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view_geometry.py
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view_geometry.py
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""" Script to plot geometry for aero, struct, or aerostruct cases.
Usage is
`python view_geometry.py aero.db` for aero only,
`python view_geometry.py struct.db` for struct only,
`python view_geometry.py aerostruct.db` for aerostruct, or
`python view_geometry.py __name__` for user-named database.
You can select a certain zoom factor for the 3d view by adding a number as a
last keyword.
The larger the number, the closer the view. Floats or ints are accepted.
Ex: `python view_geometry.py aero.db 1` a wider view than `python view_geometry.py aero.db 5`.
"""
from __future__ import division, print_function
import sys
major_python_version = sys.version_info[0]
from six import iteritems
import numpy as np
try:
import matplotlib
matplotlib.use('TkAgg')
matplotlib.rcParams['lines.linewidth'] = 2
matplotlib.rcParams['axes.edgecolor'] = 'gray'
matplotlib.rcParams['axes.linewidth'] = 0.5
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg,\
NavigationToolbar2TkAgg
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d import Axes3D
from matplotlib import cm
import matplotlib.animation as manimation
import sqlitedict
except:
print()
print("Correct plotting modules not available; please consult import list")
print()
#####################
# User-set parameters
#####################
db_name = sys.argv[1]
try:
zoom_scale = sys.argv[2]
except:
zoom_scale = 2.8
class Display(object):
def __init__(self, db_name):
self.f = plt.figure(dpi=100, figsize=(14, 14), facecolor='white')
self.ax = plt.subplot2grid((4, 4), (0, 0), rowspan=4,
colspan=4, projection='3d')
self.num_iters = 0
self.db_name = db_name
self.show_wing = True
self.show_tube = True
self.curr_pos = 0
self.old_n = 0
self.aerostruct = False
self.load_db()
self.plot_wing()
def load_db(self):
self.db = sqlitedict.SqliteDict(self.db_name, 'iterations')
self.twist = []
self.mesh = []
self.def_mesh = []
self.radius = []
self.thickness = []
sec_forces = []
normals = []
widths = []
self.lift = []
self.lift_ell = []
self.vonmises = []
alpha = []
rho = []
v = []
self.CL = []
self.AR = []
self.S_ref = []
self.obj = []
meta_db = sqlitedict.SqliteDict(self.db_name, 'metadata')
self.opt = False
for item in meta_db['Unknowns']:
if 'is_objective' in meta_db['Unknowns'][item].keys():
self.obj_key = item
if major_python_version == 3:
keys_length = sum(1 for _ in self.db.keys())
else:
keys_length = len(self.db.keys())
if keys_length > 2:
self.opt = True
deriv_keys = sqlitedict.SqliteDict(self.db_name, 'derivs').keys()
deriv_keys = [int(key.split('|')[-1]) for key in deriv_keys]
for i, (case_name, case_data) in enumerate(iteritems(self.db)):
if i == 0:
pass
elif i not in deriv_keys:
if deriv_keys:
continue # don't plot these cases
if self.opt:
self.obj.append(case_data['Unknowns'][self.obj_key])
names = []
for key in case_data['Unknowns'].keys():
# Aerostructural
if 'coupled' in key and 'loads' in key:
self.aerostruct = True
names.append(key.split('_')[:-1][0])
# Aero only
elif 'def_mesh' in key and 'coupled' not in key:
names.append(key.split('.')[0])
# Structural only
elif 'disp_aug' in key and 'coupled' not in key:
names.append(key.split('.')[0])
self.names = names
n_names = len(names)
self.twist_included = False
# Loop through each of the surfaces
for name in names:
