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First Version of ACS Controller #329

Merged
muellerr merged 106 commits from acs-ctrl-v1 into develop 2022-12-02 16:21:58 +01:00
Conversation 0 Commits 106 Files Changed 50 +380 -255
3 changed files with 380 additions and 255 deletions
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9
mission/controller/AcsController.cpp
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@ -95,7 +95,8 @@ void AcsController::performSafe() {
timeval now; timeval now;
Clock::getClock_timeval(&now); Clock::getClock_timeval(&now);
sensorProcessing.process(now, &sensorValues, &outputValues, &acsParameters); sensorProcessing.process(now, &sensorValues, &mgmDataProcessed, &susDataProcessed,
&gyrDataProcessed, &gpsDataProcessed, &acsParameters);
ReturnValue_t validMekf; ReturnValue_t validMekf;
navigation.useMekf(&sensorValues, &outputValues, &validMekf); navigation.useMekf(&sensorValues, &outputValues, &validMekf);
@ -148,7 +149,8 @@ void AcsController::performDetumble() {
timeval now; timeval now;
Clock::getClock_timeval(&now); Clock::getClock_timeval(&now);
sensorProcessing.process(now, &sensorValues, &outputValues, &acsParameters); sensorProcessing.process(now, &sensorValues, &mgmDataProcessed, &susDataProcessed,
&gyrDataProcessed, &gpsDataProcessed, &acsParameters);
ReturnValue_t validMekf; ReturnValue_t validMekf;
navigation.useMekf(&sensorValues, &outputValues, &validMekf); navigation.useMekf(&sensorValues, &outputValues, &validMekf);
@ -182,7 +184,8 @@ void AcsController::performPointingCtrl() {
timeval now; timeval now;
Clock::getClock_timeval(&now); Clock::getClock_timeval(&now);
sensorProcessing.process(now, &sensorValues, &outputValues, &acsParameters); sensorProcessing.process(now, &sensorValues, &mgmDataProcessed, &susDataProcessed,
&gyrDataProcessed, &gpsDataProcessed, &acsParameters);
ReturnValue_t validMekf; ReturnValue_t validMekf;
navigation.useMekf(&sensorValues, &outputValues, &validMekf); navigation.useMekf(&sensorValues, &outputValues, &validMekf);

595
mission/controller/acs/SensorProcessing.cpp
View File

@ -1,5 +1,6 @@
#include "SensorProcessing.h" #include "SensorProcessing.h"
#include <fsfw/datapool/PoolReadGuard.h>
#include <fsfw/globalfunctions/constants.h> #include <fsfw/globalfunctions/constants.h>
#include <fsfw/globalfunctions/math/MatrixOperations.h> #include <fsfw/globalfunctions/math/MatrixOperations.h>
#include <fsfw/globalfunctions/math/QuaternionOperations.h> #include <fsfw/globalfunctions/math/QuaternionOperations.h>
@ -13,27 +14,35 @@
using namespace Math; using namespace Math;
SensorProcessing::SensorProcessing(AcsParameters *acsParameters_) : savedMagFieldEst{0, 0, 0} { SensorProcessing::SensorProcessing(AcsParameters *acsParameters_)
validMagField = false; : savedMgmVecTot{0, 0, 0}, validMagField(false), validGcLatitude(false) {}
validGcLatitude = false;
}
SensorProcessing::~SensorProcessing() {} SensorProcessing::~SensorProcessing() {}
bool SensorProcessing::processMgm(const float *mgm0Value, bool mgm0valid, const float *mgm1Value, void SensorProcessing::processMgm(const float *mgm0Value, bool mgm0valid, const float *mgm1Value,
bool mgm1valid, const float *mgm2Value, bool mgm2valid, bool mgm1valid, const float *mgm2Value, bool mgm2valid,
const float *mgm3Value, bool mgm3valid, const float *mgm4Value, const float *mgm3Value, bool mgm3valid, const float *mgm4Value,
bool mgm4valid, timeval timeOfMgmMeasurement, bool mgm4valid, timeval timeOfMgmMeasurement,
const AcsParameters::MgmHandlingParameters *mgmParameters, const AcsParameters::MgmHandlingParameters *mgmParameters,
const double gpsLatitude, const double gpsLongitude, acsctrl::GpsDataProcessed *gpsDataProcessed,
const double gpsAltitude, bool gpsValid, double *magFieldEst, const double gpsAltitude, bool gpsValid,
bool *outputValid, double *magFieldModel, acsctrl::MgmDataProcessed *mgmDataProcessed) {
bool *magFieldModelValid, double *magneticFieldVectorDerivative,
bool *magneticFieldVectorDerivativeValid) {
if (!mgm0valid && !mgm1valid && !mgm2valid && !mgm3valid && !mgm4valid) { if (!mgm0valid && !mgm1valid && !mgm2valid && !mgm3valid && !mgm4valid) {
*outputValid = false; {
validMagField = false; PoolReadGuard pg(mgmDataProcessed);
return false; if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(mgmDataProcessed->mgm0vec.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->mgm1vec.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->mgm2vec.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->mgm3vec.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->mgm4vec.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->mgmVecTot.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->mgmVecTotDerivative.value, zeroVector, 3 * sizeof(float));
std::memcpy(mgmDataProcessed->magIgrfModel.value, zeroVector, 3 * sizeof(double));
mgmDataProcessed->setValidity(false, true);
}
}
return;
} }
float mgm0ValueNoBias[3] = {0, 0, 0}, mgm1ValueNoBias[3] = {0, 0, 0}, float mgm0ValueNoBias[3] = {0, 0, 0}, mgm1ValueNoBias[3] = {0, 0, 0},
mgm2ValueNoBias[3] = {0, 0, 0}, mgm3ValueNoBias[3] = {0, 0, 0}, mgm2ValueNoBias[3] = {0, 0, 0}, mgm3ValueNoBias[3] = {0, 0, 0},
@ -104,34 +113,26 @@ bool SensorProcessing::processMgm(const float *mgm0Value, bool mgm0valid, const
sensorFusionDenominator[i] += 1 / mgmParameters->mgm4variance[i]; sensorFusionDenominator[i] += 1 / mgmParameters->mgm4variance[i];
} }
} }
float mgmVecTot[3] = {0.0, 0.0, 0.0};
for (uint8_t i = 0; i < 3; i++) { for (uint8_t i = 0; i < 3; i++) {
magFieldEst[i] = sensorFusionNumerator[i] / sensorFusionDenominator[i]; mgmVecTot[i] = sensorFusionNumerator[i] / sensorFusionDenominator[i];
} }
validMagField = true;
//-----------------------Mag Rate Computation --------------------------------------------------- //-----------------------Mgm Rate Computation ---------------------------------------------------
float mgmVecTotDerivative[3] = {0.0, 0.0, 0.0};
bool mgmVecTotDerivativeValid = false;
double timeDiff = timevalOperations::toDouble(timeOfMgmMeasurement - timeOfSavedMagFieldEst); double timeDiff = timevalOperations::toDouble(timeOfMgmMeasurement - timeOfSavedMagFieldEst);
for (uint8_t i = 0; i < 3; i++) { if (timeOfSavedMagFieldEst.tv_sec != 0) {
magneticFieldVectorDerivative[i] = (magFieldEst[i] - savedMagFieldEst[i]) / timeDiff; for (uint8_t i = 0; i < 3; i++) {
savedMagFieldEst[i] = magFieldEst[i]; mgmVecTotDerivative[i] = (mgmVecTot[i] - savedMgmVecTot[i]) / timeDiff;
savedMgmVecTot[i] = mgmVecTot[i];
}
} }
*magneticFieldVectorDerivativeValid = true;
if (timeOfSavedMagFieldEst.tv_sec == 0) {
magneticFieldVectorDerivative[0] = 0;
magneticFieldVectorDerivative[1] = 0;
magneticFieldVectorDerivative[2] = 0;
*magneticFieldVectorDerivativeValid = false;
}
timeOfSavedMagFieldEst = timeOfMgmMeasurement; timeOfSavedMagFieldEst = timeOfMgmMeasurement;
*outputValid = true;
// ---------------- IGRF- 13 Implementation here ------------------------------------------------ // ---------------- IGRF- 13 Implementation here ------------------------------------------------
if (!gpsValid) { double magIgrfModel[3] = {0.0, 0.0, 0.0};
*magFieldModelValid = false; if (gpsValid) {
} else {
// Should be existing class object which will be called and modified here. // Should be existing class object which will be called and modified here.
