you so much.
Actually, derivative is a quotation, the differential devided by argument variation (you can see it if look at definition of differentiable function and differential as a linear part of function variation). And problem with cancelling dx actually lies in that dx in integral is just a part of notation, and you actually have to prove that you can use this notation as actually multiplication by dx. There's another problem with thinking derivatives as a quotation, when you can't prove chain rule by just cancelling out dy in (df/dy)*(dy/dx). But this problem we have because of notation duality: we have the same notation for differential and for argument variation. And in this formula dy at the bottom is a variation of argument and dy at the top is the differential. Of course, differential is not equal to just variation, it's just a part of it. And also df that you see in two parts of this formula is a two different functions, because differential is a linear function of argument variation, and it depends on which argument function have, y or x
This video was heat 🔥 we gotta get you more subs. I legit thought calc 3 was beyond me until I watched this and for the first time I actually get it. Keep the uploads coming king 👑
Part of why multivariable calc can be a weeder class is a hyperfocus on building all the necsessary tools for Stokes theorem from the bottom up first without giving some grounding structure like this video does until the very last couple weeks of the course if that. It would be very helpful for more instructors to forsake a little rigor every now and then to remind students that calculus isnt just a bunch of random tools that kind of rhyme with each other.
14:28 At this moment I literally was like "Dude, you really need bivectors." Learn geometric algebra, dude, this will make your math life easier. This dS really should be bivector.
Yes. Also, the cross-product vector really is a bivector called a "pseudovector", as in n dimensions, you can have a pseudo-(n-x)-vector that is orthogonal to the x-vector.
Dude you are so underrated!!! You have only 1K subs? I can't believe it! I thought you had 1M subs, your content was that good! You truly deserve more! Please keep making content like these!!!!!
I havent yet learnt multivariable calculus yet. But I think this was a really good introduction video. Now I am really excited to this in my college. 😊
That was great. My mind is blown, but yet I feel like I understand multivariable calculus much more than I did before. And I haven't even truly taken multivariable calculus yet! I've just watched about the first quarter of Professor Leonard's Calc III sequence here on UA-cam. And some 3blue1brown videos, of course. 🙂
Great video! I didn't understand these fundamental connections until years after I took Calc III. Good luck with #SoME3! By the way, one thing that is often left out - just as Green's theorem is a special case of Stokes, there is a 2D version of the divergence theorem, in which you're equating flux across a curved boundary in 2D to the divergence of the 2D vector field on the interior. It's actually equivalent to Green's theorem with the vector component functions rearranged.
Great video. Title is a little misleading - maybe add ‘Stokes’ in there? The way you weaved the definitions in, and simplified for the General Stokes Theorem was magical…I guess those calculus essays helped! This is now the best video on Stokes, with Aleph O runner up! Please keep doing math videos - you have the gift! Maybe Fourier / Dot Product, linear algebra, quantum stuff? Check out ‘goldplatedgoof’ Fourier for the rest of us. Super cool - using Fourier epicycles to create equations from curves (data). Mind blowing!
Thank you! My goal for this video was make it accessible for anyone who knew even a little bit of calculus which is why I titled it as it did-I figured putting “Stokes Theorem” in there like AlephO did would have made it miss the students who haven’t taken multivar yet…but you’re definitely right, the title is a little misleading lol, albeit intentionally
Just a note as a viewer: at 18min I was unsure about your distinction between surface and curve when describing Stokes theorem, it's clear now that C is a 1d curve embedded in 3d, and S is a hull of that curve, a 2d surface embedded in 3d. For a while there I thought C was a 2d surface in 3d, which caused the confusion. I still engage with math pretty heavily but I haven't touched multivariate calculus specifically for a while.
