def calculatePoints(self): pos_x = -self.position.get_x() pos_y = -self.position.get_y() pos_z = -self.position.get_z() self.vertexList.append(self.position) self.vertexList.append( Vec3( self.position.get_x() + 0.25 * dimensions_room['length'], self.position.get_y() + 0.25 * dimensions_room['length'] * tan(self.opening / 2), self.position.get_z() + 0.25 * dimensions_room['length'] * tan(self.opening / 2))) self.vertexList.append( Vec3( self.position.get_x() + 0.25 * dimensions_room['length'], self.position.get_y() + 0.25 * dimensions_room['length'] * tan(self.opening / 2), self.position.get_z() - 0.25 * dimensions_room['length'] * tan(self.opening / 2))) self.vertexList.append( Vec3( self.position.get_x() + 0.25 * dimensions_room['length'], self.position.get_y() - 0.25 * dimensions_room['length'] * tan(self.opening / 2), self.position.get_z() + 0.25 * dimensions_room['length'] * tan(self.opening / 2))) self.vertexList.append( Vec3( self.position.get_x() + 0.25 * dimensions_room['length'], self.position.get_y() - 0.25 * dimensions_room['length'] * tan(self.opening / 2), self.position.get_z() - 0.25 * dimensions_room['length'] * tan(self.opening / 2)))
def _create_parabola(self): # creates visualization of the parable, must finish!!!!!!! length, width, height = self.dimensions.get_tuple() r = ((height * height / 4) + length * length) / (2 * length) self.angle_ouverture = degrees(arcsin(height / (2 * r))) self.points_parable_origin = [] self.points_parable = [] rotation = Orientation(0, 90, 0) self.points_per_level = 10 self.angle_levels = 10 matRot = rotation.rotation_matrix() for theta in range(0, int(self.angle_ouverture), self.angle_levels): for phi in range(0, 360, int(360 / self.points_per_level)): theta_rad = radians(theta) phi_rad = radians(phi) x0 = r * sin(theta_rad) * cos(phi_rad) y0 = r * sin(theta_rad) * sin(phi_rad) z0 = r * (1 - sqrt(1 - sin(theta_rad) * sin(theta_rad))) p = Vec3(x0, y0, z0) p = matRot * p - Vec3(length / 2, 0, 0) p = Vec3(p.item(0), p.item(1), p.item(2)) p2 = Vec3(p.item(0), p.item(1), p.item(2)) self.points_parable_origin.append(p) self.points_parable.append(p2) self.squares_edges = [] # for() self._update_vertices_points()
def convertXY(self, x, y): d = x * x + y * y radiusSquared = self.ballRadius * self.ballRadius if (d > radiusSquared): return Vec3(x, y, 0) else: return Vec3(x, y, sqrt(radiusSquared - d))
def get_haut_haut(): return { 'PF_000': Vec3(0, 0, Ideal.z), # PF_000 'PF_100': Vec3(Ideal.x, 0, Ideal.z), # PF_100 'PF_010': Vec3(0, Ideal.y, Ideal.z), # PF_010 'PF_110': Vec3(Ideal.x, Ideal.y, Ideal.z), # PF_110 'PF_001': Vec3(0, 0, Ideal.z), # PF_001 'PF_101': Vec3(Ideal.x, 0, Ideal.z), # PF_101 'PF_011': Vec3(0, Ideal.y, Ideal.z), # PF_011 'PF_111': Vec3(Ideal.x, Ideal.y, Ideal.z) # PF_111 }
def test_new(self): v = Vec3(0.0, 0.0, 0.0) self.subTest('type Vec3') self.assertEqual(type(v), Vec3) self.subTest('is matrix') self.assertTrue(isinstance(v, matrix)) self.subTest('shape') self.assertEqual(v.shape, (3, 1))
def _get_source_demo_config_ancrage(self): x_centre_source = sum( point.get_x() for point in self.config_ancrage.get_points_fixes()) / 8 y_centre_source = sum( point.get_y() for point in self.config_ancrage.get_points_fixes()) / 8 z_centre_source = self.chambre.dimensions['height'] / 2 centre_demo = Vec3(x_centre_source, y_centre_source, z_centre_source) source_demo = Box(dimensions=self.dimensions_source, centre=centre_demo, ypr_angles=TupleAnglesRotation.ZERO()) return source_demo
def _is_coliding(self, other_box: 'Box', k_discretisation=None) -> bool: """ Tests if there are points on pave1's faces inside other_box. the function needs to be called twice to be sure that there are no intersections pave1: dictionary with dimensions(dictionary),_center(matrix 3x1), orientation(dictionary) k: (k+1)^2 = number of points to be tested on each face, the greater the k, the plus reliable the result. """ # default value if needed k = k_discretisation if k_discretisation else DefaultValues.box_colision_k_dicretisation # dimensions length, width, height = self.dimensions.get_tuple() # points to test points_to_be_tested = [] # create "points" on the faces for i in range(k + 1): for j in range(k + 1): # XZ faces x = i * length / k z = j * height / k points_to_be_tested.append(Vec3(x, 0, z)) points_to_be_tested.append(Vec3(x, width, z)) # XY faces x = i * length / k y = j * width / k points_to_be_tested.append(Vec3(x, y, 0)) points_to_be_tested.append(Vec3(x, y, height)) # YZ faces y = i * width / k z = j * height / k points_to_be_tested.append(Vec3(0, y, z)) points_to_be_tested.append(Vec3(length, y, z)) # test them for index in range(len(points_to_be_tested)): # rotate the point points_to_be_tested[index] = self.orientation.rotation_matrix * points_to_be_tested[index] # check type TODO: remove this assert assert isinstance(points_to_be_tested[index], Vec3), "problem here with vec3" # next line converts from 3d rotation matrix to vecteur3d # points_to_be_tested[index] = Vec3(points_to_be_tested[index].__getitem__((0, 0)), # points_to_be_tested[index].__getitem__((1, 0)), # points_to_be_tested[index].__getitem__((2, 0))) halves = Vec3(length / 2, width / 2, height / 2) points_to_be_tested[index] = points_to_be_tested[index] + self.center + (-halves) # check if the point is in the other if other_box.is_in_box(points_to_be_tested[index]): return True return False