Igrf13Model igrf13; Igrf13Model igrf13;
// So the line above should not be done here. Update: Can be done here as long updated coffs // So the line above should not be done here. Update: Can be done here as long updated coffs
@ -139,12 +140,32 @@ bool SensorProcessing::processMgm(const float *mgm0Value, bool mgm0valid, const
igrf13.updateCoeffGH(timeOfMgmMeasurement); igrf13.updateCoeffGH(timeOfMgmMeasurement);
// maybe put a condition here, to only update after a full day, this // maybe put a condition here, to only update after a full day, this
// class function has around 700 steps to perform // class function has around 700 steps to perform
igrf13.magFieldComp(gpsLongitude, gpsLatitude, gpsAltitude, timeOfMgmMeasurement, igrf13.magFieldComp(gpsDataProcessed->gdLongitude.value, gpsDataProcessed->gcLatitude.value,
magFieldModel); gpsAltitude, timeOfMgmMeasurement, magIgrfModel);
*magFieldModelValid = false; }
{
PoolReadGuard pg(mgmDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(mgmDataProcessed->mgm0vec.value, mgm0ValueBody, 3 * sizeof(float));
mgmDataProcessed->mgm0vec.setValid(mgm0valid);
std::memcpy(mgmDataProcessed->mgm1vec.value, mgm1ValueBody, 3 * sizeof(float));
mgmDataProcessed->mgm1vec.setValid(mgm1valid);
std::memcpy(mgmDataProcessed->mgm2vec.value, mgm2ValueBody, 3 * sizeof(float));
mgmDataProcessed->mgm2vec.setValid(mgm2valid);
std::memcpy(mgmDataProcessed->mgm3vec.value, mgm3ValueBody, 3 * sizeof(float));
mgmDataProcessed->mgm3vec.setValid(mgm3valid);
std::memcpy(mgmDataProcessed->mgm4vec.value, mgm4ValueBody, 3 * sizeof(float));
mgmDataProcessed->mgm4vec.setValid(mgm4valid);
std::memcpy(mgmDataProcessed->mgmVecTot.value, mgmVecTot, 3 * sizeof(float));
mgmDataProcessed->mgmVecTot.setValid(true);
std::memcpy(mgmDataProcessed->mgmVecTotDerivative.value, mgmVecTotDerivative,
3 * sizeof(float));
mgmDataProcessed->mgmVecTotDerivative.setValid(mgmVecTotDerivativeValid);
std::memcpy(mgmDataProcessed->magIgrfModel.value, magIgrfModel, 3 * sizeof(double));
mgmDataProcessed->magIgrfModel.setValid(gpsValid);
mgmDataProcessed->setValidity(true, false);
}
} }
return true;
} }
void SensorProcessing::processSus( void SensorProcessing::processSus(
@ -155,9 +176,8 @@ void SensorProcessing::processSus(
const uint16_t *sus8Value, bool sus8valid, const uint16_t *sus9Value, bool sus9valid, const uint16_t *sus8Value, bool sus8valid, const uint16_t *sus9Value, bool sus9valid,
const uint16_t *sus10Value, bool sus10valid, const uint16_t *sus11Value, bool sus11valid, const uint16_t *sus10Value, bool sus10valid, const uint16_t *sus11Value, bool sus11valid,
timeval timeOfSusMeasurement, const AcsParameters::SusHandlingParameters *susParameters, timeval timeOfSusMeasurement, const AcsParameters::SusHandlingParameters *susParameters,
const AcsParameters::SunModelParameters *sunModelParameters, double *sunDirEst, const AcsParameters::SunModelParameters *sunModelParameters,
bool *sunDirEstValid, double *sunVectorInertial, bool *sunVectorInertialValid, acsctrl::SusDataProcessed *susDataProcessed) {
double *sunVectorDerivative, bool *sunVectorDerivativeValid) {
if (sus0valid) { if (sus0valid) {
sus0valid = susConverter.checkSunSensorData(sus0Value); sus0valid = susConverter.checkSunSensorData(sus0Value);
} }
@ -197,142 +217,176 @@ void SensorProcessing::processSus(
if (!sus0valid && !sus1valid && !sus2valid && !sus3valid && !sus4valid && !sus5valid && if (!sus0valid && !sus1valid && !sus2valid && !sus3valid && !sus4valid && !sus5valid &&
!sus6valid && !sus7valid && !sus8valid && !sus9valid && !sus10valid && !sus11valid) { !sus6valid && !sus7valid && !sus8valid && !sus9valid && !sus10valid && !sus11valid) {
*sunDirEstValid = false; {
return; PoolReadGuard pg(susDataProcessed);
} else { if (pg.getReadResult() == returnvalue::OK) {
// WARNING: NOT TRANSFORMED IN BODY FRAME YET std::memcpy(susDataProcessed->sus0vec.value, zeroVector, 3 * sizeof(float));
// Transformation into Geomtry Frame std::memcpy(susDataProcessed->sus1vec.value, zeroVector, 3 * sizeof(float));
float sus0VecBody[3] = {0, 0, 0}, sus1VecBody[3] = {0, 0, 0}, sus2VecBody[3] = {0, 0, 0}, std::memcpy(susDataProcessed->sus2vec.value, zeroVector, 3 * sizeof(float));
sus3VecBody[3] = {0, 0, 0}, sus4VecBody[3] = {0, 0, 0}, sus5VecBody[3] = {0, 0, 0}, std::memcpy(susDataProcessed->sus3vec.value, zeroVector, 3 * sizeof(float));
sus6VecBody[3] = {0, 0, 0}, sus7VecBody[3] = {0, 0, 0}, sus8VecBody[3] = {0, 0, 0}, std::memcpy(susDataProcessed->sus4vec.value, zeroVector, 3 * sizeof(float));
sus9VecBody[3] = {0, 0, 0}, sus10VecBody[3] = {0, 0, 0}, sus11VecBody[3] = {0, 0, 0}; std::memcpy(susDataProcessed->sus5vec.value, zeroVector, 3 * sizeof(float));
std::memcpy(susDataProcessed->sus6vec.value, zeroVector, 3 * sizeof(float));
if (sus0valid) { std::memcpy(susDataProcessed->sus7vec.value, zeroVector, 3 * sizeof(float));
MatrixOperations<float>::multiply( std::memcpy(susDataProcessed->sus8vec.value, zeroVector, 3 * sizeof(float));
susParameters->sus0orientationMatrix[0], std::memcpy(susDataProcessed->sus9vec.value, zeroVector, 3 * sizeof(float));
susConverter.getSunVectorSensorFrame(sus0Value, susParameters->sus0coeffAlpha, std::memcpy(susDataProcessed->sus10vec.value, zeroVector, 3 * sizeof(float));
susParameters->sus0coeffBeta), std::memcpy(susDataProcessed->sus11vec.value, zeroVector, 3 * sizeof(float));
sus0VecBody, 3, 3, 1); std::memcpy(susDataProcessed->susVecTot.value, zeroVector, 3 * sizeof(float));
