Fitting two sets of data with two different model functions simultaneously giving a unique optimal parameter

Question

I am new to python. Using curve_fit from scipy.optimize, I am trying to fit two sets of data with two different model functions (each for one set of data) simultaneously with the same parameters which should be optimised.

Here a sketch of the code for fitting:

def f(x,a,b,c,d,e): 
   return some function

def g(x,a,b,c,d,e): 
   return some other function

a=1
b=2
c=3
d=4
e=5

guesspar=(a,b,c,d,e)
optimalparf, covf=opti.curve_fit(f,x,ydata1,guesspar,some sigma)

print optimalparf


guesspar=(a,b,c,d,e)
optimalparg, covg=opti.curve_fit(g,x,ydata2,guesspar,some sigma)

print optimalparg

where guesspar is the initial value of parameters, optimalparf and optimalparg are the optimal values I am searching for, ydata1 and ydata2 are the two sets of data, and covf and covg are covariance matrices.

Now, my problem is the following: I do get two different sets of optimal value for guesspar which is obviously wrong, since the optimal values should be the same for the whole diagram, that is, for both model functions. (Besides that, one of the sets of the optimal value is nonsense in the context I am interested in).

I know, that the code I have written here is very misleading. I would appreciate a hint at how one could fit two sets of data with two different functions fitting each set of data at the same time which leads to a unique set of optimal parameter.

PS: Here the original code:

import numpy as np
import matplotlib.pyplot as plt
from matplotlib.pyplot import ion 
import time
import random as rd 
import scipy.optimize as opti 
import sys
from numpy import *

n0=1.5 

data =np.genfromtxt('some data') 
data=1000*data

pos=[]
for j in range(len(data)): 
pos.append(np.arcsin(np.sin(np.deg2rad(data[j,0]/1000))/1.5))

m1=[]
for j in range(len(data)): 
m1.append(data[j,1]) 

m1Sig=[]
for j in range(len(data)): 
m1Sig.append(data[j,2]) 

p1=[]
for j in range(len(data)): 
p1.append(data[j,3]) 

p1Sig=[]
for j in range(len(data)): 
p1Sig.append(data[j,4]) 

zero=[]
for j in range(len(data)): 
zero.append(data[j,5]) 

zeroSig=[]
for j in range(len(data)): 
zeroSig.append(data[j,6]) 

#define theta plot-range
thetaMin=-0.5 #[rad]
thetaMax=0.5 
thetaStep=1./635.
theta=np.arange(thetaMin,thetaMax,thetaStep) 
#define r plot-range
rMin=0.02 
rMax=0.09

comboY = np.append(m1, p1)

comboX = np.append(pos, pos)
comboTheta = np.append(theta, theta)

def rM1(theta,lam,d0,deltan,per,y0): 
return y0+((np.pi*deltan*d0)/(lam*np.cos(theta)))**2.*np.sin(np.sqrt(((np.pi*deltan*d0)/(lam*np.cos(theta)))**2.+((np.pi*d0*(-np.arcsin(lam/(2*per*n0))-theta))/per)**2.))**2./(((np.pi*deltan*d0)/(lam*np.cos(theta)))**2.+((np.pi*d0*(-np.arcsin(lam/(2*per*n0))-theta))/per)**2.) 


def rP1(theta,lam,d0,deltan,per,y0): 
return y0+((np.pi*deltan*d0)/(lam*np.cos(theta)))**2.*np.sin(np.sqrt(((np.pi*deltan*d0)/(lam*np.cos(theta)))**2.+((np.pi*d0*(np.arcsin(lam/(2*per*n0))-theta))/per)**2.))**2./(((np.pi*deltan*d0)/(lam*np.cos(theta)))**2.+((np.pi*d0*(np.arcsin(lam/(2*per*n0))-theta))/per)**2.)


