FullIMUFactor.h

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#pragma once

#include <gtsam/base/numericalDerivative.h>
#include <gtsam/nonlinear/NonlinearFactor.h>
#include <gtsam_unstable/dynamics/PoseRTV.h>

namespace gtsam {

template<class POSE>
class FullIMUFactor : public NoiseModelFactorN<POSE, POSE> {
public:
  typedef NoiseModelFactorN<POSE, POSE> Base;
  typedef FullIMUFactor<POSE> This;

protected:

  Vector3 accel_, gyro_;
  double dt_; 

public:

  // Provide access to the Matrix& version of evaluateError:
  using Base::evaluateError;

  FullIMUFactor(const Vector3& accel, const Vector3& gyro,
      double dt, const Key& key1, const Key& key2, const SharedNoiseModel& model)
  : Base(model, key1, key2), accel_(accel), gyro_(gyro), dt_(dt) {
    assert(model->dim() == 9);
  }

  FullIMUFactor(const Vector6& imu,
      double dt, const Key& key1, const Key& key2, const SharedNoiseModel& model)
  : Base(model, key1, key2), accel_(imu.head(3)), gyro_(imu.tail(3)), dt_(dt) {
    assert(imu.size() == 6);
    assert(model->dim() == 9);
  }

  ~FullIMUFactor() override {}

  gtsam::NonlinearFactor::shared_ptr clone() const override {
    return std::static_pointer_cast<gtsam::NonlinearFactor>(
        gtsam::NonlinearFactor::shared_ptr(new This(*this))); }

  bool equals(const NonlinearFactor& e, double tol = 1e-9) const override {
    const This* const f = dynamic_cast<const This*>(&e);
    return f && Base::equals(e) &&
        equal_with_abs_tol(accel_, f->accel_, tol) &&
        equal_with_abs_tol(gyro_, f->gyro_, tol) &&
        std::abs(dt_ - f->dt_) < tol;
  }

  void print(const std::string& s="", const gtsam::KeyFormatter& formatter = gtsam::DefaultKeyFormatter) const override {
    std::string a = "FullIMUFactor: " + s;
    Base::print(a, formatter);
    gtsam::print((Vector)accel_, "accel");
    gtsam::print((Vector)gyro_, "gyro");
    std::cout << "dt: " << dt_ << std::endl;
  }

  // access
  const Vector3& gyro() const { return gyro_; }
  const Vector3& accel() const { return accel_; }
  Vector6 z() const { return (Vector(6) << accel_, gyro_).finished(); }

  Vector evaluateError(const PoseRTV& x1, const PoseRTV& x2,
      OptionalMatrixType H1, OptionalMatrixType H2) const override {
    Vector9 z;
    z.head(3).operator=(accel_); // Strange syntax to work around ambiguous operator error with clang
    z.segment(3, 3).operator=(gyro_); // Strange syntax to work around ambiguous operator error with clang
    z.tail(3).operator=(x2.t()); // Strange syntax to work around ambiguous operator error with clang
    if (H1) *H1 = numericalDerivative21<Vector9, PoseRTV, PoseRTV>(
        std::bind(This::predict_proxy, std::placeholders::_1, std::placeholders::_2, dt_), x1, x2, 1e-5);
    if (H2) *H2 = numericalDerivative22<Vector9, PoseRTV, PoseRTV>(
        std::bind(This::predict_proxy, std::placeholders::_1, std::placeholders::_2, dt_), x1, x2, 1e-5);
    return z - predict_proxy(x1, x2, dt_);
  }

  virtual Vector evaluateError(const Pose3& x1, const Pose3& x2,
      OptionalMatrixType H1, OptionalMatrixType H2) const {
    assert(false);
    return Vector6::Zero();
  }

private:

  static Vector9 predict_proxy(const PoseRTV& x1, const PoseRTV& x2, double dt) {
    Vector9 hx;
    hx.head(6).operator=(x1.imuPrediction(x2, dt)); // Strange syntax to work around ambiguous operator error with clang
    hx.tail(3).operator=(x1.translationIntegration(x2, dt)); // Strange syntax to work around ambiguous operator error with clang
    return hx;
  }
};

} // \namespace gtsam