} std::memcpy(susDataProcessed->susVecTotDerivative.value, zeroVector, 3 * sizeof(float));
if (sus1valid) { std::memcpy(susDataProcessed->sunIjkModel.value, zeroVector, 3 * sizeof(double));
MatrixOperations<float>::multiply( susDataProcessed->setValidity(false, true);
susParameters->sus1orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus1Value, susParameters->sus1coeffAlpha,
susParameters->sus1coeffBeta),
sus1VecBody, 3, 3, 1);
}
if (sus2valid) {
MatrixOperations<float>::multiply(
susParameters->sus2orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus2Value, susParameters->sus2coeffAlpha,
susParameters->sus2coeffBeta),
sus2VecBody, 3, 3, 1);
}
if (sus3valid) {
MatrixOperations<float>::multiply(
susParameters->sus3orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus3Value, susParameters->sus3coeffAlpha,
susParameters->sus3coeffBeta),
sus3VecBody, 3, 3, 1);
}
if (sus4valid) {
MatrixOperations<float>::multiply(
susParameters->sus4orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus4Value, susParameters->sus4coeffAlpha,
susParameters->sus4coeffBeta),
sus4VecBody, 3, 3, 1);
}
if (sus5valid) {
MatrixOperations<float>::multiply(
susParameters->sus5orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus5Value, susParameters->sus5coeffAlpha,
susParameters->sus5coeffBeta),
sus5VecBody, 3, 3, 1);
}
if (sus6valid) {
MatrixOperations<float>::multiply(
susParameters->sus6orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus6Value, susParameters->sus6coeffAlpha,
susParameters->sus6coeffBeta),
sus6VecBody, 3, 3, 1);
}
if (sus7valid) {
MatrixOperations<float>::multiply(
susParameters->sus7orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus7Value, susParameters->sus7coeffAlpha,
susParameters->sus7coeffBeta),
sus7VecBody, 3, 3, 1);
}
if (sus8valid) {
MatrixOperations<float>::multiply(
susParameters->sus8orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus8Value, susParameters->sus8coeffAlpha,
susParameters->sus8coeffBeta),
sus8VecBody, 3, 3, 1);
}
if (sus9valid) {
MatrixOperations<float>::multiply(
susParameters->sus9orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus9Value, susParameters->sus9coeffAlpha,
susParameters->sus9coeffBeta),
sus9VecBody, 3, 3, 1);
}
if (sus10valid) {
MatrixOperations<float>::multiply(
susParameters->sus10orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus10Value, susParameters->sus10coeffAlpha,
susParameters->sus10coeffBeta),
sus10VecBody, 3, 3, 1);
}
if (sus11valid) {
MatrixOperations<float>::multiply(
susParameters->sus11orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus11Value, susParameters->sus11coeffAlpha,
susParameters->sus11coeffBeta),
sus11VecBody, 3, 3, 1);
}
/* ------ Mean Value: susDirEst ------ */
bool validIds[12] = {sus0valid, sus1valid, sus2valid, sus3valid, sus4valid, sus5valid,
sus6valid, sus7valid, sus8valid, sus9valid, sus10valid, sus11valid};
float susVecBody[3][12] = {{sus0VecBody[0], sus1VecBody[0], sus2VecBody[0], sus3VecBody[0],
sus4VecBody[0], sus5VecBody[0], sus6VecBody[0], sus7VecBody[0],
sus8VecBody[0], sus9VecBody[0], sus10VecBody[0], sus11VecBody[0]},
{sus0VecBody[1], sus1VecBody[1], sus2VecBody[1], sus3VecBody[1],
sus4VecBody[1], sus5VecBody[1], sus6VecBody[1], sus7VecBody[1],
sus8VecBody[1], sus9VecBody[1], sus10VecBody[1], sus11VecBody[1]},
{sus0VecBody[2], sus1VecBody[2], sus2VecBody[2], sus3VecBody[2],
sus4VecBody[2], sus5VecBody[2], sus6VecBody[2], sus7VecBody[2],
sus8VecBody[2], sus9VecBody[2], sus10VecBody[2], sus11VecBody[2]}};
double susMeanValue[3] = {0, 0, 0};
for (uint8_t i = 0; i < 12; i++) {
if (validIds[i]) {
susMeanValue[0] += susVecBody[0][i];
susMeanValue[1] += susVecBody[1][i];
susMeanValue[2] += susVecBody[2][i];
} }
} }
VectorOperations<double>::normalize(susMeanValue, sunDirEst, 3); return;
*sunDirEstValid = true;
} }
// WARNING: NOT TRANSFORMED IN BODY FRAME YET
// Transformation into Geomtry Frame
float sus0VecBody[3] = {0, 0, 0}, sus1VecBody[3] = {0, 0, 0}, sus2VecBody[3] = {0, 0, 0},
sus3VecBody[3] = {0, 0, 0}, sus4VecBody[3] = {0, 0, 0}, sus5VecBody[3] = {0, 0, 0},
sus6VecBody[3] = {0, 0, 0}, sus7VecBody[3] = {0, 0, 0}, sus8VecBody[3] = {0, 0, 0},
sus9VecBody[3] = {0, 0, 0}, sus10VecBody[3] = {0, 0, 0}, sus11VecBody[3] = {0, 0, 0};
if (sus0valid) {
MatrixOperations<float>::multiply(
susParameters->sus0orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus0Value, susParameters->sus0coeffAlpha,
susParameters->sus0coeffBeta),
sus0VecBody, 3, 3, 1);
}
{
PoolReadGuard pg(susDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(susDataProcessed->sus0vec.value, sus0VecBody, 3 * sizeof(float));
susDataProcessed->sus0vec.setValid(sus0valid);
if (!sus0valid) {
std::memcpy(susDataProcessed->sus0vec.value, zeroVector, 3 * sizeof(float));
}
}
}
if (sus1valid) {
MatrixOperations<float>::multiply(
susParameters->sus1orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus1Value, susParameters->sus1coeffAlpha,
susParameters->sus1coeffBeta),
sus1VecBody, 3, 3, 1);
}
{
PoolReadGuard pg(susDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(susDataProcessed->sus1vec.value, sus1VecBody, 3 * sizeof(float));
susDataProcessed->sus1vec.setValid(sus1valid);
if (!sus1valid) {
std::memcpy(susDataProcessed->sus1vec.value, zeroVector, 3 * sizeof(float));
}
}
}
if (sus2valid) {
MatrixOperations<float>::multiply(
susParameters->sus2orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus2Value, susParameters->sus2coeffAlpha,
susParameters->sus2coeffBeta),
