How Do You Calculate the Limit of (2n-1)/(3n+1) as n Approaches Infinity?

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SUMMARY

The limit of the function (2n-1)/(3n+1) as n approaches infinity is calculated to be 2/3. The method involves recognizing that the highest powers of n in both the numerator and denominator are the same, allowing the use of their coefficients directly. An alternative approach is to divide each term by n, simplifying the expression to (2 - 1/n)/(3 + 1/n), which also leads to the limit of 2/3 as n approaches infinity. This discussion clarifies the calculation process and provides a useful online reference for further learning.

PREREQUISITES
  • Understanding of limits in calculus
  • Familiarity with polynomial functions
  • Basic algebraic manipulation skills
  • Knowledge of asymptotic behavior of functions
NEXT STEPS
  • Study the concept of limits in calculus, focusing on L'Hôpital's Rule
  • Learn about polynomial long division for rational functions
  • Explore the properties of asymptotic notation in mathematical analysis
  • Review online resources for limit calculations, such as the provided link
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Students learning calculus, mathematics educators, and anyone seeking to understand the behavior of functions as they approach infinity.

shan
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This isn't really a homework question so feel free to move is somewhere else. My teacher tried to explain this to me but I didn't understand it so I thought I'd try hearing another person's point of view.

The question is
lim n->infinity (2n-1)/(3n+1)

The working out I was showed is
= lim n->infinity (2n+2/3)/(3n+1) - (1 2/3)/(3n+1)
= 2/3 - 0 = 2/3

What I don't understand is how to work out that the lim n->infinity (2n+2/3)/(3n+1) is 2/3. We were shown rules for limits as n tends to infinity but I don't think I've come across the above situation before.
 
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shan said:
This isn't really a homework question so feel free to move is somewhere else. My teacher tried to explain this to me but I didn't understand it so I thought I'd try hearing another person's point of view.

The question is
lim n->infinity (2n-1)/(3n+1)

The working out I was showed is
= lim n->infinity (2n+2/3)/(3n+1) - (1 2/3)/(3n+1)
= 2/3 - 0 = 2/3

What I don't understand is how to work out that the lim n->infinity (2n+2/3)/(3n+1) is 2/3. We were shown rules for limits as n tends to infinity but I don't think I've come across the above situation before.

Ok this is your function:

\lim_{\substack{n\rightarrow \infty}}f(n)=\frac{2n-1}{3n+1}

Now, there's a shortcut. I don't know if you know it already but, if the powers are the same on the numerator and the denominator, just use the coefficients. Look at the 2n and the 3n. They have the same powers of 1 so use their coefficients 2 and 3. That will basically equal to 2/3. Hope that helps. Remember only when the powers are the same.

What you can also do is divide everything by the highest power in the denominator which is going to be n.

\lim_{\substack{n\rightarrow \infty}}f(n)=\frac {{\frac{2n}{n}}-{\frac{1}{n}}}{\frac{3n}{n}+{\frac{1}{n}}}

Cancel and you're left with:

\lim_{\substack{n\rightarrow \infty}}f(n)=\frac{{2}-\frac{1}{n}}{{3}+\frac{1}{n}}

Now plug zero into the n's and you're left with:

\lim_{\substack{n\rightarrow \infty}}f(n)=\frac{2}{3}

The method you were taught seems complicated to me. :confused:
 
Last edited:
Cool, that makes it much clearer and simpler. Thanks very much :)
 
jzq said:
\lim_{\substack{n\rightarrow \infty}}f(n)=\frac{{2}-\frac{1}{n}}{{3}+\frac{1}{n}}

Now plug zero into the n's and you're left with:

\lim_{\substack{n\rightarrow \infty}}f(n)=\frac{2}{3}

I agree with jzq but with a small edition:
Since n approaches infinity in this question, I think jzq meant to say:

"Now plug zero in for (1/n)'s and you're left with:" ...

(that is because 1/infinity = 0).

A good online reference for "limit questions" can be viewed at:
http://www.jtaylor1142001.net/calcjat/Contents/CLimits.html
 
Man...limits are fun, aren't they?
 

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