def project(vx, vy, occlusion):
"""Project the velocity field to be approximately mass-conserving,
using a few iterations of Gauss-Seidel."""
p = np.zeros(vx.shape)
div = -0.5 * (np.roll(vx, -1, axis=1) - np.roll(vx, 1, axis=1)
+ np.roll(vy, -1, axis=0) - np.roll(vy, 1, axis=0))
div = make_continuous(div, occlusion)
for k in range(50):
p = (div + np.roll(p, 1, axis=1) + np.roll(p, -1, axis=1)
+ np.roll(p, 1, axis=0) + np.roll(p, -1, axis=0))/4.0
p = make_continuous(p, occlusion)
vx = vx - 0.5*(np.roll(p, -1, axis=1) - np.roll(p, 1, axis=1))
vy = vy - 0.5*(np.roll(p, -1, axis=0) - np.roll(p, 1, axis=0))
vx = occlude(vx, occlusion)
vy = occlude(vy, occlusion)
return vx, vy
def make_continuous(f, occlusion):
non_occluded = 1 - occlusion
num = np.roll(f, 1, axis=0) * np.roll(non_occluded, 1, axis=0)\
+ np.roll(f, -1, axis=0) * np.roll(non_occluded, -1, axis=0)\
+ np.roll(f, 1, axis=1) * np.roll(non_occluded, 1, axis=1)\
+ np.roll(f, -1, axis=1) * np.roll(non_occluded, -1, axis=1)
den = np.roll(non_occluded, 1, axis=0)\
+ np.roll(non_occluded, -1, axis=0)\
+ np.roll(non_occluded, 1, axis=1)\
+ np.roll(non_occluded, -1, axis=1)
return f * non_occluded + (1 - non_occluded) * num / ( den + 0.001)
def project(vx, vy):
"""Project the velocity field to be approximately mass-conserving,
using a few iterations of Gauss-Seidel."""
p = np.zeros(vx.shape)
h = 1.0/vx.shape[0]
div = -0.5 * h * (np.roll(vx, -1, axis=0) - np.roll(vx, 1, axis=0)
+ np.roll(vy, -1, axis=1) - np.roll(vy, 1, axis=1))
for k in range(10):
p = (div + np.roll(p, 1, axis=0) + np.roll(p, -1, axis=0)
+ np.roll(p, 1, axis=1) + np.roll(p, -1, axis=1))/4.0
vx -= 0.5*(np.roll(p, -1, axis=0) - np.roll(p, 1, axis=0))/h
vy -= 0.5*(np.roll(p, -1, axis=1) - np.roll(p, 1, axis=1))/h
return vx, vy
