for the following series state whether the divergence test applies either state that lim n-> infinity...

Apply the Root Test to determine convergence or divergence, or state that the Root Test is...

Apply the Root Test to determine convergence or divergence, or state that the Root Test is inconclusive. from n=1 to infinity (3n-1/4n+3)^(2n) Calculate lim n→∞ n cube root of the absolute value of an What can you say about the series using the Root Test? Determine whether the series is absolutely convergent, conditionally convergent, or divergent.

Test the series for convergence or divergence. ∞ (−1)n 8n − 5 9n + 5 n...

Test the series for convergence or divergence. ∞ (−1)n 8n − 5 9n + 5 n = 1 Step 1 To decide whether ∞ (−1)n 8n − 5 9n + 5 n = 1 converges, we must find lim n → ∞ 8n − 5 9n + 5 . The highest power of n in the fraction is 1    1 . Step 2 Dividing numerator and denominator by n gives us lim n → ∞ 8n − 5 9n +...

State whether the given series converges or diverges, and why. #21 sum 1/n^5, n=1 to infinity...

State whether the given series converges or diverges, and why. #21 sum 1/n^5, n=1 to infinity #22 sum 1/5^n, n=0 to infinity #23 sum 6^n / 5^n, n=0 to infinity #24 sum n^-4, n=1 to infinity #25 sum sqrt(n), n=1 to infinity

Determine whether the series Summation from n equals 0 to infinity e Superscript negative 5 n∑n=0∞e^−5n...

Determine whether the series Summation from n equals 0 to infinity e Superscript negative 5 n∑n=0∞e^−5n converges or diverges. If it​ converges, find its sum. Select the correct choice below​ and, if​ necessary, fill in the answer box within your choice. A.The series converges because ModifyingBelow lim With n right arrow infinitylimn→∞ e Superscript negative 5 ne−5nequals=0. The sum of the series is nothing. ​(Type an exact​ answer.) B.The series diverges because it is a geometric series with StartAbsoluteValue r...

Use the RATIO test to determine whether the series is convergent or divergent. a) sigma from...

Use the RATIO test to determine whether the series is convergent or divergent. a) sigma from n=1 to infinity of (1/n!) b) sigma from n=1 to infinity of (2n)!/(3n) Use the ROOT test to determine whether the series converges or diverges. a) sigma from n=1 to infinity of    (tan-1(n))-n b) sigma from n=1 to infinity of ((-2n)/(n+1))5n For each series, use and state any appropriate tests to decide if it converges or diverges. Be sure to verify all necessary...

Consider the following series: lim n=1 to infinite 1 + 2n/ 3^n (a) Determine the value...

Consider the following series: lim n=1 to infinite 1 + 2n/ 3^n (a) Determine the value of s2, the second partial sum. (b) Does the series converge? Explain why or why not

Use the ratio test to determine whether∑n=12∞n2+55n converges or diverges. (a) Find the ratio of successive...

Use the ratio test to determine whether∑n=12∞n2+55n converges or diverges. (a) Find the ratio of successive terms. Write your answer as a fully simplified fraction. For n≥12, limn→∞∣∣∣an+1an∣∣∣=limn→∞ (b) Evaluate the limit in the previous part. Enter ∞ as infinity and −∞ as -infinity. If the limit does not exist, enter DNE. limn→∞∣∣∣an+1an∣∣∣ =   (c) By the ratio test, does the series converge, diverge, or is the test inconclusive?

Determine whether the given series is convergent or divergent. Show you work and state the theorem/test...

Determine whether the given series is convergent or divergent. Show you work and state the theorem/test you use. Σ (2)/(sqrt(n)+2) n=1 and upper infinity

Determine whether the given series is convergent or divergent. Show you work and state the theorem/test...

Determine whether the given series is convergent or divergent. Show you work and state the theorem/test you use. Σ(-1)^n (sqrt(n))/(2n+3) n=1 and upper infinity

1. Test the series below for convergence using the Root Test. ∞∑n=1 (4n/10n+1)^n The limit of...

1. Test the series below for convergence using the Root Test. ∞∑n=1 (4n/10n+1)^n The limit of the root test simplifies to lim n→∞ |f(n)| where f(n)= The limit is:     Based on this, the series Diverges Converges 2. We want to use the Alternating Series Test to determine if the series: ∞∑k=4 (−1)^k+2 k^2/√k^5+3 converges or diverges. We can conclude that: The Alternating Series Test does not apply because the terms of the series do not alternate. The Alternating Series Test...