I am using
curve_fit to fit a step response of a first order dynamic system to estimate the gain and time constant. I use two approaches. First approach is to fit the curve generated from the function , in the time domain .
# define the first order dynamics in the time domain def model(t,gain,tau): return (gain*(1-exp(-t/tau))) #define the time intervals time_interval = linspace(1,100,100) #genearte the output using the model with gain= 10 and tau= 4 output= model(t,10,4) # fit to output and estimate parameters - gain and tau par = curve_fit(time_interval, output)
par reveals an array of 10 and 4 which is perfect.
The second approach is to estimate gain and time constant by fitting to a step response of a LTI system The LTI System is defined as a transfer function with numerator and denominator.
#define function as a step response of a LTI system . # The argument x has no significance here, # I have included because , the curve_fit requires passing "x" data to the function def model1(x ,gain1,tau1): return lti(gain1,[tau1,1]).step() #generate output using the above model output1 = model1(0,10,4) par1 = curve_fit(model1,1,output1)
now checking par1 reveals an array of [ 1.00024827, 0.01071004] which is wrong. What is wrong with my second approach here? Is there more efficient way of estimating the transfer function coefficients from the data by curve_fit