PowerTester/firmware/v01_orig.ino

// include the library code:
#include <LiquidCrystal.h>
#define delay_1 800


#define b_nav 16
#define b_ok 18
#define b_back 19
#define l_charge 17
#define a_charge A6
#define a_batt A7

// initialize the library with the numbers of the interface pins
LiquidCrystal lcd(7, 6, 2, 3, 4, 5);


//Analog volt read pin
//const int voltPin = A7;

// Variables for voltage divider
float denominator;
int resistor1 = 22000; // Values measured in circuit
int resistor2 = 2200;  // for better accuracy
// ----------------------------------------------------


// Function declarations -----------------------------------------------------------------
void volt_batt (void);           // Read and display voltage
//-----------------------------------------------------------------------------------------


void setup() {

	pinMode(b_nav, INPUT);
	pinMode(b_ok, INPUT);
	pinMode(b_back, INPUT);
	pinMode(l_charge, OUTPUT);
	lcd.begin(16, 2);
	// Print a message to the LCD.
	lcd.print("PowerTester v01");
	//Convert resistor values to division value
	//  Equation is previously mentions voltage divider equation
	//  R2 / (R1 + R2)
	//  In this case returns 0.20 or 1/5
	denominator = (float)resistor2 / (resistor1 + resistor2);

	digitalWrite(l_charge, LOW);

} // Void Setup Close

void loop() {

//	lcd.setCursor(0, 1); // bottom left
//	lcd.print("");

	if (!digitalRead(b_nav)) {
		volt_batt();
	}

	else if (!digitalRead(b_ok)) {
		digitalWrite(l_charge, !digitalRead(l_charge));
		lcd.setCursor(0, 1); // bottom left
		lcd.print("Charge is toggled");
		delay(500);
	}

	else if (!digitalRead(b_back)) {
		float voltage_c;
		float cur_c;
		//Obtain RAW voltage data
		voltage_c = analogRead(a_charge);

		//Convert to actual voltage (Calibrated by hand)
		voltage_c = (voltage_c / 1024) * 3.3;

		cur_c = voltage_c / 0.5;

		//Output to LCD
		lcd.setCursor(0, 1); // bottom left
		lcd.print("cur C =   ");
		lcd.setCursor(11,1);
		lcd.print(cur_c);

		//Delay to make LCD readable
		delay(500);
	}

	else {
		volt_batt();
	}


} // void loop close


void volt_batt(void) {

	float voltage;
	//Obtain RAW voltage data
	voltage = analogRead(a_batt);

	//Convert to actual voltage (Calibrated by hand)
	voltage = (voltage / 1024) * 3.3;

	//Convert to voltage before divider
	//  Divide by divider = multiply
	//  Divide by 1/5 = multiply by 5
	voltage = voltage / denominator;

	//Output to LCD
	lcd.setCursor(0, 1); // bottom left
	lcd.print("Batt V =  ");
	lcd.setCursor(10,1);
	lcd.print(voltage);

	//Delay to make LCD readable
	delay(500);
}
Working on firmware, completly changed code and kept the old one inside ./firmware. 2018-06-12 13:58:55 +00:00			`// include the library code:`
			`#include <LiquidCrystal.h>`
			`#define delay_1 800`


			`#define b_nav 16`
			`#define b_ok 18`
			`#define b_back 19`
			`#define l_charge 17`
			`#define a_charge A6`
			`#define a_batt A7`

			`// initialize the library with the numbers of the interface pins`
			`LiquidCrystal lcd(7, 6, 2, 3, 4, 5);`


			`//Analog volt read pin`
			`//const int voltPin = A7;`

			`// Variables for voltage divider`
			`float denominator;`
			`int resistor1 = 22000; // Values measured in circuit`
			`int resistor2 = 2200; // for better accuracy`
			`// ----------------------------------------------------`


			`// Function declarations -----------------------------------------------------------------`
			`void volt_batt (void); // Read and display voltage`
			`//-----------------------------------------------------------------------------------------`



			`void setup() {`

			`pinMode(b_nav, INPUT);`
			`pinMode(b_ok, INPUT);`
			`pinMode(b_back, INPUT);`
			`pinMode(l_charge, OUTPUT);`
			`lcd.begin(16, 2);`
			`// Print a message to the LCD.`
			`lcd.print("PowerTester v01");`
			`//Convert resistor values to division value`
			`// Equation is previously mentions voltage divider equation`
			`// R2 / (R1 + R2)`
			`// In this case returns 0.20 or 1/5`
			`denominator = (float)resistor2 / (resistor1 + resistor2);`

			`digitalWrite(l_charge, LOW);`

			`} // Void Setup Close`

			`void loop() {`

			`// lcd.setCursor(0, 1); // bottom left`
			`// lcd.print("");`

			`if (!digitalRead(b_nav)) {`
			`volt_batt();`
			`}`

			`else if (!digitalRead(b_ok)) {`
			`digitalWrite(l_charge, !digitalRead(l_charge));`
			`lcd.setCursor(0, 1); // bottom left`
			`lcd.print("Charge is toggled");`
			`delay(500);`
			`}`

			`else if (!digitalRead(b_back)) {`
			`float voltage_c;`
			`float cur_c;`
			`//Obtain RAW voltage data`
			`voltage_c = analogRead(a_charge);`

			`//Convert to actual voltage (Calibrated by hand)`
			`voltage_c = (voltage_c / 1024) * 3.3;`

			`cur_c = voltage_c / 0.5;`

			`//Output to LCD`
			`lcd.setCursor(0, 1); // bottom left`
			`lcd.print("cur C = ");`
			`lcd.setCursor(11,1);`
			`lcd.print(cur_c);`

			`//Delay to make LCD readable`
			`delay(500);`
			`}`

			`else {`
			`volt_batt();`
			`}`


			`} // void loop close`


			`void volt_batt(void) {`

			`float voltage;`
			`//Obtain RAW voltage data`
			`voltage = analogRead(a_batt);`

			`//Convert to actual voltage (Calibrated by hand)`
			`voltage = (voltage / 1024) * 3.3;`

			`//Convert to voltage before divider`
			`// Divide by divider = multiply`
			`// Divide by 1/5 = multiply by 5`
			`voltage = voltage / denominator;`

			`//Output to LCD`
			`lcd.setCursor(0, 1); // bottom left`
			`lcd.print("Batt V = ");`
			`lcd.setCursor(10,1);`
			`lcd.print(voltage);`

			`//Delay to make LCD readable`
			`delay(500);`
			`}`