diff options
Diffstat (limited to 'src/modules/mc_att_control/mc_att_control_base.cpp')
-rw-r--r-- | src/modules/mc_att_control/mc_att_control_base.cpp | 283 |
1 files changed, 283 insertions, 0 deletions
diff --git a/src/modules/mc_att_control/mc_att_control_base.cpp b/src/modules/mc_att_control/mc_att_control_base.cpp new file mode 100644 index 000000000..d4270b153 --- /dev/null +++ b/src/modules/mc_att_control/mc_att_control_base.cpp @@ -0,0 +1,283 @@ +/* + * mc_att_control_base.cpp + * + * Created on: Sep 25, 2014 + * Author: roman + */ + +#include "mc_att_control_base.h" +#include <geo/geo.h> +#include <math.h> + +#ifdef CONFIG_ARCH_ARM +#else +#include <cmath> +using namespace std; +#endif + +MulticopterAttitudeControlBase::MulticopterAttitudeControlBase() : + + _task_should_exit(false), _control_task(-1), + + _actuators_0_circuit_breaker_enabled(false), + + /* performance counters */ + _loop_perf(perf_alloc(PC_ELAPSED, "mc_att_control")) + +{ + memset(&_v_att, 0, sizeof(_v_att)); + memset(&_v_att_sp, 0, sizeof(_v_att_sp)); + memset(&_v_rates_sp, 0, sizeof(_v_rates_sp)); + memset(&_manual_control_sp, 0, sizeof(_manual_control_sp)); + memset(&_v_control_mode, 0, sizeof(_v_control_mode)); + memset(&_actuators, 0, sizeof(_actuators)); + memset(&_armed, 0, sizeof(_armed)); + + _params.att_p.zero(); + _params.rate_p.zero(); + _params.rate_i.zero(); + _params.rate_d.zero(); + _params.yaw_ff = 0.0f; + _params.yaw_rate_max = 0.0f; + _params.man_roll_max = 0.0f; + _params.man_pitch_max = 0.0f; + _params.man_yaw_max = 0.0f; + _params.acro_rate_max.zero(); + + _rates_prev.zero(); + _rates_sp.zero(); + _rates_int.zero(); + _thrust_sp = 0.0f; + _att_control.zero(); + + _I.identity(); +} + +MulticopterAttitudeControlBase::~MulticopterAttitudeControlBase() { +} + +void MulticopterAttitudeControlBase::vehicle_attitude_setpoint_poll() { +} + +void MulticopterAttitudeControlBase::control_attitude(float dt) { + float yaw_sp_move_rate = 0.0f; + bool publish_att_sp = false; + + if (_v_control_mode.flag_control_manual_enabled) { + /* manual input, set or modify attitude setpoint */ + + if (_v_control_mode.flag_control_velocity_enabled + || _v_control_mode.flag_control_climb_rate_enabled) { + /* in assisted modes poll 'vehicle_attitude_setpoint' topic and modify it */ + vehicle_attitude_setpoint_poll(); + } + + if (!_v_control_mode.flag_control_climb_rate_enabled) { + /* pass throttle directly if not in altitude stabilized mode */ + _v_att_sp.thrust = _manual_control_sp.z; + publish_att_sp = true; + } + + if (!_armed.armed) { + /* reset yaw setpoint when disarmed */ + _reset_yaw_sp = true; + } + + /* move yaw setpoint in all modes */ + if (_v_att_sp.thrust < 0.1f) { + // TODO + //if (_status.condition_landed) { + /* reset yaw setpoint if on ground */ + // reset_yaw_sp = true; + //} + } else { + /* move yaw setpoint */ + yaw_sp_move_rate = _manual_control_sp.r * _params.man_yaw_max; + _v_att_sp.yaw_body = _wrap_pi( + _v_att_sp.yaw_body + yaw_sp_move_rate * dt); + float yaw_offs_max = _params.man_yaw_max / _params.att_p(2); + float yaw_offs = _wrap_pi(_v_att_sp.yaw_body - _v_att.yaw); + if (yaw_offs < -yaw_offs_max) { + _v_att_sp.yaw_body = _wrap_pi(_v_att.yaw - yaw_offs_max); + + } else if (yaw_offs > yaw_offs_max) { + _v_att_sp.yaw_body = _wrap_pi(_v_att.yaw + yaw_offs_max); + } + _v_att_sp.R_valid = false; + publish_att_sp = true; + } + + /* reset yaw setpint to current position if needed */ + if (_reset_yaw_sp) { + _reset_yaw_sp = false; + _v_att_sp.yaw_body = _v_att.yaw; + _v_att_sp.R_valid = false; + publish_att_sp = true; + } + + if (!_v_control_mode.flag_control_velocity_enabled) { + /* update attitude setpoint if not in position control mode */ + _v_att_sp.roll_body = _manual_control_sp.y * _params.man_roll_max; + _v_att_sp.pitch_body = -_manual_control_sp.x + * _params.man_pitch_max; + _v_att_sp.R_valid = false; + publish_att_sp = true; + } + + } else { + /* in non-manual mode use 'vehicle_attitude_setpoint' topic */ + vehicle_attitude_setpoint_poll(); + + /* reset yaw setpoint after non-manual control mode */ + _reset_yaw_sp = true; + } + + _thrust_sp = _v_att_sp.thrust; + + /* construct attitude setpoint rotation matrix */ + math::Matrix<3, 3> R_sp; + + if (_v_att_sp.R_valid) { + /* rotation