rolling shutter projection factor

2021-04-22 08:52:28 +03:00 · 2021-04-22 08:52:28 +03:00 · d4eaa15280
parent 301f7fe1a3
commit d4eaa15280
4 changed files with 250 additions and 4 deletions
--- a/gtsam/base/Lie.h
+++ b/gtsam/base/Lie.h
@ -319,11 +319,30 @@ T expm(const Vector& x, int K=7) {
 }
 /**
- * Linear interpolation between X and Y by coefficient t in [0, 1].
+ * Linear interpolation and some extrapolation between X and Y by coefficient t in [0, 1.5], optinal jacobians calculations.
 */
-template <typename T>
+template <typename T, int N>
-T interpolate(const T& X, const T& Y, double t) {
+T interpolate(const T& X, const T& Y, double t, OptionalJacobian<N, N> Hx = boost::none, OptionalJacobian<N, N> Hy = boost::none) {
-  assert(t >= 0 && t <= 1);
+  assert(t >= 0 && t <= 1.5);
  if (Hx && Hy) {
    typedef Eigen::Matrix<double, N, N> Jacobian;
    typename traits<T>::TangentVector tres;
    T tres1;
    Jacobian d1;
    Jacobian d2;
    tres1 = traits<T>::Between(X, Y, Hx, Hy);
    tres = traits<T>::Logmap(tres1, d1);
    *Hx = d1 * (*Hx);
    *Hy = d1 * (*Hy);
    tres1 = traits<T>::Expmap(t * tres, d1);
    *Hx = t * d1 * (*Hx);
    *Hy = t * d1 * (*Hy);
    tres1 = traits<T>::Compose(X, tres1, d1, d2);
    *Hx = d1 + d2 * (*Hx);
    *Hy = d2 * (*Hy);
    return tres1;
  }
  return traits<T>::Compose(X, traits<T>::Expmap(t * traits<T>::Logmap(traits<T>::Between(X, Y))));
 }
--- a/gtsam/geometry/Pose3.cpp
+++ b/gtsam/geometry/Pose3.cpp
@ -423,4 +423,8 @@ std::ostream &operator<<(std::ostream &os, const Pose3& pose) {
  return os;
 }
 Pose3 pose3_interp(const Pose3& X, const Pose3& Y, double t, Matrix& Hx, Matrix& Hy) {
  return X.interp(t, Y, Hx, Hy);
 }
 } // namespace gtsam
--- a/gtsam/geometry/Pose3.h
+++ b/gtsam/geometry/Pose3.h
@ -353,6 +353,15 @@ public:
    return std::make_pair(0, 2);
  }
  /**
   * @brief Spherical Linear interpolation between *this and other
   * @param s a value between 0 and 1.5
   * @param other final point of iterpolation geodesic on manifold
   * @param Hx jacobian of the interpolation on this
   & @param Hy jacobian of the interpolation on other
   */
  Pose3 interp(double t, const Pose3& other, OptionalJacobian<6, 6> Hx = boost::none, OptionalJacobian<6, 6> Hy = boost::none) const;
  /// Output stream operator
  GTSAM_EXPORT
  friend std::ostream &operator<<(std::ostream &os, const Pose3& p);
--- a/gtsam_unstable/slam/RollingShutterProjectionFactor.h
+++ b/gtsam_unstable/slam/RollingShutterProjectionFactor.h
@ -0,0 +1,214 @@
 /* ----------------------------------------------------------------------------
 * 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 RollingShutterProjectionFactor.h
 * @brief Basic bearing factor from 2D measurement for rolling shutter cameras
 * @author Yotam Stern
 */
 #pragma once
 #include <gtsam/nonlinear/NonlinearFactor.h>
 #include <gtsam/geometry/SimpleCamera.h>
 #include <boost/optional.hpp>
 namespace gtsam {
  /**
   * Non-linear factor for a constraint derived from a 2D measurement. The calibration is known here.
   * i.e. the main building block for visual SLAM.
   * this version takes rolling shutter information into account like so: consider camera A (pose A) and camera B, and Point2 from camera A.
   * camera A has timestamp t_A for the exposure time of its first row, and so does camera B t_B, Point2 has timestamp t_p according to the timestamp
   * corresponding to the time of exposure of the row in the camera it belongs to.
