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Use the modified Euler method to find approximate solution of the following initial- value problem y'...
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
Find approximate values of the solution of the given initial value problem at T=0.1, 0.2, 0.3, and 0.4 using Euler method with h=0.1 y'= 0.5-t+2y ; y(o)=1
Need Help with solving for answers in Part C and Part D! Find approximate values of the solution of the given initial value problem at t = 0.1, 0.2, 0,3, and 0.4, (A COmputer algebra system is recommended. Round your answers to five decimal places.) (a) Use the Euler method with0.05 (0.11.5875 y(0.2)2.12747 y(0.3)2.62455 y(0.4)3.0829 (b) Use the Euler method with h0.025 y(0.1)1.58156 y(0.2)2.11675 (o.3)261 y(0.4)3.0654 (c) Use the backward Euler method with h 0.05 (0.2) y(0.3) y(0.4) (d) Use...
Consider the initial value problem i. Find approximate value of the solution of the initial value problem at using the Euler method with . ii. Obtain a formula for the local truncation error for the Euler method in terms of t and the exact solution . 2,,2 5 0.1 y = o(t) 2,,2 5 0.1 y = o(t)
Question 1: Given the initial-value problem 12-21 0 <1 <1, y(0) = 1, 12+10 with exact solution v(t) = 2t +1 t2 + 1 a. Use Euler's method with h = 0.1 to approximate the solution of y b. Calculate the error bound and compare the actual error at each step to the error bound. c. Use the answers generated in part (a) and linear interpolation to approximate the following values of y, and compare them to the actual value...
Apply Euler-trapezoidal predictor-corrector method to the IVP in problem 1 to approximate y(2), by choosing two values of h, for which the iteration converges. (Don't really need to show work or do by hand, MATLAB code will work just as well). 1. For the IVP: y' =ty, y(0) = ) 0t 4 Compare the true solution with the approximate solutions from t = 0 to t 4, with the step size h 0.5, obtained by each of the following methods....
2. Use the Taylor's method of order two to approximate the solution to the following initial-value problem y's et-y,0 < t < 1, y (0)-1, with h-0.5 2. Use the Taylor's method of order two to approximate the solution to the following initial-value problem y's et-y,0
a use Euler's method with each of the following step sizes to estimate the value of y 0.4 where y is the solution of the initial value problem y -y, y 0 3 カー0.4 0.4) (i) y10.4) (in) h= 0.1 b we know that the exact solution of the initial value problem n part a s yー3e ra , as accurately as you can the graph of y e r 4 together with the Euler approximations using the step sizes...
How do I approach this? 61. Use Euler's method to find approximate values for the solution of the initial value problem dy dx = I – Y y(0) 1 on the interval [0, 1] using a) five steps of size h = 0.2, and b) ten steps of size h = 0.1. Solve the initial – value problem and find the errors in the above calculations.
3. Use the Modified Euler method(explicit and implicit) and Midpoint methods to approxi mate the solutions to each of the following initial-value problems, and compare the results. (a) te - 2y, 0t1, y(0) = 0, h = 0.5 (b) 1y/t, 1 <t < 2, y(0)= 0, h 0.25 3. Use the Modified Euler method(explicit and implicit) and Midpoint methods to approxi mate the solutions to each of the following initial-value problems, and compare the results. (a) te - 2y, 0t1,...