How to fix the time step in ODE45

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Vahid Jahangiri 2018년 7월 6일

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https://kr.mathworks.com/matlabcentral/answers/409203-how-to-fix-the-time-step-in-ode45

댓글: Abla Nevame Edzenunye 2022년 10월 12일

I want to fix the time step for my ode45 function. The code which I am using is as follows:

    dt = 0.02;
    tf = 600;
    t = dt:dt:tf;
    y0 = zeros(14,1);
    [tout,yout] = ode45(@OC3_odefull,t,y0);

When I run my code, I have no control over the time step size and ode45 uses an adaptive time step. Is there any way that I can force ode45 to use the time step that I want?

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Jan 2018년 7월 8일

The "45" means, that each step is calculated with an order 4 and order 5 method. The difference between the results is used to control the step size. It is not meaningful to run an ODE45 method with a fixed step size.

Abla Nevame Edzenunye 2022년 10월 12일

Thank you!!!

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Answer 1

Steven Lord 2018년 7월 8일

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https://kr.mathworks.com/matlabcentral/answers/409203-how-to-fix-the-time-step-in-ode45#answer_327928

Why do you want to fix the time step?

If you want to find the solution of the system of ODEs at specific times, you don't need to control the time step to do that. Specify the time span vector as a vector with more than two elements and the ODE solver will return the solution at the specified times. [Note that this affects the times at which the solver returns the solution, not the times used by the solver internally.]

If you have a differential equation where the value of the right-hand side depends upon the value of the solution at earlier times (and you're trying to ensure the solver computes the solution at those earlier times) you don't want to use the ordinary differential equation solvers. Use the delay differential equation solvers instead, like dde23 or ddesd.

If there's a different reason you want to control the time step, please say more about that reason.

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Vishesh Mangla 2020년 6월 18일

편집: Vishesh Mangla 2020년 6월 18일

MATLAB Online에서 열기

v 2018a

This is the whole code and you can replicate by just copying. Just try obj.temperature function which takes argument as a vector, so try linspace or [0 .1 .2 ] but still instead of 3 points on the time axis there is all that stuff making the plot dirty.

FiniteElement.m a class

classdef FiniteElement
    %FINITEELEMENT Summary of this class goes here
    
    properties
        simpson_nodes 
        N%number of nodes
        H% step in x direction
        domain % 0 to 1
        beta% hyperparameter
        
        %initial conditions
        alpha
        
        %analytic solution
        exact
        
        f%f(x, t)
        
        
        %Define boundary conditions
        g0  % alpha0
        g1  %alphaN
        g0dash  %alpha'0
        g1dash  %alpha'N
        
        %stiffness matrices
        A
        D
        % time to calculate at
        time_at
    end
    
    methods
        
        function obj = FiniteElement(N, beta)
            
            % Constructor initialize all variables
            %Parameters Initialization
            obj.N = N;
            obj.beta = beta;
            obj.H = 1 / N; % step in x direction
            obj.domain = linspace(0, 1, N + 1);
            obj.f = @(x, t) (1 - pi^2 * obj.beta ) * exp(t) * sin(pi * x);
            
            %Set initial conditions here
            obj.alpha = sin(pi * obj.domain(2:end - 1));
            
            %Set exact solution here
            obj.exact = @(t) exp(t) * obj.alpha;
            obj.simpson_nodes = 3*20*obj.N; % number of nodes to be used for
            %Define boundary conditions
            obj.g0 = @(t) 0;
            obj.g1 = @(t) 0;
            obj.g0dash = @(t) 0;
            obj.g1dash = @(t) 0;
            obj = obj.matrices_req();
        end
        
        function output = phi(obj, i, x)
            % basis functions see live script for better representation
            if i == 0
                
                if x >= 0 && x <= obj.H
                    output = -(x - 1 * obj.H) / obj.H;
                else
                    output = 0;
                end
                
            elseif i == obj.N
                
                if x >= (obj.N - 1) * obj.H  &&  x <= obj.N * obj.H
                    output = (x - (obj.N - 1) * obj.H) / obj.H;
                else
                    output = 0;
                end
                
            else
                
                if x >= (i - 1) * obj.H && x <= i * obj.H
                    output = (x - (i - 1) * obj.H) / obj.H;
                elseif x >= i * obj.H && x <= (i + 1) * obj.H
                    output = -(x - (i + 1) * obj.H) / obj.H;
                else
                    output = 0;
                end
                
            end
            
        end
        
        function output = phidash(obj, i, x)  % derivative
            
            %derivative of phi
            if i == 0
                
                if x >= 0 && x <= obj.H
                    output = -1 / obj.H;
                else
                    output = 0;
                end
                
