150 lines
4.0 KiB
Python
150 lines
4.0 KiB
Python
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from .constants import *
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# -----------------------------------------------------------------------------
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# Generic profile generator
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# -----------------------------------------------------------------------------
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class KSZ_Profile(object):
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R_star= 0.050 # 15 kpc/h
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L_gal0 = 10**(0.4*(tmpp_cat['Msun']-tmpp_cat['Mstar']))
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def __init__(self):
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self.rGalaxy = 1.0
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def evaluate_profile(r):
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raise NotImplementedError("Abstract function")
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def projected_profile(cos_theta,angularDistance):
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idx = np.where(cos_theta > 0)[0]
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tan_theta_2 = 1/(cos_theta[idx]**2) - 1
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tan_theta_2_max = (self.rGalaxy/angularDistance)**2
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tan_theta_2_min = (R_star/angularDistance)**2
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idx0 = np.where((tan_theta_2 < tan_theta_2_max))
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idx = idx[idx0]
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tan_theta_2 = tan_theta_2[idx0]
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tan_theta = np.sqrt(tan_theta_2)
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r = (tan_theta*DA)
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m,idx_mask = self.evaluate_profile(r)
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idx_mask = np.append(idx_mask,np.where(tan_theta_2<tan_theta_2_min)[0])
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idx_mask = np.append(idx_mask,[tan_theta_2.argmin()])
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return idx,idx_mask,m
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# -----------------------------------------------------------------------------
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# Isothermal profile generator
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# -----------------------------------------------------------------------------
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class KSZ_Isothermal(KSZ_Profile):
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sigma_FP=160e3 #m/s
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R_innergal = 0.226
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def __init__(self, Lgal, x, y=0.0):
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"Support for Isothermal profile"
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super(KSZ_Isothermal,self).__init__()
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self.R_gal = 0.226 * x
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self.R_innergal *= y
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self.rho0 = self.sigma_FP**2/(2*np.pi*G) # * (Lgal/L_gal0)**(2./3)
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self.rGalaxy = self.R_gal*(Lgal/self.L_gal0)**(1./3)
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self.rInnerGalaxy = self.R_innergal*(Lgal/self.L_gal0)**(1./3)
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# self._prepare()
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def _prepare(self, x_min, x_max):
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from scipy.integrate import quad
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from numpy import sqrt, log10
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lmin = log10(x_min)
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lmax = log10(x_max)
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x = 10**(np.arange(100)*(lmax-lmin)/100.+lmin)
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profile = np.empty(x.size)
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nu_tilde = lambda u: (1/(u**2*(1+u)))
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for i in range(x.size):
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profile[i] = 2*quad(lambda y: (nu_tilde(sqrt(x[i]**2+y**2))), 0, args.x)[0]
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self._table = x,profile
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def evaluate_profile(r):
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rho0, rGalaxy, rInner = self.rho0, self.rGalaxy, self.rInnerGalaxy
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Q=rho0*2/r*np.arctan(np.sqrt((rGalaxy/r)**2 - 1))/Mpc
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# Q[r<rInner] = 0
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return Q,np.where(r<rInner)[0]
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# -----------------------------------------------------------------------------
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# NFW profile generator
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# -----------------------------------------------------------------------------
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class KSZ_NFW(KSZ_Profile):
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""" Support for NFW profile
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"""
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def __init__(self,x,y=0.0):
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from numpy import log, pi
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if 'pre_nfw' not in self:
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self._prepare()
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kiso = KSZ_Isothermal(x,y)
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r_is = kiso.rGalaxy
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rho_is = kiso.rho0
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r_inner = kiso.rInnerGalaxy
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self.Mgal = rho_is*4*pi*(r_is/args.x)*Mpc #Lgal*M_over_L_galaxy
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self.Rvir = r_is/x
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cs = self._get_concentration(Mgal)
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self.rs = Rvir/cs
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b = (log(1.+cs)-cs/(1.+cs))
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self.rho_s = Mgal/(4*pi*b*(rs*Mpc)**3)
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def _prepare(self, _x_min=1e-4, _x_max=1e4):
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from scipy.integrate import quad
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from numpy import sqrt, log10
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from scipy.interpolate import interp1d
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lmin = log10(x_min)
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lmax = log10(x_max)
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x = 10**(np.arange(100)*(lmax-lmin)/100.+lmin)
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profile = np.empty(x.size)
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nu_tilde = lambda u: (1/(u*(1+u)**2))
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for i in range(x.size):
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if x[i] < args.x:
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profile[i] = 2*quad(lambda y: (nu_tilde(sqrt(x[i]**2+y**2))), 0, np.sqrt((args.x)**2-x[i]**2))[0]
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else:
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profile[i] = 0
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# Insert the interpolator into the class definition
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KSZ_NFW.pre_nfw = self.pre_nfw = interp1d(x,prof)
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def _get_concentration(self, Mvir):
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from numpy import exp, log
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return exp(0.971 - 0.094*log(Mvir/(1e12*MassSun)))
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def evaluate_profile(r):
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cs = self._get_concentration(self.Mvir)
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rs = self.Rvir/cs
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return self.rho_s*rs*Mpc*self.pre_nfw(r/rs),np.array([],dtype=int)
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