Taylor Series. Math114. March 1, Department of Mathematics, University of Kentucky. Math114 Lecture 18 1/ 13

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1 Taylor Series Math114 Department of Mathematics, University of Kentucky March 1, 2017 Math114 Lecture 18 1/ 13

2 Given a function, can we find a power series representation? Math114 Lecture 18 2/ 13

3 Given a function, can we find a power series representation? When can we find such a thing? Math114 Lecture 18 2/ 13

4 Given a function, can we find a power series representation? When can we find such a thing? If it exists, how can we construct it? Math114 Lecture 18 2/ 13

5 Suppose f can be written as a power series centered at a. Then, f (x) = c n (x a) n = c 0 + c 1 (x a) + c 2 (x a) 2 + c 3 (x a) 3 + f (x) = c 1 + 2c 2 (x a) + 3c 3 (x a) 2 + f (x) = 2c 2 + 3!c 3 (x a) + f (x) = 3!c 3 + 4!x 4 (x a) + Math114 Lecture 18 3/ 13

6 Suppose f can be written as a power series centered at a. Then, f (x) = c n (x a) n = c 0 + c 1 (x a) + c 2 (x a) 2 + c 3 (x a) 3 + f (x) = c 1 + 2c 2 (x a) + 3c 3 (x a) 2 + f (x) = 2c 2 + 3!c 3 (x a) + f (x) = 3!c 3 + 4!x 4 (x a) + Evaluating at x = a: f (a) = c 0 f (a) = c 1 f (a) = 2c 2 f (a) = 3!c 3. f (n) (a) = c n = c n = f (n) (a) Math114 Lecture 18 3/ 13

7 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) =. f (n) (a) (x a) n for x a < R. Math114 Lecture 18 4/ 13

8 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) = Defintion. f (n) (a) (x a) n for x a < R. f (n) (a) (x a) n is called the Taylor Series representation (expansion) for f centered at a. Math114 Lecture 18 4/ 13

9 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) = Defintion. f (n) (a) (x a) n for x a < R. f (n) (a) (x a) n is called the Taylor Series representation (expansion) for f centered at a. If a = 0, it is sometimes called a Maclaurin Series. Math114 Lecture 18 4/ 13

10 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) = Defintion. f (n) (a) (x a) n for x a < R. f (n) (a) (x a) n is called the Taylor Series representation (expansion) for f centered at a. If a = 0, it is sometimes called a Maclaurin Series. Example: Find the Maclaurin series for f (x) = e x. Math114 Lecture 18 4/ 13

11 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) = Defintion. f (n) (a) (x a) n for x a < R. f (n) (a) (x a) n is called the Taylor Series representation (expansion) for f centered at a. If a = 0, it is sometimes called a Maclaurin Series. Example: Find the Maclaurin series for f (x) = e x. Note: f (n) (x) = e x for every n. Math114 Lecture 18 4/ 13

12 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) = Defintion. f (n) (a) (x a) n for x a < R. f (n) (a) (x a) n is called the Taylor Series representation (expansion) for f centered at a. If a = 0, it is sometimes called a Maclaurin Series. Example: Find the Maclaurin series for f (x) = e x. Note: f (n) (x) = e x for every n. So, f (n) (0) = e 0 = 1 for every n. Math114 Lecture 18 4/ 13

13 Theorem If f has a power series representation c n(x a) n for x a < R, then c n = f (n) (a) That is, f (x) = Defintion. f (n) (a) (x a) n for x a < R. f (n) (a) (x a) n is called the Taylor Series representation (expansion) for f centered at a. If a = 0, it is sometimes called a Maclaurin Series. Example: Find the Maclaurin series for f (x) = e x. Note: f (n) (x) = e x for every n. So, f (n) (0) = e 0 = 1 for every n. So, the Maclaurin series for f is f (n) (0) (x 0) n 1 = x n Math114 Lecture 18 4/ 13

14 We have shown: IF e x has a power series representation, THEN it is xn Math114 Lecture 18 5/ 13

15 We have shown: IF e x has a power series representation, THEN it is xn How do we know a given function f has a power series representation? Math114 Lecture 18 5/ 13

16 f(x)=e x T 1 T 2 T Math114 Lecture 18 6/ 13

17 f(x)=e x T 1 T 2 T Math114 Lecture 18 7/ 13

18 f(x)=e x T 1 T 2 T Math114 Lecture 18 8/ 13

19 f(x)=e x T 1 T 2 T Math114 Lecture 18 9/ 13

20 Idea: Let T n (x) denote the n th degree Taylor polynomial. Let R n (x) = f (x) T n (x) (i.e. the remainder of the Taylor series). If lim n R n = 0, then f (x) = T n (x). Theorem If R n (x) = f (x) T n (x) and lim n R n = 0 for x a < R, then f (x) = f (n) (a) (x a) n on the interval x a < R. Math114 Lecture 18 10/ 13

21 Idea: Let T n (x) denote the n th degree Taylor polynomial. Let R n (x) = f (x) T n (x) (i.e. the remainder of the Taylor series). If lim n R n = 0, then f (x) = T n (x). Theorem If R n (x) = f (x) T n (x) and lim n R n = 0 for x a < R, then f (x) = f (n) (a) (x a) n on the interval x a < R. We will come back to the question: how to estimate R n? Math114 Lecture 18 10/ 13

22 Examples Find the Maclaurin series (i.e. the Taylor series centered at 0) for 1 f (x) = cos(x) Math114 Lecture 18 11/ 13

23 Examples Find the Maclaurin series (i.e. the Taylor series centered at 0) for 1 f (x) = cos(x) 2 f (x) = sin(x) Math114 Lecture 18 11/ 13

24 Examples Find the Maclaurin series (i.e. the Taylor series centered at 0) for 1 f (x) = cos(x) 2 f (x) = sin(x) 3 f (x) = 1 2 (ex e x ) Math114 Lecture 18 11/ 13

25 Examples Use series to evaluate the following limits: 1 lim x 0 sin(x) x Math114 Lecture 18 12/ 13

26 Examples Use series to evaluate the following limits: 1 lim x 0 sin(x) x 2 lim x 0 x ln(1 + x) x 2 Math114 Lecture 18 12/ 13

27 Theorem - Taylor s Remainder Estimate If f (n+1) (x) is continuous on an open interval I containing a, and x I, then there exists c [a, x] such that R n (x) = f (n+1) (c) (n+1)! (x a)n+1. Example: Using this theorem, determine how large n must be to compute e to 4 decimal places? Math114 Lecture 18 13/ 13

28 Theorem - Taylor s Remainder Estimate If f (n+1) (x) is continuous on an open interval I containing a, and x I, then there exists c [a, x] such that R n (x) = f (n+1) (c) (n+1)! (x a)n+1. Example: Using this theorem, determine how large n must be to compute e to 4 decimal places? In other words, how large must n be so that R n < ? Math114 Lecture 18 13/ 13

Section 8.7. Taylor and MacLaurin Series. (1) Definitions, (2) Common Maclaurin Series, (3) Taylor Polynomials, (4) Applications.

Section 8.7. Taylor and MacLaurin Series. (1) Definitions, (2) Common Maclaurin Series, (3) Taylor Polynomials, (4) Applications. Section 8.7 Taylor and MacLaurin Series (1) Definitions, (2) Common Maclaurin Series, (3) Taylor Polynomials, (4) Applications. MATH 126 (Section 8.7) Taylor and MacLaurin Series The University of Kansas