# Fitting complex model using Python and lmfit?

I would like to fit ellipsometric data to complex model using lmfit. Two measured parameters, psi and delta, are variables in a complex function rho.

I could try with separating problem to real and imaginary part with shared parameters or picewise approach, but is there any way to do it directly with complex function? Fitting only real part of function works beautifully, but when I define complex residual function I get:

> TypeError: no ordering relation is defined for complex numbers.

Below is my code for real function fitting and my attempt at tackling complex fit problem.

    from __future__ import division
from __future__ import print_function
import numpy as np
from pylab import *
from lmfit import minimize, Parameters, Parameter, report_errors

#=================================================================
#             MODEL

def r01_p(eps2, th):
c=cos(th)
s=(sin(th))**2

stev= sqrt(eps2) * c - sqrt(1-(s / eps2))
imen= sqrt(eps2) * c + sqrt(1-(s / eps2))
return stev/imen

def r01_s(eps2, th):
c=cos(th)
s=(sin(th))**2

stev= c - sqrt(eps2) * sqrt(1-(s/eps2))
imen= c + sqrt(eps2) * sqrt(1-(s/eps2))
return stev/imen

def rho(eps2, th):
return r01_p(eps2, th)/r01_s(eps2, th)

def psi(eps2, th):
x1=abs(r01_p(eps2, th))
x2=abs(r01_s(eps2, th))
return np.arctan2(x1,x2)

#=================================================================
#                   REAL FIT
#

#%%

# generate data from model
error=0.01
var_re=np.random.normal(size=len(th), scale=error)
data = psi(2,th) + var_re

# residual function
def residuals(params, th, data):
eps2 = params['eps2'].value

diff = psi(eps2, th) - data
return diff

# create a set of Parameters
params = Parameters()

# do fit, here with leastsq model
result = minimize(residuals, params, args=(th, data),method="leastsq")

# calculate final result
final = data + result.residual

# write error report
report_errors(params)

# try to plot results
try:
import pylab
clf()
fig=plot(th, data, 'r o',
th, final, 'b')
setp(fig,lw=2.)
xlabel(r'$\theta$ $(^{\circ})$', size=20)
ylabel(r'$\psi$ $(^{\circ})$',size=20)

show()

except:
pass

#%%
#=================================================================
#                   COMPLEX FIT

# TypeError: no ordering relation is defined for complex numbers

"""
# data from model with added noise
error=0.001
var_re=np.random.normal(size=len(th), scale=error)
var_im=np.random.normal(size=len(th), scale=error) * 1j

data = rho(4-1j,th) + var_re + var_im

# residual function
def residuals(params, th, data):
eps2 = params['eps2'].value

diff = rho(eps2, th) - data
return np.abs(diff)

# create a set of Parameters
params = Parameters()

# do fit, here with leastsq model
result = minimize(residuals, params, args=(th, data),method="leastsq")

# calculate final result
final = data + result.residual

# write error report
report_errors(params)
"""
#=================================================================


Thank you for any suggestions :).

Edit: I solved problem with separated variables for imaginary and real part. Data should be shaped as [[imaginary_data],[real_data]], objective function must return 1D array.

def objective(params, th_data, data):
eps_re  = params['eps_re'].value
eps_im  = params['eps_im'].value
d       = params['d'].value

residual_delta = data[0,:] - delta(eps_re - eps_im*1j, d, frac, lambd, th_data)
residual_psi   = data[1,:] - psi(eps_re - eps_im*1j, d, frac, lambd, th_data)

return np.append(residual_delta,residual_psi)

# create a set of Parameters
params = Parameters()
params.add('eps_re',   value= 1.5,  min=1.0,      max=5  )
params.add('eps_im',   value= 1.0,  min=0.0,      max=5  )
params.add('d',        value= 10.0,   min=5.0,    max=100.0   )

# All available methods
methods=['leastsq','nelder','lbfgsb','anneal','powell','cobyla','slsqp']
# Chosen method
#metoda='leastsq'

# run the global fit to all the data sets
result = minimize(objective, params, args=(th_data,data),method=metoda))

....

return ...

-
While I don't know for sure, I think the TypeError you're getting essentially answers your question: lmfit will need to know whether to increase or decrease its parameters, and since ordering for complex numbers is undefined, it can't (is j larger or smaller than 1?). –  Evert May 2 '14 at 9:13
Sometimes answer is too obvious to see it... I solved problem with separating probem to real and imaginary variable, see my edit if interested. Thank you Evert! :) –  Jur Kravla May 3 '14 at 13:11