sus2VecBody, 3, 3, 1);
}
if (sus3valid) {
MatrixOperations<float>::multiply(
susParameters->sus3orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus3Value, susParameters->sus3coeffAlpha,
susParameters->sus3coeffBeta),
sus3VecBody, 3, 3, 1);
}
if (sus4valid) {
MatrixOperations<float>::multiply(
susParameters->sus4orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus4Value, susParameters->sus4coeffAlpha,
susParameters->sus4coeffBeta),
sus4VecBody, 3, 3, 1);
}
if (sus5valid) {
MatrixOperations<float>::multiply(
susParameters->sus5orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus5Value, susParameters->sus5coeffAlpha,
susParameters->sus5coeffBeta),
sus5VecBody, 3, 3, 1);
}
if (sus6valid) {
MatrixOperations<float>::multiply(
susParameters->sus6orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus6Value, susParameters->sus6coeffAlpha,
susParameters->sus6coeffBeta),
sus6VecBody, 3, 3, 1);
}
if (sus7valid) {
MatrixOperations<float>::multiply(
susParameters->sus7orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus7Value, susParameters->sus7coeffAlpha,
susParameters->sus7coeffBeta),
sus7VecBody, 3, 3, 1);
}
if (sus8valid) {
MatrixOperations<float>::multiply(
susParameters->sus8orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus8Value, susParameters->sus8coeffAlpha,
susParameters->sus8coeffBeta),
sus8VecBody, 3, 3, 1);
}
if (sus9valid) {
MatrixOperations<float>::multiply(
susParameters->sus9orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus9Value, susParameters->sus9coeffAlpha,
susParameters->sus9coeffBeta),
sus9VecBody, 3, 3, 1);
}
if (sus10valid) {
MatrixOperations<float>::multiply(
susParameters->sus10orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus10Value, susParameters->sus10coeffAlpha,
susParameters->sus10coeffBeta),
sus10VecBody, 3, 3, 1);
}
if (sus11valid) {
MatrixOperations<float>::multiply(
susParameters->sus11orientationMatrix[0],
susConverter.getSunVectorSensorFrame(sus11Value, susParameters->sus11coeffAlpha,
susParameters->sus11coeffBeta),
sus11VecBody, 3, 3, 1);
}
/* ------ Mean Value: susDirEst ------ */
bool validIds[12] = {sus0valid, sus1valid, sus2valid, sus3valid, sus4valid, sus5valid,
sus6valid, sus7valid, sus8valid, sus9valid, sus10valid, sus11valid};
float susVecBody[3][12] = {{sus0VecBody[0], sus1VecBody[0], sus2VecBody[0], sus3VecBody[0],
sus4VecBody[0], sus5VecBody[0], sus6VecBody[0], sus7VecBody[0],
sus8VecBody[0], sus9VecBody[0], sus10VecBody[0], sus11VecBody[0]},
{sus0VecBody[1], sus1VecBody[1], sus2VecBody[1], sus3VecBody[1],
sus4VecBody[1], sus5VecBody[1], sus6VecBody[1], sus7VecBody[1],
sus8VecBody[1], sus9VecBody[1], sus10VecBody[1], sus11VecBody[1]},
{sus0VecBody[2], sus1VecBody[2], sus2VecBody[2], sus3VecBody[2],
sus4VecBody[2], sus5VecBody[2], sus6VecBody[2], sus7VecBody[2],
sus8VecBody[2], sus9VecBody[2], sus10VecBody[2], sus11VecBody[2]}};
float susMeanValue[3] = {0, 0, 0};
for (uint8_t i = 0; i < 12; i++) {
if (validIds[i]) {
susMeanValue[0] += susVecBody[0][i];
susMeanValue[1] += susVecBody[1][i];
susMeanValue[2] += susVecBody[2][i];
}
}
float susVecTot[3] = {0.0, 0.0, 0.0};
VectorOperations<float>::normalize(susMeanValue, susVecTot, 3);
/* -------- Sun Derivatiative --------------------- */ /* -------- Sun Derivatiative --------------------- */
float susVecTotDerivative[3] = {0.0, 0.0, 0.0};
bool susVecTotDerivativeValid = false;
double timeDiff = timevalOperations::toDouble(timeOfSusMeasurement - timeOfSavedSusDirEst); double timeDiff = timevalOperations::toDouble(timeOfSusMeasurement - timeOfSavedSusDirEst);
for (uint8_t i = 0; i < 3; i++) { if (timeOfSavedSusDirEst.tv_sec != 0) {
sunVectorDerivative[i] = (sunDirEst[i] - savedSunVector[i]) / timeDiff; for (uint8_t i = 0; i < 3; i++) {
savedSunVector[i] = sunDirEst[i]; susVecTotDerivative[i] = (susVecTot[i] - savedSusVecTot[i]) / timeDiff;
savedSusVecTot[i] = susVecTot[i];
}
} }
*sunVectorDerivativeValid = true;
if (timeOfSavedSusDirEst.tv_sec == 0) {
sunVectorDerivative[0] = 0;
sunVectorDerivative[1] = 0;
sunVectorDerivative[2] = 0;
*sunVectorDerivativeValid = false;
}
timeOfSavedSusDirEst = timeOfSusMeasurement; timeOfSavedSusDirEst = timeOfSusMeasurement;
/* -------- Sun Model Direction (IJK frame) ------- */ /* -------- Sun Model Direction (IJK frame) ------- */
@ -340,6 +394,7 @@ void SensorProcessing::processSus(
double JD2000 = MathOperations<double>::convertUnixToJD2000(timeOfSusMeasurement); double JD2000 = MathOperations<double>::convertUnixToJD2000(timeOfSusMeasurement);
// Julean Centuries // Julean Centuries
double sunIjkModel[3] = {0.0, 0.0, 0.0};
double JC2000 = JD2000 / 36525; double JC2000 = JD2000 / 36525;
double meanLongitude = double meanLongitude =
@ -351,11 +406,46 @@ void SensorProcessing::processSus(
double epsilon = sunModelParameters->e - (sunModelParameters->e1) * JC2000; double epsilon = sunModelParameters->e - (sunModelParameters->e1) * JC2000;
sunVectorInertial[0] = cos(eclipticLongitude); sunIjkModel[0] = cos(eclipticLongitude);
sunVectorInertial[1] = sin(eclipticLongitude) * cos(epsilon); sunIjkModel[1] = sin(eclipticLongitude) * cos(epsilon);
sunVectorInertial[2] = sin(eclipticLongitude) * sin(epsilon); sunIjkModel[2] = sin(eclipticLongitude) * sin(epsilon);
{
*sunVectorInertialValid = true; PoolReadGuard pg(susDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(susDataProcessed->sus0vec.value, sus0VecBody, 3 * sizeof(float));
susDataProcessed->sus0vec.setValid(sus0valid);
