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

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Homework Help Overview

The discussion revolves around evaluating the limit of (3/4)^(n+1) as n approaches infinity, a topic within calculus focusing on limits and exponential functions.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • The original poster attempts to apply L'Hôpital's rule but questions whether this approach is effective. Some participants suggest that the denominator grows faster than the numerator, leading to a limit of zero. Others propose alternative methods, such as rewriting the expression using the natural logarithm.

Discussion Status

Participants are exploring different interpretations of the limit and discussing various approaches. Some guidance has been offered regarding the behavior of the numerator and denominator, as well as suggestions for alternative methods that do not require L'Hôpital's rule.

Contextual Notes

There is mention of homework guidelines that encourage organization of the problem and the work done, indicating that participants are expected to follow a structured approach in their discussions.

seal308
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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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