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LocalizationExample.cpp
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LocalizationExample.cpp
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/* ----------------------------------------------------------------------------
* GTSAM Copyright 2010, Georgia Tech Research Corporation,
* Atlanta, Georgia 30332-0415
* All Rights Reserved
* Authors: Frank Dellaert, et al. (see THANKS for the full author list)
* See LICENSE for the license information
* -------------------------------------------------------------------------- */
/**
* @file LocalizationExample.cpp
* @brief Simple robot localization example, with three "GPS-like" measurements
* @author Frank Dellaert
*/
/**
* A simple 2D pose slam example with "GPS" measurements
* - The robot moves forward 2 meter each iteration
* - The robot initially faces along the X axis (horizontal, to the right in 2D)
* - We have full odometry between pose
* - We have "GPS-like" measurements implemented with a custom factor
*/
// We will use Pose2 variables (x, y, theta) to represent the robot positions
#include <gtsam/geometry/Pose2.h>
// We will use simple integer Keys to refer to the robot poses.
#include <gtsam/inference/Key.h>
// As in OdometryExample.cpp, we use a BetweenFactor to model odometry measurements.
#include <gtsam/slam/BetweenFactor.h>
// We add all facors to a Nonlinear Factor Graph, as our factors are nonlinear.
#include <gtsam/nonlinear/NonlinearFactorGraph.h>
// The nonlinear solvers within GTSAM are iterative solvers, meaning they linearize the
// nonlinear functions around an initial linearization point, then solve the linear system
// to update the linearization point. This happens repeatedly until the solver converges
// to a consistent set of variable values. This requires us to specify an initial guess
// for each variable, held in a Values container.
#include <gtsam/nonlinear/Values.h>
// Finally, once all of the factors have been added to our factor graph, we will want to
// solve/optimize to graph to find the best (Maximum A Posteriori) set of variable values.
// GTSAM includes several nonlinear optimizers to perform this step. Here we will use the
// standard Levenberg-Marquardt solver
#include <gtsam/nonlinear/LevenbergMarquardtOptimizer.h>
// Once the optimized values have been calculated, we can also calculate the marginal covariance
// of desired variables
#include <gtsam/nonlinear/Marginals.h>
using namespace std;
using namespace gtsam;
// Before we begin the example, we must create a custom unary factor to implement a
// "GPS-like" functionality. Because standard GPS measurements provide information
// only on the position, and not on the orientation, we cannot use a simple prior to
// properly model this measurement.
//
// The factor will be a unary factor, affect only a single system variable. It will
// also use a standard Gaussian noise model. Hence, we will derive our new factor from
// the NoiseModelFactor1.
#include <gtsam/nonlinear/NonlinearFactor.h>
class UnaryFactor: public NoiseModelFactor1<Pose2> {
// The factor will hold a measurement consisting of an (X,Y) location
// We could this with a Point2 but here we just use two doubles
double mx_, my_;
public:
/// shorthand for a smart pointer to a factor
typedef boost::shared_ptr<UnaryFactor> shared_ptr;
// The constructor requires the variable key, the (X, Y) measurement value, and the noise model
UnaryFactor(Key j, double x, double y, const SharedNoiseModel& model):
NoiseModelFactor1<Pose2>(model, j), mx_(x), my_(y) {}
virtual ~UnaryFactor() {}
// Using the NoiseModelFactor1 base class there are two functions that must be overridden.
// The first is the 'evaluateError' function. This function implements the desired measurement
// function, returning a vector of errors when evaluated at the provided variable value. It
// must also calculate the Jacobians for this measurement function, if requested.
Vector evaluateError(const Pose2& q, boost::optional<Matrix&> H = boost::none) const
{
// The measurement function for a GPS-like measurement is simple:
// error_x = pose.x - measurement.x
// error_y = pose.y - measurement.y
// Consequently, the Jacobians are:
// [ derror_x/dx derror_x/dy derror_x/dtheta ] = [1 0 0]
// [ derror_y/dx derror_y/dy derror_y/dtheta ] = [0 1 0]
if (H) (*H) = (Matrix(2,3) << 1.0,0.0,0.0, 0.0,1.0,0.0).finished();
return (Vector(2) << q.x() - mx_, q.y() - my_).finished();
}
// The second is a 'clone' function that allows the factor to be copied. Under most
// circumstances, the following code that employs the default copy constructor should
// work fine.
virtual gtsam::NonlinearFactor::shared_ptr clone() const {
return boost::static_pointer_cast<gtsam::NonlinearFactor>(
gtsam::NonlinearFactor::shared_ptr(new UnaryFactor(*this))); }
// Additionally, we encourage you the use of unit testing your custom factors,
// (as all GTSAM factors are), in which you would need an equals and print, to satisfy the
// GTSAM_CONCEPT_TESTABLE_INST(T) defined in Testable.h, but these are not needed below.
}; // UnaryFactor
int main(int argc, char** argv) {
// 1. Create a factor graph container and add factors to it
NonlinearFactorGraph graph;
// 2a. Add odometry factors
// For simplicity, we will use the same noise model for each odometry factor
noiseModel::Diagonal::shared_ptr odometryNoise = noiseModel::Diagonal::Sigmas(Vector3(0.2, 0.2, 0.1));
// Create odometry (Between) factors between consecutive poses
graph.emplace_shared<BetweenFactor<Pose2> >(1, 2, Pose2(2.0, 0.0, 0.0), odometryNoise);
graph.emplace_shared<BetweenFactor<Pose2> >(2, 3, Pose2(2.0, 0.0, 0.0), odometryNoise);
// 2b. Add "GPS-like" measurements
// We will use our custom UnaryFactor for this.
noiseModel::Diagonal::shared_ptr unaryNoise = noiseModel::Diagonal::Sigmas(Vector2(0.1, 0.1)); // 10cm std on x,y
graph.emplace_shared<UnaryFactor>(1, 0.0, 0.0, unaryNoise);
graph.emplace_shared<UnaryFactor>(2, 2.0, 0.0, unaryNoise);
graph.emplace_shared<UnaryFactor>(3, 4.0, 0.0, unaryNoise);
graph.print("\nFactor Graph:\n"); // print
// 3. Create the data structure to hold the initialEstimate estimate to the solution
// For illustrative purposes, these have been deliberately set to incorrect values
Values initialEstimate;
initialEstimate.insert(1, Pose2(0.5, 0.0, 0.2));
initialEstimate.insert(2, Pose2(2.3, 0.1, -0.2));
initialEstimate.insert(3, Pose2(4.1, 0.1, 0.1));
initialEstimate.print("\nInitial Estimate:\n"); // print
// 4. Optimize using Levenberg-Marquardt optimization. The optimizer
// accepts an optional set of configuration parameters, controlling
// things like convergence criteria, the type of linear system solver
// to use, and the amount of information displayed during optimization.
// Here we will use the default set of parameters. See the
// documentation for the full set of parameters.
LevenbergMarquardtOptimizer optimizer(graph, initialEstimate);
Values result = optimizer.optimize();
result.print("Final Result:\n");
// 5. Calculate and print marginal covariances for all variables
Marginals marginals(graph, result);
cout << "x1 covariance:\n" << marginals.marginalCovariance(1) << endl;
cout << "x2 covariance:\n" << marginals.marginalCovariance(2) << endl;
cout << "x3 covariance:\n" << marginals.marginalCovariance(3) << endl;
return 0;
}