ceres-solver

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	.. highlight:: c++

	.. default-domain:: cpp

	.. _chapter-nnls_tutorial:

	========================
	Non-linear Least Squares
	========================

	Introduction
	============

	Ceres can solve bounds constrained robustified non-linear least
	squares problems of the form

	.. math:: :label: ceresproblem

	\min_{\mathbf{x}} &\quad \frac{1}{2}\sum_{i} \rho_i\left(\left\\|f_i\left(x_{i_1}, ... ,x_{i_k}\right)\right\\|^2\right) \\
	\text{s.t.} &\quad l_j \le x_j \le u_j

	Problems of this form comes up in a broad range of areas across
	science and engineering - from `fitting curves`_ in statistics, to
	constructing `3D models from photographs`_ in computer vision.

	.. _fitting curves: http://en.wikipedia.org/wiki/Nonlinear_regression
	.. _3D models from photographs: http://en.wikipedia.org/wiki/Bundle_adjustment

	In this chapter we will learn how to solve :eq:`ceresproblem` using
	Ceres Solver. Full working code for all the examples described in this
	chapter and more can be found in the `examples
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/>`_
	directory.

	The expression
	:math:`\rho_i\left(\left\\|f_i\left(x_{i_1},...,x_{i_k}\right)\right\\|^2\right)`
	is known as a ``ResidualBlock``, where :math:`f_i(\cdot)` is a
	:class:`CostFunction` that depends on the parameter blocks
	:math:`\left[x_{i_1},... , x_{i_k}\right]`. In most optimization
	problems small groups of scalars occur together. For example the three
	components of a translation vector and the four components of the
	quaternion that define the pose of a camera. We refer to such a group
	of small scalars as a ``ParameterBlock``. Of course a
	``ParameterBlock`` can just be a single parameter. :math:`l_j` and
	:math:`u_j` are bounds on the parameter block :math:`x_j`.

	:math:`\rho_i` is a :class:`LossFunction`. A :class:`LossFunction` is
	a scalar function that is used to reduce the influence of outliers on
	the solution of non-linear least squares problems.

	As a special case, when :math:`\rho_i(x) = x`, i.e., the identity
	function, and :math:`l_j = -\infty` and :math:`u_j = \infty` we get
	the more familiar `non-linear least squares problem
	<http://en.wikipedia.org/wiki/Non-linear_least_squares>`_.

	.. math:: \frac{1}{2}\sum_{i} \left\\|f_i\left(x_{i_1}, ... ,x_{i_k}\right)\right\\|^2.
	:label: ceresproblemnonrobust

	.. _section-hello-world:

	Hello World!
	============

	To get started, consider the problem of finding the minimum of the
	function

	.. math:: \frac{1}{2}(10 -x)^2.

	This is a trivial problem, whose minimum is located at :math:`x = 10`,
	but it is a good place to start to illustrate the basics of solving a
	problem with Ceres [#f1]_.

	The first step is to write a functor that will evaluate this the
	function :math:`f(x) = 10 - x`:

	.. code-block:: c++

	struct CostFunctor {
	template <typename T>
	bool operator()(const T* const x, T* residual) const {
	residual[0] = 10.0 - x[0];
	return true;
	}
	};

	The important thing to note here is that ``operator()`` is a templated
	method, which assumes that all its inputs and outputs are of some type
	``T``. The use of templating here allows Ceres to call
	``CostFunctor::operator<T>()``, with ``T=double`` when just the value
	of the residual is needed, and with a special type ``T=Jet`` when the
	Jacobians are needed. In :ref:`section-derivatives` we will discuss the
	various ways of supplying derivatives to Ceres in more detail.

	Once we have a way of computing the residual function, it is now time
	to construct a non-linear least squares problem using it and have
	Ceres solve it.

	.. code-block:: c++

	int main(int argc, char** argv) {
	google::InitGoogleLogging(argv[0]);

	// The variable to solve for with its initial value.
	double initial_x = 5.0;
	double x = initial_x;

	// Build the problem.
	Problem problem;

	// Set up the only cost function (also known as residual). This uses
	// auto-differentiation to obtain the derivative (jacobian).
	CostFunction* cost_function =
	new AutoDiffCostFunction<CostFunctor, 1, 1>(new CostFunctor);
	problem.AddResidualBlock(cost_function, nullptr, &x);

	// Run the solver!
	Solver::Options options;
	options.linear_solver_type = ceres::DENSE_QR;
	options.minimizer_progress_to_stdout = true;
	Solver::Summary summary;
	Solve(options, &problem, &summary);

	std::cout << summary.BriefReport() << "\n";
	std::cout << "x : " << initial_x
	<< " -> " << x << "\n";
	return 0;
	}

	:class:`AutoDiffCostFunction` takes a ``CostFunctor`` as input,
	automatically differentiates it and gives it a :class:`CostFunction`
	interface.

