Fix bug in ReactionDialog where reaction angle was displayed in radians not degrees

Fixed two bugs related to energy loss units in SPSTarget. Result is change in final energies by around 20 keV>
2024-11-22 18:18:52 -05:00 · 2023-03-31 16:44:54 -04:00 · 2023-03-31 16:26:43 -04:00
3 changed files with 23 additions and 19 deletions
--- a/spspy/SPSReaction.py
+++ b/spspy/SPSReaction.py
@ -89,7 +89,6 @@ class Reaction:
        beamRxnEnergy = self.params.beamEnergy - self.targetMaterial.get_incoming_energyloss(self.params.projectile.Z, self.params.projectile.mass, self.params.beamEnergy, self.rxnLayer, 0.0)
        beamRxnP = sqrt(beamRxnEnergy * (beamRxnEnergy + 2.0 * self.params.projectile.mass))
        residRxnEnergy = beamRxnEnergy + self.params.projectile.mass + self.params.target.mass - ejectileRxnEnergy - self.params.ejectile.mass
        residRxnP2 = beamRxnP**2.0 + ejectileRxnP**2.0 - 2.0 * ejectileRxnP * beamRxnP * cos(self.params.spsAngle)
        return sqrt(residRxnEnergy**2.0 - residRxnP2) - self.residual.mass
--- a/spspy/SPSTarget.py
+++ b/spspy/SPSTarget.py
@ -43,10 +43,10 @@ def get_reverse_energyloss(projectile: catima.Projectile, material: catima.Mater
            e_step = catima.dedx(projectile, material)*x_step
            e_initial += e_step*A_recip
            projectile.T(e_initial)
-            return (e_initial - e_out)*projectile.A()
+            return (e_initial - e_out)
        elif depth == ADAPTIVE_DEPTH_MAX:
-            return e_out*projectile.A()
+            return e_out
        else:
            e_step = catima.dedx(projectile, material)*x_step
            e_initial += e_step*A_recip
@ -80,10 +80,10 @@ def get_energyloss(projectile: catima.Projectile, material: catima.Material) ->
            e_step = catima.dedx(projectile, material)*x_step*A_recip
            e_final -= e_step
            projectile.T(e_final)
-            return (e_in - e_final)*projectile.A()
+            return (e_in - e_final)
        elif depth == ADAPTIVE_DEPTH_MAX:
-            return e_in*projectile.A()
+            return e_in
        else:
            e_step = catima.dedx(projectile, material)*x_step*A_recip
@ -94,6 +94,7 @@ def get_energyloss(projectile: catima.Projectile, material: catima.Material) ->
 class SPSTarget:
    MEV2U: float = 1.0/931.493614838475
    UG2G: float = 1.0e-6 #convert ug to g
    def __init__(self, layers: list[TargetLayer], name: str = "default"):
        self.layer_details = layers
@ -114,31 +115,33 @@ class SPSTarget:
        if angle == pi*0.5:
            return e_initial
-        projectile = catima.Projectile(ap, zp)
+        ap_u = ap * self.MEV2U
-        e_current = e_initial/ap
+        projectile = catima.Projectile(ap_u, zp)
        e_current = e_initial/ap_u
        for (idx, layer) in enumerate(self.layer_details):
-            material = catima.Material([(global_nuclear_data.get_data(z, a).mass, z, float(s)) for (z, a, s) in layer.compound_list])
+            material = catima.Material([(global_nuclear_data.get_data(z, a).mass * self.MEV2U, z, float(s)) for (z, a, s) in layer.compound_list])
            projectile.T(e_current) #catima wants MeV/u
            if idx == rxn_layer:
                material.thickness(self.layer_details[idx].thickness * self.UG2G / (2.0 * abs(cos(angle))))
                e_current -= get_energyloss(projectile, material)
-                return e_initial - e_current*ap
+                return e_initial - e_current*ap_u
            else:
                material.thickness(self.layer_details[idx].thickness * self.UG2G / abs(cos(angle)))
                e_current -= get_energyloss(projectile, material)
-        return e_initial - e_current*ap
+        return e_initial - e_current*ap_u
    #Calculate energy loss for a particle leaving the target, from rxn layer (halfway through rxn layer) to end