# Check if this is an aerostructual case; treat differently
# due to the way the problem is organized
if not self.aerostruct:
# A mesh exists for all types of cases
self.mesh.append(case_data['Unknowns'][name+'.mesh'])
try:
self.radius.append(case_data['Unknowns'][name+'.radius'])
self.thickness.append(case_data['Unknowns'][name+'.thickness'])
self.vonmises.append(
np.max(case_data['Unknowns'][name+'.vonmises'], axis=1))
self.show_tube = True
except:
self.show_tube = False
try:
self.def_mesh.append(case_data['Unknowns'][name+'.def_mesh'])
normals.append(case_data['Unknowns'][name+'.normals'])
widths.append(case_data['Unknowns'][name+'.widths'])
sec_forces.append(case_data['Unknowns']['aero_states.' + name + '_sec_forces'])
self.CL.append(case_data['Unknowns'][name+'_perf.CL1'])
self.S_ref.append(case_data['Unknowns'][name+'.S_ref'])
self.show_wing = True
# Not the best solution for now, but this will ensure
# that this plots corectly even if twist isn't a desvar
try:
self.twist.append(case_data['Unknowns'][name+'.twist'])
self.twist_included = True
except:
pass
except:
self.show_wing = False
else:
self.show_wing, self.show_tube = True, True
short_name = name.split('.')[1:][0]
self.mesh.append(case_data['Unknowns'][short_name+'.mesh'])
self.radius.append(case_data['Unknowns'][short_name+'.radius'])
self.thickness.append(case_data['Unknowns'][short_name+'.thickness'])
self.vonmises.append(
np.max(case_data['Unknowns'][short_name+'_perf.vonmises'], axis=1))
self.def_mesh.append(case_data['Unknowns'][name+'.def_mesh'])
normals.append(case_data['Unknowns'][name+'.normals'])
widths.append(case_data['Unknowns'][name+'.widths'])
sec_forces.append(case_data['Unknowns']['coupled.aero_states.' + short_name + '_sec_forces'])
self.CL.append(case_data['Unknowns'][short_name+'_perf.CL1'])
self.S_ref.append(case_data['Unknowns'][name+'.S_ref'])
# Not the best solution for now, but this will ensure
# that this plots corectly even if twist isn't a desvar
try:
self.twist.append(case_data['Unknowns'][short_name+'.twist'])
self.twist_included = True
except:
pass
if not self.twist_included:
ny = self.mesh[0].shape[1]
self.twist.append(np.zeros(ny))
if self.show_wing:
alpha.append(case_data['Unknowns']['alpha'] * np.pi / 180.)
rho.append(case_data['Unknowns']['rho'])
v.append(case_data['Unknowns']['v'])
if self.opt:
self.num_iters = np.max([int(len(self.mesh) / n_names) - 1, 1])
else:
self.num_iters = 0
symm_count = 0
for mesh in self.mesh:
if np.all(mesh[:, :, 1] >= -1e-8) or np.all(mesh[:, :, 1] <= 1e-8):
symm_count += 1
if symm_count == len(self.mesh):
self.symmetry = True
else:
self.symmetry = False
if self.symmetry:
new_mesh = []
if self.show_tube:
new_r = []
new_thickness = []
new_vonmises = []
if self.show_wing:
new_twist = []
new_sec_forces = []
new_def_mesh = []
new_widths = []
new_normals = []
for i in range(self.num_iters + 1):
for j, name in enumerate(names):
mirror_mesh = self.mesh[i*n_names+j].copy()
mirror_mesh[:, :, 1] *= -1.
mirror_mesh = mirror_mesh[:, ::-1, :][:, 1:, :]
new_mesh.append(np.hstack((self.mesh[i*n_names+j], mirror_mesh)))
if self.show_tube:
thickness = self.thickness[i*n_names+j]
new_thickness.append(np.hstack((thickness, thickness[::-1])))
r = self.radius[i*n_names+j]
new_r.append(np.hstack((r, r[::-1])))
vonmises = self.vonmises[i*n_names+j]
new_vonmises.append(np.hstack((vonmises, vonmises[::-1])))
if self.show_wing:
mirror_mesh = self.def_mesh[i*n_names+j].copy()
mirror_mesh[:, :, 1] *= -1.
