824 lines
33 KiB
ReStructuredText
824 lines
33 KiB
ReStructuredText
.. highlight:: c++
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.. default-domain:: cpp
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.. _chapter-nnls_tutorial:
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========================
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Non-linear Least Squares
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========================
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Introduction
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============
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Ceres can solve bounds constrained robustified non-linear least
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squares problems of the form
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.. math:: :label: ceresproblem
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\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) \\
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\text{s.t.} &\quad l_j \le x_j \le u_j
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Problems of this form comes up in a broad range of areas across
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science and engineering - from `fitting curves`_ in statistics, to
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constructing `3D models from photographs`_ in computer vision.
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.. _fitting curves: http://en.wikipedia.org/wiki/Nonlinear_regression
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.. _3D models from photographs: http://en.wikipedia.org/wiki/Bundle_adjustment
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In this chapter we will learn how to solve :eq:`ceresproblem` using
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Ceres Solver. Full working code for all the examples described in this
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chapter and more can be found in the `examples
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/>`_
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directory.
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The expression
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:math:`\rho_i\left(\left\|f_i\left(x_{i_1},...,x_{i_k}\right)\right\|^2\right)`
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is known as a ``ResidualBlock``, where :math:`f_i(\cdot)` is a
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:class:`CostFunction` that depends on the parameter blocks
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:math:`\left[x_{i_1},... , x_{i_k}\right]`. In most optimization
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problems small groups of scalars occur together. For example the three
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components of a translation vector and the four components of the
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quaternion that define the pose of a camera. We refer to such a group
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of small scalars as a ``ParameterBlock``. Of course a
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``ParameterBlock`` can just be a single parameter. :math:`l_j` and
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:math:`u_j` are bounds on the parameter block :math:`x_j`.
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:math:`\rho_i` is a :class:`LossFunction`. A :class:`LossFunction` is
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a scalar function that is used to reduce the influence of outliers on
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the solution of non-linear least squares problems.
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As a special case, when :math:`\rho_i(x) = x`, i.e., the identity
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function, and :math:`l_j = -\infty` and :math:`u_j = \infty` we get
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the more familiar `non-linear least squares problem
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<http://en.wikipedia.org/wiki/Non-linear_least_squares>`_.
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.. math:: \frac{1}{2}\sum_{i} \left\|f_i\left(x_{i_1}, ... ,x_{i_k}\right)\right\|^2.
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:label: ceresproblem2
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.. _section-hello-world:
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Hello World!
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============
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To get started, consider the problem of finding the minimum of the
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function
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.. math:: \frac{1}{2}(10 -x)^2.
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This is a trivial problem, whose minimum is located at :math:`x = 10`,
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but it is a good place to start to illustrate the basics of solving a
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problem with Ceres [#f1]_.
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The first step is to write a functor that will evaluate this the
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function :math:`f(x) = 10 - x`:
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.. code-block:: c++
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struct CostFunctor {
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template <typename T>
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bool operator()(const T* const x, T* residual) const {
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residual[0] = T(10.0) - x[0];
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return true;
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}
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};
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The important thing to note here is that ``operator()`` is a templated
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method, which assumes that all its inputs and outputs are of some type
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``T``. The use of templating here allows Ceres to call
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``CostFunctor::operator<T>()``, with ``T=double`` when just the value
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of the residual is needed, and with a special type ``T=Jet`` when the
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Jacobians are needed. In :ref:`section-derivatives` we will discuss the
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various ways of supplying derivatives to Ceres in more detail.
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Once we have a way of computing the residual function, it is now time
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to construct a non-linear least squares problem using it and have
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Ceres solve it.
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.. code-block:: c++
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int main(int argc, char** argv) {
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google::InitGoogleLogging(argv[0]);
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// The variable to solve for with its initial value.
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double initial_x = 5.0;
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double x = initial_x;
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// Build the problem.
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Problem problem;
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// Set up the only cost function (also known as residual). This uses
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// auto-differentiation to obtain the derivative (jacobian).
