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

 .. _chapter-modeling_faqs:

 .. default-domain:: cpp

 .. cpp:namespace:: ceres

 ========
 Modeling
 ========

 #. Use analytical/automatic derivatives.

    This is the single most important piece of advice we can give to
    you. It is tempting to take the easy way out and use numeric
    differentiation. This is a bad idea. Numeric differentiation is
    slow, ill-behaved, hard to get right, and results in poor
    convergence behaviour.

    Ceres allows the user to define templated functors which will
    be automatically differentiated. For most situations this is enough
    and we recommend using this facility. In some cases the derivatives
    are simple enough or the performance considerations are such that
    the overhead of automatic differentiation is too much. In such
    cases, analytic derivatives are recommended.

    The use of numerical derivatives should be a measure of last
    resort, where it is simply not possible to write a templated
    implementation of the cost function.

    In many cases it is not possible to do analytic or automatic
    differentiation of the entire cost function, but it is generally
    the case that it is possible to decompose the cost function into
    parts that need to be numerically differentiated and parts that can
    be automatically or analytically differentiated.

    To this end, Ceres has extensive support for mixing analytic,
    automatic and numeric differentiation. See
    :class:`CostFunctionToFunctor`.

 #. When using Quaternions,  consider using :class:`QuaternionParameterization`.

    `Quaternions <https://en.wikipedia.org/wiki/Quaternion>`_ are a
    four dimensional parameterization of the space of three dimensional
    rotations :math:`SO(3)`.  However, the :math:`SO(3)` is a three
    dimensional set, and so is the tangent space of a
    Quaternion. Therefore, it is sometimes (not always) benefecial to
    associate a local parameterization with parameter blocks
    representing a Quaternion. Assuming that the order of entries in
    your parameter block is :math:`w,x,y,z`, you can use
    :class:`QuaternionParameterization`.

    .. NOTE::

      If you are using `Eigen's Quaternion
      <http://eigen.tuxfamily.org/dox/classEigen_1_1Quaternion.html>`_
      object, whose layout is :math:`x,y,z,w`, then you should use
      :class:`EigenQuaternionParameterization`.


 #. How do I solve problems with general linear & non-linear
    **inequality** constraints with Ceres Solver?

    Currently, Ceres Solver only supports upper and lower bounds
    constraints on the parameter blocks.

    A crude way of dealing with inequality constraints is have one or
    more of your cost functions check if the inequalities you are
    interested in are satisfied, and if not return false instead of
    true. This will prevent the solver from ever stepping into an
    infeasible region.

    This requires that the starting point for the optimization be a
    feasible point.  You also risk pre-mature convergence using this
    method.

 #. How do I solve problems with general linear & non-linear **equality**
    constraints with Ceres Solver?

    There is no built in support in ceres for solving problems with
    equality constraints.  Currently, Ceres Solver only supports upper
    and lower bounds constraints on the parameter blocks.

    The trick described above for dealing with inequality
    constraints will **not** work for equality constraints.

 #. How do I set one or more components of a parameter block constant?

    Using :class:`SubsetParameterization`.

 #. Putting `Inverse Function Theorem
    <http://en.wikipedia.org/wiki/Inverse_function_theorem>`_ to use.

    Every now and then we have to deal with functions which cannot be
    evaluated analytically. Computing the Jacobian in such cases is
    tricky. A particularly interesting case is where the inverse of the
    function is easy to compute analytically. An example of such a
    function is the Coordinate transformation between the `ECEF
    <http://en.wikipedia.org/wiki/ECEF>`_ and the `WGS84
    <http://en.wikipedia.org/wiki/World_Geodetic_System>`_ where the
    conversion from WGS84 to ECEF is analytic, but the conversion
    back to WGS84 uses an iterative algorithm. So how do you compute the
    derivative of the ECEF to WGS84 transformation?

    One obvious approach would be to numerically
    differentiate the conversion function. This is not a good idea. For
    one, it will be slow, but it will also be numerically quite
    bad.

    Turns out you can use the `Inverse Function Theorem
    <http://en.wikipedia.org/wiki/Inverse_function_theorem>`_ in this
    case to compute the derivatives more or less analytically.

    The key result here is. If :math:`x = f^{-1}(y)`, and :math:`Df(x)`
    is the invertible Jacobian of :math:`f` at :math:`x`. Then the
    Jacobian :math:`Df^{-1}(y) = [Df(x)]^{-1}`, i.e., the Jacobian of
    the :math:`f^{-1}` is the inverse of the Jacobian of :math:`f`.

    Algorithmically this means that given :math:`y`, compute :math:`x =
    f^{-1}(y)` by whatever means you can. Evaluate the Jacobian of
    :math:`f` at :math:`x`. If the Jacobian matrix is invertible, then
    its inverse is the Jacobian of :math:`f^{-1}(y)` at  :math:`y`.

    One can put this into practice with the following code fragment.

    .. code-block:: c++

       Eigen::Vector3d ecef; // Fill some values
       // Iterative computation.
       Eigen::Vector3d lla = ECEFToLLA(ecef);
       // Analytic derivatives
       Eigen::Matrix3d lla_to_ecef_jacobian = LLAToECEFJacobian(lla);
       bool invertible;
       Eigen::Matrix3d ecef_to_lla_jacobian;
       lla_to_ecef_jacobian.computeInverseWithCheck(ecef_to_lla_jacobian, invertible);
	.. _chapter-modeling_faqs:

	.. default-domain:: cpp

	.. cpp:namespace:: ceres

	========
	Modeling
	========

	#. Use analytical/automatic derivatives.