	Compiling and running `examples/helloworld.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld.cc>`_
	gives us

	.. code-block:: bash

	iter cost cost_change \|gradient\| \|step\| tr_ratio tr_radius ls_iter iter_time total_time
	0 4.512500e+01 0.00e+00 9.50e+00 0.00e+00 0.00e+00 1.00e+04 0 5.33e-04 3.46e-03
	1 4.511598e-07 4.51e+01 9.50e-04 9.50e+00 1.00e+00 3.00e+04 1 5.00e-04 4.05e-03
	2 5.012552e-16 4.51e-07 3.17e-08 9.50e-04 1.00e+00 9.00e+04 1 1.60e-05 4.09e-03
	Ceres Solver Report: Iterations: 2, Initial cost: 4.512500e+01, Final cost: 5.012552e-16, Termination: CONVERGENCE
	x : 0.5 -> 10

	Starting from a :math:`x=5`, the solver in two iterations goes to 10
	[#f2]_. The careful reader will note that this is a linear problem and
	one linear solve should be enough to get the optimal value. The
	default configuration of the solver is aimed at non-linear problems,
	and for reasons of simplicity we did not change it in this example. It
	is indeed possible to obtain the solution to this problem using Ceres
	in one iteration. Also note that the solver did get very close to the
	optimal function value of 0 in the very first iteration. We will
	discuss these issues in greater detail when we talk about convergence
	and parameter settings for Ceres.

	.. rubric:: Footnotes

	.. [#f1] `examples/helloworld.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld.cc>`_
	.. [#f2] Actually the solver ran for three iterations, and it was
	by looking at the value returned by the linear solver in the third
	iteration, it observed that the update to the parameter block was too
	small and declared convergence. Ceres only prints out the display at
	the end of an iteration, and terminates as soon as it detects
	convergence, which is why you only see two iterations here and not
	three.

	.. _section-derivatives:


	Derivatives
	===========

	Ceres Solver like most optimization packages, depends on being able to
	evaluate the value and the derivatives of each term in the objective
	function at arbitrary parameter values. Doing so correctly and
	efficiently is essential to getting good results. Ceres Solver
	provides a number of ways of doing so. You have already seen one of
	them in action --
	Automatic Differentiation in `examples/helloworld.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld.cc>`_

	We now consider the other two possibilities. Analytic and numeric
	derivatives.


	Numeric Derivatives
	-------------------

	In some cases, its not possible to define a templated cost functor,
	for example when the evaluation of the residual involves a call to a
	library function that you do not have control over. In such a
	situation, numerical differentiation can be used. The user defines a
	functor which computes the residual value and construct a
	:class:`NumericDiffCostFunction` using it. e.g., for :math:`f(x) = 10 - x`
	the corresponding functor would be

	.. code-block:: c++

	struct NumericDiffCostFunctor {
	bool operator()(const double* const x, double* residual) const {
	residual[0] = 10.0 - x[0];
	return true;
	}
	};

	Which is added to the :class:`Problem` as:

	.. code-block:: c++

	CostFunction* cost_function =
	new NumericDiffCostFunction<NumericDiffCostFunctor, ceres::CENTRAL, 1, 1>(
	new NumericDiffCostFunctor);
	problem.AddResidualBlock(cost_function, nullptr, &x);

	Notice the parallel from when we were using automatic differentiation

	.. code-block:: c++

	CostFunction* cost_function =
	new AutoDiffCostFunction<CostFunctor, 1, 1>(new CostFunctor);
	problem.AddResidualBlock(cost_function, nullptr, &x);

	The construction looks almost identical to the one used for automatic
	differentiation, except for an extra template parameter that indicates
	the kind of finite differencing scheme to be used for computing the
	numerical derivatives [#f3]_. For more details see the documentation
	for :class:`NumericDiffCostFunction`.

	**Generally speaking we recommend automatic differentiation instead of
	numeric differentiation. The use of C++ templates makes automatic
	differentiation efficient, whereas numeric differentiation is
	expensive, prone to numeric errors, and leads to slower convergence.**


	Analytic Derivatives
	--------------------

	In some cases, using automatic differentiation is not possible. For
	example, it may be the case that it is more efficient to compute the
	derivatives in closed form instead of relying on the chain rule used
	by the automatic differentiation code.

	In such cases, it is possible to supply your own residual and jacobian
	computation code. To do this, define a subclass of
	:class:`CostFunction` or :class:`SizedCostFunction` if you know the
	sizes of the parameters and residuals at compile time. Here for
	example is ``SimpleCostFunction`` that implements :math:`f(x) = 10 -
	x`.

	.. code-block:: c++

	class QuadraticCostFunction : public ceres::SizedCostFunction<1, 1> {
	public:
	virtual ~QuadraticCostFunction() {}
	virtual bool Evaluate(double const* const* parameters,
	double* residuals,
	double** jacobians) const {
	const double x = parameters[0][0];
	residuals[0] = 10 - x;

	// Compute the Jacobian if asked for.
	if (jacobians != nullptr && jacobians[0] != nullptr) {
	jacobians[0][0] = -1;
	}
	return true;
	}
	};


	``SimpleCostFunction::Evaluate`` is provided with an input array of
	``parameters``, an output array ``residuals`` for residuals and an
	output array ``jacobians`` for Jacobians. The ``jacobians`` array is
	optional, ``Evaluate`` is expected to check when it is non-null, and
	if it is the case then fill it with the values of the derivative of
	the residual function. In this case since the residual function is
	linear, the Jacobian is constant [#f4]_ .

	As can be seen from the above code fragments, implementing
	:class:`CostFunction` objects is a bit tedious. We recommend that
	unless you have a good reason to manage the jacobian computation
	yourself, you use :class:`AutoDiffCostFunction` or
	:class:`NumericDiffCostFunction` to construct your residual blocks.

