no BS. no beating around the bush. he cuts to the chase and just tutors. fucking lovely mate.

Andrew, this quick video has done much more for my understanding of Green’s function than my professor was able to do in 3 weeks. Thank you for the great content.

I cannot explain what an oasis this video was for me in a desert of frustration. Thank you for providing just a simple, clear example with only the necessary information. I finally feel like I have some scaffolding to understand these in general.

I'm currently trying to get my head around actually using these Greens functions and I'd like to see you do an example of a Neumann/Dirichlet boundary valued problem to solve for a potential.

Oh mein Gott! Thank you so much! So far no one has properly showed how the Green function actually workes within a problem, but thanks to your two videos I've finally understood.

I looked up greens function on accident....... I’m not disappointed (Nice video)

This is an excellent introduction to Green's functions. The example chosen was simply enough to makes the ideas shine through. This is basically the method for calculating Greens functions for all cases. When you have infinite domains you can use transforms to get the Greens function but the added pain is obtaining the inverse transform from the transformed Green's function.

I've spent the last hour or so searching through video after video about Green's functions and this was by far the best one! Thank you so much!

Beautifully explained, it appeared so easy here, while in class, I struggled to understand this. Thanks.

Awesome example! I know it was a rather simple case, but that made me feel way more confident about tackling Green’s function problems in the future!

You inspired me! I'm now doing tutoring up to Diff EQ and I've already got a reoccuring client. I'm really excited.

Wow, Green's function is an incredibly clever to solve DiffEqs

This was amazing! Can you please make another video where you find the Green's function for another operator? Or perhaps one with different boundary conditions. Thank you so much for this video, the explanation was super clear.

Thank you so much for posting this. Your explanation was clear and your manner was very kind, which I greatly appreciated as someone who has to ask for a lot of help. If you aren't a teacher or a professor, you would make an excellent one.

great, this is the best explanation that I have ever seen

very very nice presentation. I also liked how you started explaining about the Green's function using matrix inversion method to solve for vector equations.

Weldone mate. You make it sound so easy. Infact you made it easy

Amazing video but why does G satisfy the same boundary conditions as f?

Andrew!! I'm doing my Math Methods HW right now on GF, and you are much clearer than my text. Appreciate it!

Brilliant explanation ! It helped me in my mid term. Kind regards

1:31 For those interested, the Green's function may be understood like so: If you have a differential equation of form D | f > = | p > ; where D is a differential operator (in this video, Andrew chooses d^2/dx^2) then you can write | f > = D^-1 | p > + Sum( ci | hi >); where D^-1, if it exists if the inverse of the operator D, and |hi> are the such that D |hi> = 0, which are the solution for the homogenous equation D | f > = 0. Then in a standard x basis, < x | f > = < x | D^-1 | x' > is your Green's function. (Propagator for the QFT fans)

Clear and concise, perfect for my exam! ty ty

So glad you made this video. I had to miss a makeup lecture from my professor on the day he taught this and his notes were so hard to follow

A good “exercise for the viewer” is to integrate the Green’s function over 0 to pi for your choice of function (say, x^2) to verify that your answer is a second antiderivative of your function that satisfies the boundary conditions.

Excellent description, thank you!

Hey Andrew, Thx for this great tutorial. I have only one question. Can you tell me how to integrate this Green's function now, are the limits of integral from 0 to 1, and do I need to split integral into two parts?

Nice tutorial. It gave a good idea of how i can find green's function.

Did you live at home for undergrad? If so, can you do a video on what it was like adjusting to living away from home for grad school?

This is the thing I was looking for! Great 👍 👌

The first whiteboard video from you that i actually understood quite well. Don't worry, it has nothing to do with your explaining abilities, I'm sure, and everything to do with me still being in highschool :D

Awesome explanation, now it looks easy😎

Love your energy!

good job ! It's a clear-cut summarizing

Thanks a lot! This really helped me understand Green's functions.

really appreciate and enjoy your video 🎉

Great video; great lecture style. The only thing I would say is, try to learn to stand a little more to your right as you write on the board. It's tricky at first, but it will help your viewers see the stuff emerge as you speak.

I dont quite understand why is the boundary conditions of f applicable/ equivalent to G. Or did I interpreted it wrongly?

Thanks, it helped us a lot!

I am so thankful for this video! Thank you so much :)

There's a missing piece which is 1 for x=y Nice presentation dude !

youre the best ting that has happened in the history of the universe after popeyes

hey andrew great video, i have a question, let's say i know the homogenous solution do i still need the observation point (y) in your case, as for my case my function is not discontinuous so where do i use the point y if it is the case. thank you

200th video will be live of him studying

Should there be a factor of 2 floating around somewhere to make it so when you operate on your solution you get the delta function? I'm reading about Greens fxn's now and am a bit confused on that part.

How exactly would one find the solution for a specific p(x) using this function?

Thanks man. You save me alot :)

Thank you for this awesome introduction! However, I have one question. As you wrote, for a Green function ÔG(x,y) = 𝛿(x-y) must hold true. However, I do not really know how to derive 𝛿(x-y) from a piecewise defined function…? As someone who doesn’t really care about rigor, I would rewrite the piecewise definition using Heaviside step functions H(x -y), as their derivative is 𝛿(x-y). However I would like to know, if this is a proper method. Furthermore, using such an procedure would render G(y,y) being defined, contrary to the G given in your video.

Is it possible to calculate the Green's function for the Poisson's equation for Newtonian gravity

My question is what is the value of G(x,x') at x=x' ? If it is continuous then why not defined at x=x'?

isnt it easier to Fourier Transform ÔG = delta(x-y) ?

‏‪2:39‬‏ can you please explain why is it equal to the delta function?

Greens functions replace solving a hard problem with creating an even harder problem which you then have to solve in order to solve an easier problem which is made harder by solving a Green's function etc, QED and a Kronecker delta. Hence just just learn MATLAB and problems become not problems ie problem solved.

Good video.

A great video.

Why could we substitute the boundary values of f(x) in the greens function tho..??

Bien explicado. Gracias

But why is the integral of the dirac delta from the right and left of y equal to 1?(The real reason I'm presuming that tells us why we should set the difference of the derivative of the green's function at the same locations equal to 1)

Excellent

Thanks bro.

Thanks.

Why isn't G(x, y) defined at x=y? is it because of the delta? like if u were to define G at x=y then the second derivative with respect to x, it blows to infinity

Thanks a lot!

200th video should be campus tour!!!

Is really unfair that you are clever and handsome

for this specific example can't we just integrate p(x) twice to get the result?

Excuse me! Sir.... Kindly solve greens function for laplace equation in partial differential equation for non-homogeneous equation

What does the d in d^2/dx^2 mean?

awesome

Not offering tutoring services anymore? Your link is dead.

Why does the Dirac Delta have x--1 in it?

Zeroeth view!

It's Green function by the way.

Cool

what

That moment when you start watching, understand a bit, a minute goes by you understand almost nothing. What do i watching this even though i am a highschool student

Why didn't you just use the look-up table for that integral?! lol

Your underlined ONE looks like a TWO, thats really irritating

it feels like bullshit idk

Hi Andrew, People who understand physics are cursed. If you research molten salt cooled reactors (FHRs, MSRs, etc), you will understand that this is *the technology* that can reverse climate change and end poverty. Ian

It's weird, this function is not even differentiable in it's domain. Then how can it be a solution to a differential equation. These things really tick me off in physics. I guess physics is not my cup of tea.

It would be good if you improved your handwriting as it looks like a 5 year old wrote that y

Excellent