std::memcpy(susDataProcessed->sus1vec.value, sus1VecBody, 3 * sizeof(float));
susDataProcessed->sus1vec.setValid(sus1valid);
std::memcpy(susDataProcessed->sus2vec.value, sus2VecBody, 3 * sizeof(float));
susDataProcessed->sus2vec.setValid(sus2valid);
std::memcpy(susDataProcessed->sus3vec.value, sus3VecBody, 3 * sizeof(float));
susDataProcessed->sus3vec.setValid(sus3valid);
std::memcpy(susDataProcessed->sus4vec.value, sus4VecBody, 3 * sizeof(float));
susDataProcessed->sus4vec.setValid(sus4valid);
std::memcpy(susDataProcessed->sus5vec.value, sus5VecBody, 3 * sizeof(float));
susDataProcessed->sus5vec.setValid(sus5valid);
std::memcpy(susDataProcessed->sus6vec.value, sus6VecBody, 3 * sizeof(float));
susDataProcessed->sus6vec.setValid(sus6valid);
std::memcpy(susDataProcessed->sus7vec.value, sus7VecBody, 3 * sizeof(float));
susDataProcessed->sus7vec.setValid(sus7valid);
std::memcpy(susDataProcessed->sus8vec.value, sus8VecBody, 3 * sizeof(float));
susDataProcessed->sus8vec.setValid(sus8valid);
std::memcpy(susDataProcessed->sus9vec.value, sus9VecBody, 3 * sizeof(float));
susDataProcessed->sus9vec.setValid(sus9valid);
std::memcpy(susDataProcessed->sus10vec.value, sus10VecBody, 3 * sizeof(float));
susDataProcessed->sus10vec.setValid(sus10valid);
std::memcpy(susDataProcessed->sus11vec.value, sus11VecBody, 3 * sizeof(float));
susDataProcessed->sus11vec.setValid(sus11valid);
std::memcpy(susDataProcessed->susVecTot.value, susVecTot, 3 * sizeof(float));
susDataProcessed->susVecTot.setValid(true);
std::memcpy(susDataProcessed->susVecTotDerivative.value, susVecTotDerivative,
3 * sizeof(float));
susDataProcessed->susVecTotDerivative.setValid(susVecTotDerivativeValid);
std::memcpy(susDataProcessed->sunIjkModel.value, sunIjkModel, 3 * sizeof(double));
susDataProcessed->sunIjkModel.setValid(true);
susDataProcessed->setValidity(true, false);
}
}
} }
void SensorProcessing::processGyr( void SensorProcessing::processGyr(
@ -366,133 +456,166 @@ void SensorProcessing::processGyr(
const double gyr2axZvalue, bool gyr2axZvalid, const double gyr3axXvalue, bool gyr3axXvalid, const double gyr2axZvalue, bool gyr2axZvalid, const double gyr3axXvalue, bool gyr3axXvalid,
const double gyr3axYvalue, bool gyr3axYvalid, const double gyr3axZvalue, bool gyr3axZvalid, const double gyr3axYvalue, bool gyr3axYvalid, const double gyr3axZvalue, bool gyr3axZvalid,
timeval timeOfGyrMeasurement, const AcsParameters::GyrHandlingParameters *gyrParameters, timeval timeOfGyrMeasurement, const AcsParameters::GyrHandlingParameters *gyrParameters,
double *satRatEst, bool *satRateEstValid) { acsctrl::GyrDataProcessed *gyrDataProcessed) {
if (!gyr0axXvalid && !gyr0axYvalid && !gyr0axZvalid && !gyr1axXvalid && !gyr1axYvalid && bool gyr0valid = (gyr0axXvalid && gyr0axYvalid && gyr0axZvalid);
!gyr1axZvalid && !gyr2axXvalid && !gyr2axYvalid && !gyr2axZvalid && !gyr3axXvalid && bool gyr1valid = (gyr1axXvalid && gyr1axYvalid && gyr1axZvalid);
!gyr3axYvalid && !gyr3axZvalid) { bool gyr2valid = (gyr2axXvalid && gyr2axYvalid && gyr2axZvalid);
*satRateEstValid = false; bool gyr3valid = (gyr3axXvalid && gyr3axYvalid && gyr3axZvalid);
if (!gyr0valid && !gyr1valid && !gyr2valid && !gyr3valid) {
{
PoolReadGuard pg(gyrDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(gyrDataProcessed->gyr0vec.value, zeroVector, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyr1vec.value, zeroVector, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyr2vec.value, zeroVector, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyr3vec.value, zeroVector, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyrVecTot.value, zeroVector, 3 * sizeof(double));
gyrDataProcessed->setValidity(false, true);
}
}
return; return;
} }
// Transforming Values to the Body Frame (actually it is the geometry frame atm) // Transforming Values to the Body Frame (actually it is the geometry frame atm)
double gyr0ValueBody[3] = {0, 0, 0}, gyr1ValueBody[3] = {0, 0, 0}, gyr2ValueBody[3] = {0, 0, 0}, double gyr0ValueBody[3] = {0, 0, 0}, gyr1ValueBody[3] = {0, 0, 0}, gyr2ValueBody[3] = {0, 0, 0},
gyr3ValueBody[3] = {0, 0, 0}; gyr3ValueBody[3] = {0, 0, 0};
bool validUnit[4] = {false, false, false, false}; if (gyr0valid) {
if (gyr0axXvalid && gyr0axYvalid && gyr0axZvalid) {
const double gyr0Value[3] = {gyr0axXvalue, gyr0axYvalue, gyr0axZvalue}; const double gyr0Value[3] = {gyr0axXvalue, gyr0axYvalue, gyr0axZvalue};
MatrixOperations<double>::multiply(gyrParameters->gyr0orientationMatrix[0], gyr0Value, MatrixOperations<double>::multiply(gyrParameters->gyr0orientationMatrix[0], gyr0Value,
gyr0ValueBody, 3, 3, 1); gyr0ValueBody, 3, 3, 1);
validUnit[0] = true;
} }
if (gyr1axXvalid && gyr1axYvalid && gyr1axZvalid) { if (gyr1valid) {
const double gyr1Value[3] = {gyr1axXvalue, gyr1axYvalue, gyr1axZvalue}; const double gyr1Value[3] = {gyr1axXvalue, gyr1axYvalue, gyr1axZvalue};
MatrixOperations<double>::multiply(gyrParameters->gyr1orientationMatrix[0], gyr1Value, MatrixOperations<double>::multiply(gyrParameters->gyr1orientationMatrix[0], gyr1Value,
gyr1ValueBody, 3, 3, 1); gyr1ValueBody, 3, 3, 1);
validUnit[1] = true;
} }
if (gyr2axXvalid && gyr2axYvalid && gyr2axZvalid) { if (gyr2valid) {
const double gyr2Value[3] = {gyr2axXvalue, gyr2axYvalue, gyr2axZvalue}; const double gyr2Value[3] = {gyr2axXvalue, gyr2axYvalue, gyr2axZvalue};
MatrixOperations<double>::multiply(gyrParameters->gyr2orientationMatrix[0], gyr2Value, MatrixOperations<double>::multiply(gyrParameters->gyr2orientationMatrix[0], gyr2Value,