def combinedFunction(comboData,lam,d0,deltan,per,y0):

result1 = rM1(theta,lam,d0,deltan,per,y0)
result2 = rP1(theta,lam,d0,deltan,per,y0)

return np.append(result1, result2)

lam1=0.633
d01=100.
deltan1=0.0005
per1=1. 
y01=0.02

m1Err=np.sqrt(m1)
p1Err=np.sqrt(p1)

comboErr=np.append(m1Err,p1Err)

startParam=[lam1, d01 ,deltan1, per1, y01]

popt, pcov = opti.curve_fit(combinedFunction, comboX, comboY, startParam) 
print popt 

lam,d0,deltan,per,y0 = popt

y_fit_1 = rM1(theta,lam,d0,deltan,per,y0) # first data set, first equation
y_fit_2 = rP1(theta,lam,d0,deltan,per,y0) # second data set, second equation

plt.plot(comboX, comboY, '.') # plot the raw data
plt.plot(pos, y_fit_1,'b') # plot the equation using the fitted parameters
plt.plot(pos, y_fit_2,'r') # plot the equation using the fitted parameters
plt.show()

print('lam,d0,deltan,per,y0:', popt)

Answer 1

I think this example will help, it has a single shared parameter for two data sets and two functions, just make all of the parameters shared and it should be what you need.

import numpy as np
import matplotlib
import matplotlib.pyplot as plt
from scipy.optimize import curve_fit

y1 = np.array([ 16.00,  18.42,  20.84,  23.26])
y2 = np.array([-20.00, -25.50, -31.00, -36.50, -42.00])
comboY = np.append(y1, y2)

x1 = np.array([5.0, 6.1, 7.2, 8.3])
x2 = np.array([15.0, 16.1, 17.2, 18.3, 19.4])
comboX = np.append(x1, x2)

if len(y1) != len(x1):
    raise(Exception('Unequal x1 and y1 data length'))
if len(y2) != len(x2):
    raise(Exception('Unequal x2 and y2 data length'))


def function1(data, a, b, c): # not all parameters are used here, c is shared
        return a * data + c

def function2(data, a, b, c): # not all parameters are used here, c is shared
        return b * data + c


def combinedFunction(comboData, a, b, c):
    # single data reference passed in, extract separate data
    extract1 = comboData[:len(x1)] # first data
    extract2 = comboData[len(x1):] # second data

    result1 = function1(extract1, a, b, c)
    result2 = function2(extract2, a, b, c)

    return np.append(result1, result2)


# some initial parameter values
initialParameters = np.array([1.0, 1.0, 1.0])

# curve fit the combined data to the combined function
fittedParameters, pcov = curve_fit(combinedFunction, comboX, comboY, initialParameters)

# values for display of fitted function
a, b, c = fittedParameters

y_fit_1 = function1(x1, a, b, c) # first data set, first equation
y_fit_2 = function2(x2, a, b, c) # second data set, second equation

plt.plot(comboX, comboY, 'D') # plot the raw data
plt.plot(x1, y_fit_1) # plot the equation using the fitted parameters
plt.plot(x2, y_fit_2) # plot the equation using the fitted parameters
plt.show()

print('a, b, c:', fittedParameters)

Answer 2

If you wouldn't mind using an additional package which wraps scipy, then the symfit package I wrote would allow you to do this quite simply. Example code:

from symfit import variables, parameters, Fit

# These are your datasets
xdata = np.array([...])
ydata = np.array([...])
zdata = np.array([...])

a, b, c, d, e = parameters('a, b, c, d, e')
x, y, z = variables('x, y, z')

model_dict = {
    y: a * x + b * x**2 + ...,
    z: a / x + b / x**2 + ...
}

fit = Fit(model_dict, x=xdata, y=ydata, z=zdata)
fit_result = fit.execute()
print(fit_result)

That's it! I assumed here that the two datasets share the same x-axis, but even that does not have to be the case. The parameters will now be optimized to give the optimal solution to this system of equations.

For more info, you can find the documentation here.