Ejemplo n.º 1
0
class TestFlatGeomTilted(unittest.TestCase):
    """Use a flat surface rotated about the x axis by 45 degrees"""
    def setUp(self):
        s2 = math.sqrt(2)
        dir = N.c_[[1, 0, -s2], [-1, 0, -s2], [-1, -s2, 0],
                   [1, -s2, 0]] / math.sqrt(3)
        position = N.c_[[0, 1 / s2, 1 / s2], [1, 0, s2], [1, s2, 0],
                        [-1, s2, 0]]
        self._bund = RayBundle(position, dir)

        self.gm = FlatGeometryManager()
        frame = SP.generate_transform(N.r_[1., 0, 0], -N.pi / 4.,
                                      N.zeros((3, 1)))
        self.prm = self.gm.find_intersections(frame, self._bund)

    def test_find_intersections(self):
        """The correct parametric locations are found for flat geometry"""
        self.failUnlessEqual(self.prm.shape, (4,),
            "Shape of parametric location array is wrong: " + \
            str(self.prm.shape))
        N.testing.assert_array_almost_equal(self.prm, math.sqrt(3))

    def test_get_normals(self):
        """A tilted flat geometry manager returns parallel normals"""
        s2 = math.sqrt(2)
        self.gm.select_rays(N.arange(4))
        n = self.gm.get_normals()
        N.testing.assert_array_almost_equal(
            n, N.tile(N.c_[[0, 1 / s2, 1 / s2]], (1, 4)))

    def test_select_rays_normals(self):
        """A tilted flat geometry manager returns normals only for selected rays"""
        s2 = math.sqrt(2)
        self.gm.select_rays(N.r_[1, 3])
        n = self.gm.get_normals()
        N.testing.assert_array_almost_equal(
            n, N.tile(N.c_[[0, 1 / s2, 1 / s2]], (1, 2)))

    def test_inters_points_global(self):
        """On the basic setup, a tilted flat surface returns correct intersections"""
        correct_pts = N.zeros((3, 4))
        s2 = math.sqrt(2)
        correct_pts[:, 0] = N.r_[1, 1 / s2, -1 / s2]

        self.gm.select_rays(N.arange(4))
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_almost_equal(pts, correct_pts)

    def test_select_rays_inters(self):
        """With dropped rays, a tilted flat surface returns correct intersections"""
        s2 = math.sqrt(2)
        correct_pts = N.zeros((3, 2))

        self.gm.select_rays(N.r_[1, 3])
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_almost_equal(pts, correct_pts)
Ejemplo n.º 2
0
class TestFlatGeomTilted(unittest.TestCase):
    """Use a flat surface rotated about the x axis by 45 degrees"""
    def setUp(self):
        s2 = math.sqrt(2)
        dir = N.c_[[1, 0, -s2], [-1, 0, -s2], [-1, -s2, 0], [1, -s2, 0]] / math.sqrt(3)
        position = N.c_[[0,1/s2,1/s2], [1,0,s2], [1,s2,0], [-1,s2,0]]
        self._bund = RayBundle(position, dir)

        self.gm = FlatGeometryManager()
        frame = SP.generate_transform(N.r_[1., 0, 0], -N.pi/4., N.zeros((3,1)))
        self.prm = self.gm.find_intersections(frame, self._bund)
        
    def test_find_intersections(self):
        """The correct parametric locations are found for flat geometry"""
        self.failUnlessEqual(self.prm.shape, (4,), 
            "Shape of parametric location array is wrong: " + \
            str(self.prm.shape))
        N.testing.assert_array_almost_equal(self.prm, math.sqrt(3))
    
    def test_get_normals(self):
        """A tilted flat geometry manager returns parallel normals"""
        s2 = math.sqrt(2)
        self.gm.select_rays(N.arange(4))
        n = self.gm.get_normals()
        N.testing.assert_array_almost_equal(n, N.tile(N.c_[[0,1/s2,1/s2]], (1,4)))
        
