ELEC50003-P1-CW/Energy/PV Analyses.ino

#include <Wire.h>
#include <INA219_WE.h>
#include <SPI.h>
#include <SD.h>

INA219_WE ina219; // this is the instantiation of the library for the current sensor

// set up variables using the SD utility library functions:
Sd2Card card;
SdVolume volume;
SdFile root;

const int chipSelect = 10;
unsigned int rest_timer;
unsigned int loop_trigger;
unsigned int int_count = 0; // a variables to count the interrupts. Used for program debugging.
float u0i, u1i, delta_ui, e0i, e1i, e2i; // Internal values for the current controller
float ui_max = 1, ui_min = 0; //anti-windup limitation
float kpi = 0.02512, kii = 39.4, kdi = 0; // current pid.
float Ts = 0.001; //1 kHz control frequency.
float current_measure, current_ref = 0, error_amps; // Current Control
float pwm_out;
float V_Bat;
boolean input_switch;
int state_num=0,next_state;
String dataString;
int PWM_in = 1;
float duty_cycle = 0;
int counter = 5;

void setup() {
  //Some General Setup Stuff

  Wire.begin(); // We need this for the i2c comms for the current sensor
  Wire.setClock(700000); // set the comms speed for i2c
  ina219.init(); // this initiates the current sensor
  Serial.begin(9600); // USB Communications


  //Check for the SD Card
  Serial.println("\nInitializing SD card...");
  if (!SD.begin(chipSelect)) {
    Serial.println("* is a card inserted?");
    while (true) {} //It will stick here FOREVER if no SD is in on boot
  } else {
    Serial.println("Wiring is correct and a card is present.");
  }

  if (SD.exists("BatCycle.csv")) { // Wipe the datalog when starting
    SD.remove("BatCycle.csv");
  }

  
  noInterrupts(); //disable all interrupts
  analogReference(EXTERNAL); // We are using an external analogue reference for the ADC

  //SMPS Pins
  pinMode(13, OUTPUT); // Using the LED on Pin D13 to indicate status
  pinMode(2, INPUT_PULLUP); // Pin 2 is the input from the CL/OL switch
  pinMode(6, OUTPUT); // This is the PWM Pin

  //LEDs on pin 7 and 8
  pinMode(7, OUTPUT);
  pinMode(8, OUTPUT);

  //Analogue input, the battery voltage (also port B voltage)
  pinMode(A0, INPUT);

  // TimerA0 initialization for 1kHz control-loop interrupt.
  TCA0.SINGLE.PER = 999; //
  TCA0.SINGLE.CMP1 = 999; //
  TCA0.SINGLE.CTRLA = TCA_SINGLE_CLKSEL_DIV16_gc | TCA_SINGLE_ENABLE_bm; //16 prescaler, 1M.
  TCA0.SINGLE.INTCTRL = TCA_SINGLE_CMP1_bm;

  // TimerB0 initialization for PWM output
  TCB0.CTRLA = TCB_CLKSEL_CLKDIV1_gc | TCB_ENABLE_bm; //62.5kHz

  interrupts();  //enable interrupts.
  analogWrite(6, 120); //just a default state to start with

}

void loop() {
  if (loop_trigger == 1){ // FAST LOOP (1kHZ)
      state_num = next_state; //state transition
      V_Bat = analogRead(A0)*4.096/1.03; //check the battery voltage (1.03 is a correction for measurement error, you need to check this works for you)
      current_measure = (ina219.getCurrent_mA()); // sample the inductor current (via the sensor chip)
      int_count++; //count how many interrupts since this was last reset to zero
      loop_trigger = 0; //reset the trigger and move on with life
  }
  
  if (int_count == 1000) { // SLOW LOOP (1Hz)
    input_switch = digitalRead(2); //get the OL/CL switch status
    switch (state_num) { // STATE MACHINE (see diagram)
      
      case 0:{ // Start state (no current, no LEDs)
        current_ref = 0;
        if (input_switch == 1) { // if switch, move to charge
          next_state = 1;
          digitalWrite(8,true);
        } else { // otherwise stay put
          next_state = 0;
          digitalWrite(8,false);
        }
        break;
      }
      case 1:{ // Charge state (250mA and a green LED)
        analogWrite(6,PWM_in);
        
        if(counter == 5){
            if(PWM_in < 255) {
                PWM_in = PWM_in + 1;
            }
            else {
                PWM_in = 1;
            }
            counter = 0; 
        }
        
        counter = counter +1;
        duty_cycle = (PWM_in /255)*100;
        
        if(input_switch == 0){ // UNLESS the switch = 0, then go back to start
          next_state = 0;
          digitalWrite(8,false);
        }
        break;
      }
      
      case 5: { // ERROR state RED led and no current
        current_ref = 0;
        next_state = 5; // Always stay here
        digitalWrite(7,true);
        digitalWrite(8,false);
        if(input_switch == 0){ //UNLESS the switch = 0, then go back to start
          next_state = 0;
          digitalWrite(7,false);
        }
        break;
      }

      default :{ // Should not end up here ....
        Serial.println("Boop");
        current_ref = 0;
        next_state = 5; // So if we are here, we go to error
        digitalWrite(7,true);
      }
      
