Newton's Method on MATLAB for Stationary Solutions for the Non-linear Klein-Gordon Equation
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Athanasios Paraskevopoulos
am 17 Mär. 2024
Bearbeitet: Torsten
am 20 Mär. 2024
By interpreting the equation in this way, we can relate the dynamics described by the discrete Klein - Gordon equation to the behavior of DNA molecules within a biological system .
I am trying to represnt stationary points of the discrete Klein - Gordon equation. And the result are as follows.
Mathematica are different from MATLAB Any suggestion?
UPDATED CODE
% Parameters
numBases = 100; % Number of spatial points
omegaD = 0.2; % Common parameter for the equation
% Preallocate the array for the function handles
equations = cell(numBases, 1);
% Initial guess for the solution
initialGuess = 0.01 * ones(numBases, 1);
% Parameter sets for kappa and beta
paramSets = [0.1, 0.05; 0.5, 0.05; 0.1, 0.2];
% Prepare figure for subplot
figure;
set(gcf, 'Position', [100, 100, 1200, 400]); % Set figure size
% Newton-Raphson method parameters
maxIterations = 1000;
tolerance = 1e-10;
for i = 1:size(paramSets, 1)
kappa = paramSets(i, 1);
beta = paramSets(i, 2);
% Define the equations using a function
for n = 2:numBases-1
equations{n} = @(x) -kappa * (x(n+1) - 2 * x(n) + x(n-1)) - omegaD^2 * (x(n) - beta * x(n)^3);
end
% Boundary conditions with specified fixed values
someFixedValue1 = 10; % Replace with actual value if needed
someFixedValue2 = 10; % Replace with actual value if needed
equations{1} = @(x) x(1) - someFixedValue1;
equations{numBases} = @(x) x(numBases) - someFixedValue2;
% Combine all equations into a single function
F = @(x) cell2mat(cellfun(@(f) f(x), equations, 'UniformOutput', false));
% Newton-Raphson iteration
x_solution = initialGuess;
for iter = 1:maxIterations
% Evaluate function
Fx = F(x_solution);
% Evaluate Jacobian
J = zeros(numBases, numBases);
epsilon = 1e-6; % For numerical differentiation
for j = 1:numBases
x_temp = x_solution;
x_temp(j) = x_temp(j) + epsilon;
Fx_temp = F(x_temp);
J(:, j) = (Fx_temp - Fx) / epsilon;
end
% Update solution
delta = -J\Fx;
x_solution = x_solution + delta;
% Check convergence
if norm(delta, inf) < tolerance
fprintf('Convergence achieved after %d iterations.\n', iter);
break;
end
end
if iter == maxIterations
error('Maximum iterations reached without convergence.');
end
% Plot the solution in a subplot
subplot(1, 3, i);
plot(x_solution, 'o-', 'LineWidth', 2);
grid on;
xlabel('n', 'FontSize', 12);
ylabel('x[n]', 'FontSize', 12);
title(sprintf('\\kappa = %.2f, \\beta = %.2f', kappa, beta), 'FontSize', 14);
end
% Improve overall aesthetics
sgtitle('Stationary States for Different \kappa and \beta Values', 'FontSize', 16); % Super title for the figure
Mathematica plots
3 Kommentare
Akzeptierte Antwort
Torsten
am 18 Mär. 2024
Bearbeitet: Torsten
am 18 Mär. 2024
All you see in the graphs are floating point errors.
Your system of equations has solution x(i) = 0 for 1 <= i <= numBases and all three parameter constellations.
17 Kommentare
Torsten
am 20 Mär. 2024
Bearbeitet: Torsten
am 20 Mär. 2024
Because I am begginer to Matlab, when I use fsolve I replace all the following code
Yes.
and is more accurate right?
Obviously not in your case since it doesn't converge for the initialGuess you supply. Only if you set
initialGuess = 10 * ones(numBases, 1);
e.g., it converges to the solution you get with your code of Newton's method (except for the first case where at least three solutions seem to exist: 0, your solution and the solution you get with "fsolve").
So it's hard to interprete the results if you cannot apply physical reasoning to sort out solutions that make no sense.
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