eive-obsw/mission/controller/ThermalController.h
Robin Mueller 7c4f98ec22
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#ifndef MISSION_CONTROLLER_THERMALCONTROLLER_H_
#define MISSION_CONTROLLER_THERMALCONTROLLER_H_
#include <bsp_q7s/core/defs.h>
#include <fsfw/controller/ExtendedControllerBase.h>
#include <fsfw/devicehandlers/DeviceHandlerThermalSet.h>
#include <fsfw/timemanager/Countdown.h>
#include <fsfw_hal/devicehandlers/devicedefinitions/gyroL3gHelpers.h>
#include <fsfw_hal/devicehandlers/devicedefinitions/mgmLis3Helpers.h>
#include <mission/acs/gyroAdisHelpers.h>
#include <mission/acs/imtqHelpers.h>
#include <mission/acs/rwHelpers.h>
#include <mission/acs/str/strHelpers.h>
#include <mission/acs/susMax1227Helpers.h>
#include <mission/com/syrlinksDefs.h>
#include <mission/controller/tcsDefs.h>
#include <mission/payload/payloadPcduDefinitions.h>
#include <mission/power/bpxBattDefs.h>
#include <mission/power/gsDefs.h>
#include <mission/tcs/HeaterHandler.h>
#include <mission/tcs/Max31865Definitions.h>
#include <mission/tcs/Tmp1075Definitions.h>
#include <mission/utility/trace.h>
#include <atomic>
#include <list>
/**
* NOP Limit: Hard limit for device, usually from datasheet. Device damage is possible lif NOP limit
* is exceeded.
* OP Limit: Soft limit. Device should be switched off or TCS controller should take action if the
* limit is exceeded to avoid reaching NOP limit
*/
struct TempLimits {
TempLimits(float nopLowerLimit, float opLowerLimit, float cutOffLimit, float opUpperLimit,
float nopUpperLimit)
: opLowerLimit(opLowerLimit),
opUpperLimit(opUpperLimit),
cutOffLimit(cutOffLimit),
nopLowerLimit(nopLowerLimit),
nopUpperLimit(nopUpperLimit) {}
float opLowerLimit;
float opUpperLimit;
float cutOffLimit;
float nopLowerLimit;
float nopUpperLimit;
};
struct ThermalState {
uint8_t noSensorAvailableCounter;
// Is heating on for that thermal module?
bool heating = false;
heater::Switch heaterSwitch = heater::Switch::NUMBER_OF_SWITCHES;
// Heater start time and end times as UNIX seconds. Please note that these times will be updated
// when a switch command is sent, with no guarantess that the heater actually went on.
uint32_t heaterStartTime = 0;
uint32_t heaterEndTime = 0;
};
struct HeaterState {
bool switchTransition;
HeaterHandler::SwitchState target;
uint8_t heaterSwitchControlCycles;
};
using HeaterSwitchStates = std::array<HeaterHandler::SwitchState, heater::NUMBER_OF_SWITCHES>;
enum ThermalComponents : uint8_t {
NONE = 0,
ACS_BOARD = 1,
MGT = 2,
RW = 3,
STR = 4,
IF_BOARD = 5,
TCS_BOARD = 6,
OBC = 7,
// Not used anymore, was identical to OBC module.