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CostFunction* cost_function =
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new AutoDiffCostFunction<CostFunctor, 1, 1>(new CostFunctor);
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problem.AddResidualBlock(cost_function, NULL, &x);
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// Run the solver!
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Solver::Options options;
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options.linear_solver_type = ceres::DENSE_QR;
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options.minimizer_progress_to_stdout = true;
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Solver::Summary summary;
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Solve(options, &problem, &summary);
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std::cout << summary.BriefReport() << "\n";
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std::cout << "x : " << initial_x
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<< " -> " << x << "\n";
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return 0;
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}
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:class:`AutoDiffCostFunction` takes a ``CostFunctor`` as input,
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automatically differentiates it and gives it a :class:`CostFunction`
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interface.
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Compiling and running `examples/helloworld.cc
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld.cc>`_
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gives us
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.. code-block:: bash
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iter cost cost_change |gradient| |step| tr_ratio tr_radius ls_iter iter_time total_time
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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
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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
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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
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Ceres Solver Report: Iterations: 2, Initial cost: 4.512500e+01, Final cost: 5.012552e-16, Termination: CONVERGENCE
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x : 0.5 -> 10
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Starting from a :math:`x=5`, the solver in two iterations goes to 10
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[#f2]_. The careful reader will note that this is a linear problem and
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one linear solve should be enough to get the optimal value. The
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default configuration of the solver is aimed at non-linear problems,
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and for reasons of simplicity we did not change it in this example. It
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is indeed possible to obtain the solution to this problem using Ceres
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in one iteration. Also note that the solver did get very close to the
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optimal function value of 0 in the very first iteration. We will
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discuss these issues in greater detail when we talk about convergence
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and parameter settings for Ceres.
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.. rubric:: Footnotes
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.. [#f1] `examples/helloworld.cc
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld.cc>`_
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.. [#f2] Actually the solver ran for three iterations, and it was
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by looking at the value returned by the linear solver in the third
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iteration, it observed that the update to the parameter block was too
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small and declared convergence. Ceres only prints out the display at
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the end of an iteration, and terminates as soon as it detects
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convergence, which is why you only see two iterations here and not
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three.
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.. _section-derivatives:
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Derivatives
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===========
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Ceres Solver like most optimization packages, depends on being able to
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evaluate the value and the derivatives of each term in the objective
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function at arbitrary parameter values. Doing so correctly and
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efficiently is essential to getting good results. Ceres Solver
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provides a number of ways of doing so. You have already seen one of
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them in action --
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Automatic Differentiation in `examples/helloworld.cc
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld.cc>`_
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We now consider the other two possibilities. Analytic and numeric
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derivatives.
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Numeric Derivatives
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-------------------
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In some cases, its not possible to define a templated cost functor,
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for example when the evaluation of the residual involves a call to a
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library function that you do not have control over. In such a
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situation, numerical differentiation can be used. The user defines a
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functor which computes the residual value and construct a
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:class:`NumericDiffCostFunction` using it. e.g., for :math:`f(x) = 10 - x`
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the corresponding functor would be
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.. code-block:: c++
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struct NumericDiffCostFunctor {
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bool operator()(const double* const x, double* residual) const {
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residual[0] = 10.0 - x[0];
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return true;
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}
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};
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Which is added to the :class:`Problem` as:
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.. code-block:: c++
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CostFunction* cost_function =
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new NumericDiffCostFunction<NumericDiffCostFunctor, ceres::CENTRAL, 1, 1, 1>(
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new NumericDiffCostFunctor)
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problem.AddResidualBlock(cost_function, NULL, &x);
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Notice the parallel from when we were using automatic differentiation
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.. code-block:: c++
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CostFunction* cost_function =
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new AutoDiffCostFunction<CostFunctor, 1, 1>(new CostFunctor);
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problem.AddResidualBlock(cost_function, NULL, &x);
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The construction looks almost identical to the one used for automatic
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differentiation, except for an extra template parameter that indicates
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the kind of finite differencing scheme to be used for computing the
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numerical derivatives [#f3]_. For more details see the documentation
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for :class:`NumericDiffCostFunction`.
