Hi, sir! Long time fan here. I watch all your videos for fun and for study. Your calculus videos are awesome and very entertaining. Got very excited when you're doing the infinite series, one of my fav topics in calculus II. Can I make suggestions for future topics for your videos? Can you make videos about the ever interesting stuff about the Bernoulli numbers, gamma function, Zeta functions, q series, Ramanujan Summation? Any stuff related to Real, Complex and Analytical Number Theory with be great for me. Thanks and keep the genius coming!
Joshua Garcia hi josh, thank you so much for your nice comment. I may not be able to do them anytime soon tho since I have a lot of topics that I want to cover for my students first. But whenever I have time, I will definitely squeeze in some videos about random math problems for fun!
@@blackpenredpen I took the natural log but then didnt think of lhopitals rule..isnt there ankther way to do it without lhopitals? I really hope you can please respond.
I thought I recognized the function. After you got the answer, I noticed this is what we called the "Pert" function for continuously compounding yearly interest. V = P(1 + R/X)^(T*X) P=initial principal R=interest rate T=number of years the money is in the bank X=the number of times a year you compound the interest (1 for yearly, 12 for monthly, 365 for daily, etc) Compounded continuously, X=infinity, so V = P*e^(R*T)
Yup! e is just the interest rate of continuous compounding over 1 unit of time (let's say year), assuming non-compounded 100% interest over 1yr. If you increase the yrs from 1 to b, you get e^b of course, since you just grow multiplicatively by e each yr. And if you increase the rate from 1 to a, you again get the same effect, because you've reduced the time it takes to get to 100% interest w/o compounding to 1/a yrs. Meaning 1 yr at rate a is identical to a yrs at rate 1, so e^a. Combining the two gets e^ab. (You can check that, by symmetry, the same effect happens when a
You explain these things in such a clear and concise way that me being a high school student, I still get some knowledge out of these videos. Hope I have some professors as good as this next year
I'm currently taking Precalculus in High School, but the way you explained it somehow makes me understand it! The videos you've been making are awesome, and I hope you continue showing us things as cool as this!
I love the informal pet names that teachers give to certain uhh facts. It's fun and it actually helps students remember important concepts! For instance, my calculus teacher called the chain rule "THE MAGIC". She always said, REMEMBER THE MAGIC.
I think I have a simpler way of doing this.... Since (1+x)^n = 1 + nx + n(n-1)x^2/2! + n(n-1)(n-2)x^3/3!........ putting x= a/x and n=bx we get 1 + ba/1! + (ba)^2/2! - b(a)^2/x+ ... and now all the terms with x in the denominator will become 0 as x->infinity so we are left with 1 + ab/1! + (ab)^2/2! + (ab)^3/3!.... this is just like the wxpression for e^x e^x = 1 + x/1! +x^2/2!....... therefore the answer is (e)^ab
@@leif1075 you find it with developemtn in serie : exp verifies the differential equation exp = d/dx (exp) so you search a solution serie of general term (a_n x^n) and you find exp(X) = Σ x^n/n! So e = Σ 1/n!
or we can say that (1+a/x)^bx = e^(bx*ln(1+a/x)) so when x approaches infinity a/x approaches zero and we can use ln(1+x) = x+ o(x) so L = e^(b*x*a/x) = e^ab !
Can't you do it much simpler if you know what e is? what you know: lim x->∞ (1+a/x)^x = e^a and g^pq = (g^p)^q so... lim x->∞ (1+a/x)^bx = lim x->∞ ((1+a/x)^x)^b = (e^a)^b = e^ab
I'm just wondering: who would encounter this problem before learning what e is I mean, you use Ln, and limits, even the property that Ln is continuous, and l'hopital's rule, so they must have some idea.
We can use lim x tends to infinity (1+a/x)^bx as e^lim x tends to infinity a/x divide by bx So e^ limit x tends to zero a/x*bx Then a /x multiple by bx and x will be cancel our And it becomes e^ab
I enjoy your videos but I'm slightly worried by this one as it could mislead people. You haven't shown the limit is e^(ab). Rather, you have shown that if there is a limit then it must be e^(ab). I would have liked you to have mentioned why the limit must exist.
