This reminds me of a topology class I shouldn't have passed

These videos are absolutely awesome. You’ve no idea how many people you actually teach Michael, you are basically my teacher

Thanks Dr Penn for making amazing videos on mathematical analysis

Sir, when will you start linear algebra ?

He is definitely the best math teacher at KZbin!

I’m wondering if you would give some motivation regarding the usefulness of these theorems? Even if you merely say “this helps us prove xyz in the future.” Basically, tell us why these concepts matter in the larger picture. Aside: I’m absolutely loving your real analysis series. I look forward to more episodes!

16:11

6:42 we can also prove that 0 is the only limit point of A ={1/n, n ≥ 1}

@Michael Penn Are the limit points of a sequence the same thing as a limit point of a set? I am using Terrence Tao's Analysis 1 and 2 and he defined the limit point of a sequence in a metric space (X,d) as follows: ''Suppose that x_n (from n=m to n=infinity) is a sequence of points in a metric space (X,d). Let L be in space X. We say L is a limit point of the sequence x_n if and only if for every N>=m and for every (epsilon) > 0 there exists an n>=N such that d(x_n, L) =n} (as I did in step 2) is not correct? Or are the definitions for limit points of sequence and limit points of sets not the same thing?

Sir I think that at 3:43 you meant "2+e/2 is definitely not equal to 2..."

Please upload a series of measure theory.

I wonder, shouldn't we take some care of the situation that some a_n's might be equal, I mean there's nothing wrong with it even according the very definition of a limit of sequence (the induced sequence), however I think we intuitively expect all the terms a_n to be distinct and I think it's good to point out in the very statement of the teorem that it's not an issue (in the end taking a finite number of a_n's won't work as a sequence converging to x, as a_n's should not be equal to x, whereas the fact that we might end up taking particular elements of the set more than once is not itself a problem)

4:26 nice transition

Is the second theorem correct? I found a counter example but not sure if it's correct.... the sequence a_n = Cos(npi/2) /n and the set A be { +-1/n such that n is natural number } U {0} . Clearly sequence lies inside the set A and coverges to 0 but also multiple terms of the sequence are 0. Given that the reverse condition is not satisfied, we still have that 0 is a limit point of the set A. Did i go wrong anywhere? Can someone help me out......

Thanks for all your great instructional videos! I was going to hit the like button but this video is currently at pi likes and I didn't have the heart to change that

Thank you sir for your great lecture .

Sir...what are the limit points of the set {cosn: n is any natural number}?

Do we need to invoke the axiom of choice in order to choose some a_n in the (possibly) infinite set that you've constructed in your "if" direction? Is there any proof that you know of that doesn't rely on the axiom of choice?

emm i may be wrong but you do not need to have epsilon >0 since the Ve ist symmetrical around zero and you need just epsilon not equal to zero

Your content is amazing!

Pls do imo 2006 problem 5 thx for the hard work.

Really grinding up the chalk today.

Really helpful to get a handle on point set topology of the set of real numbers. Thanks for getting this ball rolling! One issue that I hope you can clarify is this: Various authors I have read have lumped together limit point, accumulation point, and cluster point. However, I came across at least one author who tried to define all 3 somewhat differently but I can no longer find that reference. Are you able to draw any distinctions among those 3 terms?

Another great video. Wonder if you might be on the lookout for opportunities to deliver an informal explanation of the intuition of a thing. The proofs get a bit dry and abstract and sometimes i just need a sentence or two on the jist of a thing to orient my thinking a bit. When I heard the learn’d astronomer, When the proofs, the figures, were ranged in columns before me, When I was shown the charts and diagrams, to add, divide, and measure them, When I sitting heard the astronomer where he lectured with much applause in the lecture-room, How soon unaccountable I became tired and sick, Till rising and gliding out I wander’d off by myself, In the mystical moist night-air, and from time to time, Look’d up in perfect silence at the stars. - WALT WHITMAN

Tank you techer for this vidios can you plise explained graph theory

An interesting question (gleefully lifted from an exercise in baby Rudin) that I'd like to see a detailed solution to (been 20 years since I took undergraduate Analysis). "Construct a bounded set of real numbers with exactly 3 limit points." I get lost in a few of the details.

5:30 won't we be out of the interval if epsilon is great than 2. Should we put a cap on epsilon so it stays in the interval?

In Spain is called acumulation point

Sir ... Is it necessary, that limit point should be ... In side the set ....???

Maybe first? Doubt it.

Isn't that definition wrong? This part confused me so much, because the definitions given made no sense, and was obviously flawed. It must contain x AND at least another point other than x... Not just any point which is not x (which this definition suggests), because then every single possible point is a limit point.

this is so hot

Chalk drop

About time to move your merchandise off Teespring given their association with extreme rightwing issues?

he needs to apply the brakes...!!