matrix in _att_sp is valid, use it */ + R_sp.set(&_v_att_sp.R_body[0][0]); + + } else { + /* rotation matrix in _att_sp is not valid, use euler angles instead */ + R_sp.from_euler(_v_att_sp.roll_body, _v_att_sp.pitch_body, + _v_att_sp.yaw_body); + + /* copy rotation matrix back to setpoint struct */ + memcpy(&_v_att_sp.R_body[0][0], &R_sp.data[0][0], + sizeof(_v_att_sp.R_body)); + _v_att_sp.R_valid = true; + } + +// /* publish the attitude setpoint if needed */ +// if (publish_att_sp) { +// _v_att_sp.timestamp = hrt_absolute_time(); +// +// if (_att_sp_pub > 0) { +// orb_publish(ORB_ID(vehicle_attitude_setpoint), _att_sp_pub, +// &_v_att_sp); +// +// } else { +// _att_sp_pub = orb_advertise(ORB_ID(vehicle_attitude_setpoint), +// &_v_att_sp); +// } +// } + + /* rotation matrix for current state */ + math::Matrix<3, 3> R; + R.set(_v_att.R); + + /* all input data is ready, run controller itself */ + + /* try to move thrust vector shortest way, because yaw response is slower than roll/pitch */ + math::Vector < 3 > R_z(R(0, 2), R(1, 2), R(2, 2)); + math::Vector < 3 > R_sp_z(R_sp(0, 2), R_sp(1, 2), R_sp(2, 2)); + + /* axis and sin(angle) of desired rotation */ + math::Vector < 3 > e_R = R.transposed() * (R_z % R_sp_z); + + /* calculate angle error */ + float e_R_z_sin = e_R.length(); + float e_R_z_cos = R_z * R_sp_z; + + /* calculate weight for yaw control */ + float yaw_w = R_sp(2, 2) * R_sp(2, 2); + + /* calculate rotation matrix after roll/pitch only rotation */ + math::Matrix<3, 3> R_rp; + + if (e_R_z_sin > 0.0f) { + /* get axis-angle representation */ + float e_R_z_angle = atan2f(e_R_z_sin, e_R_z_cos); + math::Vector < 3 > e_R_z_axis = e_R / e_R_z_sin; + + e_R = e_R_z_axis * e_R_z_angle; + + /* cross product matrix for e_R_axis */ + math::Matrix<3, 3> e_R_cp; + e_R_cp.zero(); + e_R_cp(0, 1) = -e_R_z_axis(2); + e_R_cp(0, 2) = e_R_z_axis(1); + e_R_cp(1, 0) = e_R_z_axis(2); + e_R_cp(1, 2) = -e_R_z_axis(0); + e_R_cp(2, 0) = -e_R_z_axis(1); + e_R_cp(2, 1) = e_R_z_axis(0); + + /* rotation matrix for roll/pitch only rotation */ + R_rp = R + * (_I + e_R_cp * e_R_z_sin + + e_R_cp * e_R_cp * (1.0f - e_R_z_cos)); + + } else { + /* zero roll/pitch rotation */ + R_rp = R; + } + + /* R_rp and R_sp has the same Z axis, calculate yaw error */ + math::Vector < 3 > R_sp_x(R_sp(0, 0), R_sp(1, 0), R_sp(2, 0)); + math::Vector < 3 > R_rp_x(R_rp(0, 0), R_rp(1, 0), R_rp(2, 0)); + e_R(2) = atan2f((R_rp_x % R_sp_x) * R_sp_z, R_rp_x * R_sp_x) * yaw_w; + + if (e_R_z_cos < 0.0f) { + /* for large thrust vector rotations use another rotation method: + * calculate angle and axis for R -> R_sp rotation directly */ + math::Quaternion q; + q.from_dcm(R.transposed() * R_sp); + math::Vector < 3 > e_R_d = q.imag(); + e_R_d.normalize(); + e_R_d *= 2.0f * atan2f(e_R_d.length(), q(0)); + + /* use fusion of Z axis based rotation and direct rotation */ + float direct_w = e_R_z_cos * e_R_z_cos * yaw_w; + e_R = e_R * (1.0f - direct_w) + e_R_d * direct_w; + } + + /* calculate angular rates setpoint */ + _rates_sp = _params.att_p.emult(e_R); + + /* limit yaw rate */ + _rates_sp(2) = math::constrain(_rates_sp(2), -_params.yaw_rate_max, + _params.yaw_rate_max); + + /* feed forward yaw setpoint rate */ + _rates_sp(2) += yaw_sp_move_rate * yaw_w * _params.yaw_ff; +} + +void MulticopterAttitudeControlBase::control_attitude_rates(float dt) { + /* reset integral if disarmed */ + if (!_armed.armed) { + _rates_int.zero(); + } + + /* current body angular rates */ + math::Vector < 3 > rates; + rates(0) = _v_att.rollspeed; + rates(1) = _v_att.pitchspeed; + rates(2) = _v_att.yawspeed; + + /* angular rates error */ + math::Vector < 3 > rates_err = _rates_sp - rates; + _att_control = _params.rate_p.emult(rates_err) + + _params.rate_d.emult(_rates_prev - rates) / dt + _rates_int; + _rates_prev = rates; + + /* update integral only if not saturated on low limit */ + if (_thrust_sp > MIN_TAKEOFF_THRUST) { + for (int i = 0; i < 3; i++) { + if (fabsf(_att_control(i)) < _thrust_sp) { + float rate_i = _rates_int(i) + + _params.rate_i(i) * rates_err(i) * dt; + + if (isfinite( + rate_i) && rate_i > -RATES_I_LIMIT && rate_i < RATES_I_LIMIT && + _att_control(i) > -RATES_I_LIMIT && _att_control(i) < RATES_I_LIMIT) { + _rates_int(i) = rate_i; + } + } + } + } + +} |