Matlab coding ordinary differential equation initial condition graph not running in the initial condition

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Dhivyadharshini on 29 Sep 2025 at 4:55

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https://uk.mathworks.com/matlabcentral/answers/2180252-matlab-coding-ordinary-differential-equation-initial-condition-graph-not-running-in-the-initial-cond

Edited: Torsten on 29 Sep 2025 at 14:56

Matlab coding ordinary differential equation initial condition graph not running in the initial condition. For x(2), x(6) and x(7) only getting properly graph is coming with the initial condition starting but for x(1), x(3), x(4), x(5) graph is not coming as the initial condition starting

Tr()

30 successful steps 2 failed attempts 193 function evaluations Elapsed time is 0.072265 seconds.

function Tr

options = odeset('RelTol',1e-6,'Stats','on');

%initial conditions

Xo = [0.005; 0.0007; 0.001; 0.0001; 0.0001; 0; 0];

tspan = [0,120];

tic

[t,X] = ode45(@TestFunction,tspan,Xo,options);

toc

%figure

hold on

plot(t, X(:,1), 'green')

plot(t, X(:,2), 'blue')

plot(t, X(:,3), 'red')

plot(t, X(:,4), 'yellow')

plot(t, X(:,5), 'green')

plot(t, X(:,6), 'cyan')

plot(t, X(:,7), 'y')

%hold on

% legend('x1','x2')

% ylabel('x - Population')

% xlabel('t - Time')

%hold on

end

function [dx_dt]= TestFunction(~,x)

% Parameters

s = 0.038;

alpha = 0.02;

gamma = 0.10;

r = 0.03;

dH = 0.0083;

dX = 0.0125;

rho = 0.07;

K = 500;

beta = 0.0005;

theta = 0.03;

eta = 0.015;

muH = 0.015;

muI = 0.08;

lambdaP = 0.05;

lambdaL = 0.043;

UP = 0.20;

deltaP = 0.033;

UL = 0.50;

deltaL = 0.05;

kappa = 0.005;

dx_dt(1) = (s) - ((alpha * x(3) * x(1)) / (1 + gamma * x(1))) - (dH * x(1)) + (r * x(2));

dx_dt(2) = ((alpha * x(3) * x(1)) / (1 + gamma * x(1))) - ((r+dX) * x(2));

dx_dt(3) = ((rho * x(3)) * (1 - (x(3) + x(4)) / K)) - (beta * x(3) * x(5)) - (lambdaP * x(6) * x(3)) - (lambdaL * x(7) * x(3)) - (muH * x(3));

dx_dt(4) = (beta * x(3) * x(5)) - (lambdaP * x(6) * x(4)) - (lambdaL * x(7) * x(4)) - (muI * x(4)) - (kappa * x(5) * x(4));

dx_dt(5) = (theta * x(4)) - (eta * x(5));

dx_dt(6) = (UP) - (deltaP * x(6));

dx_dt(7) = (UL) - (deltaL * x(7));

dx_dt = dx_dt';

end

%hold on

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Sam Chak on 29 Sep 2025 at 12:24

Edited: Torsten on 29 Sep 2025 at 14:56

Open in MATLAB Online

Hi @Dhivyadharshini

The responses for x1, x3, x4, and x5 begin from the specified initial values: {0.005, 0.001, 0.0001, 0.0001}.

options = odeset('RelTol', 1e-6);

X0 = [0.005; 0.0007; 0.001; 0.0001; 0.0001; 0; 0];

% x1 x2 x3 x4 x5 x6 x7

tspan = [0, 120];

[t, X] = ode45(@TestFunction, tspan, X0, options);

% figure(1)

% tL = tiledlayout(2, 2, 'TileSpacing', 'Compact');

%

% nexttile

% plot(t, X(:,1), 'color', '#AA0815'), grid on

% title('x1')

%

% nexttile

% plot(t, X(:,3), 'color', '#F0B41C'), grid on

% title('x3')

%

% nexttile

% plot(t, X(:,4), 'color', '#49B6A9'), grid on

% title('x4')

%

% nexttile

% plot(t, X(:,5), 'color', '#3D9BE1'), grid on

% title('x5')

%

% xlabel(tL, 'Time')

% ylabel(tL, 'Population')

figure(2)

tL2 = tiledlayout(2, 2, 'TileSpacing', 'Compact');

nexttile

plot(t, X(:,1), 'color', '#AA0815'), grid on

xlim([0, 120])

title('x1')

nexttile

plot(t, X(:,3), 'color', '#F0B41C'), grid on

xlim([0, 120])

title('x3')

nexttile

plot(t, X(:,4), 'color', '#49B6A9'), grid on

xlim([0, 120])

title('x4')

nexttile

plot(t, X(:,5), 'color', '#3D9BE1'), grid on

xlim([0, 120])

title('x5')

%title(tL2, 'Zoomed-in')

xlabel(tL2, 'Time')

ylabel(tL2, 'Population')

%% Dynamics of Population Growth

function [dx_dt]= TestFunction(~,x)

% Parameters

s = 0.038;

alpha = 0.02;

gamma = 0.10;

r = 0.03;

dH = 0.0083;

dX = 0.0125;

rho = 0.07;

K = 500;

beta = 0.0005;

theta = 0.03;

eta = 0.015;

muH = 0.015;

muI = 0.08;

lambdaP = 0.05;

lambdaL = 0.043;

UP = 0.20;

deltaP = 0.033;

UL = 0.50;

deltaL = 0.05;

kappa = 0.005;

dx_dt(1) = (s) - ((alpha * x(3) * x(1)) / (1 + gamma * x(1))) - (dH * x(1)) + (r * x(2));

dx_dt(2) = ((alpha * x(3) * x(1)) / (1 + gamma * x(1))) - ((r+dX) * x(2));

dx_dt(3) = ((rho * x(3)) * (1 - (x(3) + x(4)) / K)) - (beta * x(3) * x(5)) - (lambdaP * x(6) * x(3)) - (lambdaL * x(7) * x(3)) - (muH * x(3));

dx_dt(4) = (beta * x(3) * x(5)) - (lambdaP * x(6) * x(4)) - (lambdaL * x(7) * x(4)) - (muI * x(4)) - (kappa * x(5) * x(4));

dx_dt(5) = (theta * x(4)) - (eta * x(5));

dx_dt(6) = (UP) - (deltaP * x(6));

dx_dt(7) = (UL) - (deltaL * x(7));

dx_dt = dx_dt';

end

Dhivyadharshini on 29 Sep 2025 at 14:45

I want for 120 days x-axis 120 should come

Matlab coding ordinary differential equation initial condition graph not running in the initial condition

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Matlab coding ordinary differential equation initial condition graph not running in the initial condition

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