docs/source/spivak_notation.rst - ceres-solver - Git at Google

 .. default-domain:: cpp

 .. cpp:namespace:: ceres

 .. _chapter-spivak_notation:

 ===============
 Spivak Notation
 ===============

 To preserve our collective sanities, we will use Spivak's notation for
 derivatives. It is a functional notation that makes reading and
 reasoning about expressions involving derivatives simple.

 For a univariate function :math:`f`, :math:`f(a)` denotes its value at
 :math:`a`. :math:`Df` denotes its first derivative, and
 :math:`Df(a)` is the derivative evaluated at :math:`a`, i.e

 .. math::
    Df(a) = \left . \frac{d}{dx} f(x) \right |_{x = a}

 :math:`D^kf` denotes the :math:`k^{\text{th}}` derivative of :math:`f`.

 For a bi-variate function :math:`g(x,y)`. :math:`D_1g` and
 :math:`D_2g` denote the partial derivatives of :math:`g` w.r.t the
 first and second variable respectively. In the classical notation this
 is equivalent to saying:

 .. math::

    D_1 g = \frac{\partial}{\partial x}g(x,y) \text{ and }  D_2 g  = \frac{\partial}{\partial y}g(x,y).


 :math:`Dg` denotes the Jacobian of `g`, i.e.,

 .. math::

   Dg = \begin{bmatrix} D_1g & D_2g \end{bmatrix}

 More generally for a multivariate function :math:`g:\mathbb{R}^n
 \longrightarrow \mathbb{R}^m`, :math:`Dg` denotes the :math:`m\times
 n` Jacobian matrix. :math:`D_i g` is the partial derivative of
 :math:`g` w.r.t the :math:`i^{\text{th}}` coordinate and the
 :math:`i^{\text{th}}` column of :math:`Dg`.

 Finally, :math:`D^2_1g` and :math:`D_1D_2g` have the obvious meaning
 as higher order partial derivatives.

 For more see Michael Spivak's book `Calculus on Manifolds
 <https://www.amazon.com/Calculus-Manifolds-Approach-Classical-Theorems/dp/0805390219>`_
 or a brief discussion of the `merits of this notation
 <http://www.vendian.org/mncharity/dir3/dxdoc/>`_ by
 Mitchell N. Charity.
	.. default-domain:: cpp

	.. cpp:namespace:: ceres

	.. _chapter-spivak_notation:

	===============
	Spivak Notation
	===============

	To preserve our collective sanities, we will use Spivak's notation for
	derivatives. It is a functional notation that makes reading and
	reasoning about expressions involving derivatives simple.

	For a univariate function :math:`f`, :math:`f(a)` denotes its value at
	:math:`a`. :math:`Df` denotes its first derivative, and
	:math:`Df(a)` is the derivative evaluated at :math:`a`, i.e

	.. math::
	Df(a) = \left . \frac{d}{dx} f(x) \right \|_{x = a}

	:math:`D^kf` denotes the :math:`k^{\text{th}}` derivative of :math:`f`.

	For a bi-variate function :math:`g(x,y)`. :math:`D_1g` and
	:math:`D_2g` denote the partial derivatives of :math:`g` w.r.t the
	first and second variable respectively. In the classical notation this
	is equivalent to saying:

	.. math::

	D_1 g = \frac{\partial}{\partial x}g(x,y) \text{ and } D_2 g = \frac{\partial}{\partial y}g(x,y).


	:math:`Dg` denotes the Jacobian of `g`, i.e.,

	.. math::

	Dg = \begin{bmatrix} D_1g & D_2g \end{bmatrix}

	More generally for a multivariate function :math:`g:\mathbb{R}^n
	\longrightarrow \mathbb{R}^m`, :math:`Dg` denotes the :math:`m\times
	n` Jacobian matrix. :math:`D_i g` is the partial derivative of
	:math:`g` w.r.t the :math:`i^{\text{th}}` coordinate and the
	:math:`i^{\text{th}}` column of :math:`Dg`.

	Finally, :math:`D^2_1g` and :math:`D_1D_2g` have the obvious meaning
	as higher order partial derivatives.

	For more see Michael Spivak's book `Calculus on Manifolds
	<https://www.amazon.com/Calculus-Manifolds-Approach-Classical-Theorems/dp/0805390219>`_
	or a brief discussion of the `merits of this notation
	<http://www.vendian.org/mncharity/dir3/dxdoc/>`_ by
	Mitchell N. Charity.