Numerical Simulation of a Damped, Driven Nonlinear Wave System with Spatially Extended Initial Conditions

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Athanasios Paraskevopoulos on 20 May 2024

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Answered: Athanasios Paraskevopoulos on 23 May 2024

Accepted Answer: Athanasios Paraskevopoulos

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The study of the dynamics of the discrete Klein - Gordon equation (DKG) with friction is given by the equation :

In the above equation, W describes the potential function:

to which every coupled unit

adheres. In Eq. (1), the variable

is the unknown displacement of the oscillator occupying the n-th position of the lattice, and

is the discretization parameter. We denote by h the distance between the oscillators of the lattice. The chain (DKG) contains linear damping with a damping coefficient

, while β is the coefficient of the nonlinear cubic term.

For the DKG chain (1), we will consider the problem of initial-boundary values, with initial conditions

and Dirichlet boundary conditions at the boundary points

and

, that is,

.

Therefore, when necessary, we will use the short notation

for the one-dimensional discrete Laplacian

We investigate numerically the dynamics of the system (1)-(2)-(3). Our first aim is to conduct a numerical study of the property of Dynamic Stability of the system, which directly depends on the existence and linear stability of the branches of equilibrium points.

For the discussion of numerical results, it is also important to emphasize the role of the parameter

. By changing the time variable

, we rewrite Eq. (1) in the form

The change in the scaling of the lattice parameter of the problem makes it important to comment here on the nature of the continuous and anti-continuous limit. For the anti-continuous limit, we need to consider the case in Eq. (1) where

. In the case of nonlinearity present in the governing equations, the continuous limit needs to be taken as well. On the other hand, for small values of the parameter, the system becomes significant. However, because of the model we consider, we take the asymptotic linear limit as

.

We consider spatially extended initial conditions of the form:

where

is the distance of the grid and

is the amplitude of the initial condition

We also assume zero initial velocity:

I am trying to create the following plots but as you can see my code doesn;t give these results. Any sugestions?

for

% Parameters

a = 2; % Amplitude of the initial condition

j = 2; % Mode number

L = 200; % Length of the system

K = 99; % Number of spatial points

% Spatial grid

h = L / (K + 1);

n = -L/2:h:L/2; % Spatial points

% Compute U_n(0) for each n

U_n0 = a * sin((j * pi * h * n) / L);

% Plot the results

figure;

plot(n, U_n0, 'ro'); % 'ro' creates red circles

xlabel('$x_n$', 'Interpreter', 'latex');

ylabel('$U_n$', 'Interpreter', 'latex');

title('$t=0$', 'Interpreter', 'latex');

xlim([-L/2 L/2]);

ylim([-3 3]);

grid on;

UPDATED : I need to replicate the red and the blue graphs of the papers. I am sure that I need to change a parameter but I dont know which one for

and

.

% Parameters

L = 200; % Length of the system

K = 99; % Number of spatial points

j = 2; % Mode number

omega_d = 1; % Characteristic frequency

beta = 1; % Nonlinearity parameter

delta = 0.05; % Damping coefficient

% Spatial grid

h = L / (K + 1);

n = linspace(-L/2, L/2, K+2); % Spatial points

N = length(n);

omegaDScaled = h * omega_d;

deltaScaled = h * delta;

% Time parameters

dt = 0.05; % Time step

tmax = 3000; % Maximum time

tspan = 0:dt:tmax; % Time vector

% Values of amplitude 'a' to iterate over

a_values = [2, 1.95, 1.9, 1.85, 1.82]; % Modify this array as needed

% Differential equation solver function

function dYdt = odefun(~, Y, N, h, omegaDScaled, deltaScaled, beta)

U = Y(1:N);

Udot = Y(N+1:end);

Uddot = zeros(size(U));

% Laplacian (discrete second derivative)

for k = 2:N-1

Uddot(k) = (U(k+1) - 2 * U(k) + U(k-1)) / h^2;

end

% System of equations

dUdt = Udot;

dUdotdt = Uddot - deltaScaled * Udot + omegaDScaled^2 * (U - beta * U.^3);

% Pack derivatives

dYdt = [dUdt; dUdotdt];

end

% Create a figure for subplots

figure;

% Initial plot

a_init = 2; % Example initial amplitude for the initial condition plot

U0_init = a_init * sin((j * pi * h * n) / L); % Initial displacement

U0_init(1) = 0; % Boundary condition at n = 0

U0_init(end) = 0; % Boundary condition at n = K+1

subplot(3, 2, 1);

plot(n, U0_init, 'r.-', 'LineWidth', 1.5, 'MarkerSize', 10); % Line and marker plot

xlabel('$x_n$', 'Interpreter', 'latex');

ylabel('$U_n$', 'Interpreter', 'latex');

title('$t=0$', 'Interpreter', 'latex');

set(gca, 'FontSize', 12, 'FontName', 'Times');

xlim([-L/2 L/2]);

ylim([-3 3]);

grid on;

