예제 #1
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파일: fluid.py 프로젝트: asrvsn/gds
def backward_step():
    ''' Poiseuille flow with a boundary asymmetry '''
    m = 22
    n = 67
    step_height = 12
    step_width = 10
    obstacle = gds.utils.flatten([[(j, i) for i in range(step_height)]
                                  for j in range(step_width)])
    G, (l, r, t, b) = gds.triangular_lattice(m, n, with_boundaries=True)
    for g in [G, l, r, t, b]:
        g.remove_nodes_from(obstacle)
    for i in range(step_width + 1):
        b.add_node((i, step_height))
        if i > 0:
            b.add_edge((i - 1, step_height), (i, step_height))
    for j in range(step_height + 1):
        b.add_node((step_width, j))
        if i > 0:
            b.add_edge((step_width, j - 1), (step_width, j))
    G.remove_edges_from(list(nx.edge_boundary(G, l, l)))
    G.remove_edges_from(
        list(
            nx.edge_boundary(G, [(0, 2 * i + 1) for i in range(m // 2)],
                             [(1, 2 * i) for i in range(m // 2 + 1)])))
    G.remove_edges_from(list(nx.edge_boundary(G, r, r)))
    G.remove_edges_from(
        list(
            nx.edge_boundary(G, [(n // 2, 2 * i + 1) for i in range(m // 2)],
                             [(n // 2, 2 * i) for i in range(m // 2 + 1)])))
    weight = 1.
    nx.set_edge_attributes(G, weight, name='w')

    inlet_v = 1.0
    # outlet_v=2*(m - step_height - 2)*inlet_v / (m - 2)
    outlet_p = 0.0
    # ref_p=0.0
    # grad_p=100.0
    velocity, pressure = navier_stokes(G,
                                       viscosity=100.,
                                       density=1.0,
                                       inlets=l.nodes,
                                       outlets=r.nodes,
                                       w_key='w')
    pressure.set_constraints(dirichlet=gds.combine_bcs(
        # {n: grad_p/2 for n in l.nodes},
        # {n: -grad_p/2 for n in r.nodes if n[1] > step_height//2}
        {(n // 2 + 1, j): outlet_p
         for j in range(n)}
        # {(n//2+1,m): ref_p}
    ))
    velocity.set_constraints(dirichlet=gds.combine_bcs(
        {((0, i), (1, i)): inlet_v
         for i in range(step_height + 1, m)},
        # {((n//2, i), (n//2+1, i)): outlet_v for i in range(1, m)},
        # {((n//2-1, 2*i+1), (n//2, 2*i+1)): outlet_v for i in range(0, m//2)},
        gds.zero_edge_bc(t),
        gds.zero_edge_bc(b),
    ))
    return velocity, pressure
예제 #2
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파일: telegrapher.py 프로젝트: asrvsn/gds
def voronoi_poiseuille():
    np.random.seed(401)
    gradP = 1.0
    n_boundary = 10
    n_interior = 100

    G, (l, r, t, b) = gds.voronoi_lattice(n_boundary,
                                          n_interior,
                                          with_boundaries=True,
                                          eps=0.07)
    # tb = set(t.nodes()) | set(b.nodes())
    v_free_l, v_free_r = set(l.nodes()), set(r.nodes())
    v_free = v_free_l | v_free_r
    v_bd_l = set()
    # for v in v_free_l:
    # 	u = v - 1j
    # 	G.add_node(u)
    # 	G.add_edge(u, v)
    # 	G.nodes[u]['pos'] = (G.nodes[v]['pos'][0] - 0.1, G.nodes[v]['pos'][1])
    # 	v_bd_l.add(u)
    v_bd_r = set()
    # for v in v_free_r:
    # 	u = v - 1j
    # 	G.add_node(u)
    # 	G.add_edge(v, u)
    # 	G.nodes[u]['pos'] = (G.nodes[v]['pos'][0] + 0.1, G.nodes[v]['pos'][1])
    # 	v_bd_r.add(u)
    v_bd = v_bd_l | v_bd_r

