I am trying to optimize (minimize) a two dimensional function
E(n,k) defined as follows:
error=lambda x,y,w: (math.log(abs(Tformulated(x,y,w))) - math.log(abs(Tw[w])))**2 + (math.atan2(Tformulated(x,y,w).imag,Tformulated(x,y,w).real) - math.atan2(Tw[w].imag,Tw[w].real))**2
Tformulated is obtained as follows :
def Tformulated(n,k,w): z=1j L=1 C=0.1 RC=(w*L)/C n1=complex(1,0) n3=complex(1,0) n2=complex(n,k) FP=1/(1-(((n2-n1)/(n2+n1))*((n2-n3)/(n2+n3))*math.exp(-2*z*n2*RC))) Tform=((2*n2*(n1+n3))/((n2+n1)*(n2+n3)))*(math.exp(-z*(n2-n1)*RC))*FP return Tform
Tw is a list previously calculated having complex valued elements.
What I am exactly trying to do is for each value of
w (used in "error x,y,w ....") I want to minimize the function "error" for the values of
w ranges from 1 to 2048. So, it is basically a 2D minimization problem. I have tried programming on my part (though I am getting stuck at what method to use and how to use it); my code is as follows :
temp= i=range(5) retval = fmin_powell(error , x ,y, args=(i) , maxiter=100 ,maxfun=100) temp.append(retval)
I am not sure even if
fmin_powell is the correct way to go.