% Loop through each value of 'a' and generate the plot

for i = 1:length(a_values)

a = a_values(i);

% Initial conditions

U0 = a * sin((j * pi * h * n) / L); % Initial displacement

U0(1) = 0; % Boundary condition at n = 0

U0(end) = 0; % Boundary condition at n = K+1

Udot0 = zeros(size(U0)); % Initial velocity

% Pack initial conditions

Y0 = [U0, Udot0];

% Solve ODE

opts = odeset('RelTol', 1e-5, 'AbsTol', 1e-6);

[t, Y] = ode45(@(t, Y) odefun(t, Y, N, h, omegaDScaled, deltaScaled, beta), tspan, Y0, opts);

% Extract solutions

U = Y(:, 1:N);

Udot = Y(:, N+1:end);

% Plot final displacement profile

subplot(3, 2, i+1);

plot(n, U(end,:), 'b.-', 'LineWidth', 1.5, 'MarkerSize', 10); % Line and marker plot

xlabel('$x_n$', 'Interpreter', 'latex');

ylabel('$U_n$', 'Interpreter', 'latex');

title(['$t=3000$, $a=', num2str(a), '$'], 'Interpreter', 'latex');

set(gca, 'FontSize', 12, 'FontName', 'Times');

xlim([-L/2 L/2]);

ylim([-2 2]);

grid on;

end

% Adjust layout

set(gcf, 'Position', [100, 100, 1200, 900]); % Adjust figure size as needed

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Athanasios Paraskevopoulos on 20 May 2024

Edited: Athanasios Paraskevopoulos on 20 May 2024

The given equation and the initial conditions describe the dynamics of a spatially discrete system, often encountered in the context of lattice vibrations or discrete models in physics. Let's break down the notation and terms step by step.

The Equation

The primary equation is:

Terms in the Equation:

-

: The displacement at site

and time t.

-

: The second time derivative of

, representing the acceleration at site n.

-

: The first time derivative of

, representing the velocity at site n.

-

: The discrete Laplacian operator applied to

, which typically represents the interaction between neighboring sites. For a one-dimensional lattice, it can be defined as:

-

: A damping term proportional to the velocity, with

being the damping coefficient.

-

: A squared frequency term, defined as

, where

is a spatial scaling factor, and

is a characteristic frequency.

-

A nonlinear coefficient that dictates the strength of the nonlinear term

Parameters

-

: The squared frequency term incorporating the spatial scaling factor h.

-

: The damping coefficient incorporating the spatial scaling factor

Initial Conditions

The initial conditions are given for

and its time derivative:

1. Initial Displacement:

- a: The amplitude of the initial displacement.

-

: A sinusoidal function representing the initial displacement pattern across the lattice.

-

: The grid spacing, where L is the length of the domain andK is the number of segments.

2. Initial Velocity:

- This indicates that the initial velocity of all sites is zero.

William Rose on 21 May 2024

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@Athanasios Paraskevopoulos, thanhk you for your expanded explanation.

Your revised initial post begins with

and in the following text you say "

is the discretization parameter". Are K and k the same thing?

The left had side of equation 1 includes W'(Un), but you define

, without the prime after W. What is the meaning of the prime after W in equation 1? Are W'() and W() the same thing?

In an earlier comment, I asked about consistency of units. I ask about units because it is a good idea to check for consistent units, when a simulation is not working as expected - which is what you have reported. Your revised post does not address those questions, so I wil ask th questions again, in a revised form, in light of your revised initial post:

You define a new time variable, t=t/h^2. In my experience, normalized variables are frequenctly dimensionless. For example, time in seconds becomes t/T, which is dimensionless, or x in meters becomes x/L, which is dimensionless. But your new time variable does not work this way. In fact, the new time variable has units of time/length^2. Why make the units more complicated?
What are the units for K, in equation 1? I think K=c^2, where c=speed of wave propagation, with units length/time, and therefore units for K are length^2/time^2. Do you agree?
What are the units for δ in equation 1? I think the units are 1/time. Do you agree?

I think the answer to my quesiton about new time=t/h^2 is that you are choosing a time variable in which c, the speed of wave propagation (in the absence of damping), is unity. Is that right?

You define

K = 100;  % Number of spatial points
h = L / (K + 1);
n = -L/2:h:L/2;  % Spatial points

This results in values for n that are not integers, and it results in 102 spatial points, where I think you want 100 spatial points. If you use

h = L / (K - 1);

this inconsistency will disappear.

