def test13(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.particles.add_particles(solsys)
idpos1 = [ (p.position - q.position) for p in mercury.particles[1:10] for q in mercury.particles[1:10] ]
mercury.evolve_model(11.8618|units.yr)
edpos1 = [ (p.position - q.position) for p in mercury.particles[1:10] for q in mercury.particles[1:10] ]
mercury.stop()
centre, orbiters = new_solar_system_for_mercury()
mercury = MercuryWayWard()
mercury.central_particle.add_particles(centre)
mercury.orbiters.add_particles(orbiters)
idpos2 = [ (p.position - q.position) for p in mercury.orbiters[0:9] for q in mercury.orbiters[0:9] ]
mercury.evolve_model(11.8618|units.yr)
edpos2 = [ (p.position - q.position) for p in mercury.orbiters[0:9] for q in mercury.orbiters[0:9] ]
mercury.stop()
for d1,d2 in zip(idpos1,idpos2):
self.assertAlmostEqual(d1,d2, 7)
for d1,d2 in zip(edpos1,edpos2):
self.assertAlmostEqual(d1,d2, 7)
def test13(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.particles.add_particles(solsys)
idpos1 = [ (p.position - q.position) for p in mercury.particles[1:10] for q in mercury.particles[1:10] ]
mercury.evolve_model(11.8618|units.yr)
edpos1 = [ (p.position - q.position) for p in mercury.particles[1:10] for q in mercury.particles[1:10] ]
mercury.stop()
centre, orbiters = new_solar_system_for_mercury()
mercury = MercuryWayWard()
mercury.central_particle.add_particles(centre)
mercury.orbiters.add_particles(orbiters)
idpos2 = [ (p.position - q.position) for p in mercury.orbiters[0:9] for q in mercury.orbiters[0:9] ]
mercury.evolve_model(11.8618|units.yr)
edpos2 = [ (p.position - q.position) for p in mercury.orbiters[0:9] for q in mercury.orbiters[0:9] ]
mercury.stop()
for d1,d2 in zip(idpos1,idpos2):
self.assertAlmostEqual(d1,d2, 7)
for d1,d2 in zip(edpos1,edpos2):
self.assertAlmostEqual(d1,d2, 7)
def test11(self):
solsys = new_solar_system()
mercury = Mercury()
self.assertEqual(mercury.parameters.timestep, 8 | units.day)
mercury.parameters.timestep = 1 | units.day
self.assertEqual(mercury.parameters.timestep, 1 | units.day)
mercury.particles.add_particles(solsys)
start_pos = mercury.particles[5].position
mercury.evolve_model(11.8618|units.yr)
self.assertAlmostEqual(mercury.particles[5].position, start_pos, 1)
mercury.stop()
def test3(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.initialize_code()
mercury.particles.add_particles(solsys)
mercury.commit_particles()
start_pos = mercury.orbiters[2].position
mercury.evolve_model(365.14|units.day)
self.assertAlmostEqual(mercury.orbiters[2].position, start_pos, 1)
mercury.stop()
def test11(self):
solsys = new_solar_system()
mercury = Mercury()
self.assertEquals(mercury.parameters.timestep, 8 | units.day)
mercury.parameters.timestep = 1 | units.day
self.assertEquals(mercury.parameters.timestep, 1 | units.day)
mercury.particles.add_particles(solsys)
start_pos = mercury.particles[5].position
mercury.evolve_model(11.8618|units.yr)
self.assertAlmostEqual(mercury.particles[5].position, start_pos, 1)
mercury.stop()
def test3(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.initialize_code()
mercury.particles.add_particles(solsys)
mercury.commit_particles()
start_pos = mercury.orbiters[2].position
mercury.evolve_model(365.14|units.day)
self.assertAlmostEqual(mercury.orbiters[2].position, start_pos, 1)
mercury.stop()
def test17(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.particles.add_particles(solsys)
mercury.evolve_model(5.|units.yr)
mercury.evolve_model(10.|units.yr)
dpos1=mercury.particles[0].position-mercury.particles[5].position
