s = w50/(2*np.sqrt(2*np.log(2))) #sigma calculated through the dutycycle a = 1 #amplitude. at some point this will be replaced by the intrinsic spectrum. trainlength = 20 ## Intrinsic profile bins, profile = psr.makeprofile(nbins = P, ncomps = 1, amps = a, means = m, sigmas = s) xaxlong = np.linspace(1,20*P,20*P) #xaxlong = np.linspace(1,100*P,100*P) spectralindex = 1.6 #Input spectral index as a postivie number, for nu^-alpha profile_intr = psr.profilespec(nurange,spectralindex,profile) profile_intr_norm = profile_intr/np.sum(profile_intr[0]) #Normalised such that the max intrinsic flux = 1.0. That is the intrinsice pulse at the lowest frequency has flux = 1 ############################################################################### ## ISOTROPIC ############################################################################### ## In the case of importing data/broadening functions these parameters will only play a roll in plotting the alpha = 4.0 spectrum to compare ## In the case where I simulate the data to fit here, these paramteres will dicatate the shape of the broadening function Dval, Dsval = float(DD),float(Dss) k1 = sigma1 kappa1 = k1*mrad tauval = psr.tau(Dval,Dsval,kappa1,nurange,light)
print 'bandwidth: '+str(bandw)+' GHz' print str(nulow)+'-'+str(nuhigh)+' GHz' ### Create the properties of the ingoing pulse pulseperiod =1.382 #in seconds dutycycle = float(2.5) #as a % of the overall pulseperiod ## Create the profile to have the same time resolution than the broadening function created by photonscat.py P = int(pulseperiod/binstimeres) specepn = 1.8 epn_intr = psr.profilespec(nurange,specepn,epnprofy) epn_norm = epn_intr/np.sum(epn_intr[0]) ## Resample epn_norm to have the same time resolution than the broadening function produced by Ray_minimal.py newbinnumber = pulseperiod/binstimeres epnbintimeres = np.linspace(0.,1.0,len(epn_norm[0])) newtimeres= np.linspace(0,1.0,newbinnumber) epn_norm_interpp = [] for k in range(len(epn_norm)): epn_norm_interp = np.interp(newtimeres,epnbintimeres,epn_norm[k]) epn_norm_interpp.append(epn_norm_interp) ############################################################################### ## ISOTROPIC