wideband/firmware/heater_control.cpp

#include "heater_control.h"
#include "wideband_config.h"

#include "ch.h"
#include "hal.h"

#include "fault.h"
#include "pwm.h"
#include "sampling.h"
#include "pid.h"

// 400khz / 1024 = 390hz PWM
Pwm heaterPwm(PWMD1, 0, 400'000, 1024);

enum class HeaterState
{
    Preheat,
    WarmupRamp,
    ClosedLoop,
    Stopped,
};

int timeCounter = HEATER_PREHEAT_TIME / HEATER_CONTROL_PERIOD;
float rampDuty = 0.5f;

static HeaterState GetNextState(HeaterState state, float sensorEsr)
{
    switch (state)
    {
        case HeaterState::Preheat:
            timeCounter--;

            if (timeCounter <= 0)
            {
                // If enough time has elapsed, start the ramp
                // Start the ramp at 50% duty - ~6-7 volts
                rampDuty = 0.5f;

                // Next phase times out at 15 seconds
                timeCounter = HEATER_WARMUP_TIMEOUT / HEATER_CONTROL_PERIOD;

                return HeaterState::WarmupRamp;
            }

            // Stay in preheat - wait for time to elapse
            break;
        case HeaterState::WarmupRamp:
            if (sensorEsr < HEATER_CLOSED_LOOP_THRESHOLD_ESR)
            {
                return HeaterState::ClosedLoop;
            }
            else if (timeCounter == 0)
            {
                setFault(Fault::SensorDidntHeat);
                return HeaterState::Stopped;
            }

            timeCounter--;

            break;
        case HeaterState::ClosedLoop:
            if (sensorEsr < HEATER_OVERHEAT_ESR)
            {
                setFault(Fault::SensorOverheat);
                return HeaterState::Stopped;
            }
            else if (sensorEsr > HEATER_UNDERHEAT_ESR)
            {
                setFault(Fault::SensorUnderheat);
                return HeaterState::Stopped;
            }

            break;
        case HeaterState::Stopped: break;
    }

    return state;
}

static Pid heaterPid(0.01f, 0.05f, 1, HEATER_CONTROL_PERIOD);

static float GetDutyForState(HeaterState state, float heaterEsr)
{
    switch (state)
    {
        case HeaterState::Preheat: return 0.125f;
        case HeaterState::WarmupRamp:
            if (rampDuty < 0.9f)
            {
                // 0.4 volt per second, divided by battery voltage and update rate
                rampDuty += (0.4f / (14 * 20));
            }

            return rampDuty;
        case HeaterState::ClosedLoop:
            // Negated because lower resistance -> hotter
            return -heaterPid.GetOutput(HEATER_TARGET_ESR, heaterEsr);
        case HeaterState::Stopped:
            // Something has gone wrong, return 0.
            return 0;
    }

    // should be unreachable
    return 0;
}

static HeaterState state = HeaterState::Preheat;

static THD_WORKING_AREA(waHeaterThread, 256);
static void HeaterThread(void*)
{
    while (true)
    {
        // Read sensor state
        float heaterEsr = GetSensorInternalResistance();

        // Run the state machine
        state = GetNextState(state, heaterEsr);
        float duty = GetDutyForState(state, heaterEsr);

        // Pipe the output to the heater driver
        heaterPwm.SetDuty(duty);

        // Loop at ~20hz
        chThdSleepMilliseconds(HEATER_CONTROL_PERIOD);
    }
}

void StartHeaterControl()
{
    heaterPwm.Start();
    heaterPwm.SetDuty(0);

    chThdCreateStatic(waHeaterThread, sizeof(waHeaterThread), NORMALPRIO + 1, HeaterThread, nullptr);
}