mercury.stop()
mercury = Mercury()
mercury.particles.add_particles(solsys)
mercury.evolve_model(5.|units.yr)
mercury.particles.x+=1 | units.AU
mercury.particles.y+=2 | units.AU
mercury.particles.z+=3 | units.AU
mercury.particles.vx+=10. | units.kms
mercury.particles.vy+=20. | units.kms
mercury.particles.vz+=30. | units.kms
mercury.evolve_model(10.|units.yr)
dpos2=mercury.particles[0].position-mercury.particles[5].position
mercury.stop()
self.assertAlmostEqual(dpos1, dpos2, 12)
def test17(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.particles.add_particles(solsys)
mercury.evolve_model(5.|units.yr)
mercury.evolve_model(10.|units.yr)
dpos1=mercury.particles[0].position-mercury.particles[5].position
mercury.stop()
mercury = Mercury()
mercury.particles.add_particles(solsys)
mercury.evolve_model(5.|units.yr)
mercury.particles.x+=1 | units.AU
mercury.particles.y+=2 | units.AU
mercury.particles.z+=3 | units.AU
mercury.particles.vx+=10. | units.kms
mercury.particles.vy+=20. | units.kms
mercury.particles.vz+=30. | units.kms
mercury.evolve_model(10.|units.yr)
dpos2=mercury.particles[0].position-mercury.particles[5].position
mercury.stop()
self.assertAlmostEqual(dpos1, dpos2, 12)
def test12(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.parameters.timestep = 1. | units.day
mercury.particles.add_particles(solsys)
start_pos = mercury.particles[5].position
mercury.evolve_model(11.8618|units.yr)
self.assertAlmostEqual(mercury.particles[5].position, start_pos, 1)
mercury.particles.remove_particles(mercury.particles[1:5])
self.assertAlmostEqual(mercury.particles[1].position, start_pos, 1)
start_pos = mercury.particles[1].position
mercury.evolve_model(2*11.8618|units.yr)
self.assertAlmostEqual(mercury.particles[1].position, start_pos, 1)
mercury.stop()
def test12(self):
solsys = new_solar_system()
mercury = Mercury()
mercury.parameters.timestep = 1. | units.day
mercury.particles.add_particles(solsys)
start_pos = mercury.particles[5].position
mercury.evolve_model(11.8618|units.yr)
self.assertAlmostEqual(mercury.particles[5].position, start_pos, 1)
mercury.particles.remove_particles(mercury.particles[1:5])
self.assertAlmostEqual(mercury.particles[1].position, start_pos, 1)
start_pos = mercury.particles[1].position
mercury.evolve_model(2*11.8618|units.yr)
self.assertAlmostEqual(mercury.particles[1].position, start_pos, 1)
mercury.stop()
def xtest22(self):
""" collision test hangs or fails if internal collision detection is enabled """
def collision():
M=1.| units.MSun
m=1.| units.MJupiter
r=5. | units.AU
vcirc=(constants.G*(M+m)/r)**0.5
sys=datamodel.Particles(4)
sys[0].mass=M
sys[0].radius=1. | units.RSun
sys[0].x=0 | units.AU
sys[0].y=0 | units.AU
sys[0].z=0 | units.AU
sys[0].vx=0 | units.kms
sys[0].vy=0 | units.kms
sys[0].vz=0 | units.kms
sys[1].mass=m
sys[1].radius=0.01 | units.RSun
sys[1].x=r
sys[1].y=0 | units.AU
sys[1].z=0 | units.AU
sys[1].vx=0 | units.kms
sys[1].vy=vcirc
sys[1].vz=0 | units.kms
sys[2].mass=m
sys[2].radius=0.01 | units.RSun
sys[2].x=-r
sys[2].y=0 | units.AU
sys[2].z=0 | units.AU
sys[2].vx=0 | units.kms
sys[2].vy=vcirc
sys[2].vz=0 | units.kms
sys[3].mass=m
sys[3].radius=0.01 | units.RSun
sys[3].x=0 | units.AU
sys[3].y=r
sys[3].z=0 | units.AU
sys[3].vx=0 | units.kms
sys[3].vy=0 | units.kms
sys[3].vz=0 | units.kms
return sys
code=Mercury()
sys=collision()
code.particles.add_particles(sys)
tend=3.5| units.yr
dt=100. | units.day
tnow=code.model_time
while tnow<tend:
code.evolve_model(tnow+dt)
tnow=code.model_time
print(tnow.in_(units.yr))
code.stop()
