def stable_final_data_BPSwithPolyCSS(final_data):
stable_parameter = []
for i in range(final_data.N):
eos = EOS_BPSwithPoly(final_data.parameter[i].args[0:7])
pressure_trans = final_data.parameter[i].args[7]
det_density = final_data.parameter[i].args[8]
cs2 = final_data.parameter[i].args[9]
density_trans = eos.eosDensity(pressure_trans)
baryondensity_trans = eos.eosBaryonDensity(pressure_trans)
chempo = (density_trans + pressure_trans) / baryondensity_trans
if (1 - cs2 - 4. * A0 * ((chempo / m0)**2 - 1)**2.5 /
(45 * chempo *
(density_trans + det_density + pressure_trans) / m0) > 0):
stable_parameter.append(final_data.parameter[i])
return final_data_BPSwithPolyCSS(stable_parameter)
class EOS_SLY4withRMF(object):
def __init__(self,init_args,init_sat,args):
self.baryon_density_sat,self.bd_energy,self.incompressibility,\
self.m_eff,self.J,self.L,self.self_W,self.mass_args=args
self.args=args
self.eos_RMF=EOS_RMF(init_args,init_sat,args)
self.eos_args=self.eos_RMF.eos_args
self.init_sat=self.eos_RMF.init_sat
self.eos_array=self.eos_RMF.eos_array
self.sol_saturation=toMevfm(np.array(self.eos_RMF.sol_saturation),'mev4')
fix_crust_baryon_density=np.linspace(0.6,0.3,4)*self.sol_saturation[0]
self.fix_crust_logic=False
for fix_crust_baryon_density_i in fix_crust_baryon_density:
if(self.sol_saturation[2]>1.1*EOS_BPS.eosPressure_frombaryon(fix_crust_baryon_density_i)):
self.eos_SLY4withPoly=EOS_BPSwithPoly([fix_crust_baryon_density_i,self.sol_saturation[2],self.sol_saturation[0],4*self.sol_saturation[2],2*self.sol_saturation[0],8*self.sol_saturation[2],3*self.sol_saturation[0]])
self.fix_crust_logic=True
break
self.stability=self.eos_RMF.stability
self.positive_pressure=self.eos_RMF.positive_pressure
self.baryon_density_s=self.eos_RMF.baryon_density_s
self.pressure_s=self.eos_RMF.pressure_s
self.density_s=self.eos_RMF.density_s
self.unit_mass=self.eos_RMF.unit_mass
self.unit_radius=self.eos_RMF.unit_radius
self.unit_N=self.eos_RMF.unit_N
def __getstate__(self):
state_RMF=self.eos_RMF.__getstate__()
state = self.__dict__.copy()
return (state,state_RMF)
def __setstate__(self, state_):
state,state_RMF=state_
self.__dict__.update(state)
self.eos_RMF.__setstate__(state_RMF)
def eosDensity(self,pressure):
return np.where(pressure<self.sol_saturation[2],self.eos_SLY4withPoly.eosDensity(pressure),self.eos_RMF.eosDensity(pressure))
def eosBaryonDensity(self,pressure):
return np.where(pressure<self.sol_saturation[2],self.eos_SLY4withPoly.eosBaryonDensity(pressure),self.eos_RMF.eosBaryonDensity(pressure))
def setMaxmass(self,result_maxmaxmass):
self.pc_max,self.mass_max,self.cs2_max=result_maxmaxmass
def eosCs2(self,pressure):
return 1.0/derivative(self.eosDensity,pressure,dx=pressure*dlnx_cs2)
def eosChempo(self,pressure):
return (pressure+self.eosDensity(pressure))/self.eosBaryonDensity(pressure)
def __init__(self, parameter):
self.parameter = parameter
self.N = np.size(parameter)
args_matrix = list()
properity_matrix = list()
stars_type0 = list()
stars_type1 = list()
stars_type2 = list()
stars_type3 = list()
binaries_matrix = list()
tidal_binary_matrix = list()
density_trans = list()
baryondensity_trans = list()
gamma2 = list()
for i in range(self.N):
eos = EOS_BPSwithPoly(parameter[i].args[0:7])
gamma2.append(eos.eosPiecewisePoly.gamma2)
if (len(parameter[0].args) > 7):
density_trans.append(eos.eosDensity(parameter[i].args[7]))
baryondensity_trans.append(
