예제 #1
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    def test_get_rotation_displacement(self):
        # 180 degrees around z moves both x and y components by the *length* * 2
        # Use a tiny value so the cross product is not zero
        d_0 = (-1, 1e-9, 0) * q.dimensionless
        d_1 = (1, 0, 0) * q.dimensionless
        length = 5 * q.m
        gt = np.array((length * 2, length * 2, 0)) * q.m

        displ = geom.get_rotation_displacement(d_0, d_1, length)
        np.testing.assert_almost_equal(gt, displ)

        # 90 degrees around z moves both x and y components by the *length* * sqrt(2)
        # and not *length*!
        d_0 = (1, 0, 0) * q.dimensionless
        d_1 = (0, 1, 0) * q.dimensionless
        length = 5 * q.m
        gt = np.array((length * np.sqrt(2), length * np.sqrt(2), 0)) * q.m

        displ = geom.get_rotation_displacement(d_0, d_1, length)
        np.testing.assert_almost_equal(gt, displ)
예제 #2
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    def test_get_rotation_displacement(self):
        # 180 degrees around z moves both x and y components by the *length* * 2
        # Use a tiny value so the cross product is not zero
        d_0 = (-1, 1e-9, 0) * q.dimensionless
        d_1 = (1, 0, 0) * q.dimensionless
        length = 5 * q.m
        gt = np.array((length * 2, length * 2, 0)) * q.m

        displ = geom.get_rotation_displacement(d_0, d_1, length)
        np.testing.assert_almost_equal(gt, displ)

        # 90 degrees around z moves both x and y components by the *length* * sqrt(2)
        # and not *length*!
        d_0 = (1, 0, 0) * q.dimensionless
        d_1 = (0, 1, 0) * q.dimensionless
        length = 5 * q.m
        gt = np.array((length * np.sqrt(2), length * np.sqrt(2), 0)) * q.m

        displ = geom.get_rotation_displacement(d_0, d_1, length)
        np.testing.assert_almost_equal(gt, displ)
예제 #3
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파일: base.py 프로젝트: ufo-kit/syris
    def get_distance(self, t_0, t_1):
        """Return the translational and rotational travelled distance in time interval
        *t_0*, *t_1*.
        """
        if not self.trajectory.bound:
            raise ValueError("Trajectory not bound")
        # Place the point for computing the derivative very close
        dt = (t_1 - t_0) * 1e-7

        def move_and_save(abs_time):
            """Move primitive bodies to time *abs_time* and return
            their positions.
            """
            primitive = self.primitive_bodies
            self.clear_transformation()
            self.move(abs_time)

            positions = np.zeros((len(primitive), 3))
            for i in range(len(primitive)):
                positions[i] = primitive[i].position.simplified.magnitude

            return positions

        self.save_transformation_matrices()
        p_0 = move_and_save(t_0)
        p_1 = move_and_save(t_1)
        if t_0 + dt < self.time:
            d_0 = move_and_save(t_0 + dt) - p_0
        else:
            d_0 = p_0 - move_and_save(t_0 - dt)
        if t_1 + dt < self.time:
            d_1 = move_and_save(t_1 + dt) - p_1
        else:
            d_1 = p_1 - move_and_save(t_1 - dt)
        self.restore_transformation_matrices()

        trans = np.abs(p_1 - p_0) * q.m

        rot = []
        for i in range(len(self.primitive_bodies)):
            rot.append(
                geom.get_rotation_displacement(
                    d_0[i], d_1[i], self.primitive_bodies[i].furthest_point.
                    simplified.magnitude))
        rot = np.array(rot) * q.m

        return np.max(trans) + np.max(rot)
예제 #4
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파일: base.py 프로젝트: ufo-kit/syris
    def get_distance(self, t_0, t_1):
        """Return the translational and rotational travelled distance in time interval
        *t_0*, *t_1*.
        """
        if not self.trajectory.bound:
            raise ValueError('Trajectory not bound')
        # Place the point for computing the derivative very close
        dt = (t_1 - t_0) * 1e-7

        def move_and_save(abs_time):
            """Move primitive bodies to time *abs_time* and return
            their positions.
            """
            primitive = self.primitive_bodies
            self.clear_transformation()
            self.move(abs_time)

            positions = np.zeros((len(primitive), 3))
            for i in range(len(primitive)):
                positions[i] = primitive[i].position.simplified.magnitude

