2017-12-06 23:48:43 -05:00
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/**
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* The user interface of the ubitx consists of the encoder, the push-button on top of it
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* and the 16x2 LCD display.
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* The upper line of the display is constantly used to display frequency and status
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* of the radio. Occasionally, it is used to provide a two-line information that is
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* quickly cleared up.
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*/
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2018-04-16 10:56:32 -04:00
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/*
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const PROGMEM uint8_t meters_bitmap[] = {
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B10000, B10000, B10000, B10000, B10000, B10000, B10000, B10000 , //custom 1
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B11000, B11000, B11000, B11000, B11000, B11000, B11000, B11000 , //custom 2
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B11100, B11100, B11100, B11100, B11100, B11100, B11100, B11100 , //custom 3
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B11110, B11110, B11110, B11110, B11110, B11110, B11110, B11110 , //custom 4
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B11111, B11111, B11111, B11111, B11111, B11111, B11111, B11111 , //custom 5
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B01000, B11100, B01000, B00000, B10111, B10101, B10101, B10111 //custom 6
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};
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*/
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//SWR GRAPH, DrawMeter and drawingMeter Logic function by VK2ETA
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#ifdef OPTION_SKINNYBARS //We want skninny bars with more text
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//VK2ETA modded "Skinny" bitmaps
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const PROGMEM uint8_t meters_bitmap[] = {
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// B01110, B10001, B10001, B11111, B11011, B11011, B11111, B00000, //Padlock Symbol, for merging. Not working, see below
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B00000, B00000, B00000, B00000, B00000, B00000, B00000, B10000, //shortest bar
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B00000, B00000, B00000, B00000, B00000, B00000, B00100, B10100,
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B00000, B00000, B00000, B00000, B00000, B00001, B00101, B10101,
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B00000, B00000, B00000, B00000, B10000, B10000, B10000, B10000,
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B00000, B00000, B00000, B00100, B10100, B10100, B10100, B10100,
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B00000, B00000, B00001, B00101, B10101, B10101, B10101, B10101, //tallest bar
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B00000, B00010, B00111, B00010, B01000, B11100, B01000, B00000, // ++ sign
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};
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#else
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//VK2ETA "Fat" bars, easy to read, with less text
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const PROGMEM uint8_t meters_bitmap[] = {
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// B01110, B10001, B10001, B11111, B11011, B11011, B11111, B00000, //Padlock Symbol, for merging. Not working, see below
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B00000, B00000, B00000, B00000, B00000, B00000, B00000, B11111, //shortest bar
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B00000, B00000, B00000, B00000, B00000, B00000, B11111, B11111,
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B00000, B00000, B00000, B00000, B00000, B11111, B11111, B11111,
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B00000, B00000, B00000, B00000, B11111, B11111, B11111, B11111,
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B00000, B00000, B00000, B11111, B11111, B11111, B11111, B11111,
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B00000, B00000, B11111, B11111, B11111, B11111, B11111, B11111, //tallest bar
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B00000, B00010, B00111, B00010, B01000, B11100, B01000, B00000, // ++ sign
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};
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#endif //OPTION_SKINNYBARS
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PGM_P p_metes_bitmap = reinterpret_cast<PGM_P>(meters_bitmap);
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const PROGMEM uint8_t lock_bitmap[8] = {
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0b01110,
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0b10001,
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0b10001,
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0b11111,
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0b11011,
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0b11011,
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0b11111,
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0b00000};
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PGM_P plock_bitmap = reinterpret_cast<PGM_P>(lock_bitmap);
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// initializes the custom characters
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// we start from char 1 as char 0 terminates the string!
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void initMeter(){
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uint8_t tmpbytes[8];
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byte i;
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(plock_bitmap + i);
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LCD_CreateChar(0, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i);
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LCD_CreateChar(1, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 8);
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LCD_CreateChar(2, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 16);
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LCD_CreateChar(3, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 24);
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LCD_CreateChar(4, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 32);
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LCD_CreateChar(5, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 40);
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LCD_CreateChar(6, tmpbytes);
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for (i = 0; i < 8; i++)
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tmpbytes[i] = pgm_read_byte(p_metes_bitmap + i + 48);
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2018-05-03 03:20:09 -04:00
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LCD_CreateChar(7, tmpbytes);
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2018-04-16 10:56:32 -04:00
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}
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//by KD8CEC
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//0 ~ 25 : 30 over : + 10
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/*
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void drawMeter(int needle) {
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//5Char + O over
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int i;
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for (i = 0; i < 5; i++) {
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if (needle >= 5)
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lcdMeter[i] = 5; //full
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else if (needle > 0)
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lcdMeter[i] = needle; //full
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else //0
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lcdMeter[i] = 0x20;
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needle -= 5;
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}
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if (needle > 0)
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lcdMeter[5] = 6;
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else
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lcdMeter[5] = 0x20;
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}
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*/
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//VK2ETA meter for S.Meter, power and SWR
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void drawMeter(int needle)
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{
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#ifdef OPTION_SKINNYBARS
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//Fill buffer with growing set of bars, up to needle value
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2018-05-03 03:20:09 -04:00
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lcdMeter[0] = 0x20;
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lcdMeter[1] = 0x20;
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2018-04-16 10:56:32 -04:00
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for (int i = 0; i < 6; i++) {
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if (needle > i)
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lcdMeter[i / 3] = byte(i + 1); //Custom characters above
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2018-05-03 03:20:09 -04:00
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//else if (i == 1 || i == 4) {
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// lcdMeter[i / 3] = 0x20; //blank
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//}
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2018-04-16 10:56:32 -04:00
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}
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2018-05-03 03:20:09 -04:00
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if (needle > 7) {
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lcdMeter[2] = byte(7); //Custom character "++"
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} else if (needle > 6) {
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lcdMeter[2] = '+'; //"+"
