😆!!!

It was just insanely cool ! 😂👍

Is double contradiction proof always true? Our you just cheating !

@@blackpenredpen bro you can't just write ln(0) because it doesn't exist. And you can't just come and try to break this logic. You made some serious mistakes.

@@extremegamingdz1309 he literally said the same

Hey that’s a good one. Will change now. Thanks

@@blackpenredpen you didn’t 😾

@@blackpenredpen he lied!

@@blackpenredpen the lie

@@blackpenredpen how about 2 proofs 1 spoof

I found a way to prove why 0 to the power of 0 is not equal to 1, and it's legit, reply if you want to me to explain it :P

@@zerotwo9607 well, explain it boi

@@zerotwo9607 Yeah, let's see it

I have a weird proof... so we know that anything * 0 = 0 right? well we can replace the anything with x. now we know that in the equation 0x = 0, x is all real numbers right? now we can divide the coefficient of x from the equation, and get x = 0/0 and we said anything * 0 = 0? 0/0 = anything 😮 😮 😮

@@crazystuffofficialchannel4406 fam in order to get x on it's own like that you'll have to divide both sides by 0, which we all know isn't possible

Nah I am done with that spelling poll

@@blackpenredpen so you didn’t spell “contradition” four times on purpose?

@@blackpenredpen shouldn't be "contradiction"? As the KZbin closed caption says "contradiction" and u write "contradition". But still best provement 😀

The "con" in "contradition" is like the "con" in "conman". It stands for "confidence". A strong tradition of confidence.

@@Mothuzad you meant so say as con tradition right? Means Confidence tradition

lmao

But 2=0 so that means you were fine! Right?

In kidney

Hooray for new math, ne-he-hew math. It won't do you a bit of good to redo math. It's so simple, so very simple... That only a child can do it!!!

😊

StandupMaths: Mind Boggling MindYourDecisions: Mind Your Decisions YGOAbridged: MIND CRUSH!

You can prove it

@@zerotwo9607No, you can't because it isn't really "true", it's just a matter of definition. I pretty much agree 0^0 =1, but for some reason people confuse it with a case 0^m = 0 even though that's only true for positive values of 'm'. In fact, its value is often taken as many fields of maths, we just leave it undefined in standard maths is because our school teachers told us so, the reason for that is that they didn't themselves understand the whole thing very clearly, or simply couldn't bother to explain the technical details to the students

It’s not a matter of definition, it’s a matter of context. It’s indeterminate so depending on where you got your zeroes, it could be equal to 0 or 1 or 69 or whatever. This is why you can’t prove it’s not equal to 1 without saying what function the zeroes came from

@@anshumanagrawal346 hey so I don't actually know what I'm talking about sorry 😅, never been taught any of this, but is it that x^0 is x/x? And isn't 0/0 undefined? Because x^4/x^1 is x^3, and x^2 is just x^3/x^1, same with just x^1 it's x^2/x^1 so x^0 must be x^1/x^1, which is 0/0,

@@user-en5vj6vr2uThere's a very clear distinction between 0^0 (exact form), and some function whose base and exponent both go to 0, and according to you the greatest integer function of 0, should also be undefined as it's also an indeterminate form

did you comment on the wrong video

@@yoylecake313 in the sponsored segment, there is a puzzle for the viewers

and then you abused yourself instead.

@@mondherbouazizi4433 I know how that stuff works, thanks for explaining though. Just as a reminder for you, not everyone is trying to be correct in their comments on random youtube videos. In this case I just tried to explain that ln(0) reminded me of negative infinity as that is where the limit goes and this gave me the idea that this is probably where funky stuff is happening. I did not word it correctly, as again, cba.

@@mondherbouazizi4433 Verbally it's sometimes unnecessary to say "the limit as x approaches infinity bla bla" , especially when it's clear from context that's the intended meaning.

@@mondherbouazizi4433 infinity is a number. Give me one good reason not to assume a limit when calculating if infinity is unsigned like 0.

@@mondherbouazizi4433 infinity, infinity, 1, and the last one is neither, they are the same. However these can be different in context of an equation, as these are just numbers.