I wish I would have discovered this video when I so desperately wanted to understand what integrals really were. I tried learning from 3blue1brown, and though they are awesome, I couldn't understand what they were telling me. This video however explained it perfectly. 😁
Nice! Actually, one can already see these theorems as special cases of the divergence theorem - for this, one just needs to define the divergence operator on manifolds (lines, surfaces etc.). In a way, it's a more natural generalization than Gen. Stokes, as it doesn't require additional terminology (forms,...) and doesn't restrict our considerations to oriented manifolds. (on the other hand, it does require Riemannian structure on the manifold, but as long as we're working with submanifolds in R^n, it's the same structure Line Integral and Stokes theorems use anyway)
In a way, the bounday it´s acting like de derivative of their shape. Really a crazy conection when you notice that this just happends in geometry as well. thinking of a circule, it´s area is equal to πr² while it´s perimetrer (the bounday of the area) it´s equal to 2πr, the derivative of the area respect of its radius r. In Ari´s words, its just amaizing.
I was scrolling through the scientific video suggestions, saw this one and wandered why is there a video about watching knitted woolen socks through a magnifying glass...
The essence of multi-variable calculus, IMO, is: hey, here's what all this stuff you learned in two dimensions [x, f(x)] looks like in three or more dimensions of which there are only a handful of analytic solutions. So, don't get too excited unless you are prepared for some really deep and complex rabbit holes trying to solve what look like trivial equations on the surface (pun intended). However, if you are an engineering major, you will need multi-variable calculus because the real world is 3D.
Congratulations sir, you have just beaten my earlier university professors. I learned more in your 30 min than their 30 weeks 😂 (Not entirely fair, as I learned a LOT since those sophomore weeks. Much of it from 3B1B, obviously, but let's not bash those profs to death.)
My calculus textbook explicitly summed up how all the concepts of multivariable and vector calculus that were taught were extensions of the fundamental, basic concepts and theorems from the very start of calculus. It made me appreciate the courses more once I saw how seemingly unrelated concepts were simply logical extensions of earlier concepts that carried with them incredibly broad and far reaching conclusions and applications.
@@vvvvvvvvvvv631 I actually had three different books I used since I took each calculus course online from 3 different campuses, but the book that this comment is referring to is Calculus for Scientists and Engineers, Early Transcendentals by Briggs, Cochran, and Gillet. In the final chapter, (15.8) before the exercises, there is a couple paragraphs and a table showing how line integrals, green’s theorem, stoke’s theorem, and divergence theorem are just extensions of the fundamental theorem of calculus.
If I had one criticism, I’d say that calling some of those sentences “plain english” is… a bit of a stretch. Since it’s basically just a direct substitution of the symbols with their names. I think it would be more enlightening to use language like “accumulations” and “small contributions” instead of integrals and derivatives.
I was trying to understand why if the integral of the derivative is equal to the function of the boundary is the case, then for the single variable case we have it equal to f(a) - f(b) and not f(a) + f(b). Then it occurred to me. It's because if I treat those two points as an enclosing boundary then they will be pointing in different directions.
Math Professor fr be like "if this description was confusing that's because I glossed over a few important details but don't worry about that for now" that line had me dying 10:08
Great video! One question: could you ask your physics/CS friend for me if the generalised Stokes theorem has anything to do with the Holographic Principle? Seems like there should be some connection..
I didn't take calc 3, (but I did watch some video courses on youtube). I first encountered the ++real++ fundamental theorem of calculus in the context of geometric algebra/calculus. I have no idea what it means, though. :)
Hi, do you have a reference list of sources you used to make this video? Where did you learn about this kind of motivation for the Fundamental theorem of calculus for single variable calculus?
I don't really have a concretelist of references sorry-I pretty much made this video based off of what I learned in my multivar class in college. I used Wikipedia and some other sites (like Paul's Online Notes, which I highly recommend, see here for an example: tutorial.math.lamar.edu/classes/calciii/GreensTheorem.aspx) to refresh my knowledge and clear up the nuances, but that was pretty much it
Professional mathematician here, who has taught various flavors of calculus a zillion times: This was magnificent.
This is Calculus III of Calculus and Analytic Geometry correct ?
