Researchers thought this was a bug (Borwein integrals)

For the very first time, the bug actually WAS a feature

This is amazing.
I even love the way you visually explained moving averages.

I'm a retired electro-geek who last studied this stuff over 40 years ago. Having just discovered this channel, I wish I'd had this resource prior to slogging through the computational mechanisms available to us at that time. These verbal and graphical explanations are absolutely fabulous, and I foresee hours of enjoyable education in my future with a cup of coffee in one hand, these videos on my side screen, and a spreadsheet in front of me. Thank-you!

I'm a retired machinist and I ran into this twice this while machining radii from for example 9.500" to 8.500" in decrements of .01". I called tech support and no one knew the answer to this. They had never heard of it. Now I know, 15 years later.

The next video on convolutions and their relationship to FFTs is out! th-cam.com/video/KuXjwB4LzSA/w-d-xo.html

"a tiny positive number my computer couldn't compute in a reasonable amount of time"
You should do it the Matt Parker way, put it up on the internet and people will improve your code by a factor of millions in a matter of days!

Hey 3B1B team and especially Mr Sanderson,
I just wanted to say your videos never fail to enthrall and impress me. You have such a way of communicating high-level concepts that makes me feel exceptionally well-informed about the subject matter you cover. As of 3 days ago, I've finished my Bachelor of Mathematics degree, 4 years after having my love of mathematics reinforced by your popular video about 4 points on a sphere.
Your channel and its content are so important for young, mathematically-interested people and I cannot express how grateful I am for this content.
In so many words, thank you.

As someone who worked extensively with convolutions and Fourier Transforms in physics and engineering: This is a beautiful video and I’m excited to see where it leads us.

One of the main problems I have in making presentations is that I always try to make them like a story, avoiding spoilers so that everything leads up to the interesting take-home point, but you don't know what is coming until I get to it. This channel demonstrates why that's a flawed way of thinking for educational purposes. It's so much easier to follow along with these explanations knowing where they are going. The explanation at 4:22, while seeming like spoilers to me in the moment, was actually extremely helpful.

I've been trying to wrap my head around convolutions forever, so seeing that you're going to be doing a video about them has just made my day :)

So if we alter the series with 1, 1/2, 1/4, 1/8, 1/16… the integral will always be pi since the sum of this series will always be less than 2

As a Hungarian-German, the name Borwein is pretty funny:
Bor in Hungarian translates to wine, and so does Wein in German. So their name is basically wine-wine

As an electrical engineer student as soon as I saw sinc(x) I immediately thought: Ah yes, definitely something with Fourier Transformation later in this video. Here we go again!

I was taught by both Borwein brothers (Johnathan and Peter) at Simon Fraser University in math undergraduate here in British Columbia, Canada. Peter was a joy to take complex analysis with. Jonathan's 4th year real analysis course was... less joyful. Brilliant man, we as his students weren't ready to hold the volumous and requisite knowledge in our brains at all times. Still, I greatly appreciate the experience and am glad I passed his course!

Is it weird if I'm not studying or doing anything remotely to do with this kind of math, but absolutely loved it? It's strangely soothing and entertaining.

I’m currently studying maths at undergrad level, and the difference between 3B1B and the teaching I am receiving is day and night. You do so much to motivate and illuminate with these videos. I know that to learn the detail will involve a lot of hard work, and then I’ll have to develop my understanding by exercises and problem solving. However, now that I am fascinated and have a picture, this is a joy, not a chore. Thank you so much and keep doing this sort of thing.

i’m currently studying electronic engineering and i’m pretty familiar with all of this frequency domain stuff, but the sudden “aha” moment I had at the end was really something else. 3B1B really knows how to neatly wrap together seemingly disparate pieces of information

Its so nice when you know enough math that you can figure out the problem yourself midway through the video

These video's are so incredibly well made that, not only is the math beautiful and well-explained, but the scripts 3Blue1Brown uses in these videos is just as beautiful and meticulously constructed. This is one of those subtle things I love about science and math - that it teaches you to speak carefully such that what you say has exactly one meaning. It's a truly difficult art to master but if achieved, the speaker is effortlessly satisfying to listen to.