    pressure, velocity = navier_stokes(G,
                                       viscosity=1.,
                                       density=1e-2,
                                       v_free=v_bd | v_free)
    pressure.set_constraints(dirichlet=gds.combine_bcs(
        {n: gradP / 2
         for n in v_free_l | v_bd_l},
        {n: -gradP / 2
         for n in v_free_r | v_bd_r},
    ))
    # e_free_mask = np.array([1 if len(set(velocity.iX[i]) - v_bd)==2 else 0 for i in range(velocity.ndim)])
    # local_state = {'t': None, 'div': None}
    # def free_boundaries(t, e):
    # 	if local_state['t'] != t:
    # 		local_state['div'] = velocity.div(velocity.y*e_free_mask)
    # 		local_state['t'] = t
    # 	if e[1] in v_bd_l:
    # 		return -np.clip(local_state['div'][pressure.X[e[0]]], 0, None)
    # 	elif e[1] in v_bd_r:
    # 		return -np.clip(local_state['div'][pressure.X[e[0]]], None, 0)
    velocity.set_constraints(dirichlet=gds.combine_bcs(
        # free_boundaries,
        gds.zero_edge_bc(t),
        gds.zero_edge_bc(b),
    ))
    return pressure, velocity
예제 #3
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def lid_driven_cavity(G, dG, v=10, viscosity=10):
    (l, r, t, b) = dG
    v_free = (set(l.nodes()) & set(t.nodes())) | (set(r.nodes())
                                                  & set(t.nodes()))
    print('v_free:', v_free)
    velocity, pressure = navier_stokes(G, viscosity=viscosity, v_free=v_free)
    velocity.set_constraints(dirichlet=gds.combine_bcs(
        gds.const_edge_bc(t, v),
        gds.zero_edge_bc(b),
        gds.zero_edge_bc(l),
        gds.zero_edge_bc(r),
    ))
    # pressure.set_constraints(dirichlet={(0, 0): 0.}) # Pressure reference
    return velocity, pressure
예제 #4
0
파일: telegrapher.py 프로젝트: asrvsn/gds
def sq_poiseuille():
    m = 14
    n = 28
    gradP = 6.0

    G, (l, r, t, b) = gds.square_lattice(m, n, with_boundaries=True)
    v_free_l = set(l.nodes()) - (set(t.nodes()) | set(b.nodes()))
    v_free_r = set(r.nodes()) - (set(t.nodes()) | set(b.nodes()))
    v_free = v_free_l | v_free_r

    pressure, velocity = navier_stokes(G,
                                       viscosity=1.,
                                       density=1e-2,
                                       v_free=v_free)

    e_free = np.array([velocity.X[(n, (n[0] + 1, n[1]))] for n in v_free_l] +
                      [velocity.X[((n[0] - 1, n[1]), n)] for n in v_free_r],
                      dtype=np.intp)
    e_free_mask = np.ones(velocity.ndim)
    e_free_mask[e_free] = 0

    pressure, velocity = navier_stokes(G,
                                       viscosity=1.,
                                       density=1e-2,
                                       v_free=v_free)
    pressure.set_constraints(dirichlet=gds.combine_bcs(
        {n: gradP / 2
         for n in l.nodes},
        {(n[0] + 1, n[1]): gradP / 2
         for n in l.nodes},
        {n: -gradP / 2
         for n in r.nodes},
        {(n[0] - 1, n[1]): -gradP / 2
         for n in r.nodes},
    ))
    local_state = {'t': None, 'div': None}

    def free_boundaries(t, e):
        if local_state['t'] != t:
            local_state['div'] = velocity.div(velocity.y * e_free_mask)
        if e[0][1] == e[1][1] and e[0][0] + 1 == e[1][0]:
            if e[0] in v_free:
                return local_state['div'][pressure.X[e[1]]]
            elif e[1] in v_free:
                return -local_state['div'][pressure.X[e[0]]]

    velocity.set_constraints(dirichlet=gds.combine_bcs(gds.zero_edge_bc(
        t), gds.zero_edge_bc(b), free_boundaries))
    return pressure, velocity
예제 #5
0
파일: poiseuille.py 프로젝트: asrvsn/gds
def sq_poiseuille_projected(viscosity, density):
	m=14 
	n=28 
	gradP=6.0

	G, (l, r, t, b) = gds.square_lattice(m, n, with_boundaries=True)
	v_free_l = set(l.nodes()) - (set(t.nodes()) | set(b.nodes()))
	v_free_r = set(r.nodes()) - (set(t.nodes()) | set(b.nodes()))
	v_free = v_free_l | v_free_r