@@genet.2894 well yes the generalization theorem is calculus 3, but the generalization theorem its for differential manifolds or a course on manifolds: its a course for mathematicians or physicists, on calculus 3 isnt normal to see the generalization
@JoseMedina-ug6on However, it is covered in the book itself. What's more there's a difference between a course in Calc III, aimed at those majoring in the social sciences vs. a more rigorous treatment of the subject aimed at science and engineering majors, which will cover such topics for the benefit of those students. I recall at UCLA they taught from different Calculus text books depending on major. One was geared towards the liberal arts majors and the other towards science and engineering majors
@@genet.2894 The funniest part of this is when you implied liberal arts majors would be taking multivariable calculus
My whole electromagnetism understanding has changed now . Like all these rules in school has gotten so much more colorful and fun and meaningful...
glad for you :)
On the subject of visualizing higher dimensional integrals, the textbook we used had a great line. Referring to triple integrals, it said something like, "You can think of this as the four dimensional volume under a three dimensional surface. This is not particularly helpful."
I taught myself Calculus III entirely using Professor Leonard's lectures on UA-cam and doing practice problems in my college's calculus textbook. Prof Leonard does a phenomenal job explaining the intuition behind many of these key ideas, so I came into this video understanding the ideas of each theorem pretty well and understood their relationships. However, it was the end of your video that blew my mind. I honestly did not expect to see a very generalized version of all these theorems, and to see that it could be summed up so simply was super cool. Thanks for informing me about the Generalized Stokes' Theorem. I will be taking Calculus III in a month at my college, and I feel even more prepared.
As a physics and cs double major student i liked this video :D
I second that, as a physics and cs double major. Except this time I'm taking multivariable calc in a pure maths perspective.
pilani cs?
@@RocketsNRovers Haha my dad did CS at BITS. I'm doing it at ANU.
@@krishyket ohh .. nice bro
The only way I see a double major CS and Physics as being remotely possible as both are hard subjects in their own light is if you know or are extremely talented in one subject area thereby able to focus more on the other area - The subjects are so disparate
I swear these kind of videos should be watched at lessons in university. They explan so much better what we are studing instead of mechanically doing things and just memorizing theorems without actually understanding what they say. As an engineering student, I thank you and will show to my university mates
I don't know, I kind of think our professors want us to have these "holy shit" moments of our own volition. To go home and ponder as we fall asleep and wonder how the pieces fit.
You should know that professors don't care if you understand or not. To them this kind of math is too elementary that when you enroll in their class you are expected to take care of your self. BTW most of the good math programs in Universities want you to think not spoon feeding the students
In university I took a course about physics simulations. There reached a point where we needed to calculate the mass of an arbitrary polyhedron so we could model its forces properly. I was shown how you could use the divergence theorem to calculate the volume of a closed polyhedron by turning an integral over its volume into an integral over its surface. You could then assume constant density and use the volume to get your mass. I think that was coolest application of multi-variable calculus I've seen. Thank you for this video, it's such a good refresher!
This is so cool! I have taken multivariable calculus many years ago and you've taught me probably the coolest application of divergence theorem I never knew of.
Please continue making videos sir, you have immense potential for explaining complex things and more importantly for building connections and intuition, I really hope your project is recognised in the SoME3
i love watching calculus and physics videos, and this was by far the best multivariable calculus video i've ever seen!! simple and intuitive explanations of hard topics of high-level math. never have i seen such a clear explanation of the fundamental theorem of single variable calculus it was really astonishing my jaw dropped. the fact that you're from chemistry and still make this video with that passion and beauty makes me wanna learn more about new stuff. I absolute recomend this to who's starting calculus, this is some neat material
Thank you. As a recovering math-phobe, I really enjoyed this. Tremendously helpful and very instructive.
Simple but effective. This is a dope some3 submission for sure
Great video. As a meteorologist I enjoyed your perspective and it brought a smile to my face as you simply explained the maths i enjoy analyzing when i look at the diverging wind fields, the upward movement caused by the curvature of winds, over the different surfaces at varying pressure levels of our troposphere.