    }
    
    dataString = String(state_num) + "," + String(V_Bat) + "," + String(current_measure) + "," +  String(PWM_in) + "," +  String(duty_cycle); ; //build a datastring for the CSV file
    Serial.println(dataString); // send it to serial as well in case a computer is connected
    File dataFile = SD.open("BatCycle.csv", FILE_WRITE); // open our CSV file
    if (dataFile){ //If we succeeded (usually this fails if the SD card is out)
      dataFile.println(dataString); // print the data
    } else {
      Serial.println("File not open"); //otherwise print an error
    }
    dataFile.close(); // close the file
    int_count = 0; // reset the interrupt count so we dont come back here for 1000ms
  }
}

// Timer A CMP1 interrupt. Every 1000us the program enters this interrupt. This is the fast 1kHz loop
ISR(TCA0_CMP1_vect) {
  loop_trigger = 1; //trigger the loop when we are back in normal flow
  TCA0.SINGLE.INTFLAGS |= TCA_SINGLE_CMP1_bm; //clear interrupt flag
}

float saturation( float sat_input, float uplim, float lowlim) { // Saturation function
  if (sat_input > uplim) sat_input = uplim;
  else if (sat_input < lowlim ) sat_input = lowlim;
  else;
  return sat_input;
}

float pidi(float pid_input) { // discrete PID function
  float e_integration;
  e0i = pid_input;
  e_integration = e0i;

  //anti-windup
  if (u1i >= ui_max) {
    e_integration = 0;
  } else if (u1i <= ui_min) {
    e_integration = 0;
  }

  delta_ui = kpi * (e0i - e1i) + kii * Ts * e_integration + kdi / Ts * (e0i - 2 * e1i + e2i); //incremental PID programming avoids integrations.
  u0i = u1i + delta_ui;  //this time's control output

  //output limitation
  saturation(u0i, ui_max, ui_min);

  u1i = u0i; //update last time's control output
  e2i = e1i; //update last last time's error
  e1i = e0i; // update last time's error
  return u0i;
}
Energy stuff added 2021-06-08 01:10:13 +00:00			`#include <Wire.h>`
			`#include <INA219_WE.h>`
			`#include <SPI.h>`
			`#include <SD.h>`

			`INA219_WE ina219; // this is the instantiation of the library for the current sensor`

			`// set up variables using the SD utility library functions:`
			`Sd2Card card;`
			`SdVolume volume;`
			`SdFile root;`

			`const int chipSelect = 10;`
			`unsigned int rest_timer;`
			`unsigned int loop_trigger;`
			`unsigned int int_count = 0; // a variables to count the interrupts. Used for program debugging.`
			`float u0i, u1i, delta_ui, e0i, e1i, e2i; // Internal values for the current controller`
			`float ui_max = 1, ui_min = 0; //anti-windup limitation`
			`float kpi = 0.02512, kii = 39.4, kdi = 0; // current pid.`
			`float Ts = 0.001; //1 kHz control frequency.`
			`float current_measure, current_ref = 0, error_amps; // Current Control`
			`float pwm_out;`
			`float V_Bat;`
			`boolean input_switch;`
			`int state_num=0,next_state;`
			`String dataString;`
			`int PWM_in = 1;`
			`float duty_cycle = 0;`
			`int counter = 5;`

			`void setup() {`
			`//Some General Setup Stuff`

			`Wire.begin(); // We need this for the i2c comms for the current sensor`
			`Wire.setClock(700000); // set the comms speed for i2c`
			`ina219.init(); // this initiates the current sensor`
			`Serial.begin(9600); // USB Communications`


			`//Check for the SD Card`
			`Serial.println("\nInitializing SD card...");`
			`if (!SD.begin(chipSelect)) {`
			`Serial.println("* is a card inserted?");`
			`while (true) {} //It will stick here FOREVER if no SD is in on boot`
			`} else {`
			`Serial.println("Wiring is correct and a card is present.");`
			`}`

			`if (SD.exists("BatCycle.csv")) { // Wipe the datalog when starting`
			`SD.remove("BatCycle.csv");`
			`}`


			`noInterrupts(); //disable all interrupts`
			`analogReference(EXTERNAL); // We are using an external analogue reference for the ADC`

			`//SMPS Pins`
			`pinMode(13, OUTPUT); // Using the LED on Pin D13 to indicate status`
			`pinMode(2, INPUT_PULLUP); // Pin 2 is the input from the CL/OL switch`
			`pinMode(6, OUTPUT); // This is the PWM Pin`

			`//LEDs on pin 7 and 8`
			`pinMode(7, OUTPUT);`
			`pinMode(8, OUTPUT);`

			`//Analogue input, the battery voltage (also port B voltage)`
			`pinMode(A0, INPUT);`

			`// TimerA0 initialization for 1kHz control-loop interrupt.`
			`TCA0.SINGLE.PER = 999; //`
			`TCA0.SINGLE.CMP1 = 999; //`
			`TCA0.SINGLE.CTRLA = TCA_SINGLE_CLKSEL_DIV16_gc \| TCA_SINGLE_ENABLE_bm; //16 prescaler, 1M.`
			`TCA0.SINGLE.INTCTRL = TCA_SINGLE_CMP1_bm;`

