def testRaytraceMesh(self):
c = 0.5
for (Nmesh, Nrt) in [(10,10), (20,4), (4, 20)]:
mesh = ptum.regularsquaremesh(Nmesh, "BDY")
x0 = np.vstack((np.linspace(-0.2,1.2,Nrt), np.ones(Nrt)*(-0.2))).transpose()
p0 = np.vstack((np.zeros(Nrt), np.ones(Nrt))).transpose()
slowness = lambda x: np.ones(len(x))/c
gradslowness = lambda x: np.zeros_like(x)
wfs, fidxs = prw.wavefront(x0, p0, slowness, gradslowness, 1/(c * Nrt), 1.4 / c, 1/(c * Nrt))
phases = prw.nodesToPhases(wfs, fidxs, mesh, ["BDY"])
self.assertEqual(len(phases), (Nmesh+1)**2)
for vp in phases:
self.assertGreaterEqual(len(vp), 1)
for p in vp:
np.testing.assert_array_almost_equal(p, [0,1/c])
prodpw = pcb.ProductBasisRule(pw, poly)
# Product basis:
#basisrule = pcb.ProductBasisRule(pcb.planeWaveBases(2,k,npw), pcbr.ReferenceBasisRule(pcbr.Dubiner(1)))
#basisrule=pcb.ProductBasisRule(pw,pcbr.ReferenceBasisRule(pcbr.Dubiner(0)))
#basisrule = pcbred.SVDBasisReduceRule(puq.trianglequadrature(quadpoints), basisrule)
#mesh = pmm.gmshMesh('../../examples/2D/square.msh',dim=2)
for n in [16]:
bdytag = "BDY"
volentity = 5 # 6
mesh = ptum.regularrectmesh(bounds[0], bounds[1], n, n)
print mesh.nelements
vtods = prw.nodesToPhases(wavefronts, forwardidxs, mesh, [2])
rt = prb.RaytracedBasisRule(vtods)
prodrt = pcb.ProductBasisRule(rt, poly)
basisrule = prodrt
# basisrule = pcbred.SVDBasisReduceRule(puq.trianglequadrature(quadpoints), basisrule)
entityton = {volentity:slow}
bnddata = {1:zerobd,2:impbd,3:zerobd,4:zerobd}
problem = psp.VariableNProblem(entityton, mesh, k, bnddata)
# problem = psp.Problem(mesh, k, bnddata)
alpha = pdeg ^2 * n / k
beta = k / (pdeg * n)
computation = psc.Computation(problem, basisrule, pcp.HelmholtzSystem, quadpoints, alpha = alpha, beta = beta)
solution = computation.solution(psc.DirectSolver().solve, dovolumes=True)