mirror_mesh = mirror_mesh[:, ::-1, :][:, 1:, :]
new_def_mesh.append(np.hstack((self.def_mesh[i*n_names+j], mirror_mesh)))
mirror_normals = normals[i*n_names+j].copy()
mirror_normals = mirror_normals[:, ::-1, :][:, 1:, :]
new_normals.append(np.hstack((normals[i*n_names+j], mirror_normals)))
mirror_forces = sec_forces[i*n_names+j].copy()
mirror_forces = mirror_forces[:, ::-1, :]
new_sec_forces.append(np.hstack((sec_forces[i*n_names+j], mirror_forces)))
new_widths.append(np.hstack((widths[i*n_names+j], widths[i*n_names+j][::-1])))
twist = self.twist[i*n_names+j]
new_twist.append(np.hstack((twist, twist[::-1][1:])))
self.mesh = new_mesh
if self.show_tube:
self.thickness = new_thickness
self.radius = new_r
self.vonmises = new_vonmises
if self.show_wing:
self.def_mesh = new_def_mesh
self.twist = new_twist
widths = new_widths
normals = new_normals
sec_forces = new_sec_forces
if self.show_wing:
for i in range(self.num_iters + 1):
for j, name in enumerate(names):
m_vals = self.mesh[i*n_names+j].copy()
cvec = m_vals[0, :, :] - m_vals[-1, :, :]
chords = np.sqrt(np.sum(cvec**2, axis=1))
chords = 0.5 * (chords[1:] + chords[:-1])
a = alpha[i]
cosa = np.cos(a)
sina = np.sin(a)
forces = np.sum(sec_forces[i*n_names+j], axis=0)
lift = (-forces[:, 0] * sina + forces[:, 2] * cosa) / \
widths[i*n_names+j]/0.5/rho[i]/v[i]**2
span = (m_vals[0, :, 1] / (m_vals[0, -1, 1] - m_vals[0, 0, 1]))
span = span - (span[0] + .5)
lift_area = np.sum(lift * (span[1:] - span[:-1]))
lift_ell = 4 * lift_area / np.pi * np.sqrt(1 - (2*span)**2)
self.lift.append(lift)
self.lift_ell.append(lift_ell)
wingspan = np.abs(m_vals[0, -1, 1] - m_vals[0, 0, 1])
self.AR.append(wingspan**2 / self.S_ref[i*n_names+j])
# recenter def_mesh points for better viewing
for i in range(self.num_iters + 1):
center = np.zeros((3))
for j in range(n_names):
center += np.mean(self.def_mesh[i*n_names+j], axis=(0,1))
for j in range(n_names):
self.def_mesh[i*n_names+j] -= center / n_names
# recenter mesh points for better viewing
for i in range(self.num_iters + 1):
center = np.zeros((3))
for j in range(n_names):
center += np.mean(self.mesh[i*n_names+j], axis=(0,1))
for j in range(n_names):
self.mesh[i*n_names+j] -= center / n_names
if self.show_wing:
self.min_twist, self.max_twist = self.get_list_limits(self.twist)
diff = (self.max_twist - self.min_twist) * 0.05
self.min_twist -= diff
self.max_twist += diff
self.min_l, self.max_l = self.get_list_limits(self.lift)
self.min_le, self.max_le = self.get_list_limits(self.lift_ell)
self.min_l, self.max_l = min(self.min_l, self.min_le), max(self.max_l, self.max_le)
diff = (self.max_l - self.min_l) * 0.05
self.min_l -= diff
self.max_l += diff
if self.show_tube:
self.min_t, self.max_t = self.get_list_limits(self.thickness)
diff = (self.max_t - self.min_t) * 0.05
self.min_t -= diff
self.max_t += diff
self.min_vm, self.max_vm = self.get_list_limits(self.vonmises)
diff = (self.max_vm - self.min_vm) * 0.05