	More About Derivatives
	----------------------

	Computing derivatives is by far the most complicated part of using
	Ceres, and depending on the circumstance the user may need more
	sophisticated ways of computing derivatives. This section just
	scratches the surface of how derivatives can be supplied to
	Ceres. Once you are comfortable with using
	:class:`NumericDiffCostFunction` and :class:`AutoDiffCostFunction` we
	recommend taking a look at :class:`DynamicAutoDiffCostFunction`,
	:class:`CostFunctionToFunctor`, :class:`NumericDiffFunctor` and
	:class:`ConditionedCostFunction` for more advanced ways of
	constructing and computing cost functions.

	.. rubric:: Footnotes

	.. [#f3] `examples/helloworld_numeric_diff.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld_numeric_diff.cc>`_.
	.. [#f4] `examples/helloworld_analytic_diff.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld_analytic_diff.cc>`_.


	.. _section-powell:

	Powell's Function
	=================

	Consider now a slightly more complicated example -- the minimization
	of Powell's function. Let :math:`x = \left[x_1, x_2, x_3, x_4 \right]`
	and

	.. math::

	\begin{align}
	f_1(x) &= x_1 + 10x_2 \\
	f_2(x) &= \sqrt{5} (x_3 - x_4)\\
	f_3(x) &= (x_2 - 2x_3)^2\\
	f_4(x) &= \sqrt{10} (x_1 - x_4)^2\\
	F(x) &= \left[f_1(x),\ f_2(x),\ f_3(x),\ f_4(x) \right]
	\end{align}


	:math:`F(x)` is a function of four parameters, has four residuals
	and we wish to find :math:`x` such that :math:`\frac{1}{2}\\|F(x)\\|^2`
	is minimized.

	Again, the first step is to define functors that evaluate of the terms
	in the objective functor. Here is the code for evaluating
	:math:`f_4(x_1, x_4)`:

	.. code-block:: c++

	struct F4 {
	template <typename T>
	bool operator()(const T* const x1, const T* const x4, T* residual) const {
	residual[0] = sqrt(10.0) * (x1[0] - x4[0]) * (x1[0] - x4[0]);
	return true;
	}
	};


	Similarly, we can define classes ``F1``, ``F2`` and ``F3`` to evaluate
	:math:`f_1(x_1, x_2)`, :math:`f_2(x_3, x_4)` and :math:`f_3(x_2, x_3)`
	respectively. Using these, the problem can be constructed as follows:


	.. code-block:: c++

	double x1 = 3.0; double x2 = -1.0; double x3 = 0.0; double x4 = 1.0;

	Problem problem;

	// Add residual terms to the problem using the autodiff
	// wrapper to get the derivatives automatically.
	problem.AddResidualBlock(
	new AutoDiffCostFunction<F1, 1, 1, 1>(new F1), nullptr, &x1, &x2);
	problem.AddResidualBlock(
	new AutoDiffCostFunction<F2, 1, 1, 1>(new F2), nullptr, &x3, &x4);
	problem.AddResidualBlock(
	new AutoDiffCostFunction<F3, 1, 1, 1>(new F3), nullptr, &x2, &x3);
	problem.AddResidualBlock(
	new AutoDiffCostFunction<F4, 1, 1, 1>(new F4), nullptr, &x1, &x4);


	Note that each ``ResidualBlock`` only depends on the two parameters
	that the corresponding residual object depends on and not on all four
	parameters. Compiling and running `examples/powell.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/powell.cc>`_
	gives us:

	.. code-block:: bash

	Initial x1 = 3, x2 = -1, x3 = 0, x4 = 1
	iter cost cost_change \|gradient\| \|step\| tr_ratio tr_radius ls_iter iter_time total_time
	0 1.075000e+02 0.00e+00 1.55e+02 0.00e+00 0.00e+00 1.00e+04 0 4.95e-04 2.30e-03
	1 5.036190e+00 1.02e+02 2.00e+01 2.16e+00 9.53e-01 3.00e+04 1 4.39e-05 2.40e-03
	2 3.148168e-01 4.72e+00 2.50e+00 6.23e-01 9.37e-01 9.00e+04 1 9.06e-06 2.43e-03
	3 1.967760e-02 2.95e-01 3.13e-01 3.08e-01 9.37e-01 2.70e+05 1 8.11e-06 2.45e-03
	4 1.229900e-03 1.84e-02 3.91e-02 1.54e-01 9.37e-01 8.10e+05 1 6.91e-06 2.48e-03
	5 7.687123e-05 1.15e-03 4.89e-03 7.69e-02 9.37e-01 2.43e+06 1 7.87e-06 2.50e-03
	6 4.804625e-06 7.21e-05 6.11e-04 3.85e-02 9.37e-01 7.29e+06 1 5.96e-06 2.52e-03
	7 3.003028e-07 4.50e-06 7.64e-05 1.92e-02 9.37e-01 2.19e+07 1 5.96e-06 2.55e-03
	8 1.877006e-08 2.82e-07 9.54e-06 9.62e-03 9.37e-01 6.56e+07 1 5.96e-06 2.57e-03
	9 1.173223e-09 1.76e-08 1.19e-06 4.81e-03 9.37e-01 1.97e+08 1 7.87e-06 2.60e-03
	10 7.333425e-11 1.10e-09 1.49e-07 2.40e-03 9.37e-01 5.90e+08 1 6.20e-06 2.63e-03
	11 4.584044e-12 6.88e-11 1.86e-08 1.20e-03 9.37e-01 1.77e+09 1 6.91e-06 2.65e-03
	12 2.865573e-13 4.30e-12 2.33e-09 6.02e-04 9.37e-01 5.31e+09 1 5.96e-06 2.67e-03
	13 1.791438e-14 2.69e-13 2.91e-10 3.01e-04 9.37e-01 1.59e+10 1 7.15e-06 2.69e-03