I have done those proofs already 😊

You can also prove the law of cosines from vector rules

@@mrpie3055 If you mean the dot product formula, that won't work as the dot product formula uses law of cosines AFAIK

2 days ago

@@pmathewizard 🧐

Wait how??

Video uploaded 1 hour ago and comment 2 days ago *Illuminati sounds play* LOL

Peyam teach us your ways.

I was searching for this comment 😅😅😅😅

@@HrsHJ Same here... are you on instagram?

That's why it's often rewritten as 1 + sum (n >= 1) [x^n/n!] to avoid this special case I think it's better to leave 0^0 undefined and always stay away from it '_'

Well, it really depends on what you mean by "division." If you mean that we cannot multiply by the multiplicative inverse of 0, then BPRP is correct. Even in wheel theory, 0 has no multiplicative inverse. Rather, / is defined as a unary involution that specifically for 0, gives a different quantity, not the multiplicative inverse. It is an extension of division, but it can be argued whether this extension deserves to be called "division" or not. So again, it depends.

​@@angelmendez-rivera351 Let's call it, "Division PRO"! "Have you been having trouble trying to divide by zero? Are you tired of having to deal with inventions from centuries in the past? Then we have just the thing for you, Division PRO™! With Division PRO™, you will be able to divide by zero and so much more! Just call ((002)-001-0001 +1)/0 to order your own Division PRO™ for only $159.99 today!"

sounds like the halting problem

I thought proof 3 was incorrect because it had a multiplication with 0

Perfect explanation!

Since we're doing a proof by contradiction, we're purposefully looking for that contradiction. You're correct that 0n = 0n wouldn't prove anything since there would be no contradiction. Instead, take m ≠ n and write 0m = 0n (this should still be true since both expressions are equal to 0). Then divide by zero and we get m = n, which contradicts the choice of m ≠ n. As for not knowing what 0/0 is, you're correct, we don't know what it equals. But we are assuming it exists (for contradiction). You can make this more rigorous by changing "divide by 0" to "0 has a multiplicative inverse." Call this inverse whatever you like (1/0 or 0^-1 or z if you'd like. Regardless, you can take the equation 0m = 0n and multiply both sides by the multiplicative inverse of 0. This leaves you with 1m = 1n (since multiplicative inverses multiply to 1 by definition). But this is a contradiction. Therefore, 0 has no multiplicative inverse.

expanding a bit bc to get 0, the angle would have to be 0 +2npi, but e^0 = 1 so that is impossible.

Why assume either 0^x = 0 or x^0 = 1? How exponents work is that by definition x^0 = 1, and the other powers are achieved by multiplying or dividing numbers by x, so 0^0 = 1.

Thanks!

@@blackpenredpen You're welcome!

Or how about... 0/0 = # Such that # is something that is not in the real numbers It looks like it is coherent

I agree, the more elegant way i would do is prove that for every real number a, star+a is also a solution, so we can conclude that the function 2^x is identically equal to 0, and then we have a contradiction

This is actually ok because we assume 2^* = 0. Since the logarithm is the inverse of the exponential function by definition, this means log2(0) = * is also true.

This can be rectified by instead noting that 2^x is strictly increasing on R.

by definition, x^0 = 1 and the other powers are defined by multiplying or dividing x^0 by x. 0^0 has nothing to do with 0/0

If im to prove that, i would say it's the same as proving if x∈ℝ, then 2^x≠0 Proof by cases: Case 1: x>0 Because 2^x>0 ∀x>0, so 2^x≠0 P.S. 2^x=e^(xln2), Bec ln2>0, we can use power series of e^x to proof 2^x>0 Case 2: x=0, then 2^x=0 Case 3: x0 then 2^x =1/2^y, But from case 1, 2^y>0 ∀ y∈ℝ, 2^x >0 ∀ x∈ℝ Hence, 2^x≠0 ∀x∈ℝ

I think you are Indian(By username) Well I also work on Reimann hypothesis and Zeta function , and I found so many simple looking integral which are not so simple , and their exact values , infinite products and series as well using Zeta function I think you should take f(x) in terms of Jacobi theta function and use functional equation of Jacobi theta function (which also used to derive Zeta functional equation)

I am in 11 grade , and I leave maths 2months ago due to pressure to gain marks

I think I shouldn't look here

@@pardeepgarg2640 okay I will try

@@pardeepgarg2640 okay, I know, indian educational system is not very good.

