PtolemyGUI/Raphael/reactionData.py

#!/usr/bin/env python3
import re
# sys.path.append(os.path.join(os.path.dirname(__file__), '../Cleopatra'))
from IAEANuclearData import IsotopeClass

from clebschGordan import  obeys_triangle_rule
from distortedWave import DistortedWave
import opticalPotentials as op

  
def approximate_to_half_integer(value):
  return round(value * 2) / 2

class ReactionData:
  def __init__(self, nu_A:str, nu_a:str, nu_b:str, nu_B:str, JB:str, orbital:str, ExB:float, ELabPerU:float):
    self.SpinBalanced = self.ReactionDigestion(nu_A, nu_a, nu_b, nu_B, JB, orbital, ExB, ELabPerU)
    

  def ReactionDigestion(self, nu_A:str, nu_a:str, nu_b:str, nu_B:str, JB:str, orbital:str, ExB:float, ELabPerU:float):
    iso = IsotopeClass()
      
    self.A_A, self.Z_A = iso.GetAZ(nu_A)
    self.A_a, self.Z_a = iso.GetAZ(nu_a)
    self.A_b, self.Z_b = iso.GetAZ(nu_b)
    self.A_B, self.Z_B = iso.GetAZ(nu_B)

    self.ELab = self.A_a * ELabPerU

    mass_A = iso.GetMassFromSym(nu_A)
    mass_a = iso.GetMassFromSym(nu_a)
    mass_b = iso.GetMassFromSym(nu_b)
    mass_B = iso.GetMassFromSym(nu_B)
    ExB = ExB

    # sym_A = iso.GetSymbol(A_A, Z_A)
    # sym_B = iso.GetSymbol(A_B, Z_B)

    spin_A_str = iso.GetJpi(self.A_A, self.Z_A)
    self.spin_A = float(eval(re.sub(r'[+-]', '', spin_A_str)))
    self.spin_B = float(eval(re.sub(r'[+-]', '', JB)))

    if self.A_a == 2 and self.Z_a == 1:
        self.spin_a = 1.0
        self.spin_b = 0.5
    else:
        self.spin_a = 0.5
        self.spin_b = 1.0

    #====== transfering nucleon
    self.s = 1/2 # spin of x, neutron or proton
    self.A_x = abs(self.A_a - self.A_b)
    self.Z_x = abs(self.Z_a - self.Z_b)

    mass_x = iso.GetMassFromAZ(self.A_x, self.Z_x)

    #======== core
    if self.A_A < self.A_B : # (d,p)
        self.A_c = self.A_A
        self.Z_c = self.Z_A
        self.BindingEnergy = mass_B - mass_A - mass_x + ExB
    else:  #(p,d)
        self.A_c = self.A_B
        self.Z_c = self.Z_B
        self.BindingEnergy = mass_A - mass_B - ExB - mass_x

    #=================== digest orbital
    match = re.search(r'[a-zA-Z]', orbital)  # Find first letter
    if match:
        index = match.start()  # Get position of the first letter
        
    self.node = int(orbital[:index])
    l_sym = orbital[index:index+1]
    j_sym = orbital[index+1:]
    self.j = eval(j_sym)
    self.l = op.ConvertLSym(l_sym)

    self.j = approximate_to_half_integer(self.j)
    self.s = approximate_to_half_integer(self.s)
    self.spin_a = approximate_to_half_integer(self.spin_a)
    self.spin_b = approximate_to_half_integer(self.spin_b)

    passJ = False
    if obeys_triangle_rule(self.spin_A, self.spin_B, self.j):
      passJ = True
    else:
      print(f"the orbital spin-J ({self.j}) does not consver J({nu_A}) + J({nu_B}) = {self.spin_A} + {self.spin_B}.")

    passS = False
    if obeys_triangle_rule(self.spin_a, self.spin_b, self.s):
      passS = True
    else:
      print(f"the orbital spin-s ({self.s}) does not consver S({nu_a}) + S({nu_b}) = {self.spin_a} + {self.spin_b}.")