   * let us define the interp_param = (t_p - t_A) / (t_B - t_A), we will use the pose interpolated between A and B by the interp_param to project
   * the corresponding landmark to Point2.
   * @addtogroup SLAM
   */
  class RollingShutterProjectionFactor: public NoiseModelFactor3<Pose3, Pose3, Point3> {
  protected:
    // Keep a copy of measurement and calibration for I/O
    Point2 measured_;                   ///< 2D measurement
    double interp_param_;              ///< interpolation parameter corresponding to the point2 measured
    boost::shared_ptr<Cal3_S2> K_;  ///< shared pointer to calibration object
    boost::optional<Pose3> body_P_sensor_; ///< The pose of the sensor in the body frame
    // verbosity handling for Cheirality Exceptions
    bool throwCheirality_; ///< If true, rethrows Cheirality exceptions (default: false)
    bool verboseCheirality_; ///< If true, prints text for Cheirality exceptions (default: false)
  public:
    /// shorthand for base class type
    typedef NoiseModelFactor3<Pose3, Pose3, Point3> Base;
    /// shorthand for this class
    typedef RollingShutterProjectionFactor This;
    /// shorthand for a smart pointer to a factor
    typedef boost::shared_ptr<This> shared_ptr;
    /// Default constructor
  RollingShutterProjectionFactor() :
      measured_(0, 0), interp_param_(0), throwCheirality_(false), verboseCheirality_(false) {
  }
    /**
     * Constructor
     * @param measured is the 2 dimensional location of point in image (the measurement)
     * @param interp_param is the rolling shutter parameter for the measurement
     * @param model is the standard deviation
     * @param poseKey_a is the index of the first camera
     * @param poseKey_b is the index of the second camera
     * @param pointKey is the index of the landmark
     * @param K shared pointer to the constant calibration
     * @param body_P_sensor is the transform from body to sensor frame (default identity)
     */
    RollingShutterProjectionFactor(const Point2& measured, double interp_param, const SharedNoiseModel& model,
        Key poseKey_a, Key poseKey_b, Key pointKey, const boost::shared_ptr<Cal3_S2>& K,
        boost::optional<Pose3> body_P_sensor = boost::none) :
          Base(model, poseKey_a, poseKey_b, pointKey), measured_(measured), interp_param_(interp_param), K_(K), body_P_sensor_(body_P_sensor),
          throwCheirality_(false), verboseCheirality_(false) {}
    /**
     * Constructor with exception-handling flags
     * @param measured is the 2 dimensional location of point in image (the measurement)
     * @param interp_param is the rolling shutter parameter for the measurement
     * @param model is the standard deviation
     * @param poseKey_a is the index of the first camera
     * @param poseKey_b is the index of the second camera
     * @param pointKey is the index of the landmark
     * @param K shared pointer to the constant calibration
     * @param throwCheirality determines whether Cheirality exceptions are rethrown
     * @param verboseCheirality determines whether exceptions are printed for Cheirality
     * @param body_P_sensor is the transform from body to sensor frame  (default identity)
     */
    RollingShutterProjectionFactor(const Point2& measured, double interp_param, const SharedNoiseModel& model,
        Key poseKey_a, Key poseKey_b, Key pointKey, const boost::shared_ptr<Cal3_S2>& K,
        bool throwCheirality, bool verboseCheirality,
        boost::optional<Pose3> body_P_sensor = boost::none) :
          Base(model, poseKey_a, poseKey_b, pointKey), measured_(measured), interp_param_(interp_param), K_(K), body_P_sensor_(body_P_sensor),
          throwCheirality_(throwCheirality), verboseCheirality_(verboseCheirality) {}
    /** Virtual destructor */
    virtual ~RollingShutterProjectionFactor() {}
    /// @return a deep copy of this factor
    virtual gtsam::NonlinearFactor::shared_ptr clone() const {
      return boost::static_pointer_cast<gtsam::NonlinearFactor>(
          gtsam::NonlinearFactor::shared_ptr(new This(*this))); }
    /**
     * print
