plotting the bifurcation diagram of Duffing oscillations in the (x1, omega) plane?

조회 수: 6 (최근 30일)
function dx = duffing(t,x);
global alpha delta beta F omega
dx=[x(2);
-delta*x(2)-alpha*x(1)-beta*x(1)^3+F*cos(x(3));
omega];
% Define parameters
global alpha delta beta F omega
alpha=0.1;
delta=0.2;
beta=0.3;
F=0.5;
omega_range = 0.8:0.1:1; % Range of omega values
x0 = [0.1, 0.1, 0.1]; % Initial conditions
% Set simulation step
dt = 0.001;
% Presave a matrix of NaNs to save points of intersection
M = NaN * zeros(1000, length(omega_range));
pos = 0; % Indexing dummy variable
% Set ode options
options = odeset('RelTol', 1e-5, 'AbsTol', 1e-5);
for omega = omega_range
omega % Print omega, just to track progress
pos = pos + 1; % Increase index
% Simulate the system
[t, x] = ode45(@duffing, 0:dt:1000, x0, options);
% Discard transient
index = t > 400;
X = x(index, :); % Save states without transient in a new vector
l = length(X);
% Save the final x(1) value
M(1:l, pos) = X(:, 1);
end
% Plot the bifurcation diagram
figure;
plot(omega_range, M, '.b', 'MarkerSize', 2);
xlabel('\omega');
ylabel('x_1');
title('Bifurcation Diagram of Duffing System (x_1 vs. \omega)');
grid on;
Can anyone help troubleshoot my code for plotting the bifurcation diagram of Duffing oscillations in the (x1, omega) plane? It's not functioning as expected. Thanks!

답변 (1개)

Athanasios Paraskevopoulos
Athanasios Paraskevopoulos 2024년 5월 16일
편집: Athanasios Paraskevopoulos 2024년 5월 16일
function dx = duffing(t, x)
global alpha delta beta F omega
dx = [x(2);
-delta * x(2) - alpha * x(1) - beta * x(1)^3 + F * cos(omega * t);
omega];
end
% Define parameters
global alpha delta beta F omega
alpha = 0.1;
delta = 0.2;
beta = 0.3;
F = 0.5;
omega_range = 0.8:0.01:1.0; % Finer range of omega values
x0 = [0.1, 0.1, 0.1]; % Initial conditions
% Set simulation step and time
dt = 0.01;
simulation_time = 1000; % Total simulation time
transient_time = 400; % Time to discard transient
% Preallocate matrix for results
num_points = floor((simulation_time - transient_time) / dt) + 1;
M = NaN(num_points, length(omega_range));
% Set ODE options
options = odeset('RelTol', 1e-5, 'AbsTol', 1e-5);
% Loop over omega values
for pos = 1:length(omega_range)
omega = omega_range(pos);
fprintf('Processing omega = %.2f\n', omega); % Track progress
% Simulate the system
[t, x] = ode45(@duffing, 0:dt:simulation_time, x0, options);
% Remove transients
index = t > transient_time;
X = x(index, :);
% Save the x(1) values after transient
M(1:length(X), pos) = X(:, 1);
end
Processing omega = 0.80 Processing omega = 0.81 Processing omega = 0.82 Processing omega = 0.83 Processing omega = 0.84 Processing omega = 0.85 Processing omega = 0.86 Processing omega = 0.87 Processing omega = 0.88 Processing omega = 0.89 Processing omega = 0.90 Processing omega = 0.91 Processing omega = 0.92 Processing omega = 0.93 Processing omega = 0.94 Processing omega = 0.95 Processing omega = 0.96 Processing omega = 0.97 Processing omega = 0.98 Processing omega = 0.99 Processing omega = 1.00
% Plot the bifurcation diagram
figure;
hold on;
for pos = 1:length(omega_range)
omega_vals = omega_range(pos) * ones(sum(~isnan(M(:, pos))), 1);
plot(omega_vals, M(~isnan(M(:, pos)), pos), '.b', 'MarkerSize', 2);
end
xlabel('\omega');
ylabel('x_1');
title('Bifurcation Diagram of Duffing System (x_1 vs. \omega)');
grid on;
hold off;

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