More later.

William Rose on 23 May 2024

@Athanasios Paraskevopoulos, I will get you somehting on this, but I'm busy for the next two days. Sorry for the delay. And I apologize for asking so many questions.

Athanasios Paraskevopoulos on 23 May 2024

@William Rose Thank you so much! I appreciate it! Don 't worry I am asking also many questions too,

I am feeling that I am getting closer to the solution but also i feel far

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Answer 1

Athanasios Paraskevopoulos on 23 May 2024

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https://ch.mathworks.com/matlabcentral/answers/2120611-numerical-simulation-of-a-damped-driven-nonlinear-wave-system-with-spatially-extended-initial-condi#answer_1462566

Open in MATLAB Online

I found it i should remove the discretization parameter

because in the following

.

I understood that

@William Rose Thank you so much! Your questions helped me a lot

% Parameters

L = 200; % Length of the system

K = 99; % Number of spatial points

j = 2; % Mode number

omega_d = 1; % Characteristic frequency

beta = 1; % Nonlinearity parameter

delta = 0.05; % Damping coefficient

% Spatial grid

h = L / (K + 1);

n = linspace(-L/2, L/2, K+2); % Spatial points

N = length(n);

omegaDScaled = h * omega_d;

deltaScaled = h * delta;

% Time parameters

dt = 1; % Time step

tmax = 3000; % Maximum time

tspan = 0:dt:tmax; % Time vector

% Values of amplitude 'a' to iterate over

a_values = [2, 1.95, 1.9, 1.85, 1.82]; % Modify this array as needed

% Differential equation solver function

function dYdt = odefun(~, Y, N, h, omegaDScaled, deltaScaled, beta)

U = Y(1:N);

Udot = Y(N+1:end);

Uddot = zeros(size(U));

% Laplacian (discrete second derivative)

for k = 2:N-1

Uddot(k) = (U(k+1) - 2 * U(k) + U(k-1)) ;

end

% System of equations

dUdt = Udot;

dUdotdt = Uddot - deltaScaled * Udot + omegaDScaled^2 * (U - beta * U.^3);

% Pack derivatives

dYdt = [dUdt; dUdotdt];

end

% Create a figure for subplots

figure;

% Initial plot

a_init = 2; % Example initial amplitude for the initial condition plot

U0_init = a_init * sin((j * pi * h * n) / L); % Initial displacement

U0_init(1) = 0; % Boundary condition at n = 0

U0_init(end) = 0; % Boundary condition at n = K+1

subplot(3, 2, 1);

plot(n, U0_init, 'r.-', 'LineWidth', 1.5, 'MarkerSize', 10); % Line and marker plot

xlabel('$x_n$', 'Interpreter', 'latex');

ylabel('$U_n$', 'Interpreter', 'latex');

title('$t=0$', 'Interpreter', 'latex');

set(gca, 'FontSize', 12, 'FontName', 'Times');

xlim([-L/2 L/2]);

ylim([-3 3]);

grid on;

% Loop through each value of 'a' and generate the plot

for i = 1:length(a_values)

a = a_values(i);

% Initial conditions

U0 = a * sin((j * pi * h * n) / L); % Initial displacement

U0(1) = 0; % Boundary condition at n = 0

U0(end) = 0; % Boundary condition at n = K+1

Udot0 = zeros(size(U0)); % Initial velocity

% Pack initial conditions

Y0 = [U0, Udot0];

% Solve ODE

opts = odeset('RelTol', 1e-5, 'AbsTol', 1e-6);

[t, Y] = ode45(@(t, Y) odefun(t, Y, N, h, omegaDScaled, deltaScaled, beta), tspan, Y0, opts);

% Extract solutions

U = Y(:, 1:N);

Udot = Y(:, N+1:end);

% Plot final displacement profile

subplot(3, 2, i+1);

plot(n, U(end,:), 'b.-', 'LineWidth', 1.5, 'MarkerSize', 10); % Line and marker plot

xlabel('$x_n$', 'Interpreter', 'latex');

ylabel('$U_n$', 'Interpreter', 'latex');

title(['$t=3000$, $a=', num2str(a), '$'], 'Interpreter', 'latex');

set(gca, 'FontSize', 12, 'FontName', 'Times');

xlim([-L/2 L/2]);

ylim([-2 2]);

grid on;

end

% Adjust layout

set(gcf, 'Position', [100, 100, 1200, 900]); % Adjust figure size as needed

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Numerical Simulation of a Damped, Driven Nonlinear Wave System with Spatially Extended Initial Conditions

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