I'm not at all a math student, but I come to this channel every time I want to relive that feeling of "wow everything is connected, this is so beautiful"

Fun to watch after finishing an electrical engineering degree. Feels like the second you found moving averages, I could see the convolution and Fourier transform. Made me feel like I learned something in the past 4 years

As a math enthusiast that became engineer 25y ago 3B1B makes me feel I can still understand complex & fun stuff like this 😍 definitely the best youtube chanel ever, there was nothing like this before youtube

Absolutely amazing. The problem itself and the quality of this video.

👏👏👏👍👍👍 this is *the* best channel of its kind, the team never compromises the rigor while maintaining uncluttered vivid visualization! Extreme quality of their work, the modesty of the presentation, the simple fact the text and the formulae are correct and proof-read to near perfection (in contrast with their ubiquitous competition) , all these features make the channel uniquely useful in their contribution to noosphere :) 👍👏🏆

I am French chemist...very far from math in general... but your way of explaining and showing interesting mathematical things made me read my old book of mathematical analysis :D Thank you and please continue!

I've always thought your visualizations are among the best I've ever seen. Thank you 3Blue1Brown for getting me back into Mathematics after graduating from university!

I don't know if anyone will ever see this comment, but as an Electrical Engineering student, I guarantee that Fourrier and Convolution are very powerful tools. We can analyze an entire circuit through equations modeled using fourrier and laplace. Note: I was taken by surprise, I wasn't even looking for videos on this subject.

This was thrilling and magical the whole way through. This is one of the few times I've been able to see what was coming at every turn - I just spent yesterday working on a problem involving convolutions, and when that little hint popped up about the relationship between the Fourier transform and the integral definition of a convolution, it was an exhilarating feeling!

A professor in college had this on his door along with a warning about assumptions and patterns. It's been in the back of my head for years to look into this and understand it!

This video takes me back to my senior-year signal processing class back in college and learning about Laplace transforms and convolutions. I knew that the term "convolutions" sounded familiar and it seems like Fourier transforms are just a special case of Laplace transforms! This is why I love your channel - it brings back memories of learning (and the trickiness of these topics) from the past and it's sending me into a deep rabbit hole of trying to remember much of this topic. I've never commented on any of your videos before but thank you for this great video and all the others you have done over the years.

Your videos are, by far, the BEST videos on whole YT...
Explain these concepts, with the simplicity and naturalness you use... How it can be even possible? Out of this universe...
Thank you 3B1B.

These videos are just gorgeous. You make seemingly complex problems almost unnecessarily intuitive. It's a thing of beauty.

These are the kind of awesome videos that I wish I had back in my undergrad in Physics. So helpful and intuitive!

that little drawing sequence caught me by surprise, its really fun and i love how seamlessly it mixes into the video! didn't even feel like its a new thing, nice :)

For some reason watching this video the though of DNA telomeres jumped into my mind. The fact that they shorten but remain relatively functional all the way until that critical threshold after which they fail to produce coding sequence protection. It’s just fascinating how our world’s laws just mesh and meld into one another from math to biology to space-time geometry

Wow those visualisations are magical, your channel never stops to give me goosebumps. Thank you so much

Just when I was looking for a good maths problem to ponder, you swoop in to save the day! Thank you Grant for everything you do.

In a 20 minute video, 3b1b teaches what my school takes 1 month to teach

This type of stuff takes me back 20 years to my college days in the best possible way. Thanks for helping keep that feeling of wonder and amazement alive.

fun fact: Bor means wine in Hungarian, and Wein means wine in German, so if you translate it, it's the winewine integral.

Amazing to see the convolution and Fourier relationship conspire to create this interesting pattern!

Great timing! Just this week I took a dive into signal processing and I learnt about fourier transforms and convolutions, you chose a very interesting aspect of this area of math. Awesome video, I'm looking forward to the rest of the series!

Excellent ! That may also be an example of why proofs by induction are required : observing the first terms of a sequence never tells you for sure what happens next ...

Not only visuals are amazing, the wording script of what you say is insanely accurate and well-thought

I knew a lot about that, and still I learned a lot. Such a magical video. Keep this up. Can't wait for the next in the series.

