Welcome :: Homework Help and Answers :: Mathskey.com
Welcome to Mathskey.com Question & Answers Community. Ask any math/science homework question and receive answers from other members of the community.

13,459 questions

17,854 answers

1,446 comments

805,772 users

(b)find the exact solution of the differential equatin analytically,and (c) compare the solutions at the given x-value.

0 votes

(a) Use Euler's Method with a step size of h = 0.1 to approximate the particular solution of the initial value problem at the given x-value, (b) find the exact  solution of the differential equatin analytically, and (c) compare the solutions at the given x-value.

Differential Equation             Initial condition             x-value

asked Feb 11, 2015 in CALCULUS by anonymous

4 Answers

0 votes

(a)

Step 1:

The differential equation is .

The initial condition is .

Step size is .

Euler's method is a numerical approach to approximate the  particular solution of the differential equation.

Let that passes through the point .

From this starting point, one can proceed in the direction indicated by the  slope.

Use a small step , move along the tangent line.

and .

Step 2:

Use step size , , and .

So we have , , , ,.....and,

answered Feb 17, 2015 by yamin_math Mentor
0 votes

Contd....

Step 3:

Proceeding with similar calculations, we get the values in the table:

 From the table particular solution at x = 2 is 3.031.

 Solution:

The particular solution at x = 2 is 3.031.

answered Feb 17, 2015 by yamin_math Mentor
0 votes

(b)

Step 1:

The differential equation is .

The initial condition is .

Solution to the differential equation :

Integrate on each side.

Substitute initial conditions , .

The exact solution is .

 Solution:

The exact solution is .

answered Feb 17, 2015 by yamin_math Mentor
0 votes

(c)

Step 1:

The differential equation is .

From Euler's method, particular solution at x = 2 is 3.031.

From the exact solution :

The exact solution is .

Substitute x = 2 in exact solution.

Solutions to the 3rd degree equation are .

Imaginary values are neglected.

So the particular solution at x = 2 is 3.

Therefore the particular solution at x = 2 is almost same in both the methods.

 Solution:

The particular solution at x = 2 is almost same in both the methods.

answered Feb 17, 2015 by yamin_math Mentor
edited Feb 17, 2015 by yamin_math

Related questions

...