pypho_cfiber.py 7.96 KB
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#!/usr/bin/env python
#
#  Copyright 2018 Arne Striegler (arne.striegler@hm.edu)
#
#
#
# Simulates a fiber ...fast!
#
#
########################################################################

import numpy as np
import sys
from pypho_functions import *
from pypho_fiber_birefringence import pypho_fiber_birefringence
import time

import copy
from speedfiber import *
#from speedtest import *

########################################################################

class pypho_cfiber(object):
    def __init__(self, glova = None, fibertype = None, D = None, S = None, gamma = None, alpha = None, l = None, birefarray = None, phi_max = None):

        if glova == None:
            print ("ERROR: You must define the global variables")
            sys.exit("PyPho stopped!")

        self.glova     = glova
        self.D         = None
        self.S         = None
        self.l         = None
        self.gamma     = None
        self.alpha     = None
        self.birefarray = None
        self.nos        = None
        self.phi_max     = None

        self.set(fibertype, D, S, gamma, alpha, l, birefarray, phi_max)


########################################################################

    def __call__(self, E = None, fibertype = None, D = None, S = None, gamma = None, alpha = None, l = None, birefarray = None, phi_max = None):

        self.set(fibertype, D, S, gamma, alpha, l, birefarray, phi_max)

        if self.glova.cloud :
            E.append(self.get_parameters())
            return E
        else :
            return self.transmit(E, fibertype, D, S, gamma, alpha, l, phi_max)

########################################################################

    def transmit(self, E = None, fibertype = None, D = None, S = None, gamma = None, alpha = None, l = None, phi_max = None):
        """Transmit the signal"""

        if E == None:
            print ("ERROR: You must define an optical signal")
            sys.exit("PyPho stopped!")

        if type(E) != list:
            E = [E]

        self.set(fibertype, D, S, gamma, alpha, l, phi_max)

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        #self.E = E
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        self.gamma_intern = self.gamma * 1e-3
        self.max_step = 200

        z = 0

        #for Ei in E:
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        #self.fibtrans(z)
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        #z += 1
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        print('Start!')  
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        tic0 = time.time()   
        n = self.glova.sps*self.glova.nos
        #Ef_out = np.zeros((1,n)) + 1j*np.ones((1,n))
        Ex_out = np.zeros(n) + 1j*np.ones(n)
        Ey_out = np.zeros(n) + 1j*np.ones(n)
        birefarraydoubles = np.zeros((len(self.birefarray), 3))
        for i in range (0, len(self.birefarray)):
            birefarraydoubles[i,0] = self.birefarray[i].angle
            birefarraydoubles[i,1] = self.birefarray[i].z_point
            birefarraydoubles[i,2] = self.birefarray[i].delta_beta
            
        cyfiber(self.glova.sps*self.glova.nos, self.l, np.asarray(E[z]['E'][0]), np.asarray(E[z]['E'][1]),
                self.alpha, self.gamma_intern, self.phi_max, birefarraydoubles, len(self.birefarray), self.max_step, self.beta_fac,
                np.asarray(1j * scipy.fftpack.fftshift( self.Domega )), Ex_out, Ey_out)
           
        E[z]['E'][0] = Ex_out
        E[z]['E'][1] = Ey_out
 
        print ('Fertig: ', time.time() - tic0 )        

        return E
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 ########################################################################

    def fibtrans(self, zsep):
        """Calculate step"""

        print('Start!')  

        tic0 = time.time()   
        n = self.glova.sps*self.glova.nos
        #Ef_out = np.zeros((1,n)) + 1j*np.ones((1,n))
        Ex_out = np.zeros(n) + 1j*np.ones(n)
        Ey_out = np.zeros(n) + 1j*np.ones(n)
        birefarraydoubles = np.zeros((len(self.birefarray), 3))
        for i in range (0, len(self.birefarray)):
            birefarraydoubles[i,0] = self.birefarray[i].angle
            birefarraydoubles[i,1] = self.birefarray[i].z_point
            birefarraydoubles[i,2] = self.birefarray[i].delta_beta
            
        cyfiber(self.glova.sps*self.glova.nos, self.l, np.asarray(self.E[zsep]['E'][0]), np.asarray(self.E[zsep]['E'][1]),
                self.alpha, self.gamma_intern, self.phi_max, birefarraydoubles, len(self.birefarray), self.max_step, self.beta_fac,
                np.asarray(1j * scipy.fftpack.fftshift( self.Domega )), Ex_out, Ey_out)
           
        self.E[zsep]['E'][0] = Ex_out
        self.E[zsep]['E'][1] = Ey_out
 
        print ('Fertig: ', time.time() - tic0 )