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**Generally speaking we recommend automatic differentiation instead of
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numeric differentiation. The use of C++ templates makes automatic
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differentiation efficient, whereas numeric differentiation is
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expensive, prone to numeric errors, and leads to slower convergence.**
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Analytic Derivatives
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--------------------
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In some cases, using automatic differentiation is not possible. For
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example, it may be the case that it is more efficient to compute the
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derivatives in closed form instead of relying on the chain rule used
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by the automatic differentiation code.
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In such cases, it is possible to supply your own residual and jacobian
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computation code. To do this, define a subclass of
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:class:`CostFunction` or :class:`SizedCostFunction` if you know the
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sizes of the parameters and residuals at compile time. Here for
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example is ``SimpleCostFunction`` that implements :math:`f(x) = 10 -
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x`.
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.. code-block:: c++
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class QuadraticCostFunction : public ceres::SizedCostFunction<1, 1> {
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public:
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virtual ~QuadraticCostFunction() {}
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virtual bool Evaluate(double const* const* parameters,
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double* residuals,
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double** jacobians) const {
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const double x = parameters[0][0];
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residuals[0] = 10 - x;
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// Compute the Jacobian if asked for.
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if (jacobians != NULL && jacobians[0] != NULL) {
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jacobians[0][0] = -1;
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}
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return true;
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}
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};
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``SimpleCostFunction::Evaluate`` is provided with an input array of
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``parameters``, an output array ``residuals`` for residuals and an
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output array ``jacobians`` for Jacobians. The ``jacobians`` array is
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optional, ``Evaluate`` is expected to check when it is non-null, and
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if it is the case then fill it with the values of the derivative of
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the residual function. In this case since the residual function is
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linear, the Jacobian is constant [#f4]_ .
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As can be seen from the above code fragments, implementing
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:class:`CostFunction` objects is a bit tedious. We recommend that
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unless you have a good reason to manage the jacobian computation
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yourself, you use :class:`AutoDiffCostFunction` or
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:class:`NumericDiffCostFunction` to construct your residual blocks.
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More About Derivatives
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----------------------
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Computing derivatives is by far the most complicated part of using
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Ceres, and depending on the circumstance the user may need more
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sophisticated ways of computing derivatives. This section just
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scratches the surface of how derivatives can be supplied to
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Ceres. Once you are comfortable with using
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:class:`NumericDiffCostFunction` and :class:`AutoDiffCostFunction` we
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recommend taking a look at :class:`DynamicAutoDiffCostFunction`,
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:class:`CostFunctionToFunctor`, :class:`NumericDiffFunctor` and
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:class:`ConditionedCostFunction` for more advanced ways of
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constructing and computing cost functions.
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.. rubric:: Footnotes
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.. [#f3] `examples/helloworld_numeric_diff.cc
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld_numeric_diff.cc>`_.
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.. [#f4] `examples/helloworld_analytic_diff.cc
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/helloworld_analytic_diff.cc>`_.
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.. _section-powell:
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Powell's Function
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=================
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Consider now a slightly more complicated example -- the minimization
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of Powell's function. Let :math:`x = \left[x_1, x_2, x_3, x_4 \right]`
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and
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.. math::
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\begin{align}
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f_1(x) &= x_1 + 10x_2 \\
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f_2(x) &= \sqrt{5} (x_3 - x_4)\\
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f_3(x) &= (x_2 - 2x_3)^2\\
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f_4(x) &= \sqrt{10} (x_1 - x_4)^2\\
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F(x) &= \left[f_1(x),\ f_2(x),\ f_3(x),\ f_4(x) \right]
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\end{align}
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:math:`F(x)` is a function of four parameters, has four residuals
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and we wish to find :math:`x` such that :math:`\frac{1}{2}\|F(x)\|^2`
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is minimized.