Lol true that

Mine is too i almost dropped my phone when i heard him say that!

This proof is flawed, simply due to the fact that it assumes that we must work in a field. No such a requirement actually exists.

@@angelmendez-rivera351 Of Course it does requires that we must work in a field since only in a field makes sense to talk of multiplicative inverses for all elements distinct from zero.

@@victoramezcua4713 Not necessarily. Wheels exist. But more importantly, appealing to structures where "every nonzero element has an inverse" does not prove that structures where "zero has an inverse" cannot exist. All you are doing is proving that those structures are not fields, which by itself, does not demonstrate much.

@@angelmendez-rivera351 What the proof shows is that if such structure exists, it must be the "field" consisting of a single element, namley 0.

@@victoramezcua4713 No, it does not. At the most, it shows that if such a structure exists and is a field, then that field is the trivial field. It does not show that a non-field structure with 0 bring invertible cannot exist.

the answer to both is "however long it takes someone to kick you across the room for your crimes."

By assuming it's a solution, it becomes defined on 0 (i.e. we assume it is defined on 0). The contradiction shows that if it's defined, it results in 1 = 0, so it must be undefined

Your proof is invalid. There is no such a thing in mathematics as "taking the 0 to the other side." There is no mathematical operation for this.

it's more like by definition, division is the inverse of multiplication, so a/0 = b implies b*0 = a and the rest is the same

@@danielyuan9862 a/0 = b does not imply a = 0·b. If b is a unit, then there exist elements defined by being solutions of the equation b·x = 1. If · is associative, then the above equation only has 1 solution, which we call b^(-1). If, furthermore, · is also commutative, then a·b^(-1) = b^(-1)·a, and division is defined a/b := a·b^(-1). An algebraic structure with these properties is called an Abelian group. In such a structure, you can have c = a·b^(-1), which implies c·b = [a·b^(-1)]·b = a·[b^(-1)·b] = a·1 = a. c·b = a also implies (c·b)·b^(-1) = c·[b·b^(-1)] = c·1 = c = a·b^(-1). So c = a/b is equivalent to c·b = a, but this is true if and only if b^(-1) exists, and · is both commutative and associative. In other words, c = a/b is equivalent to c·b = a if and only if a, b, c are elements of a set S, where (S, ·, 1) is an Abelian group. This is where the issue comes in. Abstract and universal algebra aside, in the vast majority of mathematics, theories assume a ring structure as a background. Suppose I have an Abelian group (S, +, 0). If (S, ·, 1) is a monoid that is left-distributive and right-distributive over (S, +, 0), then the structure (S, +, 0, ·, 1) is called a ring. A monoid is an Abelian group without the commutativity, and without the guarantee of existence of inverse elements everywhere in S. Monoids are particular in that, while inverse elements are not guaranteed to exist, whenever they do exist, they are guaranteed to also be unique. Why do I mention rings? Because in a ring, 0·x = 0 is necessarily always true. As such, there is no element of S such that 0·x = 1, and so 0^(-1) does not exist. So (S, ·, 1) can never be enriched into being a group, let alone an Abelian group, because 0 has no multiplicative inverse. You can adjoin an element q to the set S, so that in the structure (S[q], ·, 1), 0·q = 1, hence 0 and q are ·-inverses of one another. However, the inevitable consequence of doing this is that (S[q], ·, 1) is no longer monoid, but a loop, and in a loop, · is not necessarily associative, and in this case, it definitely is not associative. As such, a/0 = b still does not imply a = 0·b in this situation. Furthermore, you can modify distributivity so that (S[q], +, 0) is a monoid with commutativity, or a loop with commutativity, but you can also never have a group with (S[q], +, 0).