17:37 "your" 💀💀💀

I just wrote a paper on this trick for my senior undergradd project. Everywhere I look now I see Feynman because my browser history thinks its my favorite thing ever.

Very interesting ! We can see numerically that the limit of the integral of ln(x)*cos(ln(x))/x^t converges to 1 if we let t->1, but the integral diverges for t=1, that's crazy !

amazing video, this is a great pitfall that can happen when trying these kinds of problems, misusing theorems that have caveats that you didn't account for.

13:35 Shouldn't it be +cos u?

Hi Michael you should explain better the Feynman technique. It’s very interesting but it’s not well explained in internet

Hi Michael, love your videos! 😁 The thumbnail says "Surely your joking" instead of "Surely you're joking" - I'm not joking 😛

Damn i will have trust issues with Wolfram alpha now

At 6:50, that denominator should be t^2+2t+2.

Reminded me of a competition question where the gave an example of "proving" 1=2 using DUTIS but the reason why it didn't work was again because it didn't satisfy the requirements for DUTIS, it was quite cool because doing integration bee's you kinda come to expect the question to just allow for DUTIS.

The associated Sine Integral also seems to give Wolfram trouble, as it returns 0 for this value, but if you make your substitution you will also get a divergent integral.

I've seen a few videos that use Feynman's trick but this is the first one I can recall where the goal was to find I'(t). Other times, the strategy was to get a nice formula for I'(t), integrate it, and then evaluate it.

comment made at 0:20 in video: you know its gonna get complicate when the integral has a big 'I' in front of it. comment made at 17:37 wicked! 🙂

I wonder if Wolfram is performing an Abel Sum when it’s numerically integrating? The machinery at work here is very interesting 🤔

Feynman..❤

In the late 19th century, mathematicians were awash with so-called "pathological" functions breaking the rules of integration. Mostly, this consisted of functions discontinuous somewhere (eg: at all rational points but not irrational points) to test such as the rules of Riemann integration. In this case of differentiation under the integral, it comes down to how misbehaved can a derivative be? Volterra, for example, in 1881 constructed a function that had a bounded derivative at all points (it was differentiable everywhere) but whose derivative was so discontinuous that the (Riemann) integral of the derivative did not exist. Later on, however, Lebesgue, with his bounded/dominated convergence theorem, allowed this particular pathology to disappear. I'm no mathematician but I guess there's a test that can be applied to see if the Feynman trick would work. Or, if not, then Wolfram will continue to give the odd wrong result!

Integrate from 1 to e^1, = cos(1)+sin(1)-1=2(tan(1/2)-tan(1/2)^2)

"your joking"??

But ln x is continuous on (0,1) and cos is a continuous fn thus cos(ln x) is also continuous on (0,1). The same goes fro 1/x. Shouldnt that suffice for integrals as you can remove the point 0 from your region of integration and still get the desired value of the integral.

Integration by substitution : Am I a joke to you? u=lnx => du=dx/x

For a moment I thought it would be usin(u)-integral of(-1*-cos(u))…

Love your skills at extra high maths. That is why i tell you of an angle of inves😅t

So Wolfram is wrong?

Integration is my favorite 🎉🎉🎉🎉🎉🎉🎉. This is more funny

But why do you think Wolfram got it wrong?😮

GPT-o1 argues that the Riemann integral diverges, but that it can be regularized using Mellin transform theory to yield a value of 1. I have no idea if that makes any sense, but it might explain why we got a value of 1 in the first attempt.

It isn't "Feynman's trick". He didn't invent it, he learned the technique of integration by differentiation under the integral sign from another calculus book. Did you even read Surely you're joking Mr Feynman?

6 colours is bad, 7 colours is good. It symbolizes rainbow, not filthy stuffs