def test_diagonal_rib_3d(self):
cell = self.glider.cells[self.cell_no]
diag = DiagonalRib((0.1, -1), (0.3, -1), (0.1, 0.8), (0.5, 0.8), self.cell_no)
l1, l2 = diag.get_3d(self.glider)
l1 = l1.tolist()
Graph.Graphics([Graph.Line(cell.rib1.profile_3d.data),
Graph.Line(cell.rib2.profile_3d.data),
Graph.Polygon(l1 + l2[::-1])])
def test_all(self):
att = (0.1, 0.3, 0.55, 0.8)
panels = self.get_panels()
diagonals = [self.get_diagonal(x) for x in att]
straps = [self.get_strap(x) for x in att]
Graph.Graphics([
Graph.Line(self.cell.rib1.profile_3d.data),
Graph.Line(self.cell.rib2.profile_3d.data)
] + panels + diagonals + straps)
def xtest_mirror(self):
cell1 = self.cell2
cell2 = self.cell2.copy()
cell2.mirror()
Graph.Graphics([Graph.Line(cell1.rib1.profile_3d.data),
Graph.Line(cell2.rib1.profile_3d.data),
Graph.Red,
Graph.Line(cell1.prof2.data),
Graph.Line(cell2.prof2.data),
Graph.Green] +
[Graph.Line([p, p+normvector]) for p, normvector in zip(cell2.prof2.data, cell2.basic_cell.normvectors)])
def test_gibus_arcs(self):
rib_no = random.randint(0, len(self.glider.ribs)-1)
gibus_arc = GibusArcs(rib_no=rib_no, position=.15, size=0.02)
thalist = gibus_arc.get_3d(self.glider, num_points=20)
Graph.Graphics([Graph.Line(self.glider.ribs[rib_no].profile_3d.data),
Graph.Polygon(thalist)])
def runcase(self, path):
key_dict = import_lines(path)
# print(key_dict["LINES"][2])
thalines = LineSet(key_dict["LINES"][2], np.array([100, 0, 1]))
# for line in thalines.lines:
# line.lineset = thalines
for _ in range(3):
thalines.recalc(True)
objects = map(lambda line: graph.Line(line.get_line_points(100)),
thalines.lines)
graph.Graphics3D(objects)
def test_flat(self):
prof = self.rib.profile_2d.copy()
prof = PolyLine2D(prof.data) * [self.rib.chord, self.rib.chord]
print(self.rib.profile_2d, prof)
#prof.scale(self.rib.chord)
gib_pos = [n.rib_pos for n in self.attachment_points]
gib_pos.sort()
hole_pos = [(x1 + x2) / 2 for x1, x2 in zip(gib_pos[:-1], gib_pos[1:])]
rigid = RigidFoil(-.15, .12)
r_flat = rigid.get_flattened(self.rib)
print(self.rib.rotation_matrix,
norm(self.rib.rotation_matrix.dot([2, 0, 0])))
Graph.Graphics([
Graph.Line(prof),
Graph.Line(self.rib.profile_2d.data * self.rib.chord),
Graph.Line(r_flat)
])
Graph.Graphics([
Graph.Line([self.rib.align(p, scale=False) for p in prof.data]),
Graph.Line([self.rib.align(p, scale=False) for p in r_flat]),
Graph.Line(self.rib.profile_3d.data)
])
def get_all(self):
gib_pos = [n.rib_pos for n in self.attachment_points]
gib_pos.sort()
hole_pos = [(x1 + x2) / 2 for x1, x2 in zip(gib_pos[:-1], gib_pos[1:])]
gibs = [self.get_gibus_arcs(y) for y in gib_pos]
holes = [self.get_hole(x, 0.4) for x in hole_pos]
rigid = self.get_rigid(-.15, .13)
p = self.rib.profile_2d
print(max([norm(p[0] - p2) for p2 in p]), self.rib.chord)
return [Graph.Line(self.rib.profile_3d.data)] + gibs + holes + [rigid]
def test_diagonal_rib_2d(self):
diag = DiagonalRib((0.1, -1), (0.3, -1), (0.1, 0.8), (0.5, 0.8), self.cell_no)
l1, l2 = diag.get_flattened(self.glider, ribs_flattened=None)
Graph.Graphics2D([Graph.Line(l1.data.tolist()+l2.data.tolist()[::-1])])
def test_show_cell(self, num=10):
#print(self.rib1.profile_2d.x_values)
ribs = [self.cell1.midrib(x * 1. / num) for x in range(num)]
ribs += [self.cell2.midrib(x * 1. / num) for x in range(num)]
Graph.Graphics([Graph.Line(x.data) for x in ribs] +
[Graph.Line(self.rib1.profile_3d.data)])
def test_show_cell(self, num=20):
ribs = [self.cell1.midrib(x*1./num, arc_argument=False) for x in range(num)]
ribs += [self.cell2.midrib(x*1./num) for x in range(num)]
Graph.Graphics([Graph.Line(x.data) for x in ribs]+[Graph.Line(self.rib3.profile_3d.data)])
def show(self):
baseline = Graph.Line([self.p1, self.p2])
Graph.Graphics([baseline] +
[Graph.Line(l) for l in self.text.get_vectors()])
def test_hole(self):
rib_no = random.randint(0, len(self.glider.ribs)-1)
hole = RibHole(rib_no, 0.2)
thalist = hole.get_3d(self.glider)
Graph.Graphics([Graph.Line(self.glider.ribs[rib_no].profile_3d.data),
Graph.Polygon(thalist)])
def get_rigid(self, start, stop):
rigid = RigidFoil(start, stop)
#return Graph.Line([self.rib.align(p, scale=False) for p in rigid.get_flattened(self.rib)])
return Graph.Line(rigid.get_3d(self.rib))
