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pkdgrav_cosmo.py
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pkdgrav_cosmo.py
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"""
pkdgrav_cosmo
=============
Cosmological module from PKDGRAV.
N.B. This code is being shared with skid and the I.C. generator.
**NEEDS DOCUMENTATION**
"""
import math
from scipy.integrate import ode, romberg
class Cosmology:
""" docs placeholder """
EPSCOSMO = 1e-7
def __init__(self, sim=None, H0=math.sqrt(8 * math.pi / 3), Om=0.272,
L=0.728, Ob=0.0456,
Or=0.0, Quin=0.0, Ok=0.0):
if sim is not None:
self.dOmegaM = sim.properties['omegaM0']
self.dLambda = sim.properties['omegaL0']
else:
self.dOmegaM = Om
self.dLambda = L
self.dHubble0 = H0
self.dOmegab = Ob
self.dOmegaRad = Or
self.dQuintess = Quin
self.dOmegaCurve = Ok
self.bComove = 1
# The cosmological equation of state is entirely determined here. We
# will derive all other quantities from these two functions.
def Exp2Hub(self, dExp):
dOmegaCurve = (1.0 - self.dOmegaM - self.dLambda -
self.dOmegaRad - self.dQuintess)
assert(dExp > 0.0)
return (self.dHubble0 * math.sqrt(self.dOmegaM * dExp
+ dOmegaCurve * dExp * dExp
+ self.dOmegaRad
+ self.dQuintess * dExp *
dExp * math.sqrt(dExp)
+ self.dLambda * dExp * dExp * dExp * dExp) / (dExp * dExp))
# Return a double dot over a.
def ExpDot2(self, dExp):
return (self.dHubble0 * self.dHubble0 *
(self.dLambda - 0.5 * self.dOmegaM / (dExp * dExp * dExp)
+ 0.25 * self.dQuintess / (dExp * math.sqrt(dExp))
- self.dOmegaRad / (dExp * dExp * dExp * dExp)))
def Time2Hub(self, dTime):
a = self.Time2Exp(dTime)
assert(a > 0.0)
return self.Exp2Hub(a)
def CosmoTint(self, dY):
dExp = dY ** (2.0 / 3.0)
assert(dExp > 0.0)
return 2.0 / (3.0 * dY * self.Exp2Hub(dExp))
def Exp2Time(self, dExp):
dOmegaM = self.dOmegaM
dHubble0 = self.dHubble0
if(self.dLambda == 0.0 and self.dOmegaRad == 0.0 and
self.dQuintess == 0.0):
if (dOmegaM == 1.0):
assert(dHubble0 > 0.0)
if (dExp == 0.0):
return(0.0)
return(2.0 / (3.0 * dHubble0) * dExp ** 1.5)
elif (dOmegaM > 1.0):
assert(dHubble0 >= 0.0)
if (dHubble0 == 0.0):
B = 1.0 / math.sqrt(dOmegaM)
eta = acos(1.0 - dExp)
return(B * (eta - sin(eta)))
if (dExp == 0.0):
return(0.0)
a0 = 1.0 / dHubble0 / math.sqrt(dOmegaM - 1.0)
A = 0.5 * dOmegaM / (dOmegaM - 1.0)
B = A * a0
eta = acos(1.0 - dExp / A)
return(B * (eta - sin(eta)))
elif (dOmegaM > 0.0):
assert(dHubble0 > 0.0)
if (dExp == 0.0):
return(0.0)
a0 = 1.0 / dHubble0 / math.sqrt(1.0 - dOmegaM)
A = 0.5 * dOmegaM / (1.0 - dOmegaM)
B = A * a0
eta = acosh(dExp / A + 1.0)
return(B * (sinh(eta) - eta))
elif (dOmegaM == 0.0):
assert(dHubble0 > 0.0)
if (dExp == 0.0):
return(0.0)
return(dExp / dHubble0)
else:
#* Bad value.