Finally, a chemist that understands mathematics
Really great video dude! Just about to take my first multivariable calc course and this has got me all excited to unpack the levels of abstraction in more detail.
Awesome! Enjoy the class!
@@FoolishChemist same
I'm studying mech engineering, but when I started first year, we could choose between learning "normal maths" or "advanced maths". My instinct told me to choose advanced maths, just cause why not. (very few people chose it because they thought that it's extra suffering for no benefits).
It was one of the best descisions I've ever made. Our teachers were insanely good, and analysis 1 and 2 were some of my favourite classes I've ever taken.
Sometimes I get the same feeling as you, finally properly understanding something that I couldn't grasp when we were studying it, and it's amazing.
I hope that in some of my future semesters I'll have the time to retake at least one of these classes (with the same teachers hopefully!), but we'll see.
The conclusion is very good. Certainly, well-educated friends make your life better.
5:07 i got this proof on my channel lol. it was the first thing that came to my mind when i was trying to make sense of that fundamental theorem of calculus equation like years ago in high school...thanks for pointing out that it doesn't work in all cases.would need to learn more to know more about what's going there.
Awesome mesmerising superb. I completed my BSC in electrical and electronics engineering from most famous university in my country 23 years ago . Unfortunately I didn’t fathom anything regarding greens theorem during my fields and waves course in BSC. I wish I would have watched this video during my study. Thank awfully for this video
I've never taken MVC, but the instruction in this video was so clear that I have working proficiency in it.
My favorite explanation of why the gradient is the max rate of ascent: the more something’s increasing your result, the more of it you do; the more something’s decreasing your result, the more you do the opposite
Incredible, incredible video. I took calculus 3 and absolutely loved it, and upon finishing it I had a vague sense that there was a connection between some of the theorems, but I never caught on to just how fundamental that connection was, and that it extended to not just between greens, stokes, and the divergence theorem, but to line integrals and the fundamental theorem of single variable calculus itself. Absolutely beautiful.
This was beautiful, reminds me of Poincaré’s quote “Mathematics is the art of giving the same name to different things” or in this case different names to the same thing. Thanks for sharing!
I'm gonna share this perspective on my college that's for sure, thanks a lot.
Thank you for sharing this extremely insightful simplification of an otherwise a highly complex topic (perception of complexity of multi-variable calculus). This simplified (geometric) image will likely stick in my mind for years to come. Human mind thinks differently and complex math can be translated into a human-mind-friendly format using these insightful changes in perspective.
this guy deserves mora than 1M subscribers
man i can t believe you explained it so nicely, it s the first watching one of your video, i hope you have more. congrats on you explanations, i can t believe i understood so much while i am still struggling with my PDEs and A level pure maths, etc. very big appreciation for founding your video. lots of thanks
26:10 It took me 30 years 😭😭 to come to this understanding despite all the efforts spent accross the years, by a video (amazing and mind blowing 🤯) that I have landed on it by chance.
Thank you ❤
Beautifully done!!! And very satisfying how it all comes together in the end!!!
I was a Physics Major, studying Calculus (of course), nearly forty years ago, and these connections never occurred to me.
Every minute of your video was compelling and clearly explained, and I could visualize it all (*especially* because of my familiarity with working with Maxwell's equations of Electromagnetism).
I get the "spirit" of it.... the generalization... but there are still some subtleties I'll need to ponder in the coming days, which I think will put me on a firmer foundation of understanding.
This video should be required viewing for every Calc-II student!
Very nice vid, one of my favorite submissions so far for #SoME3 I feel!
To add to the discussion, you might be interested in what you might view as a possible "sequel" to this: at around the 9 min mark, you mention that we "can't multiply vectors".
Tho, what if I told you that this is totally possible, and in a way where you don't have to resort to the math in general relativity, but can also take a lot of what you learned in vector calculus and extend it in higher dimensions?