gyr2ValueBody, 3, 3, 1); gyr2ValueBody, 3, 3, 1);
validUnit[2] = true;
} }
if (gyr3axXvalid && gyr3axYvalid && gyr3axZvalid) { if (gyr3valid) {
const double gyr3Value[3] = {gyr3axXvalue, gyr3axYvalue, gyr3axZvalue}; const double gyr3Value[3] = {gyr3axXvalue, gyr3axYvalue, gyr3axZvalue};
MatrixOperations<double>::multiply(gyrParameters->gyr3orientationMatrix[0], gyr3Value, MatrixOperations<double>::multiply(gyrParameters->gyr3orientationMatrix[0], gyr3Value,
gyr3ValueBody, 3, 3, 1); gyr3ValueBody, 3, 3, 1);
validUnit[3] = true;
} }
/* -------- SatRateEst: Middle Value ------- */ /* -------- SatRateEst: Middle Value ------- */
// take ADIS measurements, if both avail // take ADIS measurements, if both avail
// if just one ADIS measurement avail, perform sensor fusion // if just one ADIS measurement avail, perform sensor fusion
if (validUnit[0] && validUnit[2]) { double gyrVecTot[3] = {0.0, 0.0, 0.0};
if (gyr0valid && gyr2valid) {
double gyr02ValuesSum[3]; double gyr02ValuesSum[3];
VectorOperations<double>::add(gyr0ValueBody, gyr2ValueBody, gyr02ValuesSum, 3); VectorOperations<double>::add(gyr0ValueBody, gyr2ValueBody, gyr02ValuesSum, 3);
VectorOperations<double>::mulScalar(gyr02ValuesSum, .5, satRatEst, 3); VectorOperations<double>::mulScalar(gyr02ValuesSum, .5, gyrVecTot, 3);
} else if ((validUnit[0] || validUnit[2]) && !(validUnit[1] || validUnit[3])) { } else if ((gyr0valid || gyr2valid) && !(gyr1valid || gyr3valid)) {
if (validUnit[0]) { if (gyr0valid) {
satRatEst = gyr0ValueBody; std::memcpy(gyrVecTot, gyr0ValueBody, 3 * sizeof(double));
} else if (validUnit[2]) { } else if (gyr2valid) {
satRatEst = gyr2ValueBody; std::memcpy(gyrVecTot, gyr2ValueBody, 3 * sizeof(double));
} }
} else if ((validUnit[1]) && (validUnit[3])) { } else if (gyr1valid && gyr3valid) {
double gyr13ValuesSum[3]; double gyr13ValuesSum[3];
double gyr13ValuesMean[3]; double gyr13ValuesMean[3];
VectorOperations<double>::add(gyr1ValueBody, gyr3ValueBody, gyr13ValuesSum, 3); VectorOperations<double>::add(gyr1ValueBody, gyr3ValueBody, gyr13ValuesSum, 3);
VectorOperations<double>::mulScalar(gyr13ValuesSum, .5, gyr13ValuesMean, 3); VectorOperations<double>::mulScalar(gyr13ValuesSum, .5, gyr13ValuesMean, 3);
if (validUnit[0]) { if (gyr0valid) {
satRatEst[0] = gyrVecTot[0] =
((gyr0ValueBody[0] / gyrParameters->gyr02variance[0]) + ((gyr0ValueBody[0] / gyrParameters->gyr02variance[0]) +
(gyr13ValuesMean[0] / gyrParameters->gyr13variance[0])) / (gyr13ValuesMean[0] / gyrParameters->gyr13variance[0])) /
((1 / gyrParameters->gyr02variance[0]) + (1 / gyrParameters->gyr13variance[0])); ((1 / gyrParameters->gyr02variance[0]) + (1 / gyrParameters->gyr13variance[0]));
satRatEst[1] = gyrVecTot[1] =
((gyr0ValueBody[1] / gyrParameters->gyr02variance[1]) + ((gyr0ValueBody[1] / gyrParameters->gyr02variance[1]) +
(gyr13ValuesMean[1] / gyrParameters->gyr13variance[1])) / (gyr13ValuesMean[1] / gyrParameters->gyr13variance[1])) /
((1 / gyrParameters->gyr02variance[1]) + (1 / gyrParameters->gyr13variance[1])); ((1 / gyrParameters->gyr02variance[1]) + (1 / gyrParameters->gyr13variance[1]));
satRatEst[2] = gyrVecTot[2] =
((gyr0ValueBody[2] / gyrParameters->gyr02variance[2]) + ((gyr0ValueBody[2] / gyrParameters->gyr02variance[2]) +
(gyr13ValuesMean[2] / gyrParameters->gyr13variance[2])) / (gyr13ValuesMean[2] / gyrParameters->gyr13variance[2])) /
((1 / gyrParameters->gyr02variance[2]) + (1 / gyrParameters->gyr13variance[2])); ((1 / gyrParameters->gyr02variance[2]) + (1 / gyrParameters->gyr13variance[2]));
} else if (validUnit[2]) { } else if (gyr2valid) {
satRatEst[0] = gyrVecTot[0] =
((gyr2ValueBody[0] / gyrParameters->gyr02variance[0]) + ((gyr2ValueBody[0] / gyrParameters->gyr02variance[0]) +
(gyr13ValuesMean[0] / gyrParameters->gyr13variance[0])) / (gyr13ValuesMean[0] / gyrParameters->gyr13variance[0])) /
((1 / gyrParameters->gyr02variance[0]) + (1 / gyrParameters->gyr13variance[0])); ((1 / gyrParameters->gyr02variance[0]) + (1 / gyrParameters->gyr13variance[0]));
satRatEst[1] = gyrVecTot[1] =
((gyr2ValueBody[1] / gyrParameters->gyr02variance[1]) + ((gyr2ValueBody[1] / gyrParameters->gyr02variance[1]) +
(gyr13ValuesMean[1] / gyrParameters->gyr13variance[1])) / (gyr13ValuesMean[1] / gyrParameters->gyr13variance[1])) /
((1 / gyrParameters->gyr02variance[1]) + (1 / gyrParameters->gyr13variance[1])); ((1 / gyrParameters->gyr02variance[1]) + (1 / gyrParameters->gyr13variance[1]));
satRatEst[2] = gyrVecTot[2] =
((gyr2ValueBody[2] / gyrParameters->gyr02variance[2]) + ((gyr2ValueBody[2] / gyrParameters->gyr02variance[2]) +
(gyr13ValuesMean[2] / gyrParameters->gyr13variance[2])) / (gyr13ValuesMean[2] / gyrParameters->gyr13variance[2])) /
((1 / gyrParameters->gyr02variance[2]) + (1 / gyrParameters->gyr13variance[2])); ((1 / gyrParameters->gyr02variance[2]) + (1 / gyrParameters->gyr13variance[2]));
} else } else {
satRatEst = gyr13ValuesMean; std::memcpy(gyrVecTot, gyr13ValuesMean, 3 * sizeof(double));
} else if (validUnit[1]) { }
satRatEst = gyr1ValueBody; } else if (gyr1valid) {
} else if (validUnit[3]) { std::memcpy(gyrVecTot, gyr1ValueBody, 3 * sizeof(double));
satRatEst = gyr3ValueBody; } else if (gyr3valid) {
std::memcpy(gyrVecTot, gyr3ValueBody, 3 * sizeof(double));
}
{
PoolReadGuard pg(gyrDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
std::memcpy(gyrDataProcessed->gyr0vec.value, gyr0ValueBody, 3 * sizeof(double));
gyrDataProcessed->gyr0vec.setValid(gyr0valid);
