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5.3 Higher-Order Taylor Methods

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1 5.3 Higher-Order Taylor Methods
Since the object of numerical techniques is to determine accurate approximations with minimal effort, we need a means for comparing the efficiency of various approximation methods. The first device we consider is called the local truncation error of the method. The local truncation error at a specified step measures the amount by which the exact solution to the differential equation fails to satisfy the difference equation being used for the approximation.

2 local truncation error
Definition The difference method has local truncation error for each

3 local truncation error of Euler’s method
For Euler’s method, the local truncation error at the i th step for the problem is where, as usual, denotes the exact value of the solution at . . We see that Euler’s method has When is known to be bounded by a constant M on [a,b] , this implies so the local truncation error in Euler’s method is .

4 local truncation error
This error is local error because it measures the accuracy of the method at a specific step, assuming that the method was exact at the previous step. As such, it depends on the differential equation, the step size, and the particular step in the approximation.

5 Taylor method of order n
Suppose the solution to the initial-value problem has continuous derivatives. If we expand the solution, , in terms of its nth Taylor polynomial about and evaluate at , we obtain

6 Taylor method of order n
(5.15) Successive differentiation of the solution , gives , and, in general, Substituting these results into the nth Taylor polynomial gives (5.16)

7 Taylor method of order n
(5.16) The difference-equation method corresponding to Eq. (5.16) is obtained by deleting the remainder term involving . This method is called the Taylor method of order n. where

8 Example 1 Example 1 Suppose that we want to apply Taylor’s method
of order two and four to the initial-value problem Solution. We must find the first three derivative of

9 Example 1 The Taylor methods of order two is, consequently,

10 Example 1

11 Example 1 Suppose we need to determine an approximation to an intermediate point in the table, for example, at t=1.25. If we use linear interpolation on the Taylor method of order four approximations at t=1.2 and t=1.4,we have

12 Example 1 To improve the approximation to y(1.25) ,we use cubic Hermite interpolation. This requires approximations to and as well as approximations to and

13 Example 1 The cubic Hermite polynomial is 1.2 3.1799640 2.7399640
1.4 The cubic Hermite polynomial is

14 If Taylor’s method of order n is used to approximate the solution to
with step size h and if , then the local truncation error is

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