KK9JEF_DDS_VFO/VFO_WSPR/VFO_WSPR.ino

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#include <EEPROM.h>
#include <Encoder.h>
#include <Wire.h>
#include <LiquidCrystal.h>
#include <si5351.h>
//-----------Variables & Declarations---------------
/*
* The current and desired LISTENING FREQUENCY, which is not always the frequency being output by the Si5351.
* In 'testing' and 'basic' modes, the output freqeuncy is equal to currFreq
* In 'polyakov' mode, the output frequency is half of curFreq
* In BFO mode, .........
* These adjustments are mode in the setFrequency_5351 function depending on the current mode held in currMode
*/
long currFreq = 1800000;
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//FOR CQ MODE:
char CQ[] = "-.-. --.-";
char DE[] = "-.. .";
char