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

 .. default-domain:: cpp

 .. cpp:namespace:: ceres

 ====
 Why?
 ====
 .. _chapter-features:

 * **Code Quality** - Ceres Solver has been used in production at
   Google for more than four years now. It is clean, extensively tested
   and well documented code that is actively developed and supported.

 * **Modeling API** - It is rarely the case that one starts with the
   exact and complete formulation of the problem that one is trying to
   solve. Ceres's modeling API has been designed so that the user can
   easily build and modify the objective function, one term at a
   time. And to do so without worrying about how the solver is going to
   deal with the resulting changes in the sparsity/structure of the
   underlying problem.

   - **Derivatives** Supplying derivatives is perhaps the most tedious
     and error prone part of using an optimization library.  Ceres
     ships with `automatic`_ and `numeric`_ differentiation. So you
     never have to compute derivatives by hand (unless you really want
     to). Not only this, Ceres allows you to mix automatic, numeric and
     analytical derivatives in any combination that you want.

   - **Robust Loss Functions** Most non-linear least squares problems
     involve data. If there is data, there will be outliers. Ceres
     allows the user to *shape* their residuals using a
     :class:`LossFunction` to reduce the influence of outliers.

   - **Manifolds** In many cases, some parameters lie on a manifold
     other than Euclidean space, e.g., rotation matrices. In such
     cases, the user can specify the geometry of the local tangent
     space by specifying a :class:`Manifold` object.

 * **Solver Choice** Depending on the size, sparsity structure, time &
   memory budgets, and solution quality requirements, different
   optimization algorithms will suit different needs. To this end,
   Ceres Solver comes with a variety of optimization algorithms:

   - **Trust Region Solvers** - Ceres supports Levenberg-Marquardt,
     Powell's Dogleg, and Subspace dogleg methods. The key
     computational cost in all of these methods is the solution of a
     linear system. To this end Ceres ships with a variety of linear
     solvers - dense QR and dense Cholesky factorization (using
     `Eigen`_, `LAPACK`_ or `CUDA`_) for dense problems, sparse
     Cholesky factorization (`SuiteSparse`_, `Apple's Accelerate`_,
     `CXSparse`_ `Eigen`_) for large sparse problems, custom Schur
     complement based dense, sparse, and iterative linear solvers for
     `bundle adjustment`_ problems.

   - **Line Search Solvers** - When the problem size is so large that
     storing and factoring the Jacobian is not feasible or a low
     accuracy solution is required cheaply, Ceres offers a number of
     line search based algorithms. This includes a number of variants
     of Non-linear Conjugate Gradients, BFGS and LBFGS.

 * **Speed** - Ceres Solver has been extensively optimized, with C++
   templating, hand written linear algebra routines and OpenMP or
   modern C++ threads based multithreading of the Jacobian evaluation
   and the linear solvers.

 * **GPU Acceleration** If your system supports `CUDA`_ then Ceres
   Solver can use the Nvidia GPU on your system to speed up the solver.

 * **Solution Quality** Ceres is the `best performing`_ solver on the NIST
   problem set used by Mondragon and Borchers for benchmarking
   non-linear least squares solvers.

 * **Covariance estimation** - Evaluate the sensitivity/uncertainty of
   the solution by evaluating all or part of the covariance
   matrix. Ceres is one of the few solvers that allows you to do
   this analysis at scale.

 * **Community** Since its release as an open source software, Ceres
   has developed an active developer community that contributes new
   features, bug fixes and support.

 * **Portability** - Runs on *Linux*, *Windows*, *Mac OS X*, *Android*
   *and iOS*.

 * **BSD Licensed** The BSD license offers the flexibility to ship your
   application

 .. _best performing: https://groups.google.com/forum/#!topic/ceres-solver/UcicgMPgbXw
 .. _bundle adjustment: http://en.wikipedia.org/wiki/Bundle_adjustment
 .. _SuiteSparse: http://www.cise.ufl.edu/research/sparse/SuiteSparse/
 .. _Eigen: http://eigen.tuxfamily.org/
 .. _LAPACK: http://www.netlib.org/lapack/
 .. _CXSparse: https://www.cise.ufl.edu/research/sparse/CXSparse/
 .. _automatic: http://en.wikipedia.org/wiki/Automatic_differentiation
 .. _numeric: http://en.wikipedia.org/wiki/Numerical_differentiation
 .. _CUDA : https://developer.nvidia.com/cuda-toolkit
 .. _Apple's Accelerate: https://developer.apple.com/documentation/accelerate/sparse_solvers
	.. default-domain:: cpp

	.. cpp:namespace:: ceres

	====
	Why?
	====
	.. _chapter-features:

	* Code Quality - Ceres Solver has been used in production at
	Google for more than four years now. It is clean, extensively tested
	and well documented code that is actively developed and supported.

	* Modeling API - It is rarely the case that one starts with the
	exact and complete formulation of the problem that one is trying to
	solve. Ceres's modeling API has been designed so that the user can
	easily build and modify the objective function, one term at a
	time. And to do so without worrying about how the solver is going to
	deal with the resulting changes in the sparsity/structure of the
	underlying problem.

	- Derivatives Supplying derivatives is perhaps the most tedious
	and error prone part of using an optimization library. Ceres
	ships with `automatic`_ and `numeric`_ differentiation. So you
	never have to compute derivatives by hand (unless you really want
	to). Not only this, Ceres allows you to mix automatic, numeric and
	analytical derivatives in any combination that you want.

	- Robust Loss Functions Most non-linear least squares problems
	involve data. If there is data, there will be outliers. Ceres
	allows the user to shape their residuals using a
	:class:`LossFunction` to reduce the influence of outliers.

	- Manifolds In many cases, some parameters lie on a manifold
	other than Euclidean space, e.g., rotation matrices. In such
	cases, the user can specify the geometry of the local tangent
	space by specifying a :class:`Manifold` object.

	* Solver Choice Depending on the size, sparsity structure, time &
	memory budgets, and solution quality requirements, different
	optimization algorithms will suit different needs. To this end,
	Ceres Solver comes with a variety of optimization algorithms:

	- Trust Region Solvers - Ceres supports Levenberg-Marquardt,
	Powell's Dogleg, and Subspace dogleg methods. The key
	computational cost in all of these methods is the solution of a
	linear system. To this end Ceres ships with a variety of linear
	solvers - dense QR and dense Cholesky factorization (using
	`Eigen`_, `LAPACK`_ or `CUDA`_) for dense problems, sparse
	Cholesky factorization (`SuiteSparse`_, `Apple's Accelerate`_,
	`CXSparse`_ `Eigen`_) for large sparse problems, custom Schur
	complement based dense, sparse, and iterative linear solvers for
	`bundle adjustment`_ problems.

	- Line Search Solvers - When the problem size is so large that
	storing and factoring the Jacobian is not feasible or a low
	accuracy solution is required cheaply, Ceres offers a number of
	line search based algorithms. This includes a number of variants
	of Non-linear Conjugate Gradients, BFGS and LBFGS.

	* Speed - Ceres Solver has been extensively optimized, with C++
	templating, hand written linear algebra routines and OpenMP or
	modern C++ threads based multithreading of the Jacobian evaluation
	and the linear solvers.

	* GPU Acceleration If your system supports `CUDA`_ then Ceres
	Solver can use the Nvidia GPU on your system to speed up the solver.

	* Solution Quality Ceres is the `best performing`_ solver on the NIST
	problem set used by Mondragon and Borchers for benchmarking
	non-linear least squares solvers.

	* Covariance estimation - Evaluate the sensitivity/uncertainty of
	the solution by evaluating all or part of the covariance
	matrix. Ceres is one of the few solvers that allows you to do
	this analysis at scale.

	* Community Since its release as an open source software, Ceres
	has developed an active developer community that contributes new
	features, bug fixes and support.

	* Portability - Runs on Linux, Windows, Mac OS X, Android
	and iOS.

	* BSD Licensed The BSD license offers the flexibility to ship your
	application

	.. _best performing: https://groups.google.com/forum/#!topic/ceres-solver/UcicgMPgbXw
	.. _bundle adjustment: http://en.wikipedia.org/wiki/Bundle_adjustment
	.. _SuiteSparse: http://www.cise.ufl.edu/research/sparse/SuiteSparse/
	.. _Eigen: http://eigen.tuxfamily.org/
	.. _LAPACK: http://www.netlib.org/lapack/
	.. _CXSparse: https://www.cise.ufl.edu/research/sparse/CXSparse/
	.. _automatic: http://en.wikipedia.org/wiki/Automatic_differentiation
	.. _numeric: http://en.wikipedia.org/wiki/Numerical_differentiation
	.. _CUDA : https://developer.nvidia.com/cuda-toolkit
	.. _Apple's Accelerate: https://developer.apple.com/documentation/accelerate/sparse_solvers