LEGACY_OBCIF_BOARD = 8,
SBAND_TRANSCEIVER = 9,
PCDUP60_BOARD = 10,
PCDUACU = 11,
PCDUPDU = 12,
PLPCDU_BOARD = 13,
PLOCMISSION_BOARD = 14,
PLOCPROCESSING_BOARD = 15,
DAC = 16,
CAMERA = 17,
DRO = 18,
X8 = 19,
HPA = 20,
TX = 21,
MPA = 22,
SCEX_BOARD = 23,
NUM_ENTRIES
};
class ThermalController : public ExtendedControllerBase {
public:
static constexpr uint8_t SUBMODE_NO_HEATER_CTRL = 1;
static const uint16_t INVALID_TEMPERATURE = 999;
static const uint8_t NUMBER_OF_SENSORS = 16;
static constexpr int16_t SANITY_LIMIT_LOWER_TEMP = -80;
static constexpr int16_t SANITY_LIMIT_UPPER_TEMP = 160;
ThermalController(object_id_t objectId, HeaterHandler& heater,
const std::atomic_bool& tcsBoardShortUnavailable, bool pollPcdu1Tmp);
virtual ~ThermalController();
ReturnValue_t initialize() override;
protected:
struct HeaterContext {
public:
HeaterContext(heater::Switch switchNr, heater::Switch redundantSwitchNr,
const TempLimits& tempLimit)
: switchNr(switchNr), redSwitchNr(redundantSwitchNr), tempLimit(tempLimit) {}
bool doHeaterHandling = true;
heater::Switch switchNr;
HeaterHandler::SwitchState switchState = HeaterHandler::SwitchState::OFF;
heater::Switch redSwitchNr;
const TempLimits& tempLimit;
};
void performThermalModuleCtrl(const HeaterSwitchStates& heaterSwitchStates);
ReturnValue_t handleCommandMessage(CommandMessage* message) override;
void performControlOperation() override;
ReturnValue_t initializeLocalDataPool(localpool::DataPool& localDataPoolMap,
LocalDataPoolManager& poolManager) override;
LocalPoolDataSetBase* getDataSetHandle(sid_t sid) override;
// Mode abstract functions
ReturnValue_t checkModeCommand(Mode_t mode, Submode_t submode,
uint32_t* msToReachTheMode) override;
private:
static const uint32_t INIT_DELAY = 1500;
static const uint32_t TEMP_OFFSET = 5;
enum class InternalState { STARTUP, INITIAL_DELAY, READY };
InternalState internalState = InternalState::STARTUP;
HeaterHandler& heaterHandler;
bool pollPcdu1Tmp;
tcsCtrl::SensorTemperatures sensorTemperatures;
tcsCtrl::SusTemperatures susTemperatures;
tcsCtrl::DeviceTemperatures deviceTemperatures;
tcsCtrl::HeaterInfo heaterInfo;
lp_vec_t<int16_t, 9> currentVecPdu2 =
lp_vec_t<int16_t, 9>(gp_id_t(objects::PDU2_HANDLER, PDU::pool::PDU_CURRENTS));
DeviceHandlerThermalSet imtqThermalSet;
// Temperature Sensors
MAX31865::PrimarySet maxSet0PlocHspd;
MAX31865::PrimarySet maxSet1PlocMissionBrd;
MAX31865::PrimarySet maxSet2PlCam;
MAX31865::PrimarySet maxSet3DacHspd;
MAX31865::PrimarySet maxSet4Str;
MAX31865::PrimarySet maxSet5Rw1MxMy;
MAX31865::PrimarySet maxSet6Dro;
MAX31865::PrimarySet maxSet7Scex;
MAX31865::PrimarySet maxSet8X8;
MAX31865::PrimarySet maxSet9Hpa;
MAX31865::PrimarySet maxSet10EbandTx;
MAX31865::PrimarySet maxSet11Mpa;
MAX31865::PrimarySet maxSet31865Set12;
MAX31865::PrimarySet maxSet13PlPcduHspd;
MAX31865::PrimarySet maxSet14TcsBrd;
MAX31865::PrimarySet maxSet15Imtq;
TMP1075::Tmp1075Dataset tmp1075SetTcs0;
TMP1075::Tmp1075Dataset tmp1075SetTcs1;
TMP1075::Tmp1075Dataset tmp1075SetPlPcdu0;
// damaged
TMP1075::Tmp1075Dataset* tmp1075SetPlPcdu1;
TMP1075::Tmp1075Dataset tmp1075SetIfBoard;
// SUS
susMax1227::SusDataset susSet0;
susMax1227::SusDataset susSet1;
susMax1227::SusDataset susSet2;
susMax1227::SusDataset susSet3;
susMax1227::SusDataset susSet4;
susMax1227::SusDataset susSet5;
susMax1227::SusDataset susSet6;
susMax1227::SusDataset susSet7;
susMax1227::SusDataset susSet8;
susMax1227::SusDataset susSet9;
susMax1227::SusDataset susSet10;
susMax1227::SusDataset susSet11;
// If the TCS board in unavailable, for example due to a recovery, skip
// some TCS controller tasks to avoid unnecessary events.
