Limit of (3/4)^(n+1) as n approaches infinity

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The limit of (3/4)^(n+1) as n approaches infinity is 0, as the denominator grows faster than the numerator. The initial approach using L'Hôpital's rule is unnecessary since both parts go to infinity without resolving the limit. A simpler method involves recognizing that (3/4) is less than 1, leading to the conclusion that the expression approaches zero. The discussion emphasizes that for any number in the interval (-1, 1), the limit of its power as n approaches infinity is also zero. Using the exponential form e^{(n+1)ln(3/4)} clarifies why the limit converges to zero without needing advanced techniques.
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Hello,

I was just wondering how to solve this limit: Limit of (3/4)^(n+1) as n approaches infinity

My attempt:
(3/4)^(n+1) = (3^ (n+1) ) / (4 ^ (n+1))
Top goes to infinity and bottom goes to infinity to use l'hopital rule.
lim = ( ln(3) * 1 * 3^(n+1) ) / ( ln(4) * 1 * 4^(n+1) )

But the correct answer is apparently 0.
Not sure if I'm totally wrong or if I'm just halfway there.

Thanks
 
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seal308 said:
lim = ( ln(3) * 1 * 3^(n+1) ) / ( ln(4) * 1 * 4^(n+1) )
You are not done here. Both numerator and denominator still go to infinity, and you didn't gain anything.

There are more direct approaches that work.
 
mfb said:
You are not done here. Both numerator and denominator still go to infinity, and you didn't gain anything.

There are more direct approaches that work.
Am I overthinking this.
Is it as simple as the denominator is larger and gets bigger faster and numerator making the whole thing = 0 for that reason?
 
seal308 said:
Am I overthinking this.
Yes.
seal308 said:
Is it as simple as the denominator is larger and gets bigger faster and numerator making the whole thing = 0 for that reason?
Something like that, but the "whole thing" never equals zero. It gets arbitrarily close to zero, though.
 
OK I'll use that logic then. thx
 
If a is any number in the interval (-1, 1), then ##\lim_{n \to \infty}a^n = 0##.

BTW, please don't delete the three parts of the homework template. They are there for a reason; namely, to help you organize your problem and the work you've done.
 
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I see thanks again.
 
if you write (3/4)^(n+1) as ##e^{(n+1)\ln{(\frac{3}{4})}}## maybe it will be easier to see why it goes to zero since the ln is negative & you don't need l'hopital's rule either.
 
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