(you will need to drop the cross product and replace it with something else that reproduces its properties in 3D while letting it generalize in higher dimensions, called the wedge product. You'll also need to include more "directed objects" instead of restricting yourself to just directed lines, i.e. regular vectors. For instance: directed plane segments, directed volume segments, etc, modeled by multivectors, in the same way vectors modeled directed line segments geometrically).
That subject is called Geometric/Clifford Algebra, and an associated calculus to it called 'Geometric Calculus' in a similar way vector calculus was to regular vector algebra. (There is a related area called "Clifford Analysis" that goes quite in depth with pure math formalism and rigor, but you won't need it just to extend vector calculus).
Nothing gets me going like Clifford algebra lol. God I want to meet the octopus at the depths of the math trench
or alternatively u can just learn tensors and fibre bundles and do differential geometry like the rest of the world. They are more versatile and generalize to algebraic geometry via sheaves of O_X modules
So what even is a directed plane segment and how can I think about it
Can't come up with an appropriate comment. It's very good.
It's really an eye opener. Mind blowing!! 🎉🎉
This was actually so beautiful
I’m absolutely astonished. I’m a dunce when it comes to mathematics generally (a dunce who is at the same time is very interested in maths); yet now, having seen your video I’m really beginning to see that calculus is within range of my understanding it. I can’t tell you how excited I am about this leap forward! Thank you so much.
As a chemistry and maths double major, I'd say I loved this video!
Such, such, such a great understanding, great explanation...showing simple beauty of math. Thanks a lot.
Awesome video!
Which app are you using on the iPad?
Actually, derivative is a quotation, the differential devided by argument variation (you can see it if look at definition of differentiable function and differential as a linear part of function variation).
And problem with cancelling dx actually lies in that dx in integral is just a part of notation, and you actually have to prove that you can use this notation as actually multiplication by dx.
There's another problem with thinking derivatives as a quotation, when you can't prove chain rule by just cancelling out dy in (df/dy)*(dy/dx). But this problem we have because of notation duality: we have the same notation for differential and for argument variation. And in this formula dy at the bottom is a variation of argument and dy at the top is the differential.
Of course, differential is not equal to just variation, it's just a part of it. And also df that you see in two parts of this formula is a two different functions, because differential is a linear function of argument variation, and it depends on which argument function have, y or x
What a marvelous video. Thank you for this effort!
this is one of the finest videos on youtube; poetic to say the least
This video was heat 🔥 we gotta get you more subs. I legit thought calc 3 was beyond me until I watched this and for the first time I actually get it. Keep the uploads coming king 👑
Part of why multivariable calc can be a weeder class is a hyperfocus on building all the necsessary tools for Stokes theorem from the bottom up first without giving some grounding structure like this video does until the very last couple weeks of the course if that. It would be very helpful for more instructors to forsake a little rigor every now and then to remind students that calculus isnt just a bunch of random tools that kind of rhyme with each other.
Really I get impressed by your lovely video. Great
please keep making more videos about math topics where you explain everything. Its very well made and helpful !
i can’t thank you enough for the clarity you bring to your topics! ☀️
14:28 At this moment I literally was like "Dude, you really need bivectors." Learn geometric algebra, dude, this will make your math life easier. This dS really should be bivector.
Can I ask how you learned geometric algebra? I've been wanting to take a course but my university doesn't seem to offer any in the subject
@@FoolishChemist, I recommend you start with the «Swift introduction to geometric algebra» video on UA-cam.
Yes. Also, the cross-product vector really is a bivector called a "pseudovector", as in n dimensions, you can have a pseudo-(n-x)-vector that is orthogonal to the x-vector.
I love this, I'm just an undergrad, but I'm interested in higher mathematics ❤. Much love man, make more maths videos.
Dude you are so underrated!!! You have only 1K subs? I can't believe it! I thought you had 1M subs, your content was that good! You truly deserve more! Please keep making content like these!!!!!