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Again, the first step is to define functors that evaluate of the terms
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in the objective functor. Here is the code for evaluating
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:math:`f_4(x_1, x_4)`:
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.. code-block:: c++
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struct F4 {
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template <typename T>
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bool operator()(const T* const x1, const T* const x4, T* residual) const {
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residual[0] = T(sqrt(10.0)) * (x1[0] - x4[0]) * (x1[0] - x4[0]);
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return true;
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}
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};
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Similarly, we can define classes ``F1``, ``F2`` and ``F3`` to evaluate
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:math:`f_1(x_1, x_2)`, :math:`f_2(x_3, x_4)` and :math:`f_3(x_2, x_3)`
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respectively. Using these, the problem can be constructed as follows:
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.. code-block:: c++
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double x1 = 3.0; double x2 = -1.0; double x3 = 0.0; double x4 = 1.0;
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Problem problem;
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// Add residual terms to the problem using the using the autodiff
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// wrapper to get the derivatives automatically.
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problem.AddResidualBlock(
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new AutoDiffCostFunction<F1, 1, 1, 1>(new F1), NULL, &x1, &x2);
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problem.AddResidualBlock(
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new AutoDiffCostFunction<F2, 1, 1, 1>(new F2), NULL, &x3, &x4);
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problem.AddResidualBlock(
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new AutoDiffCostFunction<F3, 1, 1, 1>(new F3), NULL, &x2, &x3)
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problem.AddResidualBlock(
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new AutoDiffCostFunction<F4, 1, 1, 1>(new F4), NULL, &x1, &x4);
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Note that each ``ResidualBlock`` only depends on the two parameters
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that the corresponding residual object depends on and not on all four
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parameters. Compiling and running `examples/powell.cc
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<https://ceres-solver.googlesource.com/ceres-solver/+/master/examples/powell.cc>`_
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gives us:
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.. code-block:: bash
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Initial x1 = 3, x2 = -1, x3 = 0, x4 = 1
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iter cost cost_change |gradient| |step| tr_ratio tr_radius ls_iter iter_time total_time
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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
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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
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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
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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
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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
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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
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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
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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
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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
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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
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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
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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
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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
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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
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Ceres Solver v1.11.0 Solve Report
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----------------------------------
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Original Reduced
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Parameter blocks 4 4
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Parameters 4 4
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Residual blocks 4 4
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Residual 4 4
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Minimizer TRUST_REGION
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Dense linear algebra library EIGEN
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Trust region strategy LEVENBERG_MARQUARDT
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Given Used
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Linear solver DENSE_QR DENSE_QR
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Threads 1 1
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Linear solver threads 1 1
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Cost:
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Initial 1.075000e+02
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Final 1.791438e-14
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Change 1.075000e+02
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Minimizer iterations 14
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Successful steps 14
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Unsuccessful steps 0
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Time (in seconds):
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Preprocessor 0.002
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Residual evaluation 0.000
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Jacobian evaluation 0.000
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Linear solver 0.000
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Minimizer 0.001
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Postprocessor 0.000
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Total 0.005
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Termination: CONVERGENCE (Gradient tolerance reached. Gradient max norm: 3.642190e-11 <= 1.000000e-10)
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Final x1 = 0.000292189, x2 = -2.92189e-05, x3 = 4.79511e-05, x4 = 4.79511e-05
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It is easy to see that the optimal solution to this problem is at
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:math:`x_1=0, x_2=0, x_3=0, x_4=0` with an objective function value of
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:math:`0`. In 10 iterations, Ceres finds a solution with an objective
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|
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] = T(y_) - exp(m[0] * T(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, NULL, &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, NULL , &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 Rodriques' 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 = xp*xp + yp*yp;
|
|
T distortion = T(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,
|
|
NULL /* 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 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 :member:`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 local parameterizations 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.shtm>`_
|
|
non-linear regression problems.
|
|
|
|
#. `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.shtm>`_
|
|
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.
|