/* * ControllerQuad.h * * Created on: Jun 30, 2011 * Author: jgoppert */ #ifndef CONTROLLERQUAD_H_ #define CONTROLLERQUAD_H_ #include "../APO/AP_Controller.h" #include "../APO/AP_BatteryMonitor.h" #include "../APO/AP_ArmingMechanism.h" namespace apo { class ControllerQuad: public AP_Controller { public: ControllerQuad(AP_Navigator * nav, AP_Guide * guide, AP_HardwareAbstractionLayer * hal) : AP_Controller(nav, guide, hal, new AP_ArmingMechanism(hal,ch_thrust,ch_yaw,0.1,-0.9,0.9), ch_mode), pidRoll(new AP_Var_group(k_pidRoll, PSTR("ROLL_")), 1, PID_ATT_P, PID_ATT_I, PID_ATT_D, PID_ATT_AWU, PID_ATT_LIM, PID_ATT_DFCUT), pidPitch(new AP_Var_group(k_pidPitch, PSTR("PITCH_")), 1, PID_ATT_P, PID_ATT_I, PID_ATT_D, PID_ATT_AWU, PID_ATT_LIM, PID_ATT_DFCUT), pidYaw(new AP_Var_group(k_pidYaw, PSTR("YAW_")), 1, PID_YAWPOS_P, PID_YAWPOS_I, PID_YAWPOS_D, PID_YAWPOS_AWU, PID_YAWPOS_LIM, PID_ATT_DFCUT), pidYawRate(new AP_Var_group(k_pidYawRate, PSTR("YAWRT_")), 1, PID_YAWSPEED_P, PID_YAWSPEED_I, PID_YAWSPEED_D, PID_YAWSPEED_AWU, PID_YAWSPEED_LIM, PID_YAWSPEED_DFCUT), pidPN(new AP_Var_group(k_pidPN, PSTR("NORTH_")), 1, PID_POS_P, PID_POS_I, PID_POS_D, PID_POS_AWU, PID_POS_LIM, PID_POS_DFCUT), pidPE(new AP_Var_group(k_pidPE, PSTR("EAST_")), 1, PID_POS_P, PID_POS_I, PID_POS_D, PID_POS_AWU, PID_POS_LIM, PID_POS_DFCUT), pidPD(new AP_Var_group(k_pidPD, PSTR("DOWN_")), 1, PID_POS_Z_P, PID_POS_Z_I, PID_POS_Z_D, PID_POS_Z_AWU, PID_POS_Z_LIM, PID_POS_DFCUT), _thrustMix(0), _pitchMix(0), _rollMix(0), _yawMix(0), _cmdRoll(0), _cmdPitch(0), _cmdYawRate(0) { _hal->debug->println_P(PSTR("initializing quad controller")); /* * allocate radio channels * the order of the channels has to match the enumeration above */ _hal->rc.push_back( new AP_RcChannel(k_chMode, PSTR("MODE_"), APM_RC, 5, 1100, 1500, 1900, RC_MODE_IN, false)); _hal->rc.push_back( new AP_RcChannel(k_chRight, PSTR("RIGHT_"), APM_RC, 0, 1100, 1100, 1900, RC_MODE_OUT, false)); _hal->rc.push_back( new AP_RcChannel(k_chLeft, PSTR("LEFT_"), APM_RC, 1, 1100, 1100, 1900, RC_MODE_OUT, false)); _hal->rc.push_back( new AP_RcChannel(k_chFront, PSTR("FRONT_"), APM_RC, 2, 1100, 1100, 1900, RC_MODE_OUT, false)); _hal->rc.push_back( new AP_RcChannel(k_chBack, PSTR("BACK_"), APM_RC, 3, 1100, 1100, 1900, RC_MODE_OUT, false)); _hal->rc.push_back( new AP_RcChannel(k_chRoll, PSTR("ROLL_"), APM_RC, 0, 1100, 1500, 1900, RC_MODE_IN, false)); _hal->rc.push_back( new AP_RcChannel(k_chPitch, PSTR("PITCH_"), APM_RC, 1, 1100, 1500, 1900, RC_MODE_IN, false)); _hal->rc.push_back( new AP_RcChannel(k_chThr, PSTR("THRUST_"), APM_RC, 2, 1100, 1100, 1900, RC_MODE_IN, false)); _hal->rc.push_back( new AP_RcChannel(k_chYaw, PSTR("YAW_"), APM_RC, 3, 1100, 1500, 1900, RC_MODE_IN, false)); } private: // methods void manualLoop(const float