Exemple #1
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  def Polygon(self, polyline = False):
    """Return a PolygonArea object

    :param polyline: if True then the object describes a polyline
      instead of a polygon
    :return: a :class:`~geographiclib.polygonarea.PolygonArea`

    """

    from geographiclib.polygonarea import PolygonArea
    return PolygonArea(self, polyline)
Exemple #2
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 def __init__(self, poly):
     # Converti le polygone en liste de points
     points_lon_lat = list(poly.exterior.coords)
     points_lat_lon = [(point[1], point[0]) for point in points_lon_lat]
     # Converti le rectangle en liste de points
     rectangle = poly.minimum_rotated_rectangle
     rpoints_lon_lat = list(rectangle.exterior.coords)
     rpoints_lat_lon = [(point[1], point[0]) for point in rpoints_lon_lat]
     # Converti le polygone dans la bonne projection
     wgs84 = Geodesic.WGS84
     geopoly = PolygonArea(wgs84)
     for point in points_lat_lon[0:-1]:
         geopoly.AddPoint(point[0], point[1])
     geopoly_result = geopoly.Compute()
     # Converti le rectangle dans la bonne projection
     georectangle = PolygonArea(wgs84)
     for point in rpoints_lat_lon[0:-1]:
         georectangle.AddPoint(point[0], point[1])
     georectangle_result = georectangle.Compute()
     # Calcule les dimensions du rectangle
     rdistance = []
     for i in range(0, 4):
         rdistance.append(
             wgs84.Inverse(rpoints_lat_lon[i % 4][0],
                           rpoints_lat_lon[i % 4][1],
                           rpoints_lat_lon[(i + 1) % 4][0],
                           rpoints_lat_lon[(i + 1) % 4][1])["s12"])
     rdistance = [
         abs((rdistance[0] + rdistance[2]) / 2.0),
         abs((rdistance[1] + rdistance[3]) / 2.0)
     ]
     # Données membres
     self.polygon = poly
     self.centroid = poly.centroid
     self.rectangle = poly.minimum_rotated_rectangle
     self.perimeter = abs(geopoly_result[1])
     self.area = abs(geopoly_result[2])
     self.rectangle_min = min(rdistance)
     self.rectangle_max = max(rdistance)
     self.rectangle_perimeter = abs(georectangle_result[1])
     self.rectangle_area = abs(georectangle_result[2])
     self.ratio = self.area / self.rectangle_area
     self.polygon_conversion = self.area / self.polygon.area
     self.rectangle_conversion = self.rectangle_area / self.rectangle.area
     self.nvertices = len(points_lon_lat) - 1
     self.nedges = self.nvertices
Exemple #3
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  def Area(self, points, polyline = False):
    """Compute the area of a geodesic polygon given by points, an array of
    dictionaries with entries lat and lon.  Return a dictionary with
    entries

      number the number of verices
      perimeter the perimeter
      area the area (counter-clockwise traversal positive)

    There is no need to "close" the polygon.  If polyline is set to
    True, then the points define a polyline instead of a polygon, the
    length is returned as the perimeter, and the area is not returned.

    """

    from geographiclib.polygonarea import PolygonArea
    for p in points:
      Geodesic.CheckPosition(p['lat'], p['lon'])
    num, perimeter, area = PolygonArea.Area(self, points, polyline)
    result = {'number': num, 'perimeter': perimeter}
    if not polyline: result['area'] = area
    return result
class PlanimeterTest(unittest.TestCase):

    from geographiclib.polygonarea import PolygonArea
    polygon = PolygonArea(Geodesic.WGS84)
    polyline = PolygonArea(Geodesic.WGS84, True)

    def Planimeter(points):
        PlanimeterTest.polygon.Clear()
        for p in points:
            Geodesic.CheckPosition(p[0], p[1])
            PlanimeterTest.polygon.AddPoint(p[0], p[1])
        return PlanimeterTest.polygon.Compute(False, True)
    Planimeter = staticmethod(Planimeter)

    def PolyLength(points):
        PlanimeterTest.polyline.Clear()
        for p in points:
            Geodesic.CheckPosition(p[0], p[1])
            PlanimeterTest.polyline.AddPoint(p[0], p[1])
        return PlanimeterTest.polyline.Compute(False, True)
    PolyLength = staticmethod(PolyLength)

    def test_Planimeter0(self):
        # Check fix for pole-encircling bug found 2011-03-16
        points = [[89, 0], [89, 90], [89, 180], [89, 270]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 631819.8745, delta = 1e-4)
        self.assertAlmostEqual(area, 24952305678.0, delta = 1)
        points = [[-89, 0], [-89, 90], [-89, 180], [-89, 270]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 631819.8745, delta = 1e-4)
        self.assertAlmostEqual(area, -24952305678.0, delta = 1)

        points = [[0, -1], [-1, 0], [0, 1], [1, 0]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 627598.2731, delta = 1e-4)
        self.assertAlmostEqual(area, 24619419146.0, delta = 1)

        points = [[90, 0], [0, 0], [0, 90]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 30022685, delta = 1)
        self.assertAlmostEqual(area, 63758202715511.0, delta = 1)
        num, perimeter, area = PlanimeterTest.PolyLength(points)
        self.assertAlmostEqual(perimeter, 20020719, delta = 1)
        self.assertTrue(Math.isnan(area))

    def test_Planimeter5(self):
        # Check fix for Planimeter pole crossing bug found 2011-06-24
        points = [[89, 0.1], [89, 90.1], [89, -179.9]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 539297, delta = 1)
        self.assertAlmostEqual(area, 12476152838.5, delta = 1)

    def test_Planimeter6(self):
        # Check fix for Planimeter lon12 rounding bug found 2012-12-03
        points = [[9, -0.00000000000001], [9, 180], [9, 0]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 36026861, delta = 1)
        self.assertAlmostEqual(area, 0, delta = 1)
        points = [[9, 0.00000000000001], [9, 0], [9, 180]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 36026861, delta = 1)
        self.assertAlmostEqual(area, 0, delta = 1)
        points = [[9, 0.00000000000001], [9, 180], [9, 0]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 36026861, delta = 1)
        self.assertAlmostEqual(area, 0, delta = 1)
        points = [[9, -0.00000000000001], [9, 0], [9, 180]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 36026861, delta = 1)
        self.assertAlmostEqual(area, 0, delta = 1)

    def test_Planimeter12(self):
        # Area of arctic circle (not really -- adjunct to rhumb-area test)
        points = [[66.562222222, 0], [66.562222222, 180]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 10465729, delta = 1)
        self.assertAlmostEqual(area, 0, delta = 1)

    def test_Planimeter13(self):
        # Check encircling pole twice
        points = [[89,-360], [89,-240], [89,-120], [89,0], [89,120], [89,240]]
        num, perimeter, area = PlanimeterTest.Planimeter(points)
        self.assertAlmostEqual(perimeter, 1160741, delta = 1)
        self.assertAlmostEqual(area, 32415230256.0, delta = 1)