... The " Special " Fact (a = 1 and b = 1) --> lim(x-->inf)(1 + 1/x)^x = e lim(x-->0)(1 + x)^1/x = e ... (lol) ... thank you for a great and very clearly understood presentation, Jan-W
The answer if obvious if you recognize this as the limit of the compound interest formula as the compounding period goes to infinity. P(1+r/n)^(t*n) - > Pe^(rt)
The result still holds if we replace a & b with sequences that converge to a & b, respectively. This is often encountered in statistics. See the following video. th-cam.com/video/k1BhXt9DgA4/w-d-xo.html
Other way to do it is to simply evaluating the limit of e^(bx * ln(1 + a/x)). Doing L'Hôpital (of course doing bx = 1/(1/bx), else it would not make sense) would be essentially the same as you did, just without equalling to anything to get an answer; OR you can use the transformation lim(x->c) ln(f(x)) = lim(x->c) (f(x) - 1) if and only if lim(x->c) f(x) = 1: e^(lim(x->∞) bx (1 - a/x - 1)) = = e^(lim(x->∞) bx * a/x) = = e^(lim(x->∞) ab) = e^ab
Why don't you utilise the definition of e.... lim x->inf (1+1/x)^x =e lim x->inf (1+a/x)^bx =lim x->inf [1+1/(x/a)]^[(x/a)(ba)] ={lim x->inf [1+1/(x/a)]^(x/a)}^ba =e^ab which is much easier....
The reason is I can show this video to my students if they have to do something like, lim as x goes to inf, (1+1/x^2)^x This limit is 1. www.wolframalpha.com/input/?i=limit+as+x+goes+to+inf,+(1%2B1%2Fx%5E2)%5Ex
Man, I really wish I'd seen your videos during A levels. You are so fun in your explenations. Now I'm studying mathematics at uni and while your vids are great I don't get the same satisfaction due to the fact that I can tell the answers myself quite easily. :(
Yes, that's very fine. Just keep posting em and me and my mates'll watch them. We're very entertained. Thanks so much for these videos. You're way fun and captivating than my professors!
Okay, so you used a natural logarithm to get bx out front. What if you used any other logarithm (such as log base 10) to do so? Would that not change the answer? Are you only allowed to make everything in your equation the exponent of the base of the logarithm you want to cancel out if it is a natural logarithm?
Can anyone correct me if I'm wrong, but this formula should still work even if the denominator x, has a constant being added or subtracted, for example x + 2 or x - 5, cause at the end, it will eventually be zero and you will be left with (ab)/(1 + 0), which is just ab
I would not put the limit L because we do not know if the limit exists a priori..maybe this techniques gives a correct result in this case ,but in general it is not correct(for pathogenic functions)..If f(x) is the function mentioned in the video i would write: f(x)=e^ln(f(x)) and the compute the limit of ln(f(x))
I feel like doing the derivative of the numerator and demonstrator doesn't guarantee continuity unless the function in the numerator and denominator are the same. otherwise the delta of one will grow at a different rate and the fraction will no longer represent the same ratio. Same reason why 1/1 = 1^4/1^4 but 4/1 =/= 4^3/1^3 you can't just apply operations willy nilly on numerator and denominator.
Or you could use the well known limit of ln(1+x)/x when x tends to 0. If you don't know that this is 1, you can see this this as the derivative of x\mapsto ln(1+x) in 0. Way easier than the 'hospital rule' that is something students absolutely don't understand well enough to use correctly.