Wow, im so amazed! I had some lectures on Fourier transform and it is AMAZING to see these integrals be so wonderfully explained! Thank you so much ❤

Wow, I've never even taken a calculous class and somehow I was still able to fully understand why the pattern doesn't hold because of your explanation and animations! This is such a well put together video!

Oh man, it's such a privilege to have access to the material you produce. I don't deserve it. I feel sorry for all those brilliant minds that ever existed who would have appreciated this so much. World is better with you.

Oh man, can't wait for the next video! Even though I know convolutions very well and have used them quite often, I never was able to really wrap my head around how they work, and I'm looking forward to changing that with the follow up video :)

I went through all this in college, but that was *many* years ago. It’s nice to see the beauty of it laid out again (and without having to worry about reducing it to practice on a test next week 😁)

I'm familiar with all the concepts of this video except for convolutions, so I'm looking forward to the next one. Excellent, well thought out explanations and graphical representations.

As an electrical engineering student, convolution and Fourier transform are very useful and interesting concepts. I loved this video.

he makes such niche and complex subjects seem so simple! very nice

As soon as you started talking about rectangular pulses and the value of f(0) I immediately realized it was going to be Fourier frequency analysis and the DC offset, amazing video!

This left me breathless! Wow!
What looked like an insane thing not only got explained, but even gave me the feeling that I understood (most of?) it!
You are an amazing explainer of math!!!

My background is in optics rather than maths; as soon as you switched the discussion to rect functions, I could see the whole remainder of the discussion laid out. Very satisfying, and a great discussion!

Gosh. Convolutions were always a difficult topic to learn as it is tricky to wrap my head around computing them. The representation of the moving average to explain convulsions is quite elegant and cool. It is always great to understand the intuition and the deeper meaning behind math concepts. Can't wait for the next video!

Currently studying 'Signals and Systems' so a video about convolution is absolutely godsent.
Great video as always!

slowly but surely i'm learning that sinc() is the heart and soul of digital audio. your graphics of how the Fourier transform of a pulse relates directly to the wavy sinc() just makes me feel warm and fuzzy. add in the superposition principle, and digital audio just makes total sense to me - many thanks for showing me another way to think about this

Your visuals are top notch as always! Such great explanations here too!

I just finished a signal processing course and this is what we did all semester. So satisfying to have it explained here!!

Fun fact (also somewhat connected to the Fourier transform): You can actually integrate sin(x)/x using the Feynman trick of introducing a new parameter and then differentiating under the integral sign, but to do this you needed to somehow come up with the crazy idea of setting F(a) = integral of sin(x)/x * e^(-ax) dx from -infinity to infinity. (The rest is a routine calculation of finding F'(a), and integrating it back to get F(a), and substituting a = 0.)

This is fascinating! I happen to be looking into Fourier transforms right now, so this was a timely video indeed. I love the insight about the interval shrinking by what is effectively a subset of the Harmonic Series (which diverges). Interesting to see a real world example where what initially appears to be a weird arbitrary cutoff point turns out to have a rather elegant explanation. I look forward to the next video!

I always love your videos, great visual and oral explanations that make difficult phenomenon clear (this one in particular)! Thank you so much for your work!

I graduated in electrical engineering munching transforms and convolutions for breakfast, but never really understood what I was doing and where it all came from. These videos have been full of a-ha moments so far. Looking forward to the next one!

This is fantastic! I have actually used the relation between the convolutions of rect functions and the multiplied sinc functions in my work. The convolution of rect functions is actually one way to express a jerk-limited motion curve. Separating it into the sinc functions in frequency space can help tremendously to understand the impact that such a motion curve has on a control loop. Really cool to see this here! 🙂

Love this video!
As an electrical engineering student, I immediately link everything together as soon as I see the rect(x) and the moving average!

Wow this is absolutely extraordinary. I mean the way you explain it and how you visualize it. Really well done!

I've been aching for a high-level Fourier video for *so long* that I almost considered making one for SOME1, but holy cow this is amazing! Kudos

Convolutions and Fourier Transforms were my favorite parts of math. Great introduction here.

Yet another amazing video. Your animations and approach to explaining the problem are just great and help a lot in understanding.