    def test_select_rays_normals(self):
        """A tilted flat geometry manager returns normals only for selected rays"""
        s2 = math.sqrt(2)
        self.gm.select_rays(N.r_[1,3])
        n = self.gm.get_normals()
        N.testing.assert_array_almost_equal(n, N.tile(N.c_[[0,1/s2,1/s2]], (1,2)))
    
    def test_inters_points_global(self):
        """On the basic setup, a tilted flat surface returns correct intersections"""
        correct_pts = N.zeros((3,4))
        s2 = math.sqrt(2)
        correct_pts[:,0] = N.r_[1, 1/s2, -1/s2]
        
        self.gm.select_rays(N.arange(4))
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_almost_equal(pts, correct_pts)
    
    def test_select_rays_inters(self):
        """With dropped rays, a tilted flat surface returns correct intersections"""
        s2 = math.sqrt(2)
        correct_pts = N.zeros((3,2))
        
        self.gm.select_rays(N.r_[1,3])
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_almost_equal(pts, correct_pts)
Ejemplo n.º 3
0
class TestFlatGeomTranslated(unittest.TestCase):
    def setUp(self):
        dir = N.c_[[1, 1, -1], [-1, 1, -1], [-1, -1, -1], [1, -1, -1]] / math.sqrt(3)
        position = N.c_[[0,0,1], [1,-1,1], [1,1,1], [-1,1,1]]
        self._bund = RayBundle(position, dir)
        
        self.gm = FlatGeometryManager()
        frame = SP.translate(1., 0., 0.)
        self.prm = self.gm.find_intersections(frame, self._bund)
        
    def test_find_intersections(self):
        """The correct parametric locations are found for translated flat geometry"""
        self.failUnlessEqual(self.prm.shape, (4,),
            "Shape of parametric location array is wrong: " + \
            str(self.prm.shape))
        N.testing.assert_array_almost_equal(self.prm, N.sqrt(3))
    
    def test_get_normals(self):
        """A translated flat geometry manager returns parallel normals"""
        self.gm.select_rays(N.arange(4))
        n = self.gm.get_normals()
        N.testing.assert_array_equal(n, N.tile(N.c_[[0, 0, 1]], (1,4)))
    
    def test_inters_points_global(self):
        """When translated, a flat surface returns correct intersections"""
        correct_pts = N.zeros((3,4))
        correct_pts[:2,0] = 1
        
        self.gm.select_rays(N.arange(4))
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_equal(pts, correct_pts)
Ejemplo n.º 4
0
class TestFlatGeomTranslated(unittest.TestCase):
    def setUp(self):
        dir = N.c_[[1, 1, -1], [-1, 1, -1], [-1, -1, -1],
                   [1, -1, -1]] / math.sqrt(3)
        position = N.c_[[0, 0, 1], [1, -1, 1], [1, 1, 1], [-1, 1, 1]]
        self._bund = RayBundle(position, dir)

        self.gm = FlatGeometryManager()
        frame = SP.translate(1., 0., 0.)
        self.prm = self.gm.find_intersections(frame, self._bund)

    def test_find_intersections(self):
        """The correct parametric locations are found for translated flat geometry"""
        self.failUnlessEqual(self.prm.shape, (4,),
            "Shape of parametric location array is wrong: " + \
            str(self.prm.shape))
        N.testing.assert_array_almost_equal(self.prm, N.sqrt(3))

    def test_get_normals(self):
        """A translated flat geometry manager returns parallel normals"""
        self.gm.select_rays(N.arange(4))
        n = self.gm.get_normals()
        N.testing.assert_array_equal(n, N.tile(N.c_[[0, 0, 1]], (1, 4)))

    def test_inters_points_global(self):
        """When translated, a flat surface returns correct intersections"""
        correct_pts = N.zeros((3, 4))
        correct_pts[:2, 0] = 1

