Electropepper/NMM-1
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Working on menus.

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This commit is contained in:
Ricardo Work
2017-09-15 16:35:10 +00:00
parent bb99dd6219
commit 3942da4aee
1 changed files with 124 additions and 97 deletions
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217
firmware/v01/v01.ino
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@@ -17,44 +17,46 @@
#define OLED_RESET 8 #define OLED_RESET 8
Adafruit_SSD1306 display(OLED_RESET); Adafruit_SSD1306 display(OLED_RESET);
#define ON 0 // ON means pin is on GND
#define OFF 1 // OFF means pin is on VCC
// Assign switches and led's to arduino pins // Assign switches and led's to arduino pins
#define SW1 2 // Switch 1 connected to arduino pin 2 #define UP 2 // Switch 1 will be function UP connected to arduino pin 2
#define SW2 3 // Switch 1 connected to arduino pin 3 #define OK 3 // Switch 2 will be function OK connected to arduino pin 3
#define SW3 4 // Switch 1 connected to arduino pin 4 #define DOWN 4 // Switch 3 will be function DOWN connected to arduino pin 4
#define SW4 5 // Switch 1 connected to arduino pin 5 #define CANCEL 5 // Switch 4 will be function CANCEL connected to arduino pin 5
#define led1 9 // Led 1 connected to arduino pin 9 #define led1 9 // Led 1 connected to arduino pin 9
#define led2 10 // Led 2 connected to arduino pin 10 #define led2 10 // Led 2 connected to arduino pin 10
// Macros to read the switchs // Macros to read the switchs
#define rSW1 digitalRead(SW1) // Read switch 1 #define rUP digitalRead(UP) // Read button UP state
#define rSW2 digitalRead(SW2) // Read switch 2 #define rOK digitalRead(OK) // Read button OK state
#define rSW3 digitalRead(SW3) // Read switch 3 #define rDOWN digitalRead(DOWN) // Read button DOWN state
#define rSW4 digitalRead(SW4) // Read switch 4 #define rCANCEL digitalRead(CANCEL) // Read button CANCEL state
volatile byte state = LOW; //volatile byte state = LOW;
// Variables creation
int menuState = 0; // Integer with the number of the menu you are in
int UP_state = OFF; // Holds state for UP, either ON or OFF
int OK_state = OFF; // Holds state for OK, either ON or OFF
int DOWN_state = OFF; // Holds state for DOWN, either ON or OFF
int CANCEL_state = OFF; // Holds state for CANCEL, either ON or OFF
// Create an integer with the number of the menu you are in
int menuState = 0;
// Create SoftwareSerial object and designate pins // Create SoftwareSerial object and designate pins
SoftwareSerial mySerial(6, 7); // RX, TX SoftwareSerial mySerial(6, 7); // RX, TX
void setup() { void setup() { // BEGIN SETUP ------------------------------------
// Configure buttons and led's has inputs or outputs // Configure buttons and led's has inputs or outputs
pinMode(led1, OUTPUT); // Led 1 is an output pinMode(led1, OUTPUT); // Led 1 is an output
pinMode(led2, OUTPUT); // Led 2 is an output pinMode(led2, OUTPUT); // Led 2 is an output
pinMode(SW1, INPUT); // Switch 1 is an input pinMode(UP, INPUT); // Switch 1 is an input
pinMode(SW2, INPUT); // Switch 2 is an input pinMode(OK, INPUT); // Switch 2 is an input
pinMode(SW3, INPUT); // Switch 3 is an input pinMode(DOWN, INPUT); // Switch 3 is an input
pinMode(SW4, INPUT); // Switch 4 is an input pinMode(CANCEL, INPUT); // Switch 4 is an input
// Interrupts
// If Switch X on change state
attachInterrupt(digitalPinToInterrupt(SW1), sw1_press, CHANGE);
attachInterrupt(digitalPinToInterrupt(SW2), sw2_press, CHANGE);
attachInterrupt(digitalPinToInterrupt(SW3), sw3_press, CHANGE);
attachInterrupt(digitalPinToInterrupt(SW4), sw4_press, CHANGE);
// Define the starting state of the led's // Define the starting state of the led's
digitalWrite(led1,HIGH); // Turn off led 1 digitalWrite(led1,HIGH); // Turn off led 1
@@ -70,72 +72,77 @@ void setup() {
// Show image buffer on the display hardware. // Show image buffer on the display hardware.