	Ceres Solver v1.12.0 Solve Report
	----------------------------------
	Original Reduced
	Parameter blocks 4 4
	Parameters 4 4
	Residual blocks 4 4
	Residual 4 4

	Minimizer TRUST_REGION

	Dense linear algebra library EIGEN
	Trust region strategy LEVENBERG_MARQUARDT

	Given Used
	Linear solver DENSE_QR DENSE_QR
	Threads 1 1
	Linear solver threads 1 1

	Cost:
	Initial 1.075000e+02
	Final 1.791438e-14
	Change 1.075000e+02

	Minimizer iterations 14
	Successful steps 14
	Unsuccessful steps 0

	Time (in seconds):
	Preprocessor 0.002

	Residual evaluation 0.000
	Jacobian evaluation 0.000
	Linear solver 0.000
	Minimizer 0.001

	Postprocessor 0.000
	Total 0.005

	Termination: CONVERGENCE (Gradient tolerance reached. Gradient max norm: 3.642190e-11 <= 1.000000e-10)

	Final x1 = 0.000292189, x2 = -2.92189e-05, x3 = 4.79511e-05, x4 = 4.79511e-05

	It is easy to see that the optimal solution to this problem is at
	:math:`x_1=0, x_2=0, x_3=0, x_4=0` with an objective function value of
	:math:`0`. In 10 iterations, Ceres finds a solution with an objective
	function value of :math:`4\times 10^{-12}`.

	.. rubric:: Footnotes

	.. [#f5] `examples/powell.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/powell.cc>`_.


	.. _section-fitting:

	Curve Fitting
	=============

	The examples we have seen until now are simple optimization problems
	with no data. The original purpose of least squares and non-linear
	least squares analysis was fitting curves to data. It is only
	appropriate that we now consider an example of such a problem
	[#f6]_. It contains data generated by sampling the curve :math:`y =
	e^{0.3x + 0.1}` and adding Gaussian noise with standard deviation
	:math:`\sigma = 0.2`. Let us fit some data to the curve

	.. math:: y = e^{mx + c}.

	We begin by defining a templated object to evaluate the
	residual. There will be a residual for each observation.

	.. code-block:: c++

	struct ExponentialResidual {
	ExponentialResidual(double x, double y)
	: x_(x), y_(y) {}

	template <typename T>
	bool operator()(const T* const m, const T* const c, T* residual) const {
	residual[0] = y_ - exp(m[0] * x_ + c[0]);
	return true;
	}

	private:
	// Observations for a sample.
	const double x_;
	const double y_;
	};

	Assuming the observations are in a :math:`2n` sized array called
	``data`` the problem construction is a simple matter of creating a
	:class:`CostFunction` for every observation.


	.. code-block:: c++

	double m = 0.0;
	double c = 0.0;

	Problem problem;
	for (int i = 0; i < kNumObservations; ++i) {
	CostFunction* cost_function =
	new AutoDiffCostFunction<ExponentialResidual, 1, 1, 1>(
	new ExponentialResidual(data[2 * i], data[2 * i + 1]));
	problem.AddResidualBlock(cost_function, nullptr, &m, &c);
	}

	Compiling and running `examples/curve_fitting.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/curve_fitting.cc>`_
	gives us:

	.. code-block:: bash

	iter cost cost_change \|gradient\| \|step\| tr_ratio tr_radius ls_iter iter_time total_time
	0 1.211734e+02 0.00e+00 3.61e+02 0.00e+00 0.00e+00 1.00e+04 0 5.34e-04 2.56e-03
	1 1.211734e+02 -2.21e+03 0.00e+00 7.52e-01 -1.87e+01 5.00e+03 1 4.29e-05 3.25e-03
	2 1.211734e+02 -2.21e+03 0.00e+00 7.51e-01 -1.86e+01 1.25e+03 1 1.10e-05 3.28e-03
	3 1.211734e+02 -2.19e+03 0.00e+00 7.48e-01 -1.85e+01 1.56e+02 1 1.41e-05 3.31e-03
	4 1.211734e+02 -2.02e+03 0.00e+00 7.22e-01 -1.70e+01 9.77e+00 1 1.00e-05 3.34e-03
	5 1.211734e+02 -7.34e+02 0.00e+00 5.78e-01 -6.32e+00 3.05e-01 1 1.00e-05 3.36e-03
	6 3.306595e+01 8.81e+01 4.10e+02 3.18e-01 1.37e+00 9.16e-01 1 2.79e-05 3.41e-03
	7 6.426770e+00 2.66e+01 1.81e+02 1.29e-01 1.10e+00 2.75e+00 1 2.10e-05 3.45e-03
	8 3.344546e+00 3.08e+00 5.51e+01 3.05e-02 1.03e+00 8.24e+00 1 2.10e-05 3.48e-03
	9 1.987485e+00 1.36e+00 2.33e+01 8.87e-02 9.94e-01 2.47e+01 1 2.10e-05 3.52e-03
	10 1.211585e+00 7.76e-01 8.22e+00 1.05e-01 9.89e-01 7.42e+01 1 2.10e-05 3.56e-03
	11 1.063265e+00 1.48e-01 1.44e+00 6.06e-02 9.97e-01 2.22e+02 1 2.60e-05 3.61e-03
	12 1.056795e+00 6.47e-03 1.18e-01 1.47e-02 1.00e+00 6.67e+02 1 2.10e-05 3.64e-03
	13 1.056751e+00 4.39e-05 3.79e-03 1.28e-03 1.00e+00 2.00e+03 1 2.10e-05 3.68e-03
	Ceres Solver Report: Iterations: 13, Initial cost: 1.211734e+02, Final cost: 1.056751e+00, Termination: CONVERGENCE
	Initial m: 0 c: 0
	Final m: 0.291861 c: 0.131439