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} else lcdMeter[2] = 0x20;
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2018-04-16 10:56:32 -04:00
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#else //Must be "fat" bars
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//Fill buffer with growing set of bars, up to needle value
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for (int i = 0; i < 6; i++) {
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if (needle > i)
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lcdMeter[i] = byte(i + 1); //Custom characters above
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else
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lcdMeter[i] = 0x20; //blank
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}
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2018-05-03 03:20:09 -04:00
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2018-04-16 10:56:32 -04:00
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if (needle > 7) {
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lcdMeter[6] = byte(7); //Custom character "++"
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} else if (needle > 6) {
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2018-05-03 03:20:09 -04:00
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lcdMeter[6] = '+'; //"+"
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2018-04-16 10:56:32 -04:00
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} else lcdMeter[6] = 0x20;
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2018-05-03 03:20:09 -04:00
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2018-04-16 10:56:32 -04:00
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#endif //OPTION_FATBARS
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}
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2018-04-05 09:57:07 -04:00
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char byteToChar(byte srcByte){
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if (srcByte < 10)
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return 0x30 + srcByte;
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else
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return 'A' + srcByte - 10;
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}
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2017-12-06 23:48:43 -05:00
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//returns true if the button is pressed
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2018-03-09 08:02:10 -05:00
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int btnDown(void){
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2018-04-17 08:26:29 -04:00
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#ifdef EXTEND_KEY_GROUP1
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if (analogRead(FBUTTON) > FUNCTION_KEY_ADC)
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return 0;
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else
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return 1;
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#else
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2017-12-06 23:48:43 -05:00
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if (digitalRead(FBUTTON) == HIGH)
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return 0;
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else
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return 1;
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2018-04-17 08:26:29 -04:00
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#endif
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}
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#ifdef EXTEND_KEY_GROUP1
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int getBtnStatus(void){
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int readButtonValue = analogRead(FBUTTON);
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if (analogRead(FBUTTON) < FUNCTION_KEY_ADC)
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return FKEY_PRESS;
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else
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{
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2018-04-22 19:29:19 -04:00
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readButtonValue = readButtonValue / 4;
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2018-04-24 04:26:34 -04:00
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//return FKEY_VFOCHANGE;
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2018-04-17 08:26:29 -04:00
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for (int i = 0; i < 16; i++)
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2018-05-23 02:07:37 -04:00
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if (KeyValues[i][2] != 0 && KeyValues[i][0] <= readButtonValue && KeyValues[i][1] >= readButtonValue)
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2018-04-24 04:26:34 -04:00
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return KeyValues[i][2];
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//return i;
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2018-04-17 08:26:29 -04:00
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}
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return -1;
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2017-12-06 23:48:43 -05:00
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}
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2018-04-17 08:26:29 -04:00
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#endif
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2017-12-06 23:48:43 -05:00
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int enc_prev_state = 3;
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/**
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* The A7 And A6 are purely analog lines on the Arduino Nano
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* These need to be pulled up externally using two 10 K resistors
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*
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* There are excellent pages on the Internet about how these encoders work
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* and how they should be used. We have elected to use the simplest way
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* to use these encoders without the complexity of interrupts etc to
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* keep it understandable.
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*
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* The enc_state returns a two-bit number such that each bit reflects the current
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* value of each of the two phases of the encoder
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*
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* The enc_read returns the number of net pulses counted over 50 msecs.
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* If the puluses are -ve, they were anti-clockwise, if they are +ve, the
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* were in the clockwise directions. Higher the pulses, greater the speed
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* at which the enccoder was spun
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*/
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byte enc_state (void) {
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return (analogRead(ENC_A) > 500 ? 1 : 0) + (analogRead(ENC_B) > 500 ? 2: 0);
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}
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int enc_read(void) {
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int result = 0;
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byte newState;
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int enc_speed = 0;
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2018-01-20 08:05:04 -05:00
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unsigned long start_at = millis();
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2017-12-06 23:48:43 -05:00
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2018-01-20 08:05:04 -05:00
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while (millis() - start_at < 50) { // check if the previous state was stable
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2017-12-06 23:48:43 -05:00
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newState = enc_state(); // Get current state
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if (newState != enc_prev_state)
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delay (1);
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if (enc_state() != newState || newState == enc_prev_state)
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continue;
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//these transitions point to the encoder being rotated anti-clockwise
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if ((enc_prev_state == 0 && newState == 2) ||
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(enc_prev_state == 2 && newState == 3) ||
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(enc_prev_state == 3 && newState == 1) ||
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(enc_prev_state == 1 && newState == 0)){
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result--;
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}
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//these transitions point o the enccoder being rotated clockwise
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if ((enc_prev_state == 0 && newState == 1) ||
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(enc_prev_state == 1 && newState == 3) ||
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(enc_prev_state == 3 && newState == 2) ||
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(enc_prev_state == 2 && newState == 0)){
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result++;
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}
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enc_prev_state = newState; // Record state for next pulse interpretation
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enc_speed++;
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delay(1);
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}
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return(result);
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}
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