bool IsRunningClosedLoop()
{
    return state == HeaterState::ClosedLoop;
}
extract heater control 2020-10-30 01:53:54 -07:00			`#include "heater_control.h"`
heater pid 2020-10-31 14:58:34 -07:00			`#include "wideband_config.h"`
extract heater control 2020-10-30 01:53:54 -07:00
maybe heater logic 2020-10-30 02:40:18 -07:00			`#include "ch.h"`
extract heater control 2020-10-30 01:53:54 -07:00			`#include "hal.h"`
detect warmup failure 2020-12-10 18:32:41 -08:00
			`#include "fault.h"`
extract heater control 2020-10-30 01:53:54 -07:00			`#include "pwm.h"`
			`#include "sampling.h"`
heater pid 2020-10-31 14:58:34 -07:00			`#include "pid.h"`
extract heater control 2020-10-30 01:53:54 -07:00
			`// 400khz / 1024 = 390hz PWM`
			`Pwm heaterPwm(PWMD1, 0, 400'000, 1024);`

maybe heater logic 2020-10-30 02:40:18 -07:00			`enum class HeaterState`
			`{`
			`Preheat,`
			`WarmupRamp,`
			`ClosedLoop,`
detect warmup failure 2020-12-10 18:32:41 -08:00			`Stopped,`
maybe heater logic 2020-10-30 02:40:18 -07:00			`};`

detect sensor overheat 2020-12-10 22:08:00 -08:00			`int timeCounter = HEATER_PREHEAT_TIME / HEATER_CONTROL_PERIOD;`
maybe heater logic 2020-10-30 02:40:18 -07:00			`float rampDuty = 0.5f;`

			`static HeaterState GetNextState(HeaterState state, float sensorEsr)`
			`{`
			`switch (state)`
			`{`
			`case HeaterState::Preheat:`
detect warmup failure 2020-12-10 18:32:41 -08:00			`timeCounter--;`
maybe heater logic 2020-10-30 02:40:18 -07:00
detect warmup failure 2020-12-10 18:32:41 -08:00			`if (timeCounter <= 0)`
maybe heater logic 2020-10-30 02:40:18 -07:00			`{`
			`// If enough time has elapsed, start the ramp`
			`// Start the ramp at 50% duty - ~6-7 volts`
			`rampDuty = 0.5f;`
detect warmup failure 2020-12-10 18:32:41 -08:00
			`// Next phase times out at 15 seconds`
detect sensor overheat 2020-12-10 22:08:00 -08:00			`timeCounter = HEATER_WARMUP_TIMEOUT / HEATER_CONTROL_PERIOD;`
detect warmup failure 2020-12-10 18:32:41 -08:00
maybe heater logic 2020-10-30 02:40:18 -07:00			`return HeaterState::WarmupRamp;`
			`}`
add IsRunningClosedLoop 2020-10-31 14:54:50 -07:00
			`// Stay in preheat - wait for time to elapse`
			`break;`
maybe heater logic 2020-10-30 02:40:18 -07:00			`case HeaterState::WarmupRamp:`
detect sensor overheat 2020-12-10 22:08:00 -08:00			`if (sensorEsr < HEATER_CLOSED_LOOP_THRESHOLD_ESR)`
maybe heater logic 2020-10-30 02:40:18 -07:00			`{`
			`return HeaterState::ClosedLoop;`
			`}`
detect warmup failure 2020-12-10 18:32:41 -08:00			`else if (timeCounter == 0)`
			`{`
			`setFault(Fault::SensorDidntHeat);`
			`return HeaterState::Stopped;`
			`}`