########################################################################
    def get_parameters(self):
        """Get all fiber parameters set by the user"""
        biref_angle = []
        biref_zpoint = []
        biref_delta_beta = []
        for x in self.birefarray:
            biref_angle.append(x.angle)
            biref_zpoint.append(x.z_point)
            biref_delta_beta.append(x.delta_beta)

        params = {'type' : 'fiber', 'D':  self.D, 'S' : self.S,'l' : self.l, 'gamma' : self.gamma, 'alpha' : 4.343e3*self.alpha, 'biref_delta_beta' : biref_delta_beta, 'biref_zpoint' : biref_zpoint, 'biref_angle' : biref_angle, 'useYPol' : True}
        return params

########################################################################
    def set(self, fibertype = None, D = None, S = None, gamma = None, alpha = None, l = None, birefarray = None, phi_max = None):
        """Set fibre properties"""


        if fibertype ==  'SSMF':
            self.D         = 17.0                   # [ps/(nm km)]
            self.S         = 0.0                         # [ps/(nm2 km)]
            self.gamma     = 1.14                   # [1/(W m)]
            self.alpha     = db2neper(0.20)  / 1.0e3     # [1/m]


        if fibertype == 'DCF':
            self.D         = -100.0                    # [ps/(nm km)]
            self.S         = 0.0                        # [ps/(nm2 km)]
            self.gamma     = 1.7                        # [1/(W m)]
            self.alpha     = db2neper(0.20)  / 1.0e3   # [1/m]


        if D == None and fibertype == None and self.D == None:
            print ("Warning: D and fibertype not specified, so I set D = 16.8 ps/nm/km")
            self.D             = 17.0
        elif D != None:
            self.D = D

        if S == None and fibertype == None and self.S == None:
            print ("Warning: S and fibertype not specified, so I set S = 0.68 ps/nm**2/km")
            self.S             = 0.68
        elif S != None:
            self.S = S

        if gamma == None and fibertype == None and self.gamma == None:
            print ("Warning: gamma and fibertype not specified, so I set gamma = 1.14 1/W/km")
            self.gamma            = 1.14
        elif gamma != None:
            self.gamma = gamma

        if alpha == None and fibertype == None and self.alpha == None:
            print ("Warning: alpha and fibertype not specified, so I set alpha = 0.25 dB/km")
            self.alpha         = db2neper(0.25)  / 1.0e3
        elif alpha != None:
            self.alpha = db2neper(alpha) / 1.0e3

        if l == None and fibertype == None and self.l == None:
            print ("Warning: L and fibertype not specified, so I set L = 80 km")
            self.l         = 80e3
        elif l != None:
            self.l = l
            
        if phi_max == None and self.phi_max == None:
            print ("Warning: phi_max not specified, so I set phi_max = 1e-3")
            self.phi_max         = 1e-3
        elif phi_max != None:
            self.phi_max = phi_max

        if birefarray == None and self.birefarray == None:
            nosiref = pypho_fiber_birefringence (0.0, 0.0, 0.0)
            self.birefarray = [nosiref]
        elif birefarray != None:
            self.birefarray = birefarray

        (self.beta_2, self.beta_3) =  DS2beta(self.D, self.S, self.glova.lambda0)

        self.Domega     = 2.0 * np.pi * (self.glova.freqax - 1*self.glova.f0) / 1.0e12
        self.beta_fac   = -1j * fftshift  ( self.beta_2*0.5e24 * self.Domega**2.0 + self.beta_3*1.0e36 / 6.0  * self.Domega**3.0)


########################################################################