Пример #1
0
    def reduce_(self):
        r"""Return a degree-reduced version of the current curve.

        .. _pseudo-inverse:
            https://en.wikipedia.org/wiki/Moore%E2%80%93Penrose_pseudoinverse

        Does this by converting the current nodes :math:`v_0, \ldots, v_n`
        to new nodes :math:`w_0, \ldots, w_{n - 1}` that correspond to
        reversing the :meth:`elevate` process.

        This uses the `pseudo-inverse`_ of the elevation matrix. For example
        when elevating from degree 2 to 3, the matrix :math:`E_2` is given by

        .. math::

           \mathbf{v} = \left[\begin{array}{c} v_0 \\ v_1 \\ v_2
               \end{array}\right] \longmapsto \left[\begin{array}{c} v_0 \\
               \frac{v_0 + 2 v_1}{3} \\ \frac{2 v_1 + v_2}{3} \\ v_2
               \end{array}\right] = \frac{1}{3}
               \left[\begin{array}{c c} 3 & 0 \\ 2 & 1 \\ 1 & 2
               \\ 0 & 3 \end{array}\right] \mathbf{v}

        and the pseudo-inverse is given by

        .. math::

           R_2 = \left(E_2^T E_2\right)^{-1} E_2^T = \frac{1}{20}
               \left[\begin{array}{c c c c} 19 & 3 & -3 & 1 \\
               -5 & 15 & 15 & -5 \\ 1 & -3 & 3 & 19
               \end{array}\right].

        .. warning::

           Though degree-elevation preserves the start and end nodes, degree
           reduction has no such guarantee. Rather, the nodes produced are
           "best" in the least squares sense (when solving the normal
           equations).

        .. image:: ../images/curve_reduce.png
           :align: center

        .. testsetup:: curve-reduce, curve-reduce-approx

           import numpy as np
           import bezier

        .. doctest:: curve-reduce
           :options: +NORMALIZE_WHITESPACE

           >>> nodes = np.asfortranarray([
           ...     [-3.0, 3.0],
           ...     [ 0.0, 2.0],
           ...     [ 1.0, 3.0],
           ...     [ 0.0, 6.0],
           ... ])
           >>> curve = bezier.Curve(nodes, degree=3)
           >>> reduced = curve.reduce_()
           >>> reduced
           <Curve (degree=2, dimension=2)>
           >>> reduced.nodes
           array([[-3. , 3. ],
                  [ 1.5, 1.5],
                  [ 0. , 6. ]])

        .. testcleanup:: curve-reduce

           import make_images
           make_images.curve_reduce(curve, reduced)

        In the case that the current curve **is not** degree-elevated.

        .. image:: ../images/curve_reduce_approx.png
           :align: center

        .. doctest:: curve-reduce-approx
           :options: +NORMALIZE_WHITESPACE

           >>> nodes = np.asfortranarray([
           ...     [0.0 , 2.5],
           ...     [1.25, 5.0],
           ...     [3.75, 7.5],
           ...     [5.0 , 2.5],
           ... ])
           >>> curve = bezier.Curve(nodes, degree=3)
           >>> reduced = curve.reduce_()
           >>> reduced
           <Curve (degree=2, dimension=2)>
           >>> reduced.nodes
           array([[-0.125, 2.125],
                  [ 2.5  , 8.125],
                  [ 5.125, 2.875]])

        .. testcleanup:: curve-reduce-approx

           import make_images
           make_images.curve_reduce_approx(curve, reduced)

        Returns:
            Curve: The degree-reduced curve.
        """
        new_nodes = _curve_helpers.reduce_pseudo_inverse(
            self._nodes, self._degree)
        root = None if self._root is self else self._root
        return Curve(new_nodes,
                     self._degree - 1,
                     start=self._start,
                     end=self._end,
                     root=root,
                     _copy=False)
Пример #2
0
    def _call_function_under_test(nodes, degree):
        from bezier import _curve_helpers

        return _curve_helpers.reduce_pseudo_inverse(nodes, degree)