But don't understand most probably. To the majority of student, it is like 'magic'. For proof, often they use is even if f(0) eq 0. In any case, I think my suggestion is a bit more elementary, like you wished (do itt from scratch). Especially, using the 'hospital rule' with the indentity in the denominator seems a bit complicated for nothing :p
Once I found a similar problem with a more variable in the denominator. lim x->infinity ((x+a)/(x+b))^cx following the same steps of the video -log of both sides -arranging to a fraction indeterminate form - de hospital rule it came out e^(c(a-b))
or ... (x+a)/(x+b) = (x+b+a-b)/(x+b) = 1 + (a-b)/(x+b) L = lim [(x+a)/(x+b)]^(cx) = lim [1 + (a-b)/(x+b)]^(cx) x→∞ x→∞ and then, noticing that since b is a constant, x→∞ is equivalent to (x+b)→∞ , just apply "The Fact" directly: L = e^[c(a-b)] Caution: This is a bit of a jump, and *does* need to be justified, so it's good that you did that.
I call this 'The Magical Limit Escape' When all the checks, La Hospital Rule or any other rule don't lead to me any conclusion, this formula (according to you) works as a magic and leads to the exit way!!!
Would there be a similar limit for complex z, i.e. for some sequence z_n such that for all n(in Natural numbers), there exists some N such that for all m>N, |z_m|>n, the limit lim(n->∞)(1+a/z_n)^bz_n exists and is equal to e^ab?
how about if it is a number other than 1 e.g lim x-> 0 ( 2 + a/x) inside the limit (i presume the answer doesn’t involve e any more? maybe with a natural log of an integer?)
Thanks for the great explanations!!! BTW can you also make videos for improper integrals for finding the values of p and q in the condition of convergence?
We should have to first show that (assume a and b are positive for the purpose of this comment) that function is bounded above and increasing, then we will know that there's a limit.
I know I'm VERY late, but I'm sure all of us were screaming lim x->infinity (1+a/x)^x = e^a, so technically when we multiply the x in the exponent by b we get e^ab. Is this wrong?
can you clear my doubt, that 1 to the power anything is 1 because if you keep multiplying 1 to itself its not gonna change. so why 1 to the power infinity is not one?
You could use, say, base 10 log or any other base. But, when you use L'Hopital's rule and take the derivative of log(1+a/x), guess what: a ln() will sneak in there haha.
I still don't understand why ln(lim(f(x))) = lim(ln(f(x))). You said that ln was a continuous function, which I understand, but I don't understand how that yields the swap correct algebraically.
As I mentioned above: You could use, say, base 10 log or any other base. But, when you use L'Hopital's rule and take the derivative of log(1+a/x), guess what: a ln() will sneak in there haha.
I envy your students. You are an amazing teacher.
Aaron Hollander thank you!
I really love your enthusiasm. Thank you for your videos and the magnificent lessons!
Marian P. Gajda thank you for your nice comment.
Hi, sir! Long time fan here. I watch all your videos for fun and for study. Your calculus videos are awesome and very entertaining. Got very excited when you're doing the infinite series, one of my fav topics in calculus II. Can I make suggestions for future topics for your videos? Can you make videos about the ever interesting stuff about the Bernoulli numbers, gamma function, Zeta functions, q series, Ramanujan Summation? Any stuff related to Real, Complex and Analytical Number Theory with be great for me. Thanks and keep the genius coming!
Joshua Garcia hi josh, thank you so much for your nice comment. I may not be able to do them anytime soon tho since I have a lot of topics that I want to cover for my students first. But whenever I have time, I will definitely squeeze in some videos about random math problems for fun!
@@blackpenredpen I took the natural log but then didnt think of lhopitals rule..isnt there ankther way to do it without lhopitals? I really hope you can please respond.
I thought I recognized the function. After you got the answer, I noticed this is what we called the "Pert" function for continuously compounding yearly interest.
V = P(1 + R/X)^(T*X)
P=initial principal
R=interest rate
T=number of years the money is in the bank
X=the number of times a year you compound the interest (1 for yearly, 12 for monthly, 365 for daily, etc)
Compounded continuously, X=infinity, so V = P*e^(R*T)
Yup! e is just the interest rate of continuous compounding over 1 unit of time (let's say year), assuming non-compounded 100% interest over 1yr. If you increase the yrs from 1 to b, you get e^b of course, since you just grow multiplicatively by e each yr. And if you increase the rate from 1 to a, you again get the same effect, because you've reduced the time it takes to get to 100% interest w/o compounding to 1/a yrs. Meaning 1 yr at rate a is identical to a yrs at rate 1, so e^a. Combining the two gets e^ab. (You can check that, by symmetry, the same effect happens when a
You explain these things in such a clear and concise way that me being a high school student, I still get some knowledge out of these videos. Hope I have some professors as good as this next year
Thank you. I hope you the best too. Are you in 11th or 12th grade?
blackpenredpen 12th grade, currently learning about optimization in calculus. It's my favourite subject:)
Uchiha Madara I see! That's great!! I like optimizations too and should definitely make videos on then soon!