def __init__(self, dimensions_source, maisonette, chambre, config_ancrage: CableLayout, systeme_spherique_baie_vitree, configs_simulation): self.dimensions_source = dimensions_source self.maisonette = maisonette self.chambre = chambre self.config_ancrage = config_ancrage self.systeme_spherique_baie_vitree = systeme_spherique_baie_vitree self.diametre_cable = configs_simulation['diametre_cable'] self.space_recherche = configs_simulation['space_recherche'] self.n_discretisation_cables = configs_simulation[ 'n_discretisation_cables'] self.k_dicretisation_cubes = configs_simulation[ 'k_dicretisation_cubes'] self.verbose = configs_simulation['fmin_verbose'] self.source = Box(centre=Vec3(0, 0, 0), ypr_angles=TupleAnglesRotation(0, 0, 0), dimensions=dimensions_source) self.limites = {} self._source_demo = self._get_source_demo_config_ancrage() self._cables_demo = self._get_cables_demo_config_ancrage()
def _set_sommets_inside(self): """TODO doc string""" points = self.vertices_points_list(BoxVertexOrderEnum.ZYX) S0 = points[0] - Vec3(-self.wall_width, -self.wall_width, -self.wall_width) S1 = points[1] - Vec3(-self.wall_width, -self.wall_width, self.wall_width) S2 = points[2] - Vec3(-self.wall_width, self.wall_width, -self.wall_width) S3 = points[3] - Vec3(-self.wall_width, self.wall_width, self.wall_width) S4 = points[4] - Vec3(self.wall_width, -self.wall_width, -self.wall_width) S5 = points[5] - Vec3(self.wall_width, -self.wall_width, self.wall_width) S6 = points[6] - Vec3(self.wall_width, self.wall_width, -self.wall_width) S7 = points[7] - Vec3(self.wall_width, self.wall_width, self.wall_width) length, width, height = self.dimensions.get_tuple() # window_inside_points S8 = points[1] - Vec3(-self.wall_width, -(width / 2 - self.window_dimensions['width'] / 2), (height / 2 - self.window_dimensions['height'] / 2)) S9 = points[3] - Vec3(-self.wall_width, (width / 2 - self.window_dimensions['width'] / 2), (height / 2 - self.window_dimensions['height'] / 2)) S10 = points[2] - Vec3(-self.wall_width, (width / 2 - self.window_dimensions['width'] / 2), -(height / 2 - self.window_dimensions['height'] / 2)) S11 = points[0] - Vec3(-self.wall_width, -(width / 2 - self.window_dimensions['width'] / 2), -(height / 2 - self.window_dimensions['height'] / 2)) # window_outside_points S12 = points[1] - Vec3(0, -(width / 2 - self.window_dimensions['width'] / 2), (height / 2 - self.window_dimensions['height'] / 2)) S13 = points[3] - Vec3(0, (width / 2 - self.window_dimensions['width'] / 2), (height / 2 - self.window_dimensions['height'] / 2)) S14 = points[2] - Vec3(0, (width / 2 - self.window_dimensions['width'] / 2), -(height / 2 - self.window_dimensions['height'] / 2)) S15 = points[0] - Vec3(0, -(width / 2 - self.window_dimensions['width'] / 2), -(height / 2 - self.window_dimensions['height'] / 2)) S16 = points[0] S17 = points[1] S18 = points[2] S19 = points[3] self.sommets_extras = [S0, S1, S2, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12, S13, S14, S15, S16, S17, S18, S19]
CableLayout, \ CableConfiguration from src.simulation.limit_angles.angles_limites import VerificateurAnglesLimites ''' Setup d'un faux systeme. Destiné juste à faire des debugs avec des valeurs plus simples. ''' ''' ************************ Maisonette ************************ ''' # _center centre_maisonette = \ Vec3( x=7500, # mm y=5000, # mm z=5000 # mm ) # dimensions dimensions_maisonette = \ BoxDimensions( length=5000, # mm width=10000, # mm height=10000 # mm ) # pave maisonette = \ Box( centre=centre_maisonette,
) # rotation rotation_systeme_spherique = \ Orientation( yaw=180, # degrés pitch=0, # degrés row=0, # degrés unity=AngleUnityEnum.degree, ) # systeme sphérique systeme_spherique_baie_vitree = SphericalCoordinateSystem( center=centre_systeme_spherique, orientation=rotation_systeme_spherique) ''' ************************ Camera ************************ ''' camera_direction = Vec3(x=0, y=0, z=0) # position camera_position1 = Vec3( x=-dimensions_room['length'] / 2, # mm y=-0.25 * dimensions_room['width'], # mm z=-0.1 * dimensions_room['height'] # mm ) camera_position2 = Vec3( x=-dimensions_room['length'] / 2, # mm y=-0.25 * dimensions_room['width'], # mm z=0.25 * dimensions_room['height'] # mm ) camera_position3 = Vec3(
def direction_source_to_fixed(self) -> Vec3: """Unitary _vector in the direction source point -> fixed point.""" return Vec3.zero() - self._vector.direction