self.min_vm -= diff
self.max_vm += diff
def plot_wing(self):
n_names = len(self.names)
self.ax.cla()
az = self.ax.azim
el = self.ax.elev
dist = self.ax.dist
for j, name in enumerate(self.names):
mesh0 = self.mesh[self.curr_pos*n_names+j].copy()
self.ax.set_axis_off()
if self.show_wing:
def_mesh0 = self.def_mesh[self.curr_pos*n_names+j]
x = mesh0[:, :, 0]
y = mesh0[:, :, 1]
z = mesh0[:, :, 2]
try: # show deformed mesh option may not be available
if self.show_def_mesh.get():
x_def = def_mesh0[:, :, 0]
y_def = def_mesh0[:, :, 1]
z_def = def_mesh0[:, :, 2]
self.c2.grid(row=0, column=3, padx=5, sticky=Tk.W)
if self.ex_def.get():
z_def = (z_def - z) * 10 + z_def
def_mesh0 = (def_mesh0 - mesh0) * 30 + def_mesh0
else:
def_mesh0 = (def_mesh0 - mesh0) * 2 + def_mesh0
self.ax.plot_wireframe(x_def, y_def, z_def, rstride=1, cstride=1, color='k')
self.ax.plot_wireframe(x, y, z, rstride=1, cstride=1, color='k', alpha=.3)
else:
self.ax.plot_wireframe(x, y, z, rstride=1, cstride=1, color='k')
self.c2.grid_forget()
except:
self.ax.plot_wireframe(x, y, z, rstride=1, cstride=1, color='k')
if self.show_tube:
r0 = self.radius[self.curr_pos*n_names+j]
t0 = self.thickness[self.curr_pos*n_names+j]
colors = t0
colors = colors / np.max(colors)
num_circ = 12
fem_origin = 0.35
n = mesh0.shape[1]
p = np.linspace(0, 2*np.pi, num_circ)
for i, thick in enumerate(t0):
r = np.array((r0[i], r0[i]))
R, P = np.meshgrid(r, p)
X, Z = R*np.cos(P), R*np.sin(P)
chords = mesh0[-1, :, 0] - mesh0[0, :, 0]
comp = fem_origin * chords + mesh0[0, :, 0]
X[:, 0] += comp[i]
X[:, 1] += comp[i+1]
Z[:, 0] += fem_origin * (mesh0[-1, i, 2] - mesh0[0, i, 2]) + mesh0[0, i, 2]
Z[:, 1] += fem_origin * (mesh0[-1, i+1, 2] - mesh0[0, i+1, 2]) + mesh0[0, i+1, 2]
Y = np.empty(X.shape)
Y[:] = np.linspace(mesh0[0, i, 1], mesh0[0, i+1, 1], 2)
col = np.zeros(X.shape)
col[:] = colors[i]
try:
self.ax.plot_surface(X, Y, Z, rstride=1, cstride=1,
facecolors=cm.viridis(col), linewidth=0)
except:
self.ax.plot_surface(X, Y, Z, rstride=1, cstride=1,
facecolors=cm.coolwarm(col), linewidth=0)
lim = 0.
for j in range(n_names):
ma = np.max(self.mesh[self.curr_pos*n_names+j], axis=(0,1,2))
if ma > lim:
lim = ma
lim /= float(zoom_scale)
self.ax.auto_scale_xyz([-lim, lim], [-lim, lim], [-lim, lim])
self.ax.view_init(elev=el, azim=az) # Reproduce view
self.ax.dist = dist
def check_length(self):
# Load the current sqlitedict
db = sqlitedict.SqliteDict(self.db_name, 'iterations')
# Get the number of current iterations
# Minus one because OpenMDAO uses 1-indexing
self.num_iters = int(db.keys()[-1].split('|')[-1])
def get_list_limits(self, input_list):
list_min = 1.e20
list_max = -1.e20
for list_ in input_list:
mi = np.min(list_)
if mi < list_min:
list_min = mi
ma = np.max(list_)
if ma > list_max:
list_max = ma
return list_min, list_max
def disp_plot(db_name):
disp = Display(db_name)
plt.show()
if __name__ == '__main__':
disp_plot(db_name)