			`timeCounter--;`
add IsRunningClosedLoop 2020-10-31 14:54:50 -07:00
			`break;`
detect warmup failure 2020-12-10 18:32:41 -08:00			`case HeaterState::ClosedLoop:`
detect underheat fault 2020-12-11 15:46:03 -08:00			`if (sensorEsr < HEATER_OVERHEAT_ESR)`
detect sensor overheat 2020-12-10 22:08:00 -08:00			`{`
			`setFault(Fault::SensorOverheat);`
actually stop if overheated 2020-12-11 15:10:04 -08:00			`return HeaterState::Stopped;`
detect sensor overheat 2020-12-10 22:08:00 -08:00			`}`
detect underheat fault 2020-12-11 15:46:03 -08:00			`else if (sensorEsr > HEATER_UNDERHEAT_ESR)`
			`{`
			`setFault(Fault::SensorUnderheat);`
			`return HeaterState::Stopped;`
			`}`
detect sensor overheat 2020-12-10 22:08:00 -08:00
detect warmup failure 2020-12-10 18:32:41 -08:00			`break;`
			`case HeaterState::Stopped: break;`
maybe heater logic 2020-10-30 02:40:18 -07:00			`}`
add IsRunningClosedLoop 2020-10-31 14:54:50 -07:00
			`return state;`
maybe heater logic 2020-10-30 02:40:18 -07:00			`}`

clamp pid 2020-12-11 15:24:56 -08:00			`static Pid heaterPid(0.01f, 0.05f, 1, HEATER_CONTROL_PERIOD);`
heater pid 2020-10-31 14:58:34 -07:00
maybe heater logic 2020-10-30 02:40:18 -07:00			`static float GetDutyForState(HeaterState state, float heaterEsr)`
			`{`
			`switch (state)`
			`{`
			`case HeaterState::Preheat: return 0.125f;`
			`case HeaterState::WarmupRamp:`
			`if (rampDuty < 0.9f)`
			`{`
			`// 0.4 volt per second, divided by battery voltage and update rate`
			`rampDuty += (0.4f / (14 * 20));`
			`}`

			`return rampDuty;`
			`case HeaterState::ClosedLoop:`
heater PID works 2020-10-31 17:34:36 -07:00			`// Negated because lower resistance -> hotter`
simpify 2020-12-11 16:50:06 -08:00			`return -heaterPid.GetOutput(HEATER_TARGET_ESR, heaterEsr);`
detect warmup failure 2020-12-10 18:32:41 -08:00			`case HeaterState::Stopped:`
			`// Something has gone wrong, return 0.`
			`return 0;`
maybe heater logic 2020-10-30 02:40:18 -07:00			`}`
warning 2020-12-10 21:05:02 -08:00
			`// should be unreachable`
			`return 0;`
maybe heater logic 2020-10-30 02:40:18 -07:00			`}`

add IsRunningClosedLoop 2020-10-31 14:54:50 -07:00			`static HeaterState state = HeaterState::Preheat;`

maybe heater logic 2020-10-30 02:40:18 -07:00			`static THD_WORKING_AREA(waHeaterThread, 256);`
			`static void HeaterThread(void*)`
			`{`
			`while (true)`
			`{`
			`// Read sensor state`
			`float heaterEsr = GetSensorInternalResistance();`

			`// Run the state machine`
			`state = GetNextState(state, heaterEsr);`
			`float duty = GetDutyForState(state, heaterEsr);`

			`// Pipe the output to the heater driver`
			`heaterPwm.SetDuty(duty);`

			`// Loop at ~20hz`
heater pid 2020-10-31 14:58:34 -07:00			`chThdSleepMilliseconds(HEATER_CONTROL_PERIOD);`
maybe heater logic 2020-10-30 02:40:18 -07:00			`}`
			`}`

extract heater control 2020-10-30 01:53:54 -07:00			`void StartHeaterControl()`
			`{`
			`heaterPwm.Start();`
			`heaterPwm.SetDuty(0);`
maybe heater logic 2020-10-30 02:40:18 -07:00
			`chThdCreateStatic(waHeaterThread, sizeof(waHeaterThread), NORMALPRIO + 1, HeaterThread, nullptr);`
extract heater control 2020-10-30 01:53:54 -07:00			`}`
add IsRunningClosedLoop 2020-10-31 14:54:50 -07:00
			`bool IsRunningClosedLoop()`
			`{`
			`return state == HeaterState::ClosedLoop;`
			`}`