I'm currently taking Precalculus in High School, but the way you explained it somehow makes me understand it! The videos you've been making are awesome, and I hope you continue showing us things as cool as this!
I love the informal pet names that teachers give to certain uhh facts. It's fun and it actually helps students remember important concepts! For instance, my calculus teacher called the chain rule "THE MAGIC". She always said, REMEMBER THE MAGIC.
Yea, I find it super helpful too!!
Ah, that's why he uses "fish" for the W function...
I think I have a simpler way of doing this....
Since
(1+x)^n = 1 + nx + n(n-1)x^2/2! + n(n-1)(n-2)x^3/3!........
putting x= a/x and n=bx
we get
1 + ba/1! + (ba)^2/2! - b(a)^2/x+ ...
and now all the terms with x in the denominator will become 0 as
x->infinity
so we are left with
1 + ab/1! + (ab)^2/2! + (ab)^3/3!....
this is just like the wxpression for e^x
e^x = 1 + x/1! +x^2/2!.......
therefore the answer is
(e)^ab
Makes sense
Man, that's brilliant!
But what if you didn't know or haven't proved that infinite expression for e?
@@leif1075 you find it with developemtn in serie : exp verifies the differential equation exp = d/dx (exp) so you search a solution serie of general term (a_n x^n) and you find exp(X) = Σ x^n/n! So e = Σ 1/n!
Here’s a faster way:
lim((1+a/x)^(bx))
= lim((1+a/x)^x)^b
= (lim((1+a/x)^x))^b
(1+a/x)^x = e^a when x appr infinity
= (e^a)^b
= e^(ab) //
or we can say that (1+a/x)^bx = e^(bx*ln(1+a/x)) so when x approaches infinity a/x approaches zero and we can use ln(1+x) = x+ o(x) so L = e^(b*x*a/x) = e^ab !
I really love your videos btw
Imaspammedboy thank you
Can't you do it much simpler if you know what e is? what you know:
lim x->∞ (1+a/x)^x = e^a
and
g^pq = (g^p)^q
so...
lim x->∞ (1+a/x)^bx = lim x->∞ ((1+a/x)^x)^b = (e^a)^b = e^ab
mrBorkD true. But as I said "do it from scratch" without even knowing "your fact"
I'm just wondering: who would encounter this problem before learning what e is
I mean, you use Ln, and limits, even the property that Ln is continuous, and l'hopital's rule, so they must have some idea.
mrBorkD true. But I know my students. This approach is more suitable for most of them
OK. well I can't argue with you there
Exactly how I did this :D
I mean that way it can be proven with school mathematics (Binomial theorem and power rules, that's all) and done.
"The fact" is actually a very natural property :D
it's known that lim(x-->inf) (1+t/x)^x = e^t
now if b>0 just replace by (1+(ab)/(xb)) and replace x by bx, you get e^(ab) I
if b
We can use lim x tends to infinity (1+a/x)^bx
as e^lim x tends to infinity a/x divide by bx
So e^ limit x tends to zero a/x*bx
Then a /x multiple by bx and x will be cancel our
And it becomes e^ab
we can actually do this without l'hopitals rule by the way your way of explaining is so good!
I enjoy your videos but I'm slightly worried by this one as it could mislead people. You haven't shown the limit is e^(ab). Rather, you have shown that if there is a limit then it must be e^(ab). I would have liked you to have mentioned why the limit must exist.