	velocity = navier_stokes_projected(G, viscosity=viscosity, density=density, body_force=lambda t, y: gradP*np.ones_like(y), v_free=v_free)
	velocity.set_constraints(dirichlet=gds.combine_bcs(
		gds.zero_edge_bc(t),
		gds.zero_edge_bc(b),
	))
	return velocity
예제 #6
0
파일: telegrapher.py 프로젝트: asrvsn/gds
def tri_poiseuille():
    m = 14
    n = 58
    gradP = 1.0
    G, (l, r, t, b) = gds.triangular_lattice(m, n, with_boundaries=True)
    # G.remove_edges_from(l.edges())
    # G.remove_edges_from(r.edges())
    # G.remove_edges_from(G.subgraph([(0, 2*i+1) for i in range(m//2)] + [(1, 2*i) for i in range(m//2+1)]).edges())
    # G.remove_edges_from(G.subgraph([(n//2-1, 2*i+1) for i in range(m//2)] + [(n//2, 2*i) for i in range(m//2+1)]).edges())
    v_free_l = set(l.nodes()) - (set(t.nodes()) | set(b.nodes()))
    # v_free_l_int = set((n[0]+1, n[1]) for n in v_free_l)
    v_free_r = set(r.nodes()) - (set(t.nodes()) | set(b.nodes()))
    # v_free_r_int = set((n[0]-1, n[1]) for n in v_free_r)
    v_free = v_free_l | v_free_r
    pressure, velocity = navier_stokes(G,
                                       viscosity=1.,
                                       density=1e-2,
                                       v_free=v_free)
    e_free = np.array([velocity.X[(n, (n[0] + 1, n[1]))] for n in v_free_l] +
                      [velocity.X[((n[0] - 1, n[1]), n)] for n in v_free_r],
                      dtype=np.intp)
    e_free_mask = np.ones(velocity.ndim)
    e_free_mask[e_free] = 0
    pressure.set_constraints(dirichlet=gds.combine_bcs(
        {n: gradP / 2
         for n in l.nodes},
        {(n[0] + 1, n[1]): gradP / 2
         for n in l.nodes},
        {n: -gradP / 2
         for n in r.nodes},
        {(n[0] - 1, n[1]): -gradP / 2
         for n in r.nodes},
    ))
    local_state = {'t': None, 'div': None}

    def free_boundaries(t, e):
        if local_state['t'] != t:
            local_state['div'] = velocity.div(velocity.y * e_free_mask)
        if e[0][1] == e[1][1] and e[0][0] + 1 == e[1][0]:
            if e[0] in v_free:
                return local_state['div'][pressure.X[e[1]]]
            elif e[1] in v_free:
                return -local_state['div'][pressure.X[e[0]]]

    velocity.set_constraints(dirichlet=gds.combine_bcs(gds.zero_edge_bc(
        t), gds.zero_edge_bc(b), free_boundaries))
    return pressure, velocity
예제 #7
0
파일: poiseuille.py 프로젝트: asrvsn/gds
def poiseuille(G, dG, viscosity=50, density=1, gradP=10):
	(l, r, t, b) = dG
	tb = set(t.nodes()) | set(b.nodes())
	lr = set(l.nodes()) | set(r.nodes())
	v_free = lr - tb
	e_free = set(gds.edge_domain(G, lr))
	e_normal = set(nx.edge_boundary(G, lr))

	velocity, pressure = navier_stokes(G, viscosity=viscosity, density=density, v_free=v_free, e_free=e_free, e_normal=e_normal)
	pressure.set_constraints(dirichlet=gds.combine_bcs(
		{n: gradP/2 for n in l.nodes},
		{n: -gradP/2 for n in r.nodes},
	))
	velocity.set_constraints(dirichlet=gds.combine_bcs(
		gds.zero_edge_bc(t),
		gds.zero_edge_bc(b),
	))
	return velocity, pressure
예제 #8
0
파일: von_karman.py 프로젝트: asrvsn/gds
def von_karman():
    m = 20
    n = 50
    gradP = 80.0
    inlet_v = 20.0
    outlet_p = 0.0
    G, (l, r, t, b) = gds.triangular_lattice(m, n, with_boundaries=True)

    tb = set(t.nodes()) | set(b.nodes())
    lr = set(l.nodes()) | set(r.nodes())
    v_free = lr - tb
    e_free = set(gds.edge_domain(G, lr))
    e_normal = set(nx.edge_boundary(G, lr))