assert(0)
return(0.0)
else:
# Set accuracy to 0.01 EPSCOSMO to make Romberg integration
# more accurate than Newton's method criterion in Time2Exp. --JPG
return romberg(self.CosmoTint, self.EPSCOSMO, dExp ** 1.5, tol=0.01 * self.EPSCOSMO)
def Time2Exp(self, dTime):
dHubble0 = self.dHubble0
dExpOld = 0.0
dExpNew = dTime * dHubble0
dDeltaOld = dExpNew
# old change in interval
dUpper = 1.0e38
# bounds on root
dLower = 0.0
it = 0
# Root find with Newton's method.
while (math.fabs(dExpNew - dExpOld) / dExpNew > self.EPSCOSMO):
f = dTime - self.Exp2Time(dExpNew)
fprime = 1.0 / (dExpNew * self.Exp2Hub(dExpNew))
if(f * fprime > 0):
dLower = dExpNew
else:
dUpper = dExpNew
dExpOld = dExpNew
dDeltaOld = f / fprime
dExpNext = dExpNew + dDeltaOld
# check if bracketed
if((dExpNext > dLower) and (dExpNext < dUpper)):
dExpNew = dExpNext
else:
dExpNew = 0.5 * (dUpper + dLower)
it += 1
assert(it < 40)
return dExpNew
def ComoveDriftInt(self, dIExp):
return -dIExp / (Exp2Hub(1.0 / dIExp))
#* Make the substitution y = 1/a to integrate da/(a^2*H(a))
def ComoveKickInt(self, dIExp):
return -1.0 / (self.Exp2Hub(1.0 / dIExp))
#* This function integrates the time dependence of the "drift"-Hamiltonian.
def ComoveDriftFac(self, dTime, dDelta):
dOmegaM = self.dOmegaM
dHubble0 = self.dHubble0
if(self.dLambda == 0.0 and self.dOmegaRad == 0.0 and
self.dQuintess == 0.0):
a1 = self.Time2Exp(dTime)
a2 = self.Time2Exp(dTime + dDelta)
if (dOmegaM == 1.0):
return((2.0 / dHubble0) * (1.0 / math.sqrt(a1) - 1.0 / math.sqrt(a2)))
elif (dOmegaM > 1.0):
assert(dHubble0 >= 0.0)
if (dHubble0 == 0.0):
A = 1.0
B = 1.0 / math.sqrt(dOmegaM)
else:
a0 = 1.0 / dHubble0 / math.sqrt(dOmegaM - 1.0)
A = 0.5 * dOmegaM / (dOmegaM - 1.0)
B = A * a0
eta1 = acos(1.0 - a1 / A)
eta2 = acos(1.0 - a2 / A)
return(B / A / A * (1.0 / tan(0.5 * eta1) - 1.0 / tan(0.5 * eta2)))
elif (dOmegaM > 0.0):
assert(dHubble0 > 0.0)
a0 = 1.0 / dHubble0 / math.sqrt(1.0 - dOmegaM)
A = 0.5 * dOmegaM / (1.0 - dOmegaM)
B = A * a0
eta1 = acosh(a1 / A + 1.0)
eta2 = acosh(a2 / A + 1.0)
return(B / A / A * (1.0 / tanh(0.5 * eta1) - 1.0 / tanh(0.5 * eta2)))
elif (dOmegaM == 0.0):
# YOU figure this one out!
assert(0)
return(0.0)
else:
# Bad value?
assert(0)
return(0.0)
else:
return romberg(self.ComoveDriftInt, 1.0 / self.Time2Exp(dTime),
1.0 / self.Time2Exp(dTime + dDelta), tol=self.EPSCOSMO)