std::memcpy(gyrDataProcessed->gyr1vec.value, gyr1ValueBody, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyr2vec.value, gyr2ValueBody, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyr3vec.value, gyr3ValueBody, 3 * sizeof(double));
std::memcpy(gyrDataProcessed->gyrVecTot.value, gyrVecTot, 3 * sizeof(double));
gyrDataProcessed->setValidity(true, false);
}
} }
*satRateEstValid = true;
} }
void SensorProcessing::processGps(const double gps0latitude, const double gps0longitude, void SensorProcessing::processGps(const double gps0latitude, const double gps0longitude,
const bool validGps, double *gcLatitude, double *gdLongitude) { const bool validGps,
acsctrl::GpsDataProcessed *gpsDataProcessed) {
// name to convert not process // name to convert not process
double gdLongitude, gcLatitude;
if (validGps) { if (validGps) {
// Transforming from Degree to Radians and calculation geocentric lattitude from geodetic // Transforming from Degree to Radians and calculation geocentric lattitude from geodetic
*gdLongitude = gps0longitude * PI / 180; gdLongitude = gps0longitude * PI / 180;
double latitudeRad = gps0latitude * PI / 180; double latitudeRad = gps0latitude * PI / 180;
double eccentricityWgs84 = 0.0818195; double eccentricityWgs84 = 0.0818195;
double factor = 1 - pow(eccentricityWgs84, 2); double factor = 1 - pow(eccentricityWgs84, 2);
*gcLatitude = atan(factor * tan(latitudeRad)); gcLatitude = atan(factor * tan(latitudeRad));
validGcLatitude = true; // validGcLatitude = true;
}
{
PoolReadGuard pg(gpsDataProcessed);
if (pg.getReadResult() == returnvalue::OK) {
gpsDataProcessed->gdLongitude.value = gdLongitude;
gpsDataProcessed->gcLatitude.value = gcLatitude;
gpsDataProcessed->setValidity(validGps, validGps);
if (!validGps) {
gpsDataProcessed->gdLongitude.value = 0.0;
gpsDataProcessed->gcLatitude.value = 0.0;
}
}
} }
} }
void SensorProcessing::process(timeval now, ACS::SensorValues *sensorValues, void SensorProcessing::process(timeval now, ACS::SensorValues *sensorValues,
ACS::OutputValues *outputValues, acsctrl::MgmDataProcessed *mgmDataProcessed,
acsctrl::SusDataProcessed *susDataProcessed,
acsctrl::GyrDataProcessed *gyrDataProcessed,
acsctrl::GpsDataProcessed *gpsDataProcessed,
const AcsParameters *acsParameters) { const AcsParameters *acsParameters) {
sensorValues->update(); sensorValues->update();
processGps(sensorValues->gpsSet.latitude.value, sensorValues->gpsSet.longitude.value, processGps(sensorValues->gpsSet.latitude.value, sensorValues->gpsSet.longitude.value,
sensorValues->gpsSet.isValid(), &outputValues->gcLatitude, &outputValues->gdLongitude); sensorValues->gpsSet.isValid(), gpsDataProcessed);
outputValues->mgmUpdated = processMgm( processMgm(sensorValues->mgm0Lis3Set.fieldStrengths.value,
sensorValues->mgm0Lis3Set.fieldStrengths.value, sensorValues->mgm0Lis3Set.fieldStrengths.isValid(),
sensorValues->mgm0Lis3Set.fieldStrengths.isValid(), sensorValues->mgm1Rm3100Set.fieldStrengths.value,
sensorValues->mgm1Rm3100Set.fieldStrengths.value, sensorValues->mgm1Rm3100Set.fieldStrengths.isValid(),
sensorValues->mgm1Rm3100Set.fieldStrengths.isValid(), sensorValues->mgm2Lis3Set.fieldStrengths.value,
sensorValues->mgm2Lis3Set.fieldStrengths.value, sensorValues->mgm2Lis3Set.fieldStrengths.isValid(),
sensorValues->mgm2Lis3Set.fieldStrengths.isValid(), sensorValues->mgm3Rm3100Set.fieldStrengths.value,
sensorValues->mgm3Rm3100Set.fieldStrengths.value, sensorValues->mgm3Rm3100Set.fieldStrengths.isValid(),
sensorValues->mgm3Rm3100Set.fieldStrengths.isValid(), sensorValues->imtqMgmSet.mtmRawNt.value, sensorValues->imtqMgmSet.mtmRawNt.value, sensorValues->imtqMgmSet.mtmRawNt.isValid(),
sensorValues->imtqMgmSet.mtmRawNt.isValid(), now, &acsParameters->mgmHandlingParameters, now, &acsParameters->mgmHandlingParameters, gpsDataProcessed,
outputValues->gcLatitude, outputValues->gdLongitude, sensorValues->gpsSet.altitude.value, sensorValues->gpsSet.altitude.value, sensorValues->gpsSet.isValid(), mgmDataProcessed);
sensorValues->gpsSet.isValid(), outputValues->magFieldEst, &outputValues->magFieldEstValid,
outputValues->magFieldModel, &outputValues->magFieldModelValid,
outputValues->magneticFieldVectorDerivative,
&outputValues->magneticFieldVectorDerivativeValid); // VALID outputs- PoolVariable ?
processSus(sensorValues->susSets[0].channels.value, sensorValues->susSets[0].channels.isValid(), processSus(sensorValues->susSets[0].channels.value, sensorValues->susSets[0].channels.isValid(),
sensorValues->susSets[1].channels.value, sensorValues->susSets[1].channels.isValid(), sensorValues->susSets[1].channels.value, sensorValues->susSets[1].channels.isValid(),
@ -507,10 +630,7 @@ void SensorProcessing::process(timeval now, ACS::SensorValues *sensorValues,
sensorValues->susSets[10].channels.value, sensorValues->susSets[10].channels.isValid(), sensorValues->susSets[10].channels.value, sensorValues->susSets[10].channels.isValid(),
sensorValues->susSets[11].channels.value, sensorValues->susSets[11].channels.isValid(), sensorValues->susSets[11].channels.value, sensorValues->susSets[11].channels.isValid(),
now, &acsParameters->susHandlingParameters, &acsParameters->sunModelParameters, now, &acsParameters->susHandlingParameters, &acsParameters->sunModelParameters,
outputValues->sunDirEst, &outputValues->sunDirEstValid, outputValues->sunDirModel, susDataProcessed);
&outputValues->sunDirModelValid, outputValues->sunVectorDerivative,
&outputValues->sunVectorDerivativeValid);
// VALID outputs ?