    j, k = 8, m // 2
    # Introduce occlusion
    obstacle = [
        (j, k),
        (j + 1, k),
        (j + 2, k),
        # (j, k+1),
        # (j, k-1),
        # (j-1, k),
        # (j+1, k+1),
        # (j+1, k-1),
        # (j, k+2),
        # (j, k-2),
    ]
    obstacle_boundary = gds.utils.flatten([G.neighbors(n) for n in obstacle])
    obstacle_boundary = gds.edge_domain(G, obstacle_boundary)
    G.remove_nodes_from(obstacle)
    # G.remove_edges_from(list(nx.edge_boundary(G, l, l)))
    # G.remove_edges_from(list(nx.edge_boundary(G, [(0, 2*i+1) for i in range(m//2)], [(1, 2*i) for i in range(m//2+1)])))
    # G.remove_edges_from(list(nx.edge_boundary(G, r, r)))
    # G.remove_edges_from(list(nx.edge_boundary(G, [(n//2, 2*i+1) for i in range(m//2)], [(n//2, 2*i) for i in range(m//2+1)])))
    velocity, pressure = fluid.navier_stokes(G,
                                             viscosity=10,
                                             v_free=v_free,
                                             e_free=e_free,
                                             e_normal=e_normal)
    pressure.set_constraints(dirichlet=gds.combine_bcs(
        {n: gradP / 2
         for n in l.nodes}, {n: -gradP / 2
                             for n in r.nodes}
        # {n: 0 for n in l.nodes}
        # {(n//2+1, j): outlet_p for j in range(n)}
    ))
    gradation = np.linspace(-0.1, 0.1, m + 1)
    velocity.set_constraints(dirichlet=gds.combine_bcs(
        # {((0, i), (1, i)): inlet_v + gradation[i] for i in range(1, m)},
        # {((n//2, i), (n//2+1, i)): inlet_v - gradation[i] for i in range(1, m)},
        # {((n//2-1, 2*i+1), (n//2, 2*i+1)): inlet_v - gradation[2*i+1] for i in range(0, m//2)},
        {e: 0
         for e in obstacle_boundary},
        gds.zero_edge_bc(t),
        gds.zero_edge_bc(b),
    ))

    sys = gds.couple({
        'velocity': velocity,
        # 'divergence': velocity.project(gds.GraphDomain.nodes, lambda v: v.div()),
        # 'vorticity': velocity.project(gds.GraphDomain.faces, lambda v: v.curl()),
        'pressure': pressure,
    })
    gds.render(sys,
               canvas=gds.grid_canvas(sys.observables.values(), 3),
               edge_max=0.6,
               dynamic_ranges=True,
               edge_palette=cc.bgy)
예제 #9
0
파일: telegrapher.py 프로젝트: asrvsn/gds
def hex_poiseuille():
    m = 14
    n = 29
    gradP = 1.0

    G, (l, r, t, b) = gds.hexagonal_lattice(m, n, with_boundaries=True)
    v_free_l = set(l.nodes()) - (set(t.nodes()) | set(b.nodes()))
    # v_free_l.remove(min(v_free_l, key=lambda x: x[1]))
    # v_free_l.remove(max(v_free_l, key=lambda x: x[1]))
    v_free_r = set(r.nodes()) - (set(t.nodes()) | set(b.nodes()))
    # v_free_r.remove(min(v_free_r, key=lambda x: x[1]))
    # v_free_r.remove(max(v_free_r, key=lambda x: x[1]))
    v_free = v_free_l | v_free_r
    v_bd_l = set()
    for v in v_free_l:
        u = (-1, v[1])
        G.add_node(u)
        G.add_edge(u, v)
        G.nodes[u]['pos'] = (G.nodes[v]['pos'][0] - 1.0, G.nodes[v]['pos'][1])
        v_bd_l.add(u)
    v_bd_r = set()
    for v in v_free_r:
        u = (n + 1, v[1])
        G.add_node(u)
        G.add_edge(v, u)
        G.nodes[u]['pos'] = (G.nodes[v]['pos'][0] + 1.0, G.nodes[v]['pos'][1])
        v_bd_r.add(u)
    v_bd = v_bd_l | v_bd_r

    pressure, velocity = navier_stokes(G,
                                       viscosity=1.,
                                       density=1e-2,
                                       v_free=v_bd | v_free)

    e_free_mask = np.array([
        1 if len(set(velocity.iX[i]) - v_bd) == 2 else 0
        for i in range(velocity.ndim)
    ])

    pressure.set_constraints(dirichlet=gds.combine_bcs(
        {n: gradP / 2
         for n in v_free_l | v_bd_l},
        {n: -gradP / 2
         for n in v_free_r | v_bd_r},
    ))
    local_state = {'t': None, 'div': None}

    def free_boundaries(t, e):
        if local_state['t'] != t:
            local_state['div'] = velocity.div(velocity.y * e_free_mask)
            local_state['t'] = t
        if e[1] in v_bd_l:
            return -local_state['div'][pressure.X[e[0]]]
        elif e[1] in v_bd_r:
            return -local_state['div'][pressure.X[e[0]]]
        # elif (e[0][1] == e[1][1] == 0) and (e[0][0] == e[1][0] - 1):
        # 	return 0
        # elif (e[0][1] == e[1][1] == n) and (e[0][0] == e[1][0] - 1):
        # 	return 0

    velocity.set_constraints(dirichlet=gds.combine_bcs(
        free_boundaries,
        gds.zero_edge_bc(t),
        gds.zero_edge_bc(b),
    ))
    return pressure, velocity