Why do you manage to blow my mind with every single video you make?

as someone in college right now with a focus in signal processing, I immediately knew where this was going within the first 3 minutes, and it was immensely satisfying to see that confirmed :) great video as always.

me watching these videos to feel smart, knowing full well that i don’t understand a word he’s saying

Excited for the convolutions video. We learned to compute them pretty robotically for solving certain differential equations, but the intuition for what they were and how they were making things easier was almost completely swept under the rug (as is unfortunately the case for a lot of introductory diff EQ). Amazing video as always!

This is the first time I’ve felt genuinely excited for the next release of a heavy esoteric math / cs video series. Bravo!

Always makes my day better when I see that 3B1B uploads

I highly appreciate the math behind your videos. A video on Taylor's remainder theorem would complement his existing videos on Taylor series and enhance our intuition in calculus.

Your illustration at 12:40 showing how the initial wave form and the fourier transform can be calculated from it as a continous integral of the corresponding constituent waves is absolutely genious.
For a person that thinks much more visualy than most this was a perfect for me
Thank you

It's especially nice to watch this video after your convolutions video!

This takes me back to my childhood. Sitting in the Oakland Public Library reading a book about the unknown formula of an egg. You have such an amazing way of presenting!

Signals and Systems 101... Laplace transforms Heaviside step functions and convolution are our bread and butter as electrical engineers. I loved this video more than you could know!

I love watching these videos and having a moment where it clicks before its directly explained why something matters. Doesn't always happen but it is nice when it does.

This takes me back about 25 years, studying electrical engineering at the university. Laplace transform seemed like magic then. It is always a joy to listen an enthusiast.

Just finished one of my EE semesters and we learned convolution and Fourier transforms/series. This video would of been so nice to see a few months ago. Still great to see though.

As an electrical engineer, I was nodding along the whole way. Love your videos as fun reviews on key concepts! Also thanks for tackling these more "convoluted" topics ;)

Thank you for the videos and the work you are putting in to explain those concepts!
This is great!

This is a beautifully done video with a great convolution teaser. Thanks!

The fact that 57k other people watched this with me within the first 2 hours of its posting makes me happy for humanity.

As someone who never heard of Convolution and all that stuff. Things got confusing rather fast after like minute 10. But thanks to visuals and simplified explaination i could follow somehow. Top vid.

Another fascinating and thoroughly stimulating video - my only problem - how on earth do I find the time to follow up all the incredible pointers to new learning and experience in these great videos? Amazing how the team can keep coming up with such wonderful insight and explanations. Also - the illustrations are wonderful as aids in understanding. Thanks to the team so much for all the hard work.

12:35-12:50 I have never seen a more beautiful and succinct depiction of WHAT Fourier transforms are, and how they work. Brilliant.

As a guy, who's already quite familiar with Fourier transform and convolution, and even with this "strange" fact of integral sequence breaking at 15,
That was truly wonderful feeling of "holy moly, all that time it was just 1/3 +... + 1/15 > 1 and that explains everything"
I just never gave myself a moment to ponder about why should it be so,
Huge thanks once again!

My gut said this would be something to do with 15 being the first odd number with two distinct prime factors. I was expecting another video that was about the secret relationship between pi and primes. But this went in a very different direction and it was so incredibly fun to learn about

Excellent presentation. The way you have started the video, it compelled me to watch it, and I am happy to see that you have made the connection between Fourier transform and convolution process. The most interesting thing is that you have given clear justification why the integral value deviates from pi after the stage of 1/15. I am Professor and researcher in signal processing (more specifically Adaptive Signal Processing) and I tried to make extensive treatment to Fourier Series, Fourier Transform (FT), DFT, convolution in my channel. I hope if anyone is interested to learn more about these topics, he/she may follow the channel. I really like your animation. It is so beautiful and interesting. Thanks for your great effort.

I'm in the midst of learning Fourier Transforms at university and at the start, before even mentioning Fourier Transforms I was like this integral looks oddly familiar and the rect function seems like an ideal problem for a Fourier series. Seeing the connection in such a nice and visual way is so beautiful!

Those visuals are top notch 😍😍, always astonishing how you can teach complex concepts in such a simple way.

The world does not deserve a video of this quality. Thank you so much, Grant.

Fascinating. Looking forward to the convolution video!

I love your explanation of the Fourier Transform. It has been magical for electrical engineering and digital signal processing. The FFT on discrete data makes this all possible.