    passL = False
    if obeys_triangle_rule(self.j, self.s, self.l):
      passL = True
    else:
      print(f"the orbital spin-L ({self.l}) does not consver J({self.j}) + S({self.s}).")

    self.isSpinBalanced = passJ * passS * passL
    if self.isSpinBalanced == False :
      print("Fail angular momentum conservation.")
      return False
    else:
      print("All Spin are balance.")

    self.reactionStr = f"{nu_A}({spin_A_str})({nu_a},{nu_b}){nu_B}({ExB:.3f}|{JB}, {orbital}) @ {ELabPerU:.1f} MeV/u"

    self.Q_value = mass_A + mass_a - mass_b - mass_B - ExB
    self.dwI = DistortedWave(nu_A, nu_a, self.ELab)

    Ecm_I = self.dwI.Ecm
    Ecm_O = Ecm_I + self.Q_value 
    self.Eout = ((Ecm_O + mass_b + mass_B + ExB)**2 - (mass_b + mass_B + ExB)**2)/2/(mass_B + ExB)
    self.dwO = DistortedWave(nu_B, nu_b, self.Eout)

    Eout2 = self.ELab + self.Q_value #this is incorrec, but used in ptolmey infileCreator

    print("==================================================")
    print(self.reactionStr)
    print(f"Transfer Orbtial : {orbital}")
    print(f"Q-value : {self.Q_value:10.6f} MeV")
    print(f"Binding : {self.BindingEnergy:10.6f} MeV")
    print(f"   Eout : {self.Eout} MeV | {Eout2}")

    return True
seperate reactionData, add symbolic link of IAEANuclearData 2025-02-25 14:35:38 -05:00			`#!/usr/bin/env python3`
			`import re`
			`# sys.path.append(os.path.join(os.path.dirname(__file__), '../Cleopatra'))`
			`from IAEANuclearData import IsotopeClass`

			`from clebschGordan import obeys_triangle_rule`
			`from distortedWave import DistortedWave`
			`import opticalPotentials as op`


			`def approximate_to_half_integer(value):`
			`return round(value * 2) / 2`

			`class ReactionData:`
			`def __init__(self, nu_A:str, nu_a:str, nu_b:str, nu_B:str, JB:str, orbital:str, ExB:float, ELabPerU:float):`
			`self.SpinBalanced = self.ReactionDigestion(nu_A, nu_a, nu_b, nu_B, JB, orbital, ExB, ELabPerU)`


			`def ReactionDigestion(self, nu_A:str, nu_a:str, nu_b:str, nu_B:str, JB:str, orbital:str, ExB:float, ELabPerU:float):`
			`iso = IsotopeClass()`

			`self.A_A, self.Z_A = iso.GetAZ(nu_A)`
			`self.A_a, self.Z_a = iso.GetAZ(nu_a)`
			`self.A_b, self.Z_b = iso.GetAZ(nu_b)`
			`self.A_B, self.Z_B = iso.GetAZ(nu_B)`

			`self.ELab = self.A_a * ELabPerU`

			`mass_A = iso.GetMassFromSym(nu_A)`
			`mass_a = iso.GetMassFromSym(nu_a)`
			`mass_b = iso.GetMassFromSym(nu_b)`
			`mass_B = iso.GetMassFromSym(nu_B)`
			`ExB = ExB`

			`# sym_A = iso.GetSymbol(A_A, Z_A)`
			`# sym_B = iso.GetSymbol(A_B, Z_B)`

			`spin_A_str = iso.GetJpi(self.A_A, self.Z_A)`
			`self.spin_A = float(eval(re.sub(r'[+-]', '', spin_A_str)))`
			`self.spin_B = float(eval(re.sub(r'[+-]', '', JB)))`

