I don't understand your question. The integral test is used to determine the convergence (or divergence) of a series of nonnegative terms. Part of the "fine print" for this test is that the function must be monotone decreasing.RJLiberator said:Homework Statement
When using the Integral Test do you need to change the bounds to n+1 and n-1 for an increasing and decreasing function respectively?
This is a question that comes up when using the integral test.
I think that you just use the original bounds for the integral. We are a bit confused with something that the teacher wrote and I just wanted clarifying.
Homework Equations
The Attempt at a Solution
What original bounds? You're starting from an infinite series.I think that you just use the original bounds for the integral.
It doesn't really make any difference whether you integrate from 4 to ∞ or from 5 to ∞. If the definite integral comes out to a number, your series converges, and if the integral is unbounded, then the series diverges.RJLiberator said:Thank you for your reply.
Let me make this more clear.
Wiki article: https://en.wikipedia.org/wiki/Integral_test_for_convergence
Under the 'proof' section of this article it changes the bounds to n+1 and n-1 under certain occasions.
During our lecture, our instructor introduced us to this test this way.
A fellow student and I were conversing over how to use the integral test properly.
He indicated that since the function is decreasing you need to subtract 1 from the lower bound according to our notes based off this.
However, on every application/online site I do not see people subtracting or adding one to the bounds.
For example:
If you were taking the series of 1/k^2 from k = 5 to k = infinity, and wanted to do the integral test, would you set the integral up from 5 to infinity or from 4 to infinity?
The Integral Test is a method used in calculus to determine the convergence or divergence of an infinite series. It involves comparing the series to a related improper integral.
The Integral Test is used when the terms of a series are positive and decreasing. This is important because it allows us to compare the series to a related improper integral, which is necessary for the test to work.
To use the Integral Test, you first need to determine if the terms of the series are positive and decreasing. Then, you set up a related improper integral and determine its convergence or divergence. If the integral converges, then the series also converges. If the integral diverges, then the series also diverges.
The Integral Test and the Divergence Test are closely related. The Divergence Test states that if the limit of the terms of a series is not equal to 0, then the series must diverge. This can be seen as a special case of the Integral Test, where the related improper integral is evaluated at infinity and compared to the limit of the terms of the series.
Yes, there are limitations to the Integral Test. It can only be used on series with positive and decreasing terms. Additionally, it can only determine the convergence or divergence of a series, it cannot give the exact value of the sum. Furthermore, the integral used in the test must be able to be evaluated, which may not always be possible.