One of best video ever❤❤
They way you summed up the whole video is just awesome 💫💫
I havent yet learnt multivariable calculus yet. But I think this was a really good introduction video. Now I am really excited to this in my college. 😊
Dude,that was awesome. Nice vid. Like.
Underrated video holy moly
That was great. My mind is blown, but yet I feel like I understand multivariable calculus much more than I did before. And I haven't even truly taken multivariable calculus yet! I've just watched about the first quarter of Professor Leonard's Calc III sequence here on UA-cam. And some 3blue1brown videos, of course. 🙂
Amazing video. Thank you so much.
Great video! I didn't understand these fundamental connections until years after I took Calc III. Good luck with #SoME3! By the way, one thing that is often left out - just as Green's theorem is a special case of Stokes, there is a 2D version of the divergence theorem, in which you're equating flux across a curved boundary in 2D to the divergence of the 2D vector field on the interior. It's actually equivalent to Green's theorem with the vector component functions rearranged.
Great video. Title is a little misleading - maybe add ‘Stokes’ in there? The way you weaved the definitions in, and simplified for the General Stokes Theorem was magical…I guess those calculus essays helped! This is now the best video on Stokes, with Aleph O runner up! Please keep doing math videos - you have the gift! Maybe Fourier / Dot Product, linear algebra, quantum stuff? Check out ‘goldplatedgoof’ Fourier for the rest of us. Super cool - using Fourier epicycles to create equations from curves (data). Mind blowing!
Thank you! My goal for this video was make it accessible for anyone who knew even a little bit of calculus which is why I titled it as it did-I figured putting “Stokes Theorem” in there like AlephO did would have made it miss the students who haven’t taken multivar yet…but you’re definitely right, the title is a little misleading lol, albeit intentionally
Beautifully explained
Just a note as a viewer: at 18min I was unsure about your distinction between surface and curve when describing Stokes theorem, it's clear now that C is a 1d curve embedded in 3d, and S is a hull of that curve, a 2d surface embedded in 3d. For a while there I thought C was a 2d surface in 3d, which caused the confusion.
I still engage with math pretty heavily but I haven't touched multivariate calculus specifically for a while.
I wish I would have discovered this video when I so desperately wanted to understand what integrals really were. I tried learning from 3blue1brown, and though they are awesome, I couldn't understand what they were telling me. This video however explained it perfectly. 😁
What a journey…great video!
Nice! Actually, one can already see these theorems as special cases of the divergence theorem - for this, one just needs to define the divergence operator on manifolds (lines, surfaces etc.). In a way, it's a more natural generalization than Gen. Stokes, as it doesn't require additional terminology (forms,...) and doesn't restrict our considerations to oriented manifolds.
(on the other hand, it does require Riemannian structure on the manifold, but as long as we're working with submanifolds in R^n, it's the same structure Line Integral and Stokes theorems use anyway)
And the generalized stokes theorem is just a weaker version of de rhams theorem :) (at least for smooth manifolds).
Amazing video, thank you.
Math is beauty.
Great work!! Very intuitive and entertaining. Thanks a lot for your efforts...
In a way, the bounday it´s acting like de derivative of their shape. Really a crazy conection when you notice that this just happends in geometry as well.
thinking of a circule, it´s area is equal to πr² while it´s perimetrer (the bounday of the area) it´s equal to 2πr, the derivative of the area respect of its radius r.
In Ari´s words, its just amaizing.
You blew my mind
This is crazy stuff...... Blown up my mind
I was scrolling through the scientific video suggestions, saw this one and wandered why is there a video about watching knitted woolen socks through a magnifying glass...
7:15 glad the basicallyexplained guy made a cameo in this!
also thanks for making this video im tryna re-learn math after a long time so this helps.
