Consider the following second order differential equation: d2 u (N — 1) du — + —u = O in (0, 1), (0.1) dr r dr r2 where 1 + I (N — and N 1, 2, 3. Find (erplicitly) all the solutions to (0.1) having the form Hint: make the change of variables t log(r) for r e (0, 1). Find the ODE that v(log(r)) v(t) solves. Observe that this change of variable maps (0, 1) (—00, 0). Find the exact solution for the ODE (0.1) with the Final Values u(l) 0, du (l) —— 1. dr Hint: Use the explicit solutions found in i. Write one MATLAB script to solve numerically the ODE (0.1) + Final Value problem in ii.. Hint: rlYansforrn the Final Value Problem into an IVP reversing the interval (0, 1) using The script must contain at least one implementation based on the Crank-Nicholson method and another based on the Runge-Kutta method of order 2. Include plots to compare the implementatioms against the true sohltion. Provide also analysis of your findings.

Numerical Method question solutions

Mehmet Çuha

1 Jun 2021

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Updated 5 Jun 2021

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Consider the following second order differential equation: d2 u (N — 1) du

— + —u = O in (0, 1), (0.1) dr r dr r2 where 1 + I (N — and N 1, 2, 3.

Find (erplicitly) all the solutions to (0.1) having the form

Hint: make the change of variables t log(r) for r e (0, 1). Find the ODE that v(log(r)) v(t) solves. Observe that this change of variable maps (0, 1) (—00, 0).

Find the exact solution for the ODE (0.1) with the Final Values

u(l) 0, du (l) —— 1. dr

Hint: Use the explicit solutions found in i.

Write one MATLAB script to solve numerically the ODE (0.1) + Final Value problem in ii.. Hint: rlYansforrn the Final Value Problem into an IVP reversing the interval (0, 1) using

The script must contain at least one implementation based on the Crank-Nicholson method and another based on the Runge-Kutta method of order 2.

Include plots to compare the implementatioms against the true sohltion. Provide also analysis of your findings.

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James Tursa on 1 Jun 2021

What have you done so far? What specific problems are you having with your code?

Can you add an image showing the differential equation and instructions? I can't understand what you have posted.

Mehmet Çuha on 3 Jun 2021

Edited: darova on 5 Jun 2021

Open in MATLAB Online

ı am trying to use this code but I cant replaces variables .

function [t,u]=feuler(odefun,tspan,y0,Nh,varargin)
%FEULER Solves differential equations using the forward
%  Euler method.
%  [T,Y]=FEULER(ODEFUN,TSPAN,Y0,NH) with TSPAN=[T0,TF]
%  integrates the system of differential equations
%  y'=f(t,y) from time T0 to TF with initial condition
%  Y0 using the forward Euler method on an equispaced
%  grid of NH intervals.
%  Function ODEFUN(T,Y) must return a vector, whose
%  elements hold the evaluation of f(t,y), of the
%  same dimension of Y.
%  Each row in the solution array Y corresponds to a
%  time returned in the  column vector T.
%  [T,Y] = FEULER(ODEFUN,TSPAN,Y0,NH,P1,P2,...) passes
%  the additional parameters P1,P2,... to the function
%  ODEFUN as ODEFUN(T,Y,P1,P2...).
h=(tspan(2)-tspan(1))/Nh;
y=y0(:); % always creates a column vector
w=y; u=y.';
tt=linspace(tspan(1),tspan(2),Nh+1);
for t = tt(1:end-1)
 w=w+h*odefun(t,w,varargin{:});
 u = [u; w.'];
end
t=tt';
return

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Numerical Method question solutions

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