// Since the buffer is intialized with an Adafruit splashscreen // Since the buffer is intialized with an Adafruit splashscreen
// internally, this will display the splashscreen. // internally, this will display the splashscreen.
display.display(); //display.display();
delay(2000); // Wait 2 seconds //delay(2000); // Wait 2 seconds
// initialize timer1 ---------------------------------------
noInterrupts(); // disable all interrupts
TCCR1A = 0;
TCCR1B = 0;
TCNT1 = 0;
OCR1A = 9000; // Load value to compare
TCCR1B |= (1 << WGM12); // CTC mode
TCCR1B |= (1 << CS10); // 64 prescaler
TCCR1B |= (1 << CS11); //
TIMSK1 |= (1 << OCIE1A); // enable timer compare interrupt
interrupts(); // enable all interrupts
// ----------------------------------------------------------
// Clear the buffer. // Clear the buffer.
display.clearDisplay(); display.clearDisplay();
display.setTextSize(2);
display.setTextColor(WHITE);
display.setCursor(36,12);
display.println("NMM-1");
display.display(); display.display();
// display.setTextSize(2);
}
void loop() {
batt_icon();
/* if (!rSW1) {
digitalWrite(led1, LOW);
delay(300);
digitalWrite(led1, HIGH);
}
else if (!rSW2) {
digitalWrite(led2, LOW);
delay(300);
digitalWrite(led2, HIGH);
}
else if (!rSW3) {
digitalWrite(led1, LOW);
digitalWrite(led2, LOW);
delay(300);
digitalWrite(led1, HIGH);
digitalWrite(led2, HIGH);
}
else if (!rSW4) {
for (int i = 10; i > 0; i--) {
digitalWrite(led1, LOW);
digitalWrite(led2, HIGH);
delay(400);
digitalWrite(led1, HIGH);
digitalWrite(led2, LOW);
delay(400);
}
digitalWrite(led1, HIGH);
digitalWrite(led2, HIGH);
}*/
// display.setTextSize(1);
// display.setTextColor(WHITE); // display.setTextColor(WHITE);
// display.setCursor(0,8); // display.setCursor(36,12);
// display.println("Hello, world!"); // display.println("NMM-1");
// display.display(); // display.display();
// delay(2000); // delay(2000);
// display.clearDisplay(); // display.clearDisplay();
// display.display();
} // END SETUP --------------------------------------------------------------------
// Timer compare interrupt service routine --------------------------
ISR(TIMER1_COMPA_vect) // Here we chose between the blinker sequence
{ // or to show the temperature on the LEDs
if (!rUP && menuState < 2) {
menuState++;
}
if (!rDOWN && menuState > 1) {
menuState--;
}
}
// -------------------------------------------------------------------
void loop() {
//digitalWrite(led2, !digitalRead(led2)); // toggle state
batt_icon();
if (menuState == 1) {
one();
}
else if (menuState == 2) {
two();
}
else {
zero();
}
// mySerial.println("TX working, yeaiii :), stilll");
// delay(5000);
} }
@@ -152,26 +159,46 @@ void batt_icon (void) {
display.display(); display.display();
} }
void sw1_press() { void zero (void) {
digitalWrite(led1, HIGH);
digitalWrite(led2, HIGH); display.drawRect(0, 8, 168, 24, BLACK);
digitalWrite(led1, LOW); display.display();
display.setTextSize(1);
display.setTextColor(WHITE);
display.setCursor(0,12);
display.println("Read NMEA0183");
display.setCursor(0,22);
display.println("Write NMEA0183");
display.display();
} }
void sw2_press() { void one (void) {
digitalWrite(led1, HIGH);
digitalWrite(led2, HIGH); display.drawRect(0, 8, 168, 24, BLACK);
digitalWrite(led2, LOW); display.display();
display.clearDisplay();
display.setTextSize(1);
display.setTextColor(WHITE);
display.setCursor(0,12);
display.println("Read NMEA0183");
display.setCursor(0,22);
display.println("Write NMEA0183 <--");
display.display();
} }
void sw3_press() { void two (void) {
digitalWrite(led1, HIGH);
digitalWrite(led2, HIGH); display.drawRect(0, 8, 168, 24, BLACK);
digitalWrite(led1, LOW); display.display();
} display.clearDisplay();
display.setTextSize(1);
display.setTextColor(WHITE);
display.setCursor(0,12);
display.println("Read NMEA0183 <--");
display.setCursor(0,22);
display.println("Write NMEA0183");
display.display();
void sw4_press() {
digitalWrite(led1, HIGH);
digitalWrite(led2, HIGH);
digitalWrite(led2, LOW);
} }