Finally get correct formula for Energy, Semi Major Axis and Eccentricity

2022-01-14 00:58:56 +01:00
parent e34e23c450
commit 70439889db
15 changed files with 10 additions and 10 deletions
--- a/lib/objects.py
+++ b/lib/objects.py
@@ -24,10 +24,10 @@ class Body:
        self.vp = np.zeros(3,dtype=np.longdouble)
    def __repr__(self): # Called upon "print(body)"
-        return r"Body of mass: {0:.1e} $M_\odot$, position: {1}, velocity: {2}".format(self.m, self.q, self.v)
+        return r"Body of mass: {0:.1e} $M_\odot$, position: {1}, velocity: {2}".format(self.m/Ms, self.q, self.v)
    def __str__(self): # Called upon "str(body)"
-        return r"Body of mass: {0:.1e} $M_\odot$".format(self.m)
+        return r"Body of mass: {0:.1e} $M_\odot$".format(self.m/Ms)
    @property
    def p(self):
@@ -150,7 +150,7 @@ class System(Body):
            for otherbody in self.bodylist:
                if body != otherbody:
                    rij = np.linalg.norm(body.q-otherbody.q)
-                    W = W - Ga*body.m*otherbody.m/rij
+                    W = W - Ga*otherbody.m/(body.m+otherbody.m)*body.m**2/rij
        E = T + W
        return E
@@ -171,7 +171,7 @@ class System(Body):
            for otherbody in self.bodylist:
                if body != otherbody:
                    rij = np.linalg.norm(body.q-otherbody.q)
-                    W = W - Ga*body.m*otherbody.m/rij
+                    W = W - Ga*otherbody.m/(body.m+otherbody.m)*body.m**2/rij
        E = T + W
        return E
@@ -185,7 +185,7 @@ class System(Body):
    @property
    def eccCOM(self): #exentricity of two body sub system
        if len(self.bodylist) == 2 :
-            ecc = (2.*self.ECOM*(np.linalg.norm(self.LCOM)**2))/((Ga**2)*(self.M**2)*(self.mu**3)) + 1.
+            ecc = (2.*self.ECOM*(np.linalg.norm(self.LCOM)**2))/(Ga**2*self.M**2*self.mu**3) + 1.
        else :
            ecc = np.nan
        return ecc
@@ -193,7 +193,7 @@ class System(Body):
    @property
    def smaCOM(self): #semi major axis of two body sub system
        if len(self.bodylist) == 2 :
-            sma = -Ga*self.M*self.mu/(2.*self.ECOM)
+            sma = -Ga*self.mu*self.bodylist[0].m/(2.*self.ECOM)
        else :
            sma = np.nan
        return sma
@@ -201,7 +201,7 @@ class System(Body):
    @property
    def ecc(self): #exentricity of two body sub system
        if len(self.bodylist) == 2 :
-            ecc = (2.*self.EBIN*(np.linalg.norm(self.LBIN)**2))/((Ga**2)*(self.M**2)*(self.mu**3)) + 1.
+            ecc = (2.*self.EBIN*(np.linalg.norm(self.LBIN)**2))/(Ga**2*self.M**2*self.mu**3) + 1.
        else :
            ecc = np.nan
        return ecc
@@ -209,7 +209,7 @@ class System(Body):
    @property
    def sma(self): #semi major axis of two body sub system
        if len(self.bodylist) == 2 :
-            sma = -Ga*self.M*self.mu/(2.*self.EBIN)
+            sma = -Ga*self.mu*self.bodylist[0].m/(2.*self.EBIN)
        else :
            sma = np.nan
        return sma
--- a/main.py
+++ b/main.py
@@ -12,7 +12,7 @@ from lib.units import *
 def main():
    #initialisation
    m = np.array([1., 1., 1e-1],dtype=np.longdouble)*Ms#/Ms  # Masses in Solar mass
-    a = np.array([1., 1., 10.],dtype=np.longdouble)*au#/au   # Semi-major axis in astronomical units
+    a = np.array([0.75, 0.75, 5.],dtype=np.longdouble)*au#/au   # Semi-major axis in astronomical units
    e = np.array([0., 0., 0.25],dtype=np.longdouble)   # Eccentricity
    psi = np.array([0., 0., 80.],dtype=np.longdouble)*np.pi/180.    # Inclination of the orbital plane in degrees
@@ -27,7 +27,7 @@ def main():
    v = np.array([v1, v2, v3],dtype=np.longdouble)
    #integration parameters
-    duration, step = 500*yr, np.array([30./1.*86400.],dtype=np.longdouble) #integration time and step in seconds
+    duration, step = 5000*yr, np.array([30./1.*86400.],dtype=np.longdouble) #integration time and step in seconds
    step = np.sort(step)[::-1]
    integrator = "leapfrog"
    n_bodies = 3
--- a/plots/2bodies_leapfrog_E.png
+++ b/plots/2bodies_leapfrog_E.png
--- a/plots/2bodies_leapfrog_L.png
+++ b/plots/2bodies_leapfrog_L.png
--- a/plots/2bodies_leapfrog_a_e.png
+++ b/plots/2bodies_leapfrog_a_e.png
--- a/plots/2bodies_leapfrog_dEm.png
+++ b/plots/2bodies_leapfrog_dEm.png
--- a/plots/2bodies_leapfrog_dL2.png
+++ b/plots/2bodies_leapfrog_dL2.png
--- a/plots/2bodies_leapfrog_phi.png
+++ b/plots/2bodies_leapfrog_phi.png
--- a/plots/3bodies_leapfrog_E.png
+++ b/plots/3bodies_leapfrog_E.png
--- a/plots/3bodies_leapfrog_L.png
+++ b/plots/3bodies_leapfrog_L.png
--- a/plots/3bodies_leapfrog_a_e.png
+++ b/plots/3bodies_leapfrog_a_e.png
--- a/plots/3bodies_leapfrog_dEm.png
+++ b/plots/3bodies_leapfrog_dEm.png
--- a/plots/3bodies_leapfrog_dL2.png
+++ b/plots/3bodies_leapfrog_dL2.png
--- a/plots/3bodies_leapfrog_dynsyst.gif
+++ b/plots/3bodies_leapfrog_dynsyst.gif
--- a/plots/3bodies_leapfrog_phi.png
+++ b/plots/3bodies_leapfrog_phi.png