    def get_outgoing_energyloss(self, zp: int, ap: float, e_initial: float, rxn_layer: int, angle: float) -> float:
        if angle == pi*0.5:
            return e_initial
-        projectile = catima.Projectile(ap, zp)
+        ap_u = ap * self.MEV2U
-        e_current = e_initial/ap
+        projectile = catima.Projectile(ap_u, zp)
        e_current = e_initial/ap_u
        for (idx, layer) in enumerate(self.layer_details[rxn_layer:], start=rxn_layer):
-            material = catima.Material([(global_nuclear_data.get_data(z, a).mass, z, float(s)) for (z, a, s) in layer.compound_list])
+            material = catima.Material([(global_nuclear_data.get_data(z, a).mass * self.MEV2U, z, float(s)) for (z, a, s) in layer.compound_list])
            projectile.T(e_current) #catima wants MeV/u
            if idx == rxn_layer:
                material.thickness(self.layer_details[idx].thickness * self.UG2G / (2.0 * abs(cos(angle))))
@ -146,19 +149,20 @@ class SPSTarget:
                material.thickness(self.layer_details[idx].thickness * self.UG2G / abs(cos(angle)))
            e_current -= get_energyloss(projectile, material)
-        return e_initial - e_current*ap
+        return e_initial - e_current*ap_u
    #Calculate reverse energy loss (energy gain) for a particle that left the target after a reaction (end -> rxn_layer)
    def get_outgoing_reverse_energyloss(self, zp: int, ap: float, e_final: float, rxn_layer: int, angle: float) -> float:
        if angle == pi*0.5:
            return 0.0
-        projectile = catima.Projectile(ap, zp)
+        ap_u = ap * self.MEV2U
-        e_current = e_final/ap
+        projectile = catima.Projectile(ap_u, zp)
        e_current = e_final/ap_u
        sublist = self.layer_details[rxn_layer:] #only care about rxn_layer -> exit
        reveresedRxnLayer = len(sublist) -1 #when reversed rxn_layer is the last layer
        for (idx, layer) in reversed(list(enumerate(sublist))):
-            material = catima.Material([(global_nuclear_data.get_data(z, a).mass, z, float(s)) for (z, a, s) in layer.compound_list])
+            material = catima.Material([(global_nuclear_data.get_data(z, a).mass * self.MEV2U, z, float(s)) for (z, a, s) in layer.compound_list])
            projectile.T(e_current) #catima wants MeV/u
            if idx == reveresedRxnLayer:
                material.thickness(self.layer_details[idx].thickness * self.UG2G / (2.0 * abs(cos(angle))))
@ -166,5 +170,5 @@ class SPSTarget:
                material.thickness(self.layer_details[idx].thickness * self.UG2G / abs(cos(angle)))
            e_current += get_reverse_energyloss(projectile, material)
-        return e_current*ap - e_final
+        return e_current*ap_u - e_final
--- a/spspy/ui/ReactionDialog.py
+++ b/spspy/ui/ReactionDialog.py
@ -5,6 +5,7 @@ from PySide6.QtWidgets import QVBoxLayout, QFormLayout, QGroupBox
 from PySide6.QtWidgets import QSpinBox, QDoubleSpinBox, QComboBox
 from PySide6.QtWidgets import QDialog, QDialogButtonBox
 from PySide6.QtCore import Signal
 from numpy import rad2deg
 MAXIMUM_NUCLEAR_Z: int = 110
 MAXIMUM_NUCLEAR_A: int = 270
@ -116,6 +117,6 @@ class ReactionDialog(QDialog):
        self.aeInput.setValue(rxn.params.ejectile.A)
        self.aeInput.setEnabled(False)
        self.bkeInput.setValue(rxn.params.beamEnergy)
-        self.thetaInput.setValue(rxn.params.spsAngle)
+        self.thetaInput.setValue(rad2deg(rxn.params.spsAngle))
        self.bfieldInput.setValue(rxn.params.magneticField)
Author	SHA1	Message	Date
Gordon McCann	106e8ea70c	Fix bug in ReactionDialog where reaction angle was displayed in radians not degrees	2023-03-31 16:44:54 -04:00
Gordon McCann	b0a4cc3609	Fixed two bugs related to energy loss units in SPSTarget. Result is change in final energies by around 20 keV>	2023-03-31 16:26:43 -04:00