			`if self.A_a == 2 and self.Z_a == 1:`
			`self.spin_a = 1.0`
			`self.spin_b = 0.5`
			`else:`
			`self.spin_a = 0.5`
			`self.spin_b = 1.0`

			`#====== transfering nucleon`
			`self.s = 1/2 # spin of x, neutron or proton`
			`self.A_x = abs(self.A_a - self.A_b)`
			`self.Z_x = abs(self.Z_a - self.Z_b)`

			`mass_x = iso.GetMassFromAZ(self.A_x, self.Z_x)`

			`#======== core`
			`if self.A_A < self.A_B : # (d,p)`
			`self.A_c = self.A_A`
			`self.Z_c = self.Z_A`
			`self.BindingEnergy = mass_B - mass_A - mass_x + ExB`
			`else: #(p,d)`
			`self.A_c = self.A_B`
			`self.Z_c = self.Z_B`
			`self.BindingEnergy = mass_A - mass_B - ExB - mass_x`

			`#=================== digest orbital`
			`match = re.search(r'[a-zA-Z]', orbital) # Find first letter`
			`if match:`
			`index = match.start() # Get position of the first letter`

			`self.node = int(orbital[:index])`
			`l_sym = orbital[index:index+1]`
			`j_sym = orbital[index+1:]`
			`self.j = eval(j_sym)`
			`self.l = op.ConvertLSym(l_sym)`

			`self.j = approximate_to_half_integer(self.j)`
			`self.s = approximate_to_half_integer(self.s)`
			`self.spin_a = approximate_to_half_integer(self.spin_a)`
			`self.spin_b = approximate_to_half_integer(self.spin_b)`

			`passJ = False`
			`if obeys_triangle_rule(self.spin_A, self.spin_B, self.j):`
			`passJ = True`
			`else:`
			`print(f"the orbital spin-J ({self.j}) does not consver J({nu_A}) + J({nu_B}) = {self.spin_A} + {self.spin_B}.")`

			`passS = False`
			`if obeys_triangle_rule(self.spin_a, self.spin_b, self.s):`
			`passS = True`
			`else:`
			`print(f"the orbital spin-s ({self.s}) does not consver S({nu_a}) + S({nu_b}) = {self.spin_a} + {self.spin_b}.")`

			`passL = False`
			`if obeys_triangle_rule(self.j, self.s, self.l):`
			`passL = True`
			`else:`
			`print(f"the orbital spin-L ({self.l}) does not consver J({self.j}) + S({self.s}).")`

			`self.isSpinBalanced = passJ * passS * passL`
			`if self.isSpinBalanced == False :`
			`print("Fail angular momentum conservation.")`
			`return False`
			`else:`
			`print("All Spin are balance.")`

			`self.reactionStr = f"{nu_A}({spin_A_str})({nu_a},{nu_b}){nu_B}({ExB:.3f}\|{JB}, {orbital}) @ {ELabPerU:.1f} MeV/u"`

			`self.Q_value = mass_A + mass_a - mass_b - mass_B - ExB`
			`self.dwI = DistortedWave(nu_A, nu_a, self.ELab)`

			`Ecm_I = self.dwI.Ecm`
			`Ecm_O = Ecm_I + self.Q_value`
			`self.Eout = ((Ecm_O + mass_b + mass_B + ExB)2 - (mass_b + mass_B + ExB)2)/2/(mass_B + ExB)`
			`self.dwO = DistortedWave(nu_B, nu_b, self.Eout)`

			`Eout2 = self.ELab + self.Q_value #this is incorrec, but used in ptolmey infileCreator`

			`print("==================================================")`
			`print(self.reactionStr)`
			`print(f"Transfer Orbtial : {orbital}")`
			`print(f"Q-value : {self.Q_value:10.6f} MeV")`
			`print(f"Binding : {self.BindingEnergy:10.6f} MeV")`
			`print(f" Eout : {self.Eout} MeV \| {Eout2}")`

			`return True`