const std::atomic_bool& tcsBrdShortlyUnavailable = false;
lp_var_t<float> tempQ7s = lp_var_t<float>(objects::CORE_CONTROLLER, core::PoolIds::TEMPERATURE);
lp_var_t<int16_t> battTemp1 = lp_var_t<int16_t>(objects::BPX_BATT_HANDLER, bpxBat::BATT_TEMP_1);
lp_var_t<int16_t> battTemp2 = lp_var_t<int16_t>(objects::BPX_BATT_HANDLER, bpxBat::BATT_TEMP_2);
lp_var_t<int16_t> battTemp3 = lp_var_t<int16_t>(objects::BPX_BATT_HANDLER, bpxBat::BATT_TEMP_3);
lp_var_t<int16_t> battTemp4 = lp_var_t<int16_t>(objects::BPX_BATT_HANDLER, bpxBat::BATT_TEMP_4);
lp_var_t<int32_t> tempRw1 = lp_var_t<int32_t>(objects::RW1, rws::TEMPERATURE_C);
lp_var_t<int32_t> tempRw2 = lp_var_t<int32_t>(objects::RW2, rws::TEMPERATURE_C);
lp_var_t<int32_t> tempRw3 = lp_var_t<int32_t>(objects::RW3, rws::TEMPERATURE_C);
lp_var_t<int32_t> tempRw4 = lp_var_t<int32_t>(objects::RW4, rws::TEMPERATURE_C);
lp_var_t<float> tempStartracker =
lp_var_t<float>(objects::STAR_TRACKER, startracker::MCU_TEMPERATURE);
lp_var_t<float> tempSyrlinksPowerAmplifier =
lp_var_t<float>(objects::SYRLINKS_HANDLER, syrlinks::TEMP_POWER_AMPLIFIER);
lp_var_t<float> tempSyrlinksBasebandBoard =
lp_var_t<float>(objects::SYRLINKS_HANDLER, syrlinks::TEMP_BASEBAND_BOARD);
lp_var_t<int16_t> tempMgt = lp_var_t<int16_t>(objects::IMTQ_HANDLER, imtq::MCU_TEMPERATURE);
lp_vec_t<float, 3> tempAcu =
lp_vec_t<float, 3>(objects::ACU_HANDLER, ACU::pool::ACU_TEMPERATURES);
lp_var_t<float> tempPdu1 = lp_var_t<float>(objects::PDU1_HANDLER, PDU::pool::PDU_TEMPERATURE);
lp_var_t<float> tempPdu2 = lp_var_t<float>(objects::PDU2_HANDLER, PDU::pool::PDU_TEMPERATURE);
lp_var_t<float> temp1P60dock =
lp_var_t<float>(objects::P60DOCK_HANDLER, P60Dock::pool::P60DOCK_TEMPERATURE_1);
lp_var_t<float> temp2P60dock =
lp_var_t<float>(objects::P60DOCK_HANDLER, P60Dock::pool::P60DOCK_TEMPERATURE_2);
lp_var_t<float> tempGyro0 = lp_var_t<float>(objects::GYRO_0_ADIS_HANDLER, adis1650x::TEMPERATURE);
lp_var_t<float> tempGyro1 = lp_var_t<float>(objects::GYRO_1_L3G_HANDLER, l3gd20h::TEMPERATURE);
lp_var_t<float> tempGyro2 = lp_var_t<float>(objects::GYRO_2_ADIS_HANDLER, adis1650x::TEMPERATURE);
lp_var_t<float> tempGyro3 = lp_var_t<float>(objects::GYRO_3_L3G_HANDLER, l3gd20h::TEMPERATURE);
lp_var_t<float> tempMgm0 =
lp_var_t<float>(objects::MGM_0_LIS3_HANDLER, mgmLis3::TEMPERATURE_CELCIUS);
lp_var_t<float> tempMgm2 =
lp_var_t<float>(objects::MGM_2_LIS3_HANDLER, mgmLis3::TEMPERATURE_CELCIUS);
lp_var_t<float> tempAdcPayloadPcdu = lp_var_t<float>(objects::PLPCDU_HANDLER, plpcdu::TEMP);
// TempLimits
TempLimits acsBoardLimits = TempLimits(-40.0, -40.0, 80.0, 85.0, 85.0);
