eive-obsw/mission/controller/acs/control/SafeCtrl.cpp

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#include "SafeCtrl.h"
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#include <fsfw/globalfunctions/math/MatrixOperations.h>
#include <fsfw/globalfunctions/math/QuaternionOperations.h>
#include <fsfw/globalfunctions/math/VectorOperations.h>
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#include <math.h>
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SafeCtrl::SafeCtrl(AcsParameters *acsParameters_) { acsParameters = acsParameters_; }
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SafeCtrl::~SafeCtrl() {}
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uint8_t SafeCtrl::safeCtrlStrategy(const bool magFieldValid, const ReturnValue_t mekfValid,
const bool satRotRateValid, const bool sunDirValid,
const uint8_t mekfEnabled, const uint8_t dampingEnabled) {
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if (not magFieldValid) {
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return acs::SafeModeStrategy::SAFECTRL_NO_MAG_FIELD_FOR_CONTROL;
} else if (mekfEnabled and mekfValid) {
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return acs::SafeModeStrategy::SAFECTRL_ACTIVE_MEKF;
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} else if (satRotRateValid and sunDirValid) {
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return acs::SafeModeStrategy::SAFECTRL_WITHOUT_MEKF;
} else if (dampingEnabled and satRotRateValid and not sunDirValid) {
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return acs::SafeModeStrategy::SAFECTRL_ECLIPSE_DAMPING;
} else if (not dampingEnabled and satRotRateValid and not sunDirValid) {
return acs::SafeModeStrategy::SAFECTRL_ECLIPSE_IDELING;
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} else {
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return acs::SafeModeStrategy::SAFECTRL_NO_SENSORS_FOR_CONTROL;
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}
}
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void SafeCtrl::safeMekf(const double *magFieldB, const double *satRotRateB,
const double *sunDirModelI, const double *quatBI, const double *sunDirRefB,
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const double inertiaMatrix[3][3], double *magMomB, double &errorAngle) {
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// convert magFieldB from uT to T
VectorOperations<double>::mulScalar(magFieldB, 1e-6, magFieldBT, 3);
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// convert sunDirModel to body rf
double sunDirB[3] = {0, 0, 0};
QuaternionOperations::multiplyVector(quatBI, sunDirModelI, sunDirB);
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// calculate angle alpha between sunDirRef and sunDir
double dotSun = VectorOperations<double>::dot(sunDirRefB, sunDirB);
errorAngle = acos(dotSun);
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splitRotationalRate(satRotRateB, sunDirB);
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calculateRotationalRateTorque(
sunDirB, sunDirRefB, errorAngle, acsParameters->safeModeControllerParameters.k_parallelMekf,
acsParameters->safeModeControllerParameters.k_orthoMekf, inertiaMatrix);
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calculateAngleErrorTorque(sunDirB, sunDirRefB,
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acsParameters->safeModeControllerParameters.k_alignMekf);
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// sum of all torques
for (uint8_t i = 0; i < 3; i++) {
cmdTorque[i] = cmdAlign[i] + cmdOrtho[i] + cmdParallel[i];
}
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calculateMagneticMoment(magMomB);
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}
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void SafeCtrl::safeNonMekf(const double *magFieldB, const double *satRotRateB,
const double *sunDirB, const double *sunDirRefB,
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const double inertiaMatrix[3][3], double *magMomB, double &errorAngle) {
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// convert magFieldB from uT to T
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double magFieldBT[3] = {0, 0, 0};
VectorOperations<double>::mulScalar(magFieldB, 1e-6, magFieldBT, 3);
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// calculate error angle between sunDirRef and sunDir
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double dotSun = VectorOperations<double>::dot(sunDirRefB, sunDirB);
errorAngle = acos(dotSun);
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splitRotationalRate(satRotRateB, sunDirB);
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calculateRotationalRateTorque(sunDirB, sunDirRefB, errorAngle,
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acsParameters->safeModeControllerParameters.k_parallelNonMekf,
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acsParameters->safeModeControllerParameters.k_orthoNonMekf,
inertiaMatrix);
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calculateAngleErrorTorque(sunDirB, sunDirRefB,
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acsParameters->safeModeControllerParameters.k_alignNonMekf);
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// sum of all torques
for (uint8_t i = 0; i < 3; i++) {
cmdTorque[i] = cmdAlign[i] + cmdOrtho[i] + cmdParallel[i];
}
calculateMagneticMoment(magMomB);
}
void SafeCtrl::safeRateDamping(const double *magFieldB, const double *satRotRateB,
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const double *sunDirRefB, const double inertiaMatrix[3][3],
double *magMomB, double &errorAngle) {
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// convert magFieldB from uT to T
VectorOperations<double>::mulScalar(magFieldB, 1e-6, magFieldBT, 3);
// no error angle available for eclipse
errorAngle = NAN;
splitRotationalRate(satRotRateB, sunDirRefB);
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calculateRotationalRateTorque(sunDirRefB, sunDirRefB, errorAngle,
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acsParameters->safeModeControllerParameters.k_parallelNonMekf,
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acsParameters->safeModeControllerParameters.k_orthoNonMekf,
inertiaMatrix);
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// sum of all torques
double cmdTorque[3] = {0, 0, 0};
VectorOperations<double>::add(cmdParallel, cmdOrtho, cmdTorque, 3);
// calculate magnetic moment to command
calculateMagneticMoment(magMomB);
}
void SafeCtrl::splitRotationalRate(const double *satRotRateB, const double *sunDirB) {
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// split rotational rate into parallel and orthogonal parts
double parallelLength = VectorOperations<double>::dot(satRotRateB, sunDirB) *
pow(VectorOperations<double>::norm(sunDirB, 3), -2);
VectorOperations<double>::mulScalar(sunDirB, parallelLength, satRotRateParallelB, 3);
VectorOperations<double>::subtract(satRotRateB, satRotRateParallelB, satRotRateOrthogonalB, 3);
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}
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void SafeCtrl::calculateRotationalRateTorque(const double *sunDirB, const double *sunDirRefB,
double &errorAngle, const double gainParallel,
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const double gainOrtho,
const double inertiaMatrix[3][3]) {
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// calculate torque for parallel rotational rate
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VectorOperations<double>::mulScalar(satRotRateParallelB, -gainParallel, cmdParallel, 3);
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// calculate torque for orthogonal rotational rate
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double orthoFactor[3][3] = {{0, 0, 0}, {0, 0, 0}, {0, 0, 0}};
MatrixOperations<double>::multiplyScalar(*inertiaMatrix, gainOrtho, *orthoFactor, 3, 3);
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MatrixOperations<double>::multiply(*orthoFactor, satRotRateOrthogonalB, cmdOrtho, 3, 3, 1);
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}
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void SafeCtrl::calculateAngleErrorTorque(const double *sunDirB, const double *sunDirRefB,
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const double gainAlign) {
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// calculate torque for alignment
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double crossAlign[3] = {0, 0, 0};
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VectorOperations<double>::cross(sunDirRefB, sunDirB, crossAlign);
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VectorOperations<double>::mulScalar(crossAlign, gainAlign, cmdAlign, 3);
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}
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void SafeCtrl::calculateMagneticMoment(double *magMomB) {
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double torqueMgt[3] = {0, 0, 0};
VectorOperations<double>::cross(magFieldBT, cmdTorque, torqueMgt);
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double normMag = VectorOperations<double>::norm(magFieldBT, 3);
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VectorOperations<double>::mulScalar(torqueMgt, pow(normMag, -2), magMomB, 3);
}