Merge remote-tracking branch 'origin/master'
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commit
38b050ab6b
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@ -9,6 +9,7 @@ from typing import Union
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import numpy as np
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import pyny3d.geoms as pn
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import math
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from helpers.geometry_helper import GeometryHelper
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@ -198,7 +199,7 @@ class Surface:
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return self._ground_polygon
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@property
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def area(self):
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def area_geoms_class(self):
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"""
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Surface area in square meters
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:return: float
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@ -210,6 +211,79 @@ class Surface:
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self._area = 0
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return self._area
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@property
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def area(self):
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"""
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Surface area in square meters
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:return: float
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"""
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# New method to calculate area
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if self._area is None:
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print('NEW METHOD TO CALCULATE AREA')
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print('original:')
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print(self.points)
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# 1. 3D -> 2D
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z_vector = [0, 0, 1]
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normal_vector = self.normal
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print(normal_vector)
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turning_base_matrix = None
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points_2d = []
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x = normal_vector[0]
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y = normal_vector[1]
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z = normal_vector[2]
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print('x:', x)
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print('y:', y)
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print('z:', z)
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if x != 0 or y != 0:
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# cos(alpha) = n.z/|n|.|z|
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print('dot_mult:', np.dot(normal_vector, z_vector))
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alpha = math.acos(np.dot(normal_vector, z_vector) / np.linalg.norm(normal_vector) / np.linalg.norm(z_vector))
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print('alpha:', alpha)
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turning_line = np.cross(normal_vector, z_vector)
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print('turning_line:', turning_line)
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third_axis = np.cross(normal_vector, turning_line)
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print('third_axis:', third_axis)
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# orthonormal base
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w_1 = turning_line / np.linalg.norm(turning_line)
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w_2 = normal_vector
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w_3 = third_axis / np.linalg.norm(third_axis)
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# turning_base_matrix
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turning_matrix = np.array([[1, 0, 0],
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[0, math.cos(alpha), -math.sin(alpha)],
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[0, math.sin(alpha), math.cos(alpha)]])
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print('turning_matrix:', turning_matrix)
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base_matrix = np.array([w_1, w_2, w_3])
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print('base_matrix:', base_matrix)
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turning_base_matrix = np.matmul(base_matrix.transpose(), turning_matrix.transpose())
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turning_base_matrix = np.matmul(turning_base_matrix, base_matrix)
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print('turning_base_matrix:', turning_base_matrix)
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if turning_base_matrix is None:
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print('ERROR')
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else:
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for point in self.points:
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new_point = np.matmul(turning_base_matrix, point)
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print('new_point:', new_point)
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points_2d.append(new_point)
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# points_2d.append([new_point[0], new_point[1]])
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else:
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for point in self.points:
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points_2d.append([point[0], point[1], 0])
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polygon_2d = pn.Polygon(np.array(points_2d))
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print('2D:')
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print(polygon_2d.points)
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# 2. calculate area:
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area = 0
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for i in range(0, len(polygon_2d.points)-1):
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point = polygon_2d.points[i]
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next_point = polygon_2d.points[i+1]
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area += (next_point[1] + point[1]) / 2 * (next_point[0] - point[0])
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self._area = area
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return self._area
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def _is_almost_same_terrain(self, terrain_points, ground_points):
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equal = 0
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for terrain_point in terrain_points:
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