# This function integrates the time dependence of the "kick"-Hamiltonian.
def ComoveKickFac(self, dTime, dDelta):
dOmegaM = self.dOmegaM
dHubble0 = self.dHubble0
if (not self.bComove):
return(dDelta)
elif(self.dLambda == 0.0 and self.dOmegaRad == 0.0
and self.dQuintess == 0.0):
a1 = self.Time2Exp(dTime)
a2 = self.Time2Exp(dTime + dDelta)
if (dOmegaM == 1.0):
return((2.0 / dHubble0) * (math.sqrt(a2) - math.sqrt(a1)))
elif (dOmegaM > 1.0):
assert(dHubble0 >= 0.0)
if (dHubble0 == 0.0):
A = 1.0
B = 1.0 / math.sqrt(dOmegaM)
else:
a0 = 1.0 / dHubble0 / math.sqrt(dOmegaM - 1.0)
A = 0.5 * dOmegaM / (dOmegaM - 1.0)
B = A * a0
eta1 = acos(1.0 - a1 / A)
eta2 = acos(1.0 - a2 / A)
return(B / A * (eta2 - eta1))
elif (dOmegaM > 0.0):
assert(dHubble0 > 0.0)
a0 = 1.0 / dHubble0 / math.sqrt(1.0 - dOmegaM)
A = 0.5 * dOmegaM / (1.0 - dOmegaM)
B = A * a0
eta1 = acosh(a1 / A + 1.0)
eta2 = acosh(a2 / A + 1.0)
return(B / A * (eta2 - eta1))
elif (dOmegaM == 0.0):
#* YOU figure this one out!
assert(0)
return(0.0)
else:
#* Bad value?
assert(0)
return(0.0)
else:
return romberg(self.ComoveKickInt, 1.0 / self.Time2Exp(dTime),
1.0 / self.Time2Exp(dTime + dDelta), tol=self.EPSCOSMO)
def ComoveLookbackTime2Exp(self, dComoveTime):
if (not self.bComove):
return(1.0)
else:
dExpOld = 0.0
dT0 = self.Exp2Time(1.0)
dTime = dT0 - dComoveTime
dExpNew
it = 0
if(dTime < self.EPSCOSMO):
dTime = self.EPSCOSMO
dExpNew = self.Time2Exp(dTime)
# Root find with Newton's method.
while (fabs(dExpNew - dExpOld) / dExpNew > self.EPSCOSMO):
dTimeNew = self.Exp2Time(dExpNew)
f = (dComoveTime - self.ComoveKickFac(
dTimeNew, dT0 - dTimeNew))
fprime = -1.0 / (dExpNew * dExpNew * self.Exp2Hub(dExpNew))
dExpOld = dExpNew
dExpNew += f / fprime
it += 1
assert(it < 20)
return dExpNew
# delta[1] => deltadot
def GrowthFacDeriv(self, dlnExp, dlnDelta, dlnDeltadot):
dExp = exp(dlnExp)
dHubble = self.Exp2Hub(dExp)
dlnDeltadot[0] = dlnDelta[1]
dlnDeltadot[1] = (-dlnDelta[1] * dlnDelta[1]
- dlnDelta[1] * (1.0 + self.ExpDot2(
dExp) / (dHubble * dHubble))
+ 1.5 * self.Exp2Om(dExp))
def GrowthFac(self, dExp):
dlnExpStart = -15
nSteps = 200
dlnExp = math.log(dExp)
assert(dlnExp > dlnExpStart)
dDStart[0] = dlnExpStart
dDStart[1] = 1.0
# Growing mode
integrator = ode(GrowthFacDeriv).set_integrator('dopri5')
# , 2,
# , dDEnd, nSteps);
integrator = integrator.set_initial_value(
2, dlnExpStart, dDStart, dlnExp)
dDEnd = integrator.integrate(t1, step=0, relax=0)
flag = integrator.successful()
return exp(dDEnd[0])
def GrowthFacDot(self, dExp):
dlnExpStart = -15
nSteps = 200
dlnExp = math.log(dExp)
dDStart[2]
dDEnd[2]
assert(dlnExp > dlnExpStart)
dDStart[0] = dlnExpStart
dDStart[1] = 1.0
# Growing mode
integrator = ode(GrowthFacDeriv).set_integrator('dopri5')
# , 2, dlnExpStart, dDStart, dlnExp, dDEnd,nSteps);
return dDEnd[1] * self.Exp2Hub(dExp) * exp(dDEnd[0])
# expansion dependence of Omega_matter
def Exp2Om(self, dExp):
dHubble = self.Exp2Hub(dExp)
return (self.dOmegaM * self.dHubble0 * self.dHubble0 /
(dExp * dExp * dExp * dHubble * dHubble))