TempLimits mgtLimits = TempLimits(-40.0, -40.0, 65.0, 70.0, 70.0);
TempLimits rwLimits = TempLimits(-40.0, -40.0, 80.0, 85.0, 85.0);
TempLimits strLimits = TempLimits(-30.0, -20.0, 65.0, 70.0, 80.0);
TempLimits ifBoardLimits = TempLimits(-65.0, -40.0, 80.0, 85.0, 150.0);
TempLimits tcsBoardLimits = TempLimits(-60.0, -40.0, 80.0, 85.0, 130.0);
TempLimits obcLimits = TempLimits(-40.0, -40.0, 80.0, 85.0, 85.0);
TempLimits obcIfBoardLimits = TempLimits(-65.0, -40.0, 80.0, 85.0, 125.0);
TempLimits sBandTransceiverLimits = TempLimits(-40.0, -25.0, 35.0, 40.0, 65.0);
TempLimits pcduP60BoardLimits = TempLimits(-35.0, -35.0, 80.0, 85.0, 85.0);
TempLimits pcduAcuLimits = TempLimits(-35.0, -35.0, 80.0, 85.0, 85.0);
TempLimits pcduPduLimits = TempLimits(-35.0, -35.0, 80.0, 85.0, 85.0);
TempLimits plPcduBoardLimits = TempLimits(-55.0, -40.0, 80.0, 85.0, 125.0);
TempLimits plocMissionBoardLimits = TempLimits(-30.0, -10.0, 40.0, 45.0, 60);
TempLimits plocProcessingBoardLimits = TempLimits(-30.0, -10.0, 40.0, 45.0, 60.0);
TempLimits dacLimits = TempLimits(-65.0, -40.0, 113.0, 118.0, 150.0);
TempLimits cameraLimits = TempLimits(-40.0, -30.0, 60.0, 65.0, 85.0);
TempLimits droLimits = TempLimits(-40.0, -30.0, 75.0, 80.0, 90.0);
TempLimits x8Limits = TempLimits(-40.0, -30.0, 75.0, 80.0, 90.0);
TempLimits hpaLimits = TempLimits(-40.0, -30.0, 75.0, 80.0, 90.0);
TempLimits txLimits = TempLimits(-40.0, -30.0, 75.0, 80.0, 90.0);
TempLimits mpaLimits = TempLimits(-40.0, -30.0, 75.0, 80.0, 90.0);
TempLimits scexBoardLimits = TempLimits(-60.0, -40.0, 80.0, 85.0, 150.0);
double sensorTemp = INVALID_TEMPERATURE;
ThermalComponents currThermalComponent = NONE;
bool redSwitchNrInUse = false;
MessageQueueId_t camId = MessageQueueIF::NO_QUEUE;
bool componentAboveCutOffLimit = false;
bool componentAboveUpperLimit = false;
Event overHeatEventToTrigger;
bool eBandTooHotFlag = false;
bool camTooHotOneShotFlag = false;
bool scexTooHotFlag = false;
bool plocTooHotFlag = false;
bool pcduSystemTooHotFlag = false;
bool syrlinksTooHotFlag = false;
bool obcTooHotFlag = false;
bool mgtTooHotFlag = false;
bool strTooHotFlag = false;
bool rwTooHotFlag = false;
bool transitionWhenHeatersOff = false;
uint32_t transitionWhenHeatersOffCycles = 0;
Mode_t targetMode = MODE_OFF;
Submode_t targetSubmode = SUBMODE_NONE;
uint32_t cycles = 0;
std::array<ThermalState, ThermalComponents::NUM_ENTRIES> thermalStates{};
std::array<HeaterState, heater::NUMBER_OF_SWITCHES> heaterStates{};
// Initial delay to make sure all pool variables have been initialized their owners.