The essence of multi-variable calculus, IMO, is: hey, here's what all this stuff you learned in two dimensions [x, f(x)] looks like in three or more dimensions of which there are only a handful of analytic solutions. So, don't get too excited unless you are prepared for some really deep and complex rabbit holes trying to solve what look like trivial equations on the surface (pun intended). However, if you are an engineering major, you will need multi-variable calculus because the real world is 3D.
Congratulations sir, you have just beaten my earlier university professors. I learned more in your 30 min than their 30 weeks 😂
(Not entirely fair, as I learned a LOT since those sophomore weeks. Much of it from 3B1B, obviously, but let's not bash those profs to death.)
My calculus textbook explicitly summed up how all the concepts of multivariable and vector calculus that were taught were extensions of the fundamental, basic concepts and theorems from the very start of calculus. It made me appreciate the courses more once I saw how seemingly unrelated concepts were simply logical extensions of earlier concepts that carried with them incredibly broad and far reaching conclusions and applications.
name your calculus textbook
@@vvvvvvvvvvv631 I actually had three different books I used since I took each calculus course online from 3 different campuses, but the book that this comment is referring to is Calculus for Scientists and Engineers, Early Transcendentals by Briggs, Cochran, and Gillet. In the final chapter, (15.8) before the exercises, there is a couple paragraphs and a table showing how line integrals, green’s theorem, stoke’s theorem, and divergence theorem are just extensions of the fundamental theorem of calculus.
amazing explanation!
Excellent video
Nice one mate. loved it.
really really good explanations
You are genius man!!!
YO OMG LMFAO I KNOW YOU IRL 😭 Math 53 with Sethian must have been crazy man
23:14 a more general one is the fundamental theorem of geometric calculus, it gobbles up the ones from complex analysis as well!
Gradient points to the direction of greatest ascent, as the opposite direction of the gradient can still be the greatest change
Great work! Thanks.
If I had one criticism, I’d say that calling some of those sentences “plain english” is… a bit of a stretch. Since it’s basically just a direct substitution of the symbols with their names.
I think it would be more enlightening to use language like “accumulations” and “small contributions” instead of integrals and derivatives.
This is an excellent idea! Lwk should've done that lol
I was trying to understand why if the integral of the derivative is equal to the function of the boundary is the case, then for the single variable case we have it equal to f(a) - f(b) and not f(a) + f(b). Then it occurred to me. It's because if I treat those two points as an enclosing boundary then they will be pointing in different directions.
at the end HxH, love it. Also nice vid too
Math Professor fr be like "if this description was confusing that's because I glossed over a few important details but don't worry about that for now" that line had me dying 10:08
Great video
great video! what software did you use for writing?
Penbook on the iPad!
@@FoolishChemist thanks
>"mathematically, the derivative is not a quotient"
Hyperreal numbers & non-standard analysis have entered the chat.
Great video! One question: could you ask your physics/CS friend for me if the generalised Stokes theorem has anything to do with the Holographic Principle? Seems like there should be some connection..
I didn't take calc 3, (but I did watch some video courses on youtube). I first encountered the ++real++ fundamental theorem of calculus in the context of geometric algebra/calculus. I have no idea what it means, though. :)
Great video. Thank you
If ive learnt anything from what ive seen in physics, df/dx cant be treated as a fraction until it can.
Amazing
I recommend Spivak's Calculus on manifolds if you liked this video
Making sure your getting paid, lol never had so many commercials for 1, 25 minute video
awesome vid, thanks!
so good
i loved this video!
How is this free?? I’m a mechanical engineering major and what a wonderful video! Thank you
awesome...
Hi, do you have a reference list of sources you used to make this video? Where did you learn about this kind of motivation for the Fundamental theorem of calculus for single variable calculus?
I don't really have a concretelist of references sorry-I pretty much made this video based off of what I learned in my multivar class in college. I used Wikipedia and some other sites (like Paul's Online Notes, which I highly recommend, see here for an example: tutorial.math.lamar.edu/classes/calciii/GreensTheorem.aspx) to refresh my knowledge and clear up the nuances, but that was pretty much it
Thank you itachi ❤