eos.eosBaryonDensity(parameter[i].args[7]))
else:
density_trans = []
baryondensity_trans = []
tidal_binary_matrix.append([
parameter[i].stars[0][-1], parameter[i].stars[1][-1],
parameter[i].stars[2][-1], parameter[i].stars[3][-1],
parameter[i].stars[4][-1]
])
args_matrix.append(parameter[i].args)
properity_matrix.append(parameter[i].properity)
for j in range(np.size(parameter[i].stars) / 9 - 5):
if (parameter[i].stars[j + 5][0] == 0):
stars_type0.append(parameter[i].stars[j + 5])
if (parameter[i].stars[j + 5][0] == 1):
stars_type1.append(parameter[i].stars[j + 5])
if (parameter[i].stars[j + 5][0] == 2):
stars_type2.append(parameter[i].stars[j + 5])
if (parameter[i].stars[j + 5][0] == 3):
stars_type3.append(parameter[i].stars[j + 5])
binaries_matrix += parameter[i].binaries
args_matrix = np.array(args_matrix)
self.args_matrix = args_matrix.transpose()
properity_matrix = np.array(properity_matrix)
self.properity_matrix = properity_matrix.transpose()
binaries_matrix = np.array(binaries_matrix)
self.binaries_matrix = binaries_matrix.transpose()
stars_type0 = np.array(stars_type0)
self.stars_type0 = stars_type0.transpose()
stars_type1 = np.array(stars_type1)
self.stars_type1 = stars_type1.transpose()
stars_type2 = np.array(stars_type2)
self.stars_type2 = stars_type2.transpose()
stars_type3 = np.array(stars_type3)
self.stars_type3 = stars_type3.transpose()
tidal_binary_matrix = np.array(tidal_binary_matrix)
tidal_binary_matrix = tidal_binary_matrix.transpose()
self.density_trans = np.array(density_trans)
self.baryondensity_trans = np.array(baryondensity_trans)
self.gamma2 = np.array(gamma2)
if (self.N > 0):
self.tidal_binary1 = tidal_binary(1.364653646, 1.364653646,
tidal_binary_matrix[2],
tidal_binary_matrix[2])
self.tidal_binary2 = tidal_binary(1.243697915, 1.5,
tidal_binary_matrix[1],
tidal_binary_matrix[3])
self.tidal_binary3 = tidal_binary(1.049578992, 1.8,
tidal_binary_matrix[0],
tidal_binary_matrix[4])
tidal_binay123 = np.array(
[self.tidal_binary1, self.tidal_binary2, self.tidal_binary3])
self.tidal_binary_max = tidal_binay123.max(0)
self.tidal_binary_min = tidal_binay123.min(0)
self.pressure2 = self.args_matrix[3]
self.Maximum_mass = self.properity_matrix[2]
if (len(parameter[0].args) > 7):
self.pressure_trans = self.args_matrix[7]
self.det_density = self.args_matrix[8]
[
self.R_opf_quark, self.beta_opf_quark,
self.M_binding_opf_quark, self.momentofinertia_opf_quark,
self.yR_opf_quark, self.tidal_opf_quark
] = self.properity_matrix[13:19]
else:
self.pressure_trans = []
self.det_density = []
[
self.R_opf_quark, self.beta_opf_quark,
self.M_binding_opf_quark, self.momentofinertia_opf_quark,
self.yR_opf_quark, self.tidal_opf_quark
] = [[], [], [], [], [], []]
[
self.R_opf_quark, self.beta_opf_quark,
self.M_binding_opf_quark, self.momentofinertia_opf_quark,
self.yR_opf_quark, self.tidal_opf_quark
] = [[], [], [], [], [], []]
else:
self.tidal_binary1 = []
self.tidal_binary2 = []
self.tidal_binary3 = []
self.tidal_binary_max = []
self.tidal_binary_min = []
self.pressure2 = []
self.pressure_trans = []
self.det_density = []
self.Maximum_mass = []
[
self.R_opf, self.beta_opf, self.M_binding_opf,
self.momentofinertia_opf, self.yR_opf, self.tidal_opf
] = [[], [], [], [], [], []]
[
self.R_opf_quark, self.beta_opf_quark,
self.M_binding_opf_quark, self.momentofinertia_opf_quark,
self.yR_opf_quark, self.tidal_opf_quark
] = [[], [], [], [], [], []]
