Use the pull down menu to state whether the series converges or diverges and by which...
Check if the following series converges absolutely, converges conditionally, or diverges. I know the series converges conditionally. This is determined by testing the series for "normal” convergence with the integral test, comparison test, root test or ratio test. If the series fails to be absolutely convergent the alternating series test is used in step 2. 2n + 3 Σ(-1)*. 3n2 +1 n=1
se a convergence test of your choice to determine whether the following series converges or diverges. 002 Select the correct choice below and, if necessary, fill in the answer box to complete your choice. O A. The Ratio Test yields r = This is greater than 1, so the series diverges by the Ratio Test. O B. The terms of the series are alternating and their limit is so the series converges by the Alternating Series Test. OC. The Ratio...
Use the Divergence Test to determine whether the following series diverges or state that the test is inconclusive. n=1 Select the correct answer below and fill in the answer box to complete your choice. k-+00 O A. According to the Divergence Test, the series converges because lima ko (Simplify your answer.) OB. According to the Divergence Test, the series diverges because lim aka (Simplify your answer.) OC. The Divergence Test is inconclusive because lima. (Sirrplify your answer.) OD. The Divergence...
Use the alternating series test to determine whether the series converges or diverges. Do 1 problem. 2n 1) Σ-1)". 2) Σ-1)" 3) Σ-1)**1. 4) 4η + 3 8 + 1η 4n' +2 cos(ηπ) 1 5) Στο Hel
(1 point) This series converges Check all of the following that are true for the series 5 sin na n2 n-1 OA. This series converges OB. This series diverges C. The integral test can be used to determine convergence of this series. D. The comparison test can be used to determine convergence of this series. E. The limit comparison test can be used to determine convergence of this series. OF. The ratio test can be used to determine convergence of...
QUESTION 8.1 POINT Determine whether the following geometric series converges or diverges, and if it converges, find its sum. -4()** If the series converges, enter its sum. If it does not converge, enter Ø. Provide your answer below: P FEEDBACK Content attribution QUESTION 9.1 POINT Given 72 2 (n! Inn)" which of the following tests could be used to determine the convergence of the series Select all that apply. Select all that apply: The alternating series test. The ratio test....
(I point) (a) Check all of the following that are true for the series Σ 2-1 A. This series converges B. This series diverges C. The integral test can be used to determine convergence of this series. D. The comparison test can be used to determine convergence of this series. E. The ratio test can be used to determine convergence of this series. F. The alternating series test can be used to determine convergence of this series. (b) Check all...
Use the Limit Comparison Test to determine whether the series converges or diverges 7n2+2 4n° +3 n-l
Use the Limit Comparison Test to determine whether the series converges or diverges 7n2+2 4n° +3 n-l
Determine whether the series converges or diverges. n + 1 Σ +n n = 1 The series converges by the Limit Comparison Test. Each term is less than that of a convergent geometric series. The series converges by the Limit Comparison Test. The limit of the ratio of its terms and a convergent p-series is greater than 0. The series diverges by the Limit Comparison Test. The limit of the ratio of its terms and a divergent p-series is greater...
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(b) Determine whether the alternating series converges or diverges by using the alternating series test: 2n 4n-3 n=1