We can generalise the function of 1^infinity as
Lin X-->inf f(x)^g(x) = e^[{f(x)-1}g(x)]
... The " Special " Fact (a = 1 and b = 1) --> lim(x-->inf)(1 + 1/x)^x = e lim(x-->0)(1 + x)^1/x = e ... (lol) ... thank you for a great and very clearly understood presentation, Jan-W
You could also have evaluated that limit using a series expansion: ln(1+a/x) = a/x to first order, which gives you the answer in a couple more lines.
love how you call it "The Fact"! 😂
Ahmed Anwari lol! Thank you. My students love it too! It works
I wish you had been my math teacher. Great work. I enjoy your videos even though I haven't had a math class in many decades.
The answer if obvious if you recognize this as the limit of the compound interest formula as the compounding period goes to infinity. P(1+r/n)^(t*n) - > Pe^(rt)
I think I need a channel teaching the first few billion years of maths...
you and my cal 2 professor are making cal 2 very easy!! You guys are the best:)
Even if I was doing this right I'd feel like I was doing this wrong
"ln-ded both sides" what did you just say? 10:40
It's the verb to ln of course
If you sub in a and b to be 1 then you get the equation used to find e (1+(1/n)^n which makes sense coz it’s a^(1•1) which is e.
The result still holds if we replace a & b with sequences that converge to a & b, respectively. This is often encountered in statistics. See the following video. th-cam.com/video/k1BhXt9DgA4/w-d-xo.html
Other way to do it is to simply evaluating the limit of e^(bx * ln(1 + a/x)). Doing L'Hôpital (of course doing bx = 1/(1/bx), else it would not make sense) would be essentially the same as you did, just without equalling to anything to get an answer; OR you can use the transformation lim(x->c) ln(f(x)) = lim(x->c) (f(x) - 1) if and only if lim(x->c) f(x) = 1:
e^(lim(x->∞) bx (1 - a/x - 1)) =
= e^(lim(x->∞) bx * a/x) =
= e^(lim(x->∞) ab) = e^ab
... that's THE FACT Jack ... !
WJL what jack?
Why don't you utilise the definition of e....
lim x->inf (1+1/x)^x =e
lim x->inf (1+a/x)^bx
=lim x->inf [1+1/(x/a)]^[(x/a)(ba)]
={lim x->inf [1+1/(x/a)]^(x/a)}^ba
=e^ab
which is much easier....
The reason is I can show this video to my students if they have to do something like, lim as x goes to inf, (1+1/x^2)^x
This limit is 1.
www.wolframalpha.com/input/?i=limit+as+x+goes+to+inf,+(1%2B1%2Fx%5E2)%5Ex
Hey, we can take the a in bottom and at exponent we do a/a. Like this we have direct e^ab
In my personal mnemonics i'm calling this the 'E-fact'
This Fact, was indeed very well done
Man, I really wish I'd seen your videos during A levels. You are so fun in your explenations. Now I'm studying mathematics at uni and while your vids are great I don't get the same satisfaction due to the fact that I can tell the answers myself quite easily. :(
Setting a, = b = 1 is a nice way of getting to compound interest tending to e
yea
The cool accent, mic and apparent joy from calculus make this video. As all others from this guy. Goddamn do I subscribe!
LOL! Thanks!
Can't we also substitute the variables to get the( definition of e) ^ab
What if instead of taking ln on both sides you take for example base 10 log or different base log?
Then when doing L' Hopital's rule you will need to add ln(10) because of its derivative and it will get complicated
Put = ay and the result follows at once. I guess he wanted to show the principle.
You never fail to impress me!
Thanks!
Yes, that's very fine. Just keep posting em and me and my mates'll watch them. We're very entertained. Thanks so much for these videos. You're way fun and captivating than my professors!
Okay, so you used a natural logarithm to get bx out front. What if you used any other logarithm (such as log base 10) to do so? Would that not change the answer? Are you only allowed to make everything in your equation the exponent of the base of the logarithm you want to cancel out if it is a natural logarithm?