            elseif i == obj.N
                
                if x >= (obj.N - 1) * obj.H && x <= obj.N * obj.H
                    output = 1 / obj.H;
                else
                    output = 0;
                end
                
            else
                
                if x >= (i - 1) * obj.H && x <= i * obj.H
                    output = 1 / obj.H;
                elseif x >= i * obj.H && x <= (i + 1) * obj.H
                    output = -1 / obj.H;
                else
                    output = 0;
                end
                
            end
            
        end
        
        function output = const(obj, i, t)       
            % constant in the matrix equation
            output = obj.g0dash(t) * simpsons(@(x) obj.phi(i, x) * obj.phi(0, x), 0, 1, obj.simpson_nodes) + ...
                obj.g1dash(t) * simpsons(@(x) obj.phi(i, x) * obj.phi(obj.N, x), 0, 1, obj.simpson_nodes) ...
                -obj.beta * obj.g0(t) * simpsons(@(x) obj.phidash(i, x) * obj.phidash(0, x), 0, 1, obj.simpson_nodes) + ...
                -obj.beta * obj.g1(t) * simpsons(@(x) obj.phi(i, x) * obj.phi(obj.N, x), 0, 1, obj.simpson_nodes)...
                +obj.beta*obj.phi(i, 1)*obj.phidash(obj.N, 1)*obj.g1(t)-obj.beta*obj.phi(i, 0)*obj.phidash(0, 0)*obj.g0(t) ;
        end
        
        function obj = matrices_req(obj)
            % stiffness matrices
            obj.A = zeros(obj.N - 1);
            obj.D = zeros(obj.N - 1);
            
            for i = 1:obj.N - 1
                
                for j = 1:obj.N - 1
                    
                    if ismember(abs(i - j), [0, 1])
                        obj.A(i, j) = simpsons(@(x) obj.phi(i, x) * obj.phi(j, x), 0, 1, obj.simpson_nodes);
                        obj.D( i, j) = simpsons(@(x) obj.phidash(i, x) * obj.phidash(j, x), 0, 1, obj.simpson_nodes);
                    end
                    
                end
                
            end
            
        end
        
        
        function derivative_ = dydx(obj, t, y)
            % derivative used in ode45
            C = zeros(obj.N - 1, 1);
            F = zeros(obj.N - 1, 1);
            
            for i = 1:obj.N - 1
                C(i) = obj.const(i, t);
                F(i) = simpsons(@(x) obj.phi(i, x) * obj.f(x, t), 0, 1, obj.simpson_nodes);
                
            end
            
            derivative_ = obj.A \ (-(-obj.beta * obj.D * y + C) + F);
            
        end
        
        function output = exactsoln(obj, time)
            % give exactsolution the same structure as output from ode45
            output.x = time;
            output.y = [];
            
            for t =output.x
                output.y = [output.y obj.exact(t)'];
            end
            
        end
        function [ApproxTemp, ExactTemp] = temperature(obj, time_at)
            
            % main function to be called to get temperatures
            ApproxTemp = ode45(@(t, y) obj.dydx(t, y), time_at, obj.alpha);
            ExactTemp = obj.exactsoln(ApproxTemp.x);
        end 
    end
    
end

simpsons.m

function I = simpsons(f,a,b,n)
     h=(b-a)/n; 
     
     s = f(a) + f(b);
    for i=1:2:n-1  
        s = s+ 4*f(a+i*h);
        
    end
    for i=2:2:n-2  
        s = s + 2*f(a+i*h);
        
    end
    I = h/3 * s;
end

run.m

obj = FiniteElement(8, -1);
[A, E] = obj.temperature([0 .1 .2]); 
x = obj.domain;
y = A.x;
[xx, yy] = meshgrid(x, y);
subplot(2, 1, 1);
z = vertcat(arrayfun(obj.g0, A.x), A.y,arrayfun(obj.g1, A.x) )';
heatmap(x, y, z);
colormap(flipud(hot));
title("Approximate Solution");
xlabel("The rod as x-axis");
ylabel("Time");
subplot(2, 1, 2);
z = vertcat(arrayfun(obj.g0, E.x), E.y,arrayfun(obj.g1, E.x) )';
heatmap(x, y, z);
colormap(flipud(hot));
title("Exact Solution");
xlabel("The rod as x-axis");
ylabel("Time");

Run run.m

Vishesh Mangla 2020년 6월 18일

Sorry, mb. I just saw that there are couple of output formats and the one I was using was the structure output one. My apologies. I should have read the docs more thoroughly.

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