5) a) Use the alternating estimation theorem to give the maximum error for approximating sin 3 us...
In Exercises 1-8, use Theorem 10.1 to find a bound for the error in approximating the quantity with a third-degree Taylor polynomial for the given function f(z) about 0. Com- pare the bound with the actual error. 2. sin(0.2),f(x)= sin x Theorem 10.1: The Lagrange Error Bound for Pn(a) Suppose f and all its derivatives are continuous. If P,() is the nth Taylor polynomial for f(a) about a, then n-+1 where f(n+) M on the interval between a and a....
I don't understand how to find the bounds on the error for number 21 and 23 20, f(x) = x2 cos x, n = 2, c = π and a In Exercises 21-24, approximate the function value with the indicated Taylor polynomial and give approximate bounds on the error. etter 21. Approximate sin 0.1 with the Maclaurin polynomial of de- gree 3. gree 22. Approximate cos 1 with the Maclaurin polynomial of de- gree 4. gree 23. Approximate v10 with...
a) Use an appropriate second degree Taylor polynomial to approximate cos(0.0002). b) Apply Taylor's Theorem to guarantee a level of accuracy for the result of Part a). c) Find a Maclaurin polynoinial suitable for approximaying cos(0.0002) with an error of less than 10-30.. You need not carry out the substitution, but you should explain how Taylor's Theorem guarantees that your pokynomail works.
Use the Alternating Series Estimation Theorem to estimate the error that results from replacing e^-x by 1-x+ (x^2)/2 when 0< x < 0.5 please show work
(1 point) Taylor's Remainder Theorem: Consider the function 1 f(x) = The third degree Taylor polynomial of f(x) centered at a = 2 is given by 1 3 12 60 P3(x) = -(x-2) + -(x - 2)2 – -(x - 2) 23 22! 263! Given that f (4)(x) = how closely does this polynomial approximate f(x) when x = 2.4. That is, if R3(x) = f(x) – P3(x), how large can |R3 (2.4) be? |R3(2.4) 360 x (1 point) Taylor's...
is the answer 5 or more terms? Use the alternating series estimation theorem to determine how many terms should be used to estimate the sum of the entire series with an error of less than 0.001. (-1)"337. n=1 n+5 or more terms should be used to estimate the sum of the entire series with an error of less than 0.001.
Consider the following function #x)-x2/5, a-1, n-3, 0.7 sxs 1.3 (a) Approximate fby a Taylor polynomial with degree n at the number a T3(x) (b) Use Taylor's Inequality to estimate the accuracy of the approximation x) Tn(x) when x lies in the given interval. (Round your answer to eight decimal places.) Consider the following function #x)-x2/5, a-1, n-3, 0.7 sxs 1.3 (a) Approximate fby a Taylor polynomial with degree n at the number a T3(x) (b) Use Taylor's Inequality to...
Use the alternating series estimation theorem to determine how many terms should be used to estimate the sum of the entire series with an error of less than 0.001 1 (-1)n +1 3 n=1 26n n + or more terms should be used to estimate the sum of the entire series with an error of less than 0.001
The series converges by the Alternating Series Test. Use Theorem 9.9: Error Bounds for Alternating Series to find how many terms give a partial sum, Sn, within 0.01 of the sum, S, of the series. -1 I n Theorem 9.9: Error Bounds for Alternating Series Let n = Σ Suppose that 0 < an+1 < an for all n and limn-too an-0. Then (- 1)i-lai be the nth partial sum of an alternating series and let S = lim Sn....
Complete all, especially part c and d (a) Glive the second-order Taylor polynomial T2 ( for the function () about a 16. 4+((X-16)/8)-(1/512) (X-16M2 b) Use Taylor's Theorem to give the Error Term E2(-f()T2) as a function of z and some z between 16 and az (((3/8) Z(-5/2)) (X-16) 3)/6 c) Estimate the domain of values z for which the error E2 () is less than 0.01. Enter a value p for which E2 ()I 0.01 for all 16 16+p,...