Lyapunov exponent function submitted by community
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It seems this funcftion only takes Ordinary Differential Equations (ODE). I have experimental data. how can I use it with data, instead of ODE
7 comentarios
Sam Chak
el 14 de Jun. de 2022
I'm trying to comprehend. Shouldn't your title be revised to "How to obtain Lyapunov exponent from experimental time series?"?
Walter Roberson
el 14 de Jun. de 2022
Editada: Jan
el 14 de Jun. de 2022
Jan
el 14 de Jun. de 2022
Do you mean a specific function in the FileExchange? If so, which one?
Walter Roberson
el 14 de Jun. de 2022
Probably https://www.mathworks.com/matlabcentral/fileexchange/4628-calculation-lyapunov-exponents-for-ode which is just one of the Lyapunov calculators in the File Exchange.
Walter Roberson
el 15 de Jun. de 2022
Editada: Walter Roberson
el 15 de Jun. de 2022
https://ideas.repec.org/c/boc/bocode/t741502.html
https://m.youtube.com/watch?v=I4rscPXUYFk
http://freesourcecode.net/matlabprojects/60648/calculates-full-spectrum-of-lyapunov-exponents-or-k-first-exponents--in-matlab
@Don comment moved here:
Were gaining on it!
The function i'm interested in has been submitted by the COMMUNITY:
MathWorks FileExchange website for community implementations of Lyapunov Exponent calculations. https://www.mathworks.com/matlabcentral/fileexchange/4628-calculation-lyapunov-exponents-for-ode
However, this one apparently works with ODE
I have experimental data. I need one that works with a data file. There is one in the Predictive Maintenance Toolbox, but that costs a lot of money and I have no use for the rest of the toolbox.
is tit possible to find a community supplied function that will work with data??
Don
el 15 de Jun. de 2022
Respuesta aceptada
Hi @Don
If your experimental data is not large, then you can test lyapunovExponent() here to see if it works for your case.
% Parameters
sigma = 10;
beta = 8/3;
rho = 28;
% Lorenz System
f = @(t, x) [-sigma*x(1) + sigma*x(2); ...
rho*x(1) - x(2) - x(1)*x(3); ...
-beta*x(3) + x(1)*x(2)];
tspan = linspace(0, 88, 8801);
init = [1 1 1];
[t, x] = ode45(f, tspan, init);
plot3(x(:,1), x(:,2), x(:,3)), view(45, 30)
% Characterize the rate of separation of infinitesimally close trajectories
xdata = x(:,1);
fs = 10;
dim = 3;
[~, lag] = phaseSpaceReconstruction(xdata, [], dim);
eRange = 50;
lyapunovExponent(xdata, fs, lag, dim, 'ExpansionRange', eRange)
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