dt) { setAllRadioChannelsManually(); _cmdRoll = -0.5 * _hal->rc[ch_roll]->getPosition(); _cmdPitch = -0.5 * _hal->rc[ch_pitch]->getPosition(); _cmdYawRate = -1 * _hal->rc[ch_yaw]->getPosition(); _thrustMix = _hal->rc[ch_thrust]->getPosition(); autoAttitudeLoop(dt); } void autoLoop(const float dt) { autoPositionLoop(dt); autoAttitudeLoop(dt); // XXX currently auto loop not tested, so // put vehicle in standby _hal->setState(MAV_STATE_STANDBY); } void autoPositionLoop(float dt) { float cmdNorthTilt = pidPN.update(_nav->getPN(),_nav->getVN(),dt); float cmdEastTilt = pidPE.update(_nav->getPE(),_nav->getVE(),dt); float cmdDown = pidPD.update(_nav->getPD(),_nav->getVD(),dt); // "transform-to-body" { float trigSin = sin(-_nav->getYaw()); float trigCos = cos(-_nav->getYaw()); _cmdPitch = cmdEastTilt * trigCos - cmdNorthTilt * trigSin; _cmdRoll = -cmdEastTilt * trigSin + cmdNorthTilt * trigCos; // note that the north tilt is negative of the pitch } _cmdYawRate = 0; _thrustMix = THRUST_HOVER_OFFSET + cmdDown; // "thrust-trim-adjust" if (fabs(_cmdRoll) > 0.5) _thrustMix *= 1.13949393; else _thrustMix /= cos(_cmdRoll); if (fabs(_cmdPitch) > 0.5) _thrustMix *= 1.13949393; else _thrustMix /= cos(_cmdPitch); } void autoAttitudeLoop(float dt) { _rollMix = pidRoll.update(_cmdRoll - _nav->getRoll(), _nav->getRollRate(), dt); _pitchMix = pidPitch.update(_cmdPitch - _nav->getPitch(), _nav->getPitchRate(), dt); _yawMix = pidYawRate.update(_cmdYawRate - _nav->getYawRate(), dt); } void setMotorsActive() { // turn all motors off if below 0.1 throttle if (fabs(_hal->rc[ch_thrust]->getRadioPosition()) < 0.1) { setAllRadioChannelsToNeutral(); } else { _hal->rc[ch_right]->setPosition(_thrustMix - _rollMix + _yawMix); _hal->rc[ch_left]->setPosition(_thrustMix + _rollMix + _yawMix); _hal->rc[ch_front]->setPosition(_thrustMix + _pitchMix - _yawMix); _hal->rc[ch_back]->setPosition(_thrustMix - _pitchMix - _yawMix); } } // attributes /** * note that these are not the controller radio channel numbers, they are just * unique keys so they can be reaccessed from the hal rc vector */ enum { ch_mode = 0, // note scicoslab channels set mode, left, right, front, back order ch_right, ch_left, ch_front, ch_back, ch_roll, ch_pitch, ch_thrust, ch_yaw }; // must match channel enum enum { k_chMode = k_radioChannelsStart, k_chRight, k_chLeft, k_chFront, k_chBack, k_chRoll, k_chPitch, k_chThr, k_chYaw }; enum { k_pidGroundSpeed2Throttle = k_controllersStart, k_pidStr, k_pidPN, k_pidPE, k_pidPD, k_pidRoll, k_pidPitch, k_pidYawRate, k_pidYaw, }; BlockPIDDfb pidRoll, pidPitch, pidYaw; BlockPID pidYawRate; BlockPIDDfb pidPN, pidPE, pidPD; float _thrustMix, _pitchMix, _rollMix, _yawMix; float _cmdRoll, _cmdPitch, _cmdYawRate; }; } // namespace apo #endif /* CONTROLLERQUAD_H_ */ // vim:ts=4:sw=4:expandtab