How to find the best parameters to fit damped oscillations curves

11 次查看(过去 30 天)
Louise
Louise 2020-1-22
评论: Bjorn Gustavsson 2020-1-23
Hello,
My goal is to fit the best these filtered data (attached) with the equation :
x(1)*exp(-x(2)*t).*sin(2*pi*x(3)*t+x(4)).
Here is my code (below) but this algorithm doesn't give a good fitting.
I don't know if it is a problem of parameters (for example, how to choose x0, ub and lb. I read some information on Matlab website but it doesn't help me)...
Thanks in advance for your help !
fun = @(x,t) x(1)*exp(-x(2)*t).*sin(2*pi*x(3)*t+x(4));
t=[0:1/1000:(1/1000*(length(data_TRT)-1))];
x0 = [2,1,1,1]
options = optimoptions('lsqcurvefit','Algorithm','levenberg-marquardt');
lb = [0,0,0,-1]
ub = [2,100,100,1]
[x,resnorm] = lsqcurvefit(fun,x0,t,data_TRT,lb,ub,options)
figure
plot(t,data_TRT,'k-',t,fun(x,t),'r-')
legend('Experimental Data','Modeled Data')
title('Data and Fitted Curve')
xlabel('Temps (secondes)')
Damping_Nigg =x(2)
Frequence_Nigg =x(3)

请先登录,再回答此问题。

采纳的回答

Star Strider
Star Strider 2020-1-22
编辑:Star Strider 2020-1-22
See: How to filter noise from time-frequency data and find natural frequency of a cantilever?
Specifically:
D = load('Louise data_TRT_HELP.mat');
data = D.data_TRT;
t= linspace(0, numel(data), numel(data));
y=data;
Fs=500;
Fn = Fs/2; % Nyquist Frequency
L = size(t,2);
y = detrend(y); % Remove Linear Trend
fty = fft(y)/L;
Fv = linspace(0, 1, fix(L/2)+1)*Fn; % Frequency Vector
Iv = 1:length(Fv); % Index Vector
figure(1)
plot(Fv, abs(fty(Iv)))
grid
Wp = 30/Fn; % Passband (Normalised)
Ws = 40/Fn; % Stopband (Normalised)
Rp = 1; % Passband Ripple
Rs = 50; % Stopband Ripple
[n,Wp] = ellipord(Wp,Ws,Rp,Rs); % Filter Order
[z,p,k] = ellip(n,Rp,Rs,Wp); % Transfer Function Coefficients
[sos,g] = zp2sos(z,p,k); % Second-Order-Section For Stability
figure(2)
freqz(sos, 2^14, Fs)
yf = filtfilt(sos,g,y);
yu = max(yf);
yl = min(yf);
yr = (yu-yl); % Range of ‘y’
yz = yf-yu+(yr/2);
zt = t(yz(:) .* circshift(yz(:),[1 0]) <= 0); % Find zero-crossings
per = 2*mean(diff(zt)); % Estimate period
ym = mean(y); % Estimate offset
fit = @(b,x) b(1) .* exp(b(2).*x) .* (sin(2*pi*x./(b(3)+b(4).*x) + 2*pi/b(5))) + b(6); % Objective Function to fit
fcn = @(b) sum((fit(b,t) - yf).^2); % Least-Squares cost function
s = fminsearch(fcn, [yr; -1; per; 0.01; -1; ym]) % Minimise Least-Squares
xp = linspace(min(t),max(t));
figure(3)
plot(t,y,'b')
hold on
plot(t,yf,'g', 'LineWidth',2)
plot(xp,fit(s,xp), 'r', 'LineWidth',1.5)
hold off
grid
title('Sample Data 2')
xlabel('Time')
ylabel('Amplitude')
legend('Original Data', 'Lowpass-Filtered Data', 'Fitted Curve')
producing:
How to find the best parameters to fit damped oscillations curves - 2020 01 22.png
  5 个评论
显示 3更早的评论
Star Strider
Star Strider 2020-1-23
As always, my pleasure!
I chose those values to pass the frequencies that appeared to have the most energy, and filter out the high-frequency noise that could interfere with the parameter estimation.
Probably the best way to understand how that works is to experiment with them and see what the results are. Remember that for a lowpass filter, ‘Ws’ must always be greater than ‘Wp’, and with an elliptic filter, by at least 5 Hz (with this sampling frequency) for best results.
Bjorn Gustavsson
Bjorn Gustavsson 2020-1-23
One thing to consider further is that after the low-pass filtering there might be an "over-filtering" of the initial variations (time < 20). If that's the case then it might be interesting to run the fitting to the original data using the best parameters from the fiting to the filtered data. The general idea is that the filtering reduces the risk of the fiting ending up in some local minima giving you a fit to high-frequency noise, but after the first fitting you would be close enough to the "proper" best-parameters that you now can fit to the original data.

请先登录,再进行评论。

更多回答(1 个)

Bjorn Gustavsson
Bjorn Gustavsson 2020-1-22
If you plot your data you should be able to see that the zero-crossings are increasingly further apart.
That means that your mode-function will not be able to capture the decay nicely. You might have to introduce another parameter in your function to model this chirp.
HTH

类别

Help CenterFile Exchange 中查找有关 Multirate Signal Processing 的更多信息

标签

产品


版本

R2015b

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by