	This is the single most important piece of advice we can give to
	you. It is tempting to take the easy way out and use numeric
	differentiation. This is a bad idea. Numeric differentiation is
	slow, ill-behaved, hard to get right, and results in poor
	convergence behaviour.

	Ceres allows the user to define templated functors which will
	be automatically differentiated. For most situations this is enough
	and we recommend using this facility. In some cases the derivatives
	are simple enough or the performance considerations are such that
	the overhead of automatic differentiation is too much. In such
	cases, analytic derivatives are recommended.

	The use of numerical derivatives should be a measure of last
	resort, where it is simply not possible to write a templated
	implementation of the cost function.

	In many cases it is not possible to do analytic or automatic
	differentiation of the entire cost function, but it is generally
	the case that it is possible to decompose the cost function into
	parts that need to be numerically differentiated and parts that can
	be automatically or analytically differentiated.

	To this end, Ceres has extensive support for mixing analytic,
	automatic and numeric differentiation. See
	:class:`CostFunctionToFunctor`.

	#. When using Quaternions, consider using :class:`QuaternionParameterization`.

	`Quaternions <https://en.wikipedia.org/wiki/Quaternion>`_ are a
	four dimensional parameterization of the space of three dimensional
	rotations :math:`SO(3)`. However, the :math:`SO(3)` is a three
	dimensional set, and so is the tangent space of a
	Quaternion. Therefore, it is sometimes (not always) benefecial to
	associate a local parameterization with parameter blocks
	representing a Quaternion. Assuming that the order of entries in
	your parameter block is :math:`w,x,y,z`, you can use
	:class:`QuaternionParameterization`.

	.. NOTE::

	If you are using `Eigen's Quaternion
	<http://eigen.tuxfamily.org/dox/classEigen_1_1Quaternion.html>`_
	object, whose layout is :math:`x,y,z,w`, then you should use
	:class:`EigenQuaternionParameterization`.


	#. How do I solve problems with general linear & non-linear
	inequality constraints with Ceres Solver?

	Currently, Ceres Solver only supports upper and lower bounds
	constraints on the parameter blocks.

	A crude way of dealing with inequality constraints is have one or
	more of your cost functions check if the inequalities you are
	interested in are satisfied, and if not return false instead of
	true. This will prevent the solver from ever stepping into an
	infeasible region.

	This requires that the starting point for the optimization be a
	feasible point. You also risk pre-mature convergence using this
	method.

	#. How do I solve problems with general linear & non-linear equality
	constraints with Ceres Solver?

	There is no built in support in ceres for solving problems with
	equality constraints. Currently, Ceres Solver only supports upper
	and lower bounds constraints on the parameter blocks.

	The trick described above for dealing with inequality
	constraints will not work for equality constraints.

	#. How do I set one or more components of a parameter block constant?

	Using :class:`SubsetParameterization`.

	#. Putting `Inverse Function Theorem
	<http://en.wikipedia.org/wiki/Inverse_function_theorem>`_ to use.

	Every now and then we have to deal with functions which cannot be
	evaluated analytically. Computing the Jacobian in such cases is
	tricky. A particularly interesting case is where the inverse of the
	function is easy to compute analytically. An example of such a
	function is the Coordinate transformation between the `ECEF
	<http://en.wikipedia.org/wiki/ECEF>`_ and the `WGS84
	<http://en.wikipedia.org/wiki/World_Geodetic_System>`_ where the
	conversion from WGS84 to ECEF is analytic, but the conversion
	back to WGS84 uses an iterative algorithm. So how do you compute the
	derivative of the ECEF to WGS84 transformation?

	One obvious approach would be to numerically
	differentiate the conversion function. This is not a good idea. For
	one, it will be slow, but it will also be numerically quite
	bad.

	Turns out you can use the `Inverse Function Theorem
	<http://en.wikipedia.org/wiki/Inverse_function_theorem>`_ in this
	case to compute the derivatives more or less analytically.

	The key result here is. If :math:`x = f^{-1}(y)`, and :math:`Df(x)`
	is the invertible Jacobian of :math:`f` at :math:`x`. Then the
	Jacobian :math:`Df^{-1}(y) = [Df(x)]^{-1}`, i.e., the Jacobian of
	the :math:`f^{-1}` is the inverse of the Jacobian of :math:`f`.

	Algorithmically this means that given :math:`y`, compute :math:`x =
	f^{-1}(y)` by whatever means you can. Evaluate the Jacobian of
	:math:`f` at :math:`x`. If the Jacobian matrix is invertible, then
	its inverse is the Jacobian of :math:`f^{-1}(y)` at :math:`y`.

	One can put this into practice with the following code fragment.

	.. code-block:: c++

	Eigen::Vector3d ecef; // Fill some values
	// Iterative computation.
	Eigen::Vector3d lla = ECEFToLLA(ecef);
	// Analytic derivatives
	Eigen::Matrix3d lla_to_ecef_jacobian = LLAToECEFJacobian(lla);
	bool invertible;
	Eigen::Matrix3d ecef_to_lla_jacobian;
	lla_to_ecef_jacobian.computeInverseWithCheck(ecef_to_lla_jacobian, invertible);