| #ifndef FRC971_CONTROL_LOOPS_C2D_H_ |
| #define FRC971_CONTROL_LOOPS_C2D_H_ |
| |
| #include <chrono> |
| |
| #include <Eigen/Dense> |
| // We need to include MatrixFunctions for the matrix exponential. |
| #include "unsupported/Eigen/MatrixFunctions" |
| |
| namespace frc971 { |
| namespace controls { |
| |
| template <typename Scalar, int num_states, int num_inputs> |
| void C2D(const ::Eigen::Matrix<Scalar, num_states, num_states> &A_continuous, |
| const ::Eigen::Matrix<Scalar, num_states, num_inputs> &B_continuous, |
| ::std::chrono::nanoseconds dt, |
| ::Eigen::Matrix<Scalar, num_states, num_states> *A, |
| ::Eigen::Matrix<Scalar, num_states, num_inputs> *B) { |
| // Trick from |
| // https://en.wikipedia.org/wiki/Discretization#Discretization_of_linear_state_space_models |
| // to solve for A and B more efficiently. |
| Eigen::Matrix<Scalar, num_states + num_inputs, num_states + num_inputs> |
| M_state_continuous; |
| M_state_continuous.setZero(); |
| M_state_continuous.template block<num_states, num_states>(0, 0) = |
| A_continuous * |
| ::std::chrono::duration_cast<::std::chrono::duration<Scalar>>(dt).count(); |
| M_state_continuous.template block<num_states, num_inputs>(0, num_states) = |
| B_continuous * |
| ::std::chrono::duration_cast<::std::chrono::duration<Scalar>>(dt).count(); |
| |
| Eigen::Matrix<Scalar, num_states + num_inputs, num_states + num_inputs> |
| M_state = M_state_continuous.exp(); |
| *A = M_state.template block<num_states, num_states>(0, 0); |
| *B = M_state.template block<num_states, num_inputs>(0, num_states); |
| } |
| |
| template <typename Scalar, int num_states> |
| void DiscretizeQ( |
| const Eigen::Matrix<Scalar, num_states, num_states> &Q_continuous, |
| const Eigen::Matrix<Scalar, num_states, num_states> &A_continuous, |
| ::std::chrono::nanoseconds dt, |
| Eigen::Matrix<Scalar, num_states, num_states> *Q_d) { |
| Eigen::Matrix<Scalar, num_states, num_states> Qtemp = |
| (Q_continuous + Q_continuous.transpose()) / static_cast<Scalar>(2.0); |
| Eigen::Matrix<Scalar, 2 * num_states, 2 * num_states> M_gain; |
| M_gain.setZero(); |
| // Set up the matrix M = [[-A, Q], [0, A.T]] |
| M_gain.template block<num_states, num_states>(0, 0) = -A_continuous; |
| M_gain.template block<num_states, num_states>(0, num_states) = Qtemp; |
| M_gain.template block<num_states, num_states>(num_states, num_states) = |
| A_continuous.transpose(); |
| |
| Eigen::Matrix<Scalar, 2 * num_states, 2 *num_states> phi = |
| (M_gain * |
| ::std::chrono::duration_cast<::std::chrono::duration<Scalar>>(dt) |
| .count()).exp(); |
| |
| // Phi12 = phi[0:num_states, num_states:2*num_states] |
| // Phi22 = phi[num_states:2*num_states, |
| // num_states:2*num_states] |
| Eigen::Matrix<Scalar, num_states, num_states> phi12 = |
| phi.block(0, num_states, num_states, num_states); |
| Eigen::Matrix<Scalar, num_states, num_states> phi22 = |
| phi.block(num_states, num_states, num_states, num_states); |
| |
| *Q_d = phi22.transpose() * phi12; |
| *Q_d = (*Q_d + Q_d->transpose()) / static_cast<Scalar>(2.0); |
| } |
| |
| } // namespace controls |
| } // namespace frc971 |
| |
| #endif // FRC971_CONTROL_LOOPS_C2D_H_ |