// Also, wait for system initialization to complete.
Countdown initialCountdown = Countdown(INIT_DELAY);
#if OBSW_THREAD_TRACING == 1
uint32_t opCounter = 0;
#endif
std::array<std::pair<bool, double>, 5> sensors;
uint8_t numSensors = 0;
PoolEntry<float> tmp1075Tcs0 = PoolEntry<float>({10.0});
PoolEntry<float> tmp1075Tcs1 = PoolEntry<float>({10.0});
PoolEntry<float> tmp1075PlPcdu0 = PoolEntry<float>({10.0});
PoolEntry<float> tmp1075PlPcdu1 = PoolEntry<float>({10.0});
PoolEntry<float> tmp1075IfBrd = PoolEntry<float>({10.0});
PoolEntry<uint8_t> heaterSwitchStates = PoolEntry<uint8_t>(heater::NUMBER_OF_SWITCHES);
PoolEntry<int16_t> heaterCurrent = PoolEntry<int16_t>();
static constexpr dur_millis_t MUTEX_TIMEOUT = 50;
void startTransition(Mode_t mode, Submode_t submode) override;
bool heaterCtrlAllowed() const;
void resetThermalStates();
void resetSensorsArray();
void copySensors();
void copySus();
void copyDevices();
void ctrlComponentTemperature(HeaterContext& heaterContext);
void checkLimitsAndCtrlHeater(HeaterContext& heaterContext);
bool heaterCtrlCheckUpperLimits(HeaterContext& heaterContext);
void heaterCtrlTempTooHighHandler(HeaterContext& heaterContext, const char* whatLimit);
bool chooseHeater(heater::Switch& switchNr, heater::Switch redSwitchNr);
bool selectAndReadSensorTemp(HeaterContext& htrCtx);
void heaterSwitchHelperAllOff();
void heaterSwitchHelper(heater::Switch switchNr, HeaterHandler::SwitchState state,
unsigned componentIdx);
void ctrlAcsBoard();
void ctrlMgt();
void ctrlRw();
void ctrlStr();
void ctrlIfBoard();
void ctrlTcsBoard();
void ctrlObc();
void ctrlSBandTransceiver();
void ctrlPcduP60Board();
void ctrlPcduAcu();
void ctrlPcduPdu();
void ctrlPlPcduBoard();
void ctrlPlocMissionBoard();
void ctrlPlocProcessingBoard();
void ctrlDac();
void ctrlCameraBody();
void ctrlDro();
void ctrlX8();
void ctrlHpa();
void ctrlTx();
void ctrlMpa();
void ctrlScexBoard();
void heaterTransitionControl(const HeaterSwitchStates& currentHeaterStates);
void setMode(Mode_t mode, Submode_t submode);
uint32_t tempFloatToU32() const;
bool tooHotHandler(object_id_t object, bool& oneShotFlag);
void tooHotHandlerWhichClearsOneShotFlag(object_id_t object, bool& oneShotFlag);
};
#endif /* MISSION_CONTROLLER_THERMALCONTROLLER_H_ */