     * @param s optional string naming the factor
     * @param keyFormatter optional formatter useful for printing Symbols
     */
    void print(const std::string& s = "", const KeyFormatter& keyFormatter = DefaultKeyFormatter) const {
      std::cout << s << "RollingShutterProjectionFactor, z = ";
      traits<Point2>::Print(measured_);
      std::cout << " rolling shutter interpolation param = " << interp_param_;
      if(this->body_P_sensor_)
        this->body_P_sensor_->print("  sensor pose in body frame: ");
      Base::print("", keyFormatter);
    }
    /// equals
    virtual bool equals(const NonlinearFactor& p, double tol = 1e-9) const {
      const This *e = dynamic_cast<const This*>(&p);
      return e
          && Base::equals(p, tol)
          && (interp_param_ == e->interp_param())
          && traits<Point2>::Equals(this->measured_, e->measured_, tol)
          && this->K_->equals(*e->K_, tol)
          && ((!body_P_sensor_ && !e->body_P_sensor_) || (body_P_sensor_ && e->body_P_sensor_ && body_P_sensor_->equals(*e->body_P_sensor_)));
    }
    /// Evaluate error h(x)-z and optionally derivatives
    Vector evaluateError(const Pose3& pose_a, const Pose3& pose_b, const Point3& point,
        boost::optional<Matrix&> H1 = boost::none, boost::optional<Matrix&> H2 = boost::none, boost::optional<Matrix&> H3 = boost::none) const {
      Pose3 pose;
      gtsam::Matrix Hprj;
      //pose = interpolate(pose_a, pose_b, interp_param_, H1, H2);
      pose = pose_a.interp(interp_param_, pose_b, H1, H2);
      try {
        if(body_P_sensor_) {
          if(H1 && H2) {
            gtsam::Matrix H0;
            PinholeCamera<Cal3_S2> camera(pose.compose(*body_P_sensor_, H0), *K_);
            Point2 reprojectionError(camera.project(point, Hprj, H3, boost::none) - measured_);
            *H1 = Hprj * H0 * (*H1);
            *H2 = Hprj * H0 * (*H2);
            return reprojectionError;
          } else {
            PinholeCamera<Cal3_S2> camera(pose.compose(*body_P_sensor_), *K_);
            return camera.project(point, Hprj, H3, boost::none) - measured_;
          }
        } else {
          PinholeCamera<Cal3_S2> camera(pose, *K_);
          Point2 reprojectionError(camera.project(point, Hprj, H3, boost::none) - measured_);
          if (H1) *H1 = Hprj * (*H1);
          if (H2) *H2 = Hprj * (*H2);
          return reprojectionError;
        }
      } catch( CheiralityException& e) {
        if (H1) *H1 = Matrix::Zero(2,6);
        if (H2) *H2 = Matrix::Zero(2,6);
        if (H3) *H3 = Matrix::Zero(2,3);
        if (verboseCheirality_)
          std::cout << e.what() << ": Landmark "<< DefaultKeyFormatter(this->key2()) <<
              " moved behind camera " << DefaultKeyFormatter(this->key1()) << std::endl;
        if (throwCheirality_)
          throw CheiralityException(this->key2());
      }
      return Vector2::Constant(2.0 * K_->fx());
    }
    /** return the measurement */
    const Point2& measured() const {
      return measured_;
    }
    /** return the calibration object */
    inline const boost::shared_ptr<Cal3_S2> calibration() const {
      return K_;
    }
    /** returns the rolling shutter interp param*/
    inline double interp_param() const {return interp_param_; }
    /** return verbosity */
    inline bool verboseCheirality() const { return verboseCheirality_; }
    /** return flag for throwing cheirality exceptions */
    inline bool throwCheirality() const { return throwCheirality_; }
  private:
    /// Serialization function
    friend class boost::serialization::access;
    template<class ARCHIVE>
    void serialize(ARCHIVE & ar, const unsigned int /*version*/) {
      ar & BOOST_SERIALIZATION_BASE_OBJECT_NVP(Base);
      ar & BOOST_SERIALIZATION_NVP(measured_);
      ar & BOOST_SERIALIZATION_NVP(interp_param_);
      ar & BOOST_SERIALIZATION_NVP(K_);
      ar & BOOST_SERIALIZATION_NVP(body_P_sensor_);
      ar & BOOST_SERIALIZATION_NVP(throwCheirality_);
      ar & BOOST_SERIALIZATION_NVP(verboseCheirality_);
    }
  public:
    EIGEN_MAKE_ALIGNED_OPERATOR_NEW
  }; // rolling shutter projection factor
 } //namespace gtsam