I completed the Eulers method, but I’m a bit lost on the other two. x +...
The differential equation : dy/dx = 2x -3y , has the initial conditions that y = 2 , at x = 0 Obtain a numerical solution for the differential equation, correct to 6 decimal place , using , The Euler-Cauchy method The Runge-Kutta method in the range x = 0 (0.2) 1.0
Using the Runge-Kutta fourth-order method, obtain a solution to dx/dt=f(t,x,y)=xy^3+t^2; dy/dt=g(t,x,y)=ty+x^3 for t= 0 to t= 1 second. The initial conditions are given as x(0)=0, y(0) =1. Use a time increment of 0.2 seconds. Do hand calculations for t = 0.2 sec only.
Given (dy/dx)=(3x^3+6xy^2-x)/(2y) with y=0.707 at x= 0, h=0.1 obtain a solution by the fourth order Runge-Kutta method for a range x=0 to 0.5
Help with these questions please. A mathematical model has been described by an engineer into the following differential equation: dy dx y(0) 2.5 Demonstrate an Euler method simulation of y versus x with a tabular algorithm using Ax 0.5 and 0.0 X 3.0. Demonstrate a 4th-order Runge Kutta method simulation of y versus x with a tabular algorithm using What can you say about y(x) and the methods used? a. b. Ax 0.5 and 0.0 3.0 x c. A mathematical...
Solve the ordinary differential equation below over the interval 0 sts 2s using two different methods: the Euler method and the second-order Runge-Kutta method (midpoint version). Begin by writing the state space representation of the equation. Use a time step of 1 s, and place a box around the values of x and x at t- 2 s obtained using each method. Show your work. 20d's +5dr +20x = 0 dt d x(0) = 1, x'(0) = 1 Solve the...
answer fast please 2. For y'=(1+4x)/7, and y(0)=0.5 a) Use the Euler method to integrate from x=0 to 0.5 with h=0.25. (10 pts) b) Use the 4th order Runge-Kutta method to numerically integrate the equation above for x=0 to 0.25 with h=0.25. (15 pts) Euler Method 91+1 = y + oh where $ = = f(ty 4th Order Runge-Kutta Method 2+1= ++ where $ = (ką + 2k2 + 2kg + ks) ky = f(tuy) k2 = f(t+1,91 +{kxh) kz...
Numerical Methods Consider the following IVP dy=0.01(70-y)(50-y), with y(0)-0 (a) [10 marks Use the Runge-Kutta method of order four to obtain an approximate solution to the ODE at the points t-0.5 and t1 with a step sizeh 0.5. b) [8 marks Find the exact solution analytically. (c) 7 marks] Use MATLAB to plot the graph of the true and approximate solutions in one figure over the interval [.201. Display graphically the true errors after each steps of calculations. Consider the...
hand written solution only (not computerised) if not possible then please refund the question becs i have already recieved a computerised solution from you but i dont understand. 3In modelling the velocity y of a chain slipping off a horizontal platform, the differential equation y, 10/y-y/x is derived. Suppose the initial condition is y( 1-1 (a) Euler's method for solving yf(x), y(xoyo, is given by yn+n+hf(an,yn), where h is a fixed stepsize, xn xo + nh, and yn y(xn). Apply...
Consider the IVP, 1. Apply the FEUT to show that a solution exists. 2. Use the Runge-Kutta method with various step-sizes to estimate the maximum t-value, t=t∗>0, for which the solution is defined on the interval [0,t∗). Include a few representative graphs with your submission, but not the lists of points. 3. Find the exact solution to the IVP and solve for t∗ analytically. How close was your approximation from the previous question? 4. The Runge-Kutta method continues to give...
The Program for the code should be matlab 5. [25 pointsl Given the initial value problem with the initial conditions y(0) 2 and y'(0)10, (a) Solve analytically to obtain the exact solution y(x) (b) Solve numerically using the forward Euler, backward Euler, and fourth-order Runge Kutta methods. Please implement all three methods yourselves do not use any built- in integrators (i.e., ode45)). Integrate over 0 3 r < 4, and compare the methods with the exact solution. (For example, using...