def test_ballistic_propagation(self):
cl,args = init.setup_opencl(['rays.py','run'])
divAngle = 0.5
sq = np.sin(divAngle)
cq = np.cos(divAngle)
ds = np.array([[6.0,6.0,6.0,6.0,6.0,6.0,6.0]]).astype(np.double)
xp = np.array([[
[0,0,0,0,1,0,0,1],
[0,-self.bdx,0,0,1,-sq,0,cq],
[0,+self.bdx,0,0,1,+sq,0,cq],
[0,0,-self.bdx,0,1,0,-sq,cq],
[0,0,+self.bdx,0,1,0,+sq,cq],
[0,0,0,-self.bdx,1,0,0,1],
[0,0,0,+self.bdx,1,0,0,1],
]]).astype(np.double)
vg = np.array([[
[1,0,0,1],
[1,-sq,0,cq],
[1,+sq,0,cq],
[1,0,-sq,cq],
[1,0,+sq,cq],
[1,0,0,1],
[1,0,0,1],
]]).astype(np.double)
eikonal = np.array([[0,1,0,0]]).astype(np.double)
assert ray_kernel.GetMicroAction(xp,eikonal,vg) == pytest.approx(8*self.bdx**3,1e-4)
ray_kernel.FullStep(ds,xp,eikonal,vg)
for i in range(1,4):
assert xp[0,:,i] == pytest.approx(vg[0,:,i]*ds[0,:],1e-4)
assert ray_kernel.GetMicroAction(xp,eikonal,vg) == pytest.approx(8*self.bdx**3,1e-4)
def Propagate(self, xp, eikonal, vg, orb={'idx': 0}, vol_obj=0):
'''The main function to propagate ray bundles through the surface.
Rays are left slightly downstream of the surface.'''
self.RaysGlobalToLocal(xp, eikonal, vg)
dt, impact = self.Detect(xp, vg)
if impact.shape[0] > 0:
dts = dt[impact, ...]
xps, eiks, vgs = ray_kernel.ExtractRays(impact, xp, eikonal, vg)
ray_kernel.FullStep(dts, xps, eiks, vgs)
self.Deflect(xps, eiks, vgs, vol_obj)
self.SafetyNudge(xps, vgs)
ray_kernel.UpdateRays(impact, xp, eikonal, vg, xps, eiks, vgs)
self.RaysLocalToGlobal(xp, eikonal, vg)
self.UpdateOrbits(xp, eikonal, orb)
return impact.shape[0]
def Propagate(self, xp, eikonal, vg, orb={'idx': 0}):
self.RaysGlobalToLocal(xp, eikonal, vg)
dt, impact = self.Detect(xp, vg)
xps, eiks, vgs = ray_kernel.ExtractRays(impact, xp, eikonal, vg)
ray_kernel.FullStep(dt[impact, ...], xps, eiks, vgs)
ray_kernel.UpdateRays(impact, xp, eikonal, vg, xps, eiks, vgs)
# Frequency filtering
sel = np.intersect1d(self.SelectBand(xp), impact)
self.xps = np.copy(xp[sel, 0, :])
self.eiks = np.copy(eikonal[sel, ...])
self.micro_action = ray_kernel.GetMicroAction(xp, eikonal, vg)
self.transversality = ray_kernel.GetTransversality(xp, eikonal)
self.hits = impact.shape[0]
self.filtered_hits = sel.shape[0]
self.RaysLocalToGlobal(xp, eikonal, vg)
self.UpdateOrbits(xp, eikonal, orb)
return impact.shape[0]
def Propagate(self, xp, eikonal, vg, orb={'idx': 0}, vol_obj=0):
'''Propagate rays through a surface mesh. The medium on either side must be uniform.'''
self.RaysGlobalToLocal(xp, eikonal, vg)
dt, impact = self.Detect(xp, vg)
dts = dt[impact, ...]
simps = self.simplices[impact]
xps, eiks, vgs = ray_kernel.ExtractRays(impact, xp, eikonal, vg)
# propagate bundles one at a time
for bundle in range(xps.shape[0]):
dt1 = dts[[bundle], ...]
xp1, eik1, vg1 = ray_kernel.ExtractRays([bundle], xps, eiks, vgs)
ray_kernel.FullStep(dt1, xp1, eik1, vg1)
simplex = self.GetTriangle(simps[bundle])
simplex.RaysGlobalToLocal(xp1, eik1, vg1)
simplex.Deflect(xp1, eik1, vg1, vol_obj)
simplex.SafetyNudge(xp1, vg1)
simplex.RaysLocalToGlobal(xp1, eik1, vg1)
ray_kernel.UpdateRays([bundle], xps, eiks, vgs, xp1, eik1, vg1)
ray_kernel.UpdateRays(impact, xp, eikonal, vg, xps, eiks, vgs)
self.RaysLocalToGlobal(xp, eikonal, vg)
self.UpdateOrbits(xp, eikonal, orb)