Can anyone correct me if I'm wrong, but this formula should still work even if the denominator x, has a constant being added or subtracted, for example x + 2 or x - 5, cause at the end, it will eventually be zero and you will be left with (ab)/(1 + 0), which is just ab
i don't speak english but i love this guy, i understand better than the videos in spanish
Thank you!!!!!
I would not put the limit L because we do not know if the limit exists a priori..maybe this techniques gives a correct result in this case ,but in general it is not correct(for pathogenic functions)..If f(x) is the function mentioned in the video i would write: f(x)=e^ln(f(x)) and the compute the limit of ln(f(x))
You are an amazing teacher. Thank you
NToB36 thank you for the nice comment! You are amazing too!
6:42 hocam silivri soğuktur L'hospitali youtube gibi herkese açık platformlarda kullanmayalım
I feel like doing the derivative of the numerator and demonstrator doesn't guarantee continuity unless the function in the numerator and denominator are the same. otherwise the delta of one will grow at a different rate and the fraction will no longer represent the same ratio. Same reason why 1/1 = 1^4/1^4 but 4/1 =/= 4^3/1^3 you can't just apply operations willy nilly on numerator and denominator.
Thank you so much. Your video's concept is crystal clear to me.
Great video, it was very thorough. Hopefully, this trick comes useful on my calc midterm.
yeah that's what I am telling to myself when I learn a new thing like this one...
we haven't studied "l'hopital's theorem" so here is how I would do it :
I would say let t=1+a/x so then we get lim t->1 ab ln(t)/t-1=ab
The limit as x goes to ∞ of (1+i/x)^(ix) = 1/e by the Fact
I want to be your student
this is awesome, thank you so much
Are you sure we can't differentiate with respects to n and still use L'Hopital's rule in terms of n?
Or you could use the well known limit of ln(1+x)/x when x tends to 0. If you don't know that this is 1, you can see this this as the derivative of x\mapsto ln(1+x) in 0. Way easier than the 'hospital rule' that is something students absolutely don't understand well enough to use correctly.
My students know the LH rule.
But don't understand most probably. To the majority of student, it is like 'magic'. For proof, often they use is even if f(0)
eq 0. In any case, I think my suggestion is a bit more elementary, like you wished (do itt from scratch). Especially, using the 'hospital rule' with the indentity in the denominator seems a bit complicated for nothing :p
Once I found a similar problem with a more variable in the denominator.
lim x->infinity ((x+a)/(x+b))^cx
following the same steps of the video
-log of both sides
-arranging to a fraction indeterminate form
- de hospital rule
it came out
e^(c(a-b))
or ...
(x+a)/(x+b) = (x+b+a-b)/(x+b) = 1 + (a-b)/(x+b)
L = lim [(x+a)/(x+b)]^(cx) = lim [1 + (a-b)/(x+b)]^(cx)
x→∞ x→∞
and then, noticing that since b is a constant, x→∞ is equivalent to (x+b)→∞ , just apply "The Fact" directly:
L = e^[c(a-b)]
Caution: This is a bit of a jump, and *does* need to be justified, so it's good that you did that.
You know, I think I see why you like the fact so much...
Show that limit x approaches to + infinity then prove ln(1+a^x)/x=1
Why does every colour look fade besides black?
I call this 'The Magical Limit Escape'
When all the checks, La Hospital Rule or any other rule don't lead to me any conclusion, this formula (according to you) works as a magic and leads to the exit way!!!
find a and b for lim x->inf (1+a/x)^bx = pi
you can set e^(ab) = pi, then pick whatever a and b you want to make this happen.
For example, a = 1, b = ln(pi)
Would there be a similar limit for complex z, i.e. for some sequence z_n such that for all n(in Natural numbers), there exists some N such that for all m>N, |z_m|>n, the limit lim(n->∞)(1+a/z_n)^bz_n
exists and is equal to e^ab?
lim (x to inf) (1+a/x)^bx = [t=x/a] = lim (t to inf) (1+1/t)^(abt) = [if this limit exists] (lim (t to inf) (1+1/t)^t)^ab = e^ab
any mistakes?
Thank you for “The Fact” 👌
how about if it is a number other than 1 e.g lim x-> 0 ( 2 + a/x) inside the limit (i presume the answer doesn’t involve e any more? maybe with a natural log of an integer?)