			`// TimerB0 initialization for PWM output`
			`TCB0.CTRLA = TCB_CLKSEL_CLKDIV1_gc \| TCB_ENABLE_bm; //62.5kHz`

			`interrupts(); //enable interrupts.`
			`analogWrite(6, 120); //just a default state to start with`

			`}`

			`void loop() {`
			`if (loop_trigger == 1){ // FAST LOOP (1kHZ)`
			`state_num = next_state; //state transition`
			`V_Bat = analogRead(A0)*4.096/1.03; //check the battery voltage (1.03 is a correction for measurement error, you need to check this works for you)`
			`current_measure = (ina219.getCurrent_mA()); // sample the inductor current (via the sensor chip)`
			`int_count++; //count how many interrupts since this was last reset to zero`
			`loop_trigger = 0; //reset the trigger and move on with life`
			`}`

			`if (int_count == 1000) { // SLOW LOOP (1Hz)`
			`input_switch = digitalRead(2); //get the OL/CL switch status`
			`switch (state_num) { // STATE MACHINE (see diagram)`

			`case 0:{ // Start state (no current, no LEDs)`
			`current_ref = 0;`
			`if (input_switch == 1) { // if switch, move to charge`
			`next_state = 1;`
			`digitalWrite(8,true);`
			`} else { // otherwise stay put`
			`next_state = 0;`
			`digitalWrite(8,false);`
			`}`
			`break;`
			`}`
			`case 1:{ // Charge state (250mA and a green LED)`
			`analogWrite(6,PWM_in);`

			`if(counter == 5){`
			`if(PWM_in < 255) {`
			`PWM_in = PWM_in + 1;`
			`}`
			`else {`
			`PWM_in = 1;`
			`}`
			`counter = 0;`
			`}`

			`counter = counter +1;`
			`duty_cycle = (PWM_in /255)*100;`

			`if(input_switch == 0){ // UNLESS the switch = 0, then go back to start`
			`next_state = 0;`
			`digitalWrite(8,false);`
			`}`
			`break;`
			`}`

			`case 5: { // ERROR state RED led and no current`
			`current_ref = 0;`
			`next_state = 5; // Always stay here`
			`digitalWrite(7,true);`
			`digitalWrite(8,false);`
			`if(input_switch == 0){ //UNLESS the switch = 0, then go back to start`
			`next_state = 0;`
			`digitalWrite(7,false);`
			`}`
			`break;`
			`}`

			`default :{ // Should not end up here ....`
			`Serial.println("Boop");`
			`current_ref = 0;`
			`next_state = 5; // So if we are here, we go to error`
			`digitalWrite(7,true);`
			`}`

			`}`

			`dataString = String(state_num) + "," + String(V_Bat) + "," + String(current_measure) + "," + String(PWM_in) + "," + String(duty_cycle); ; //build a datastring for the CSV file`
			`Serial.println(dataString); // send it to serial as well in case a computer is connected`
			`File dataFile = SD.open("BatCycle.csv", FILE_WRITE); // open our CSV file`
			`if (dataFile){ //If we succeeded (usually this fails if the SD card is out)`
			`dataFile.println(dataString); // print the data`
			`} else {`
			`Serial.println("File not open"); //otherwise print an error`
			`}`
			`dataFile.close(); // close the file`
			`int_count = 0; // reset the interrupt count so we dont come back here for 1000ms`
			`}`
			`}`

			`// Timer A CMP1 interrupt. Every 1000us the program enters this interrupt. This is the fast 1kHz loop`
			`ISR(TCA0_CMP1_vect) {`
			`loop_trigger = 1; //trigger the loop when we are back in normal flow`
			`TCA0.SINGLE.INTFLAGS \|= TCA_SINGLE_CMP1_bm; //clear interrupt flag`
			`}`

			`float saturation( float sat_input, float uplim, float lowlim) { // Saturation function`
			`if (sat_input > uplim) sat_input = uplim;`
			`else if (sat_input < lowlim ) sat_input = lowlim;`
			`else;`
			`return sat_input;`
			`}`

			`float pidi(float pid_input) { // discrete PID function`
			`float e_integration;`
			`e0i = pid_input;`
			`e_integration = e0i;`

			`//anti-windup`
			`if (u1i >= ui_max) {`
			`e_integration = 0;`
			`} else if (u1i <= ui_min) {`
			`e_integration = 0;`
			`}`

			`delta_ui = kpi * (e0i - e1i) + kii * Ts * e_integration + kdi / Ts * (e0i - 2 * e1i + e2i); //incremental PID programming avoids integrations.`
			`u0i = u1i + delta_ui; //this time's control output`

			`//output limitation`
			`saturation(u0i, ui_max, ui_min);`

			`u1i = u0i; //update last time's control output`
			`e2i = e1i; //update last last time's error`
			`e1i = e0i; // update last time's error`
			`return u0i;`
			`}`