How do I approach this? 61. Use Euler's method to find approximate values for the solution...
dy Use Euler's Method with step size h = 0.2 to approximate y(1), where y(x) is the solution of the initial-value problem + 3x2y = 6x2, dx y(0) = 3.
(a) Use Euler's Method with a step size h = 0.1 to approximate y(0.0), y(0.1), y(0.2), y(0.3), y(0.4), y(0.5) where y(x) is the solution of the initial-value problem ay = - y2 cos x, y(0) = 1. (b) Find and compute the exact value of y(0.5). dx
3. Euler's Method (a) Use Euler's Method with step size At = 1 to approximate values of y(2),3(3), 3(1) for the function y(t) that is a solution to the initial value problem y = 12 - y(1) = 3 (b) Use Euler's Method with step size At = 1/2 to approximate y(6) for the function y(t) that is a solution to the initial value problem y = 4y (3) (c) Use Euler's Method with step size At = 1 to...
Use Euler's Method to make a table of values for the approximate solution of y2x +2y with initial condition y(0) 4. Determine the general and partie solution. Use five steps of size 0.10. Give the error in step four. Sketch both. Use Euler's Method to make a table of values for the approximate solution of y2x +2y with initial condition y(0) 4. Determine the general and partie solution. Use five steps of size 0.10. Give the error in step four....
(d) This part of question is concerned the use the Euler's method to solve the following initial-value problem dy dx4ar (i) Without using computer software, use Euler's method (described in Unit 2) with step size of 2, to find an approximate value y(2) of the given initial-value problem. Give your approximation to six decimal places. Clearly show all your working 6 (ii) Use Mathcad worksheet Έυ1er's method, associated with Unit 2 to computer the MATHCAD estimate solutions and absolute errors...
I. Use Euler's method with step size h = 0.1 to numerically solve the initial value problem y,--2ty+y2, y(0) 1 on the interval 0 < t 2. Compare your approximations with the exact solution. I. Use Euler's method with step size h = 0.1 to numerically solve the initial value problem y,--2ty+y2, y(0) 1 on the interval 0
Problem 1 Use Euler's method with step size h = 0.5 to approximate the solution of the IVP. 2 dy ev dt t 1-t-2, y(1) = 0. Problem 2 Consider the IVP: dy dt (a) Use Euler's method with step size h0.25 to approximate y(0.5) b) Find the exact solution of the IV P c) Find the maximum error in approximating y(0.5) by y2 (d) Calculate the actual absolute error in approximating y(0.5) by /2. Problem 1 Use Euler's method...
Find the value of x(0.5) for the initial value problem at = thx(0)=1 using Euler's method with step size h 0.05 Find the value of x(0.4) for the coupled first order differential equations together with initial conditions with step size 0.1: 2. dt t+x 3. dx dt = y, dy dt x(0) = 1.2 and --ty +xt2 + y(o) 0.8 Find the value of x(0.5) for the initial value problem at = thx(0)=1 using Euler's method with step size h...
Use the backward Euler method with h = 0.1 to find approximate values of the solution of the given initial value problem at t = 0.1, 0.2, 0.3 and 0.4. y' = 0.7 – + + 2y, y(O) = 2. Make all calculations as accurately as possible and round your final answers to two decimal places. In = nh n=1 0.1 n=2 0.2 n=3 0.3 n = 4 0.4
Use Euler's method with step size h = 0.2 to approximate the solution to the initial value problem at the points x = 4.2, 4.4, 4.6, and 4.8. y = {(V2+y),y(4)=1 Complete the table using Euler's method. xn Euler's Method 4.2 4.4 n 1 2 2 3 4.6 4 4.8 (Round to two decimal places as needed.)