Thanks for the great explanations!!! BTW can you also make videos for improper integrals for finding the values of p and q in the condition of convergence?
Calisthenics Kim I have those already. th-cam.com/video/rwLkrGrugOk/w-d-xo.html
U can also go to www.blackpenredpen.com for more resources
Does that mean every continuous function can go through lim?
I don't recall much but I don't think you're able to assume the limit is equal to 'L' without showing the limit exists in the first place
You are right! However, that would be more of the (upper division) analysis-level of way to proceed it. This is mainly for my calc1, 2 students.
We should have to first show that (assume a and b are positive for the purpose of this comment) that function is bounded above and increasing, then we will know that there's a limit.
It is possible to solve this w/o using l'hopital right? can you please answer me how you solve this NOT using l'hopital? Thanks!
I know I'm VERY late, but I'm sure all of us were screaming lim x->infinity (1+a/x)^x = e^a, so technically when we multiply the x in the exponent by b we get e^ab. Is this wrong?
Shouldn't the differentiation of [ b * ln ( 1 + a/x) ] be a product rule?
can you clear my doubt, that 1 to the power anything is 1 because if you keep multiplying 1 to itself its not gonna change.
so why 1 to the power infinity is not one?
How can we define asymptotes of such Functions??
THE FACT
thanks btw, studying for math quiz tomorrow using this !
im so grateful for you!!
Salute to you Sir! I'm a huge fan
Could someone explain why f(lim g(x)) only equals lim(f(g(x)) when f(x) is continuous? in this case, f(x) = lnx.
I like this channel. It states facts.
If I used log base 10 instead of ln I would have a different answer. Why does it have to be ln
and what if instead of 1 we had another constant, such as C? the result would be e^(ab/c), right?
You are great sir
Please can you make Indian language videos maths
Hey ... Can you do some number theory problems ?
And you can take the ln because you can say that there ist an x0 so that 1+a/x will be positive for all x greater than x0?
If I chose to take the log of both sides, wouldn't I get 10^ab as my final answer?
No because when you used the LH rule the derivative of logx isn't 1/x. /1(xln(base))
Oh okay, thanks!
What if you take log base 10 instead of ln? would that change the answer?
He is my legitimate god
Thanks so much...the Fact is so useful for me...
You don't have to use a natural log for the calculation though, right? Would you get to the same result if you used a normal logarithm?
You could use, say, base 10 log or any other base. But, when you use L'Hopital's rule and take the derivative of log(1+a/x), guess what: a ln() will sneak in there haha.
Roderick Llewellyn Fascinating
I still don't understand why ln(lim(f(x))) = lim(ln(f(x))). You said that ln was a continuous function, which I understand, but I don't understand how that yields the swap correct algebraically.
Sir, I have a doubt. What is (infinity)^(infinity) ?
If they are both pos. inf, then the answer is pos. inf.
If one is negative and other is positive, then it's negative infinity. If both are negative, then it is positive infinity? Right ?
But can you please make a proof on this by limit... Please
I see a problem there. You use the derivative of ln to proof The Fact, and use The Fact to get the derivative of ln?
I did another vid with just the def. of e
th-cam.com/video/ccDNvXfJ0FU/w-d-xo.html
just wondering if I replaced the natural log with other logs wouldnt that change 'The Fact'? like if I use lg it would end up 10^ab, no?
No, the answer will still be the same.
As I mentioned above: You could use, say, base 10 log or any other base. But, when you use L'Hopital's rule and take the derivative of log(1+a/x), guess what: a ln() will sneak in there haha.
you are the best teacher!
why could you take the derivative of the numerator and denominator? do you have a video explaining this (or another good source)?
Look up L’Hopital’s rule
How would u do this without L'Hopitals ruile? :c
Great work. Do you have also a simple proof, that f(x)/g(x) equal to (d/dx f(x))/(d/dx g(x))?
Thnku very much sir❤🙏. It has helped a lot
lim (1-2/n)^3n = 0