Vn+1 11. According to the Limit Comparison Test, the series does which of the n2+1 following?...
(1 point) Test each of the following series for convergence by either the Comparison Test or the Limit Comparison Test. If at least one test can be applied to the series, enter CONV if it converges or DIV if it diverges. If neither test can be applied to the series, enter NA. (Note: this means that even if you know a given series converges by some other test, but the comparison tests cannot be applied to it, then you must...
(1 pt) Test each of the following series for convergence by either the Comparison Test or the Limit Comparison Test. If either test can be applied to the series, enter CONV if it converges or DIV if it diverges. If neither test can be applied to the series, enter NA. (Note: this means that even if you know a given series converges by some other test, but the comparison tests cannot be applied to it, then you must enter NA...
(1 pt) Test each of the following series for convergence by either the Comparison Test or the Limit Comparison Test. If either test can be applied to the series, enter CONV if it converges or DIV If it diverges. If neither test can be applied to the series, enter NA. (Note: this means that even if you know a given series converges by some other test, but the comparison tests cannot be applied to it, then you must enter NA...
-/1.78 points ROGACALCET3 10.3.041. Use the Limit Comparison Test to determine whether the infinite series is convergent. 2n +1 Identify be in the following limit. Vn +1 = n-+ L = lim b The series converges. The series diverges. Submit Answer
(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 the convergence or divergence of the series. 6 + 1 lim = L > 0 converges diverges Use the Limit Comparison Test to determine the convergence or divergence of the series. Στέ ο, Vn2 + 7 √2 + 7 lim - =L >0 n00 converges diverges -/2 POINTS LARCALCET6 9.4.016. Use the Limit Comparison Test to determine the convergence or divergence of the series. 61 + 1 70 + 1 6 7 +...
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
To test the series e 2n for convergence, you can use the Integral Test. (This is also a geometric series, so we could n=1 also investigate convergence using other methods.) Find the value of e-24 dx = Preview Ji What does this value tell you about the convergence of the series e-2n? the series definitely diverges the series might converge or diverge: we need more information the series definitely converges Compute the value of the following improper integral, if it...
Use the pull down menu to state whether the series converges or diverges and by which convergence test. 3m 4 (1y Vn+3 8" n! g0- 32 443 (-1'n Σ 4n+4 00 Σ (+: 4 4 n7 n15 W Converges-Integral/Comparison Test Converges-Ratio Test Converges-Alternating Series Test Diverges-Integral/Comparison Test Diverges-Ratio Test Diverges-Alternating Series Test Use the pull down menu to state whether the series converges or diverges and by which convergence test. 3m 4 (1y Vn+3 8" n! g0- 32 443 (-1'n...
Problem 2. (1 point) Assume we are trying to determine the convergence or divergence of the series Σ 312 + 4n? n? - 512 Which of the following statements accurately describes the series? A. The series converges by the Limit Comparison Test with the series 3 B. The series converges by the Limit Comparison Test with the series C. The series converges conditionally. D. The series diverges by the Divergence Test. E. It is impossible to tell if the series...