processGyr( processGyr(
sensorValues->gyr0AdisSet.angVelocX.value, sensorValues->gyr0AdisSet.angVelocX.isValid(), sensorValues->gyr0AdisSet.angVelocX.value, sensorValues->gyr0AdisSet.angVelocX.isValid(),
@ -525,6 +645,5 @@ void SensorProcessing::process(timeval now, ACS::SensorValues *sensorValues,
sensorValues->gyr3L3gSet.angVelocX.value, sensorValues->gyr3L3gSet.angVelocX.isValid(), sensorValues->gyr3L3gSet.angVelocX.value, sensorValues->gyr3L3gSet.angVelocX.isValid(),
sensorValues->gyr3L3gSet.angVelocY.value, sensorValues->gyr3L3gSet.angVelocY.isValid(), sensorValues->gyr3L3gSet.angVelocY.value, sensorValues->gyr3L3gSet.angVelocY.isValid(),
sensorValues->gyr3L3gSet.angVelocZ.value, sensorValues->gyr3L3gSet.angVelocZ.isValid(), now, sensorValues->gyr3L3gSet.angVelocZ.value, sensorValues->gyr3L3gSet.angVelocZ.isValid(), now,
&acsParameters->gyrHandlingParameters, outputValues->satRateEst, &acsParameters->gyrHandlingParameters, gyrDataProcessed);
&outputValues->satRateEstValid);
} }

31
mission/controller/acs/SensorProcessing.h
View File

@ -23,19 +23,21 @@ class SensorProcessing {
SensorProcessing(AcsParameters *acsParameters_); SensorProcessing(AcsParameters *acsParameters_);
virtual ~SensorProcessing(); virtual ~SensorProcessing();
void process(timeval now, ACS::SensorValues *sensorValues, ACS::OutputValues *outputValues, void process(timeval now, ACS::SensorValues *sensorValues,
acsctrl::MgmDataProcessed *mgmDataProcessed,
acsctrl::SusDataProcessed *susDataProcessed,
acsctrl::GyrDataProcessed *gyrDataProcessed,
acsctrl::GpsDataProcessed *gpsDataProcessed,
const AcsParameters *acsParameters); // Will call protected functions const AcsParameters *acsParameters); // Will call protected functions
private: private:
protected: protected:
// short description needed for every function // short description needed for every function
bool processMgm(const float *mgm0Value, bool mgm0valid, const float *mgm1Value, bool mgm1valid, void processMgm(const float *mgm0Value, bool mgm0valid, const float *mgm1Value, bool mgm1valid,
const float *mgm2Value, bool mgm2valid, const float *mgm3Value, bool mgm3valid, const float *mgm2Value, bool mgm2valid, const float *mgm3Value, bool mgm3valid,
const float *mgm4Value, bool mgm4valid, timeval timeOfMgmMeasurement, const float *mgm4Value, bool mgm4valid, timeval timeOfMgmMeasurement,
const AcsParameters::MgmHandlingParameters *mgmParameters, const AcsParameters::MgmHandlingParameters *mgmParameters,
const double gpsLatitude, const double gpsLongitude, const double gpsAltitude, acsctrl::GpsDataProcessed *gpsDataProcessed, const double gpsAltitude,
bool gpsValid, double *magFieldEst, bool *outputValid, double *magFieldModel, bool gpsValid, acsctrl::MgmDataProcessed *mgmDataProcessed);
bool *magFieldModelValid, double *magneticFieldVectorDerivative,
bool *magneticFieldVectorDerivativeValid); // Output
void processSus(const uint16_t *sus0Value, bool sus0valid, const uint16_t *sus1Value, void processSus(const uint16_t *sus0Value, bool sus0valid, const uint16_t *sus1Value,
bool sus1valid, const uint16_t *sus2Value, bool sus2valid, bool sus1valid, const uint16_t *sus2Value, bool sus2valid,
@ -47,9 +49,8 @@ class SensorProcessing {
bool sus10valid, const uint16_t *sus11Value, bool sus11valid, bool sus10valid, const uint16_t *sus11Value, bool sus11valid,
timeval timeOfSusMeasurement, timeval timeOfSusMeasurement,
const AcsParameters::SusHandlingParameters *susParameters, const AcsParameters::SusHandlingParameters *susParameters,
const AcsParameters::SunModelParameters *sunModelParameters, double *sunDirEst, const AcsParameters::SunModelParameters *sunModelParameters,
bool *sunDirEstValid, double *sunVectorInertial, bool *sunVectorInertialValid, acsctrl::SusDataProcessed *susDataProcessed);
double *sunVectorDerivative, bool *sunVectorDerivativeValid);
void processGyr(const double gyr0axXvalue, bool gyr0axXvalid, const double gyr0axYvalue, void processGyr(const double gyr0axXvalue, bool gyr0axXvalid, const double gyr0axYvalue,
bool gyr0axYvalid, const double gyr0axZvalue, bool gyr0axZvalid, bool gyr0axYvalid, const double gyr0axZvalue, bool gyr0axZvalid,
@ -60,21 +61,23 @@ class SensorProcessing {
const double gyr3axXvalue, bool gyr3axXvalid, const double gyr3axYvalue, const double gyr3axXvalue, bool gyr3axXvalid, const double gyr3axYvalue,
bool gyr3axYvalid, const double gyr3axZvalue, bool gyr3axZvalid, bool gyr3axYvalid, const double gyr3axZvalue, bool gyr3axZvalid,
timeval timeOfGyrMeasurement, timeval timeOfGyrMeasurement,
const AcsParameters::GyrHandlingParameters *gyrParameters, double *satRatEst, const AcsParameters::GyrHandlingParameters *gyrParameters,
bool *satRateEstValid); acsctrl::GyrDataProcessed *gyrDataProcessed);
void processStr(); void processStr();
void processGps(const double gps0latitude, const double gps0longitude, const bool validGps, void processGps(const double gps0latitude, const double gps0longitude, const bool validGps,
double *gcLatitude, double *gdLongitude); acsctrl::GpsDataProcessed *gpsDataProcessed);
double savedMagFieldEst[3]; double savedMgmVecTot[3];
timeval timeOfSavedMagFieldEst; timeval timeOfSavedMagFieldEst;
double savedSunVector[3]; double savedSusVecTot[3];
timeval timeOfSavedSusDirEst; timeval timeOfSavedSusDirEst;
bool validMagField; bool validMagField;
bool validGcLatitude; bool validGcLatitude;
const float zeroVector[3] = {0.0, 0.0, 0.0};
SusConverter susConverter; SusConverter susConverter;
AcsParameters acsParameters; AcsParameters acsParameters;
}; };