	Starting from parameter values :math:`m = 0, c=0` with an initial
	objective function value of :math:`121.173` Ceres finds a solution
	:math:`m= 0.291861, c = 0.131439` with an objective function value of
	:math:`1.05675`. These values are a bit different than the
	parameters of the original model :math:`m=0.3, c= 0.1`, but this is
	expected. When reconstructing a curve from noisy data, we expect to
	see such deviations. Indeed, if you were to evaluate the objective
	function for :math:`m=0.3, c=0.1`, the fit is worse with an objective
	function value of :math:`1.082425`. The figure below illustrates the fit.

	.. figure:: least_squares_fit.png
	:figwidth: 500px
	:height: 400px
	:align: center

	Least squares curve fitting.


	.. rubric:: Footnotes

	.. [#f6] `examples/curve_fitting.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/curve_fitting.cc>`_


	Robust Curve Fitting
	=====================

	Now suppose the data we are given has some outliers, i.e., we have
	some points that do not obey the noise model. If we were to use the
	code above to fit such data, we would get a fit that looks as
	below. Notice how the fitted curve deviates from the ground truth.

	.. figure:: non_robust_least_squares_fit.png
	:figwidth: 500px
	:height: 400px
	:align: center

	To deal with outliers, a standard technique is to use a
	:class:`LossFunction`. Loss functions reduce the influence of
	residual blocks with high residuals, usually the ones corresponding to
	outliers. To associate a loss function with a residual block, we change

	.. code-block:: c++

	problem.AddResidualBlock(cost_function, nullptr , &m, &c);

	to

	.. code-block:: c++

	problem.AddResidualBlock(cost_function, new CauchyLoss(0.5) , &m, &c);

	:class:`CauchyLoss` is one of the loss functions that ships with Ceres
	Solver. The argument :math:`0.5` specifies the scale of the loss
	function. As a result, we get the fit below [#f7]_. Notice how the
	fitted curve moves back closer to the ground truth curve.

	.. figure:: robust_least_squares_fit.png
	:figwidth: 500px
	:height: 400px
	:align: center

	Using :class:`LossFunction` to reduce the effect of outliers on a
	least squares fit.


	.. rubric:: Footnotes

	.. [#f7] `examples/robust_curve_fitting.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/robust_curve_fitting.cc>`_


	Bundle Adjustment
	=================

	One of the main reasons for writing Ceres was our need to solve large
	scale bundle adjustment problems [HartleyZisserman]_, [Triggs]_.

	Given a set of measured image feature locations and correspondences,
	the goal of bundle adjustment is to find 3D point positions and camera
	parameters that minimize the reprojection error. This optimization
	problem is usually formulated as a non-linear least squares problem,
	where the error is the squared :math:`L_2` norm of the difference between
	the observed feature location and the projection of the corresponding
	3D point on the image plane of the camera. Ceres has extensive support
	for solving bundle adjustment problems.

	Let us solve a problem from the `BAL
	<http://grail.cs.washington.edu/projects/bal/>`_ dataset [#f8]_.

	The first step as usual is to define a templated functor that computes
	the reprojection error/residual. The structure of the functor is
	similar to the ``ExponentialResidual``, in that there is an
	instance of this object responsible for each image observation.

	Each residual in a BAL problem depends on a three dimensional point
	and a nine parameter camera. The nine parameters defining the camera
	are: three for rotation as a Rodrigues' axis-angle vector, three
	for translation, one for focal length and two for radial distortion.
	The details of this camera model can be found the `Bundler homepage
	<http://phototour.cs.washington.edu/bundler/>`_ and the `BAL homepage
	<http://grail.cs.washington.edu/projects/bal/>`_.

