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Dependencies:   KellerDruck_pressure PID PWM-Coil-driver Sensirion_SF04 VL6180

Fork of TestBenchSerenity-proto_F429ZI by Ian Wolf

main.cpp

Committer:
dmwahl
Date:
2017-07-07
Revision:
0:67debf2ccbc2
Child:
1:d58df8cb271d

File content as of revision 0:67debf2ccbc2:

#include "main.h"

void pumpTachTrigger()
{
    pumpTachCounts++;
}

void pump_tach_update()
{
    float i = pumpTachCounts; // In case it triggers mid-calculation
    pumpTachCounts = 0;
    pumpRpm = (i/pumpTachPoles)*60;
}

void pump_init()
{
    pump.period(.001); // 1kHz PWM
    pump = 0;
    ledGrn.period(.001);
    
    InterruptIn pumpTach(pumpTachPin);
    pumpTach.rise(&pumpTachTrigger);
    
    pump_control_PID.setInputLimits(pumpMinPSI, pumpMaxPSI);
    pump_control_PID.setOutputLimits(0.0, 1.0); // Output is a PWM signal ranging from 0-1
    pump_control_PID.setMode(AUTO_MODE);
    pump_control_PID.setSetPoint(((double)pot2)*pumpMaxPSI); // pump setpoint based on pot 2*/
}

void pump_pid_update(char error)
{
    if (pumpPressure.status != 0x40) {
        pump = 0;
        pump_control_PID.reset();
    } else {
        pump_control_PID.setSetPoint(((double)pot2)*pumpMaxPSI);

        //Update the process variable.
        pump_control_PID.setProcessValue(pumpPressure.pressurePSI);
        //PID calculation and set the new output value.
        pump = pump_control_PID.compute();
        //pump = 0.1;
        ledGrn = ((float)1.0-pump.read());
    }
}

void update_pressures()
{
    Timer timer;
    timer.start();
    char error;
    while (true) {
        i2c1_m.lock();
        timer.reset();
        error = pumpPressure.readPT();
        int wait = (200 - timer.read_ms());
        i2c1_m.unlock();
        Thread::wait(wait);
        pump_pid_update(error);
    }
}

void update_airflow()
{
    Timer timer;
    timer.start();
    char error;
    while (true) {
        i2c2_m.lock();
        timer.reset();
        error = sfm7033.Measure(FLOW);
        int wait = (200 - timer.read_ms());
        i2c2_m.unlock();
        Thread::wait(wait);
    }
}

void print_process_values()
{
    //Thread::wait(100); // Wait initially to allow sensors to update, prevents a zero reading from going to serial
    Timer timer;
    timer.start();
    while (true) {
        stdio_m.lock();
        timer.reset();
        /*pc.printf("%.3fkPa %.2fPSI %.1fC %.1fF %02X %.2f%% %.0fRPM %.0f %s %.1f %.3f\n\r",
                  pumpPressure.pressureKPA, pumpPressure.pressurePSI, pumpPressure.temperatureC,
                  pumpPressure.temperatureF, pumpPressure.status, pump.read()*100, pumpRpm,
                  ((float)sfm7033.flow.i16 / sfm7033.scaleFactor.u16), sfm7033.flowUnitStr, (double)pot1*18, ((double)pot2-.002)*pumpMaxPSI);*/

        pc.printf("%.02fkPa %.02fpsi %.02fC %.02fF %02X %.2f%% %.0fRPM %u %.0f %s %.1f %.3f\r\n",
                  pumpPressure.pressureKPA, pumpPressure.pressurePSI, pumpPressure.temperatureC, pumpPressure.temperatureF, pumpPressure.status, pump.read()*100, pumpRpm, sfm7033.flow.u16, (((float)sfm7033.flow.i16 / 2) / sfm7033.scaleFactor.u16), sfm7033.flowUnitStr, (double)pot1*18, ((double)pot2)*pumpMaxPSI);
        int wait = (1000 - timer.read_ms());
        stdio_m.unlock();
        Thread::wait(wait);
    }
}

void update_lcd()
{
    Timer timer;
    timer.start();
    while (true) {
        float flow = ((((float)sfm7033.flow.i16 / 2) / sfm7033.scaleFactor.u16) < 0 ? 0 : (((float)sfm7033.flow.i16 / 2) / sfm7033.scaleFactor.u16));
        flow = flow/1000;
        stdio_m.lock();
        timer.reset();
        lcd.cls();
        lcd.font((unsigned char*)ArialR12x14);
        lcd.locate(0, 0);
        lcd.printf("%.2f slpm AA: %.1f", flow, (double)pot1*18);
        lcd.locate(0, 14);
        lcd.printf("PV: %.0f", pumpPressure.pressurePSI);
        lcd.locate(64, 14);
        lcd.printf("SV: %.0f", ((double)pot2)*pumpMaxPSI);
        int wait = (1000 - timer.read_ms());
        stdio_m.unlock();
        Thread::wait(wait);
    }
}

// main() runs in its own thread in the OS
int main()
{
    pump_init();
    ledBlu = 1;
    pc.printf("Serenity Starting up...\n\r");
    /*pc.printf("Pmin: %.03f Pmax: %.03f\r\n", pumpPressure.pmin, pumpPressure.pmax);
    pc.printf("Year: %d Month: %d Day: %d Mode: %d\r\n", pumpPressure.year, pumpPressure.month, pumpPressure.day, pumpPressure.mode);
    pc.printf("Status: 0x%x\r\n", pumpPressure.getStatus());*/

    // Thread to poll pressure sensors
    update_pressures_t.set_priority(osPriorityNormal);
    update_pressures_t.start(update_pressures);

    // Thread to poll airflow sensor
    update_airflow_t.set_priority(osPriorityNormal);
    update_airflow_t.start(update_airflow);

    // Thread to update lcd
    update_lcd_t.set_priority(osPriorityIdle);
    update_lcd_t.start(update_lcd);

    // Thread to send process values to serial port
    print_process_values_t.set_priority(osPriorityLow);
    print_process_values_t.start(&print_process_values);



    while (true) {
        //pc.printf("%.02fkPa %.02fpsi %.02fC %.02fF\r\n", pumpPressure.pressureKPA, pumpPressure.pressurePSI, pumpPressure.temperatureC, pumpPressure.temperatureF);
        Thread::wait(1000);
    }
}