            return positions

        self.save_transformation_matrices()
        p_0 = move_and_save(t_0)
        p_1 = move_and_save(t_1)
        if t_0 + dt < self.time:
            d_0 = move_and_save(t_0 + dt) - p_0
        else:
            d_0 = p_0 - move_and_save(t_0 - dt)
        if t_1 + dt < self.time:
            d_1 = move_and_save(t_1 + dt) - p_1
        else:
            d_1 = p_1 - move_and_save(t_1 - dt)
        self.restore_transformation_matrices()

        trans = np.abs(p_1 - p_0) * q.m

        rot = []
        for i in range(len(self.primitive_bodies)):
            rot.append(geom.get_rotation_displacement(d_0[i], d_1[i],
                                                      self.primitive_bodies[i].
                                                      furthest_point.simplified.magnitude))
        rot = np.array(rot) * q.m

        return np.max(trans) + np.max(rot)
예제 #5
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    def test_get_distances(self):
        """Compare analytically computed distances with the ones obtained from trajectory."""
        points = make_circle(n=128)
        x, y, z = zip(*points)
        furthest = 3 * q.mm
        ps = 10 * q.um
        tr = Trajectory(points, ps, furthest, velocity=1 * q.mm / q.s)

        d_points = np.abs(tr.points[:, 0][:, np.newaxis] - tr.points)
        t = np.linspace(0, 2 * np.pi, tr.points.shape[1])
        x, y, z = zip(*make_circle(n=tr.points.shape[1]))
        dx = -np.sin(t)
        dy = np.cos(t)
        dz = z
        derivatives = np.array(zip(dx, dy, dz)).T.copy()
        d_derivatives = get_rotation_displacement(derivatives[:, 0], derivatives, furthest)
        distances = (d_points + d_derivatives).simplified.magnitude

        np.testing.assert_almost_equal(distances, tr.get_distances())
예제 #6
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파일: base.py 프로젝트: ufo-kit/syris
    def moved(self, t_0, t_1, pixel_size, bind=True):
        """
        Return True if the body moves more than *pixel_size* in time interval *t_0*, *t_1*. If
        *bind* is True bind the trajectory to the specified *pixel_size*, otherwise use the
        trajectory as-is to compute an estimate.
        """
        if bind or not self.trajectory.bound:
            self.bind_trajectory(pixel_size)

        p_0 = self.trajectory.get_point(t_0)
        p_1 = self.trajectory.get_point(t_1)
        trans_displacement = np.abs(p_1 - p_0)

        d_0 = self.trajectory.get_direction(t_0, norm=False)
        d_1 = self.trajectory.get_direction(t_1, norm=False)
        rot_displacement = geom.get_rotation_displacement(d_0, d_1, self.furthest_point)
        total_displacement = trans_displacement + rot_displacement

        return max(total_displacement) > pixel_size
예제 #7
0
파일: base.py 프로젝트: ufo-kit/syris
    def moved(self, t_0, t_1, pixel_size, bind=True):
        """
        Return True if the body moves more than *pixel_size* in time interval *t_0*, *t_1*. If
        *bind* is True bind the trajectory to the specified *pixel_size*, otherwise use the
        trajectory as-is to compute an estimate.
        """
        if bind or not self.trajectory.bound:
            self.bind_trajectory(pixel_size)

        p_0 = self.trajectory.get_point(t_0)
        p_1 = self.trajectory.get_point(t_1)
        trans_displacement = np.abs(p_1 - p_0)

        d_0 = self.trajectory.get_direction(t_0, norm=False)
        d_1 = self.trajectory.get_direction(t_1, norm=False)
        rot_displacement = geom.get_rotation_displacement(
            d_0, d_1, self.furthest_point)
        total_displacement = trans_displacement + rot_displacement

        return max(total_displacement) > pixel_size
예제 #8
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    def test_get_distances(self):
        """Compare analytically computed distances with the ones obtained from trajectory."""
        points = make_circle(n=128)
        x, y, z = list(zip(*points))
        furthest = 3 * q.mm
        ps = 10 * q.um
        tr = Trajectory(points, ps, furthest, velocity=1 * q.mm / q.s)

        d_points = np.abs(tr.points[:, 0][:, np.newaxis] - tr.points)
        t = np.linspace(0, 2 * np.pi, tr.points.shape[1])
        x, y, z = list(zip(*make_circle(n=tr.points.shape[1])))
        dx = -np.sin(t)
        dy = np.cos(t)
        dz = z
        derivatives = np.array(list(zip(dx, dy, dz))).T.copy()
        d_derivatives = get_rotation_displacement(derivatives[:, 0],
                                                  derivatives, furthest)
        distances = (d_points + d_derivatives).simplified.magnitude

        np.testing.assert_almost_equal(distances, tr.get_distances())