        self.gm.select_rays(N.arange(4))
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_equal(pts, correct_pts)
Ejemplo n.º 5
0
class TestFlatGeomManagerInterface(unittest.TestCase):
    def setUp(self):
        dir = N.c_[[1, 1, -1], [-1, 1, -1], [-1, -1, -1],
                   [1, -1, -1]] / math.sqrt(3)
        position = N.c_[[0, 0, 1], [1, -1, 1], [1, 1, 1], [-1, 1, 1]]
        self._bund = RayBundle(position, dir)

        self.gm = FlatGeometryManager()
        self.prm = self.gm.find_intersections(N.eye(4), self._bund)

    def test_find_intersections(self):
        """The correct parametric locations are found for flat geometry"""
        self.failUnlessEqual(self.prm.shape, (4,),
            "Shape of parametric location array is wrong: " + \
            str(self.prm.shape))
        N.testing.assert_array_almost_equal(self.prm, N.sqrt(3))

    def test_get_normals(self):
        """A flat geometry manager returns parallel normals"""
        self.gm.select_rays(N.arange(4))
        n = self.gm.get_normals()
        N.testing.assert_array_equal(n, N.tile(N.c_[[0, 0, 1]], (1, 4)))

    def test_select_rays_normals(self):
        """Correct normals when some rays not selected"""
        self.gm.select_rays(N.r_[1, 3])
        n = self.gm.get_normals()
        N.testing.assert_array_equal(n, N.tile(N.c_[[0, 0, 1]], (1, 2)))

    def test_inters_points_global(self):
        """On the basic setup, a flat surface returns correct intersections"""
        correct_pts = N.zeros((3, 4))
        correct_pts[:2, 0] = 1

        self.gm.select_rays(N.arange(4))
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_equal(pts, correct_pts)

    def select_rays_inters(self):
        """Correct intersections when some rays not selected"""
        correct_pts = N.zeros((3, 2))
        correct_pts[:2, 0] = 1
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_equal(pts, correct_pts)
Ejemplo n.º 6
0
class TestFlatGeomManagerInterface(unittest.TestCase):
    def setUp(self):
        dir = N.c_[[1, 1, -1], [-1, 1, -1], [-1, -1, -1], [1, -1, -1]] / math.sqrt(3)
        position = N.c_[[0,0,1], [1,-1,1], [1,1,1], [-1,1,1]]
        self._bund = RayBundle(position, dir)

        self.gm = FlatGeometryManager()
        self.prm = self.gm.find_intersections(N.eye(4), self._bund)
        
    def test_find_intersections(self):
        """The correct parametric locations are found for flat geometry"""
        self.failUnlessEqual(self.prm.shape, (4,), 
            "Shape of parametric location array is wrong: " + \
            str(self.prm.shape))
        N.testing.assert_array_almost_equal(self.prm, N.sqrt(3))
    
    def test_get_normals(self):
        """A flat geometry manager returns parallel normals"""
        self.gm.select_rays(N.arange(4))
        n = self.gm.get_normals()
        N.testing.assert_array_equal(n, N.tile(N.c_[[0, 0, 1]], (1,4)))
        
    def test_select_rays_normals(self):
        """Correct normals when some rays not selected"""
        self.gm.select_rays(N.r_[1,3])
        n = self.gm.get_normals()
        N.testing.assert_array_equal(n, N.tile(N.c_[[0, 0, 1]], (1,2)))
    
    def test_inters_points_global(self):
        """On the basic setup, a flat surface returns correct intersections"""
        correct_pts = N.zeros((3,4))
        correct_pts[:2,0] = 1
        
        self.gm.select_rays(N.arange(4))
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_equal(pts, correct_pts)
        
    def select_rays_inters(self):
        """Correct intersections when some rays not selected"""
        correct_pts = N.zeros((3,2))
        correct_pts[:2,0] = 1
        pts = self.gm.get_intersection_points_global()
        N.testing.assert_array_equal(pts, correct_pts)