	.. code-block:: c++

	struct SnavelyReprojectionError {
	SnavelyReprojectionError(double observed_x, double observed_y)
	: observed_x(observed_x), observed_y(observed_y) {}

	template <typename T>
	bool operator()(const T* const camera,
	const T* const point,
	T* residuals) const {
	// camera[0,1,2] are the angle-axis rotation.
	T p[3];
	ceres::AngleAxisRotatePoint(camera, point, p);
	// camera[3,4,5] are the translation.
	p[0] += camera[3]; p[1] += camera[4]; p[2] += camera[5];

	// Compute the center of distortion. The sign change comes from
	// the camera model that Noah Snavely's Bundler assumes, whereby
	// the camera coordinate system has a negative z axis.
	T xp = - p[0] / p[2];
	T yp = - p[1] / p[2];

	// Apply second and fourth order radial distortion.
	const T& l1 = camera[7];
	const T& l2 = camera[8];
	T r2 = xpxp + ypyp;
	T distortion = 1.0 + r2 * (l1 + l2 * r2);

	// Compute final projected point position.
	const T& focal = camera[6];
	T predicted_x = focal * distortion * xp;
	T predicted_y = focal * distortion * yp;

	// The error is the difference between the predicted and observed position.
	residuals[0] = predicted_x - T(observed_x);
	residuals[1] = predicted_y - T(observed_y);
	return true;
	}

	// Factory to hide the construction of the CostFunction object from
	// the client code.
	static ceres::CostFunction* Create(const double observed_x,
	const double observed_y) {
	return (new ceres::AutoDiffCostFunction<SnavelyReprojectionError, 2, 9, 3>(
	new SnavelyReprojectionError(observed_x, observed_y)));
	}

	double observed_x;
	double observed_y;
	};


	Note that unlike the examples before, this is a non-trivial function
	and computing its analytic Jacobian is a bit of a pain. Automatic
	differentiation makes life much simpler. The function
	:func:`AngleAxisRotatePoint` and other functions for manipulating
	rotations can be found in ``include/ceres/rotation.h``.

	Given this functor, the bundle adjustment problem can be constructed
	as follows:

	.. code-block:: c++

	ceres::Problem problem;
	for (int i = 0; i < bal_problem.num_observations(); ++i) {
	ceres::CostFunction* cost_function =
	SnavelyReprojectionError::Create(
	bal_problem.observations()[2 * i + 0],
	bal_problem.observations()[2 * i + 1]);
	problem.AddResidualBlock(cost_function,
	nullptr /* squared loss */,
	bal_problem.mutable_camera_for_observation(i),
	bal_problem.mutable_point_for_observation(i));
	}


	Notice that the problem construction for bundle adjustment is very
	similar to the curve fitting example -- one term is added to the
	objective function per observation.

	Since this is a large sparse problem (well large for ``DENSE_QR``
	anyways), one way to solve this problem is to set
	:member:`Solver::Options::linear_solver_type` to
	``SPARSE_NORMAL_CHOLESKY`` and call :func:`Solve`. And while this is
	a reasonable thing to do, bundle adjustment problems have a special
	sparsity structure that can be exploited to solve them much more
	efficiently. Ceres provides three specialized solvers (collectively
	known as Schur-based solvers) for this task. The example code uses the
	simplest of them ``DENSE_SCHUR``.

	.. code-block:: c++

	ceres::Solver::Options options;
	options.linear_solver_type = ceres::DENSE_SCHUR;
	options.minimizer_progress_to_stdout = true;
	ceres::Solver::Summary summary;
	ceres::Solve(options, &problem, &summary);
	std::cout << summary.FullReport() << "\n";

	For a more sophisticated bundle adjustment example which demonstrates
	the use of Ceres' more advanced features including its various linear
	solvers, robust loss functions and manifolds see
	`examples/bundle_adjuster.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/bundle_adjuster.cc>`_


	.. rubric:: Footnotes

	.. [#f8] `examples/simple_bundle_adjuster.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/simple_bundle_adjuster.cc>`_

	Other Examples
	==============

	Besides the examples in this chapter, the `example
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/>`_
	directory contains a number of other examples:

	#. `bundle_adjuster.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/bundle_adjuster.cc>`_
	shows how to use the various features of Ceres to solve bundle
	adjustment problems.

	#. `circle_fit.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/circle_fit.cc>`_
	shows how to fit data to a circle.

	#. `ellipse_approximation.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/ellipse_approximation.cc>`_
	fits points randomly distributed on an ellipse with an approximate
	line segment contour. This is done by jointly optimizing the
	control points of the line segment contour along with the preimage
	positions for the data points. The purpose of this example is to
	show an example use case for ``Solver::Options::dynamic_sparsity``,
	and how it can benefit problems which are numerically dense but
	dynamically sparse.

	#. `denoising.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/denoising.cc>`_
	implements image denoising using the `Fields of Experts
	<http://www.gris.informatik.tu-darmstadt.de/~sroth/research/foe/index.html>`_
	model.

	#. `nist.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/nist.cc>`_
	implements and attempts to solves the `NIST
	<http://www.itl.nist.gov/div898/strd/nls/nls_main.shtml>`_
	non-linear regression problems.

	#. `more_garbow_hillstrom.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/more_garbow_hillstrom.cc>`_
	A subset of the test problems from the paper

	Testing Unconstrained Optimization Software
	Jorge J. More, Burton S. Garbow and Kenneth E. Hillstrom
	ACM Transactions on Mathematical Software, 7(1), pp. 17-41, 1981

	which were augmented with bounds and used for testing bounds
	constrained optimization algorithms by

	A Trust Region Approach to Linearly Constrained Optimization
	David M. Gay
	Numerical Analysis (Griffiths, D.F., ed.), pp. 72-105
	Lecture Notes in Mathematics 1066, Springer Verlag, 1984.


	#. `libmv_bundle_adjuster.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/libmv_bundle_adjuster.cc>`_
	is the bundle adjustment algorithm used by `Blender <www.blender.org>`_/libmv.

	#. `libmv_homography.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/libmv_homography.cc>`_
	This file demonstrates solving for a homography between two sets of
	points and using a custom exit criterion by having a callback check
	for image-space error.

	#. `robot_pose_mle.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/robot_pose_mle.cc>`_
	This example demonstrates how to use the ``DynamicAutoDiffCostFunction``
	variant of CostFunction. The ``DynamicAutoDiffCostFunction`` is meant to
	be used in cases where the number of parameter blocks or the sizes are not
	known at compile time.

	This example simulates a robot traversing down a 1-dimension hallway with
	noise odometry readings and noisy range readings of the end of the hallway.
	By fusing the noisy odometry and sensor readings this example demonstrates
	how to compute the maximum likelihood estimate (MLE) of the robot's pose at
	each timestep.

	#. `slam/pose_graph_2d/pose_graph_2d.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/slam/pose_graph_2d/pose_graph_2d.cc>`_
	The Simultaneous Localization and Mapping (SLAM) problem consists of building
	a map of an unknown environment while simultaneously localizing against this
	map. The main difficulty of this problem stems from not having any additional
	external aiding information such as GPS. SLAM has been considered one of the
	fundamental challenges of robotics. There are many resources on SLAM
	[#f9]_. A pose graph optimization problem is one example of a SLAM
	problem. The following explains how to formulate the pose graph based SLAM
	problem in 2-Dimensions with relative pose constraints.

	Consider a robot moving in a 2-Dimensional plane. The robot has access to a
	set of sensors such as wheel odometry or a laser range scanner. From these
	raw measurements, we want to estimate the trajectory of the robot as well as
	build a map of the environment. In order to reduce the computational
	complexity of the problem, the pose graph approach abstracts the raw
	measurements away. Specifically, it creates a graph of nodes which represent
	the pose of the robot, and edges which represent the relative transformation
	(delta position and orientation) between the two nodes. The edges are virtual
	measurements derived from the raw sensor measurements, e.g. by integrating
	the raw wheel odometry or aligning the laser range scans acquired from the
	robot. A visualization of the resulting graph is shown below.

	.. figure:: slam2d.png
	:figwidth: 500px
	:height: 400px
	:align: center

	Visual representation of a graph SLAM problem.

	The figure depicts the pose of the robot as the triangles, the measurements
	are indicated by the connecting lines, and the loop closure measurements are
	shown as dotted lines. Loop closures are measurements between non-sequential
	robot states and they reduce the accumulation of error over time. The
	following will describe the mathematical formulation of the pose graph
	problem.

	The robot at timestamp :math:`t` has state :math:`x_t = [p^T, \psi]^T` where
	:math:`p` is a 2D vector that represents the position in the plane and
	:math:`\psi` is the orientation in radians. The measurement of the relative
	transform between the robot state at two timestamps :math:`a` and :math:`b`
	is given as: :math:`z_{ab} = [\hat{p}_{ab}^T, \hat{\psi}_{ab}]`. The residual
	implemented in the Ceres cost function which computes the error between the
	measurement and the predicted measurement is:

	.. math:: r_{ab} =
	\left[
	\begin{array}{c}
	R_a^T\left(p_b - p_a\right) - \hat{p}_{ab} \\
	\mathrm{Normalize}\left(\psi_b - \psi_a - \hat{\psi}_{ab}\right)
	\end{array}
	\right]

	where the function :math:`\mathrm{Normalize}()` normalizes the angle in the range
	:math:`[-\pi,\pi)`, and :math:`R` is the rotation matrix given by

	.. math:: R_a =
	\left[
	\begin{array}{cc}
	\cos \psi_a & -\sin \psi_a \\
	\sin \psi_a & \cos \psi_a \\
	\end{array}
	\right]

	To finish the cost function, we need to weight the residual by the
	uncertainty of the measurement. Hence, we pre-multiply the residual by the
	inverse square root of the covariance matrix for the measurement,
	i.e. :math:`\Sigma_{ab}^{-\frac{1}{2}} r_{ab}` where :math:`\Sigma_{ab}` is
	the covariance.

	Lastly, we use a manifold to normalize the orientation in the range
	:math:`[-\pi,\pi)`. Specially, we define the
	:member:`AngleManifold::Plus()` function to be:
	:math:`\mathrm{Normalize}(\psi + \Delta)` and
	::member::`AngleManifold::Minus()` function to be
	:math:`\mathrm{Normalize}(y) - \mathrm{Normalize}(x)`.

	This package includes an executable :member:`pose_graph_2d` that will read a
	problem definition file. This executable can work with any 2D problem
	definition that uses the g2o format. It would be relatively straightforward
	to implement a new reader for a different format such as TORO or
	others. :member:`pose_graph_2d` will print the Ceres solver full summary and
	then output to disk the original and optimized poses (``poses_original.txt``
	and ``poses_optimized.txt``, respectively) of the robot in the following
	format:

	.. code-block:: bash

	pose_id x y yaw_radians
	pose_id x y yaw_radians
	pose_id x y yaw_radians

	where ``pose_id`` is the corresponding integer ID from the file
	definition. Note, the file will be sorted in ascending order for the
	``pose_id``.

	The executable :member:`pose_graph_2d` expects the first argument to be
	the path to the problem definition. To run the executable,

	.. code-block:: bash

	/path/to/bin/pose_graph_2d /path/to/dataset/dataset.g2o

	A python script is provided to visualize the resulting output files.

	.. code-block:: bash

	/path/to/repo/examples/slam/pose_graph_2d/plot_results.py --optimized_poses ./poses_optimized.txt --initial_poses ./poses_original.txt

	As an example, a standard synthetic benchmark dataset [#f10]_ created by
	Edwin Olson which has 3500 nodes in a grid world with a total of 5598 edges
	was solved. Visualizing the results with the provided script produces:

	.. figure:: manhattan_olson_3500_result.png
	:figwidth: 600px
	:height: 600px
	:align: center

	with the original poses in green and the optimized poses in blue. As shown,
	the optimized poses more closely match the underlying grid world. Note, the
	left side of the graph has a small yaw drift due to a lack of relative
	constraints to provide enough information to reconstruct the trajectory.

	.. rubric:: Footnotes

	.. [#f9] Giorgio Grisetti, Rainer Kummerle, Cyrill Stachniss, Wolfram
	Burgard. A Tutorial on Graph-Based SLAM. IEEE Intelligent Transportation
	Systems Magazine, 52(3):199-222, 2010.

	.. [#f10] E. Olson, J. Leonard, and S. Teller, “Fast iterative optimization of
	pose graphs with poor initial estimates,” in Robotics and Automation
	(ICRA), IEEE International Conference on, 2006, pp. 2262-2269.

	#. `slam/pose_graph_3d/pose_graph_3d.cc
	<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/slam/pose_graph_3d/pose_graph_3d.cc>`_
	The following explains how to formulate the pose graph based SLAM problem in
	3-Dimensions with relative pose constraints. The example also illustrates how
	to use Eigen's geometry module with Ceres's automatic differentiation
	functionality.

	The robot at timestamp :math:`t` has state :math:`x_t = [p^T, q^T]^T` where
	:math:`p` is a 3D vector that represents the position and :math:`q` is the
	orientation represented as an Eigen quaternion. The measurement of the
	relative transform between the robot state at two timestamps :math:`a` and
	:math:`b` is given as: :math:`z_{ab} = [\hat{p}_{ab}^T, \hat{q}_{ab}^T]^T`.
	The residual implemented in the Ceres cost function which computes the error
	between the measurement and the predicted measurement is:

	.. math:: r_{ab} =
	\left[
	\begin{array}{c}
	R(q_a)^{T} (p_b - p_a) - \hat{p}_{ab} \\
	2.0 \mathrm{vec}\left((q_a^{-1} q_b) \hat{q}_{ab}^{-1}\right)
	\end{array}
	\right]

	where the function :math:`\mathrm{vec}()` returns the vector part of the
	quaternion, i.e. :math:`[q_x, q_y, q_z]`, and :math:`R(q)` is the rotation
	matrix for the quaternion.

	To finish the cost function, we need to weight the residual by the
	uncertainty of the measurement. Hence, we pre-multiply the residual by the
	inverse square root of the covariance matrix for the measurement,
	i.e. :math:`\Sigma_{ab}^{-\frac{1}{2}} r_{ab}` where :math:`\Sigma_{ab}` is
	the covariance.

	Given that we are using a quaternion to represent the orientation,
	we need to use a manifold (:class:`EigenQuaternionManifold`) to
	only apply updates orthogonal to the 4-vector defining the
	quaternion. Eigen's quaternion uses a different internal memory
	layout for the elements of the quaternion than what is commonly
	used. Specifically, Eigen stores the elements in memory as
	:math:`[x, y, z, w]` where the real part is last whereas it is
	typically stored first. Note, when creating an Eigen quaternion
	through the constructor the elements are accepted in :math:`w`,
	:math:`x`, :math:`y`, :math:`z` order. Since Ceres operates on
	parameter blocks which are raw double pointers this difference is
	important and requires a different parameterization.

	This package includes an executable :member:`pose_graph_3d` that will read a
	problem definition file. This executable can work with any 3D problem
	definition that uses the g2o format with quaternions used for the orientation
	representation. It would be relatively straightforward to implement a new
	reader for a different format such as TORO or others. :member:`pose_graph_3d`
	will print the Ceres solver full summary and then output to disk the original
	and optimized poses (``poses_original.txt`` and ``poses_optimized.txt``,
	respectively) of the robot in the following format:

	.. code-block:: bash

	pose_id x y z q_x q_y q_z q_w
	pose_id x y z q_x q_y q_z q_w
	pose_id x y z q_x q_y q_z q_w
	...

	where ``pose_id`` is the corresponding integer ID from the file
	definition. Note, the file will be sorted in ascending order for the
	``pose_id``.

	The executable :member:`pose_graph_3d` expects the first argument to be the
	path to the problem definition. The executable can be run via

	.. code-block:: bash

	/path/to/bin/pose_graph_3d /path/to/dataset/dataset.g2o

	A script is provided to visualize the resulting output files. There is also
	an option to enable equal axes using ``--axes_equal``

	.. code-block:: bash

	/path/to/repo/examples/slam/pose_graph_3d/plot_results.py --optimized_poses ./poses_optimized.txt --initial_poses ./poses_original.txt

	As an example, a standard synthetic benchmark dataset [#f9]_ where the robot is
	traveling on the surface of a sphere which has 2500 nodes with a total of
	4949 edges was solved. Visualizing the results with the provided script
	produces:

	.. figure:: pose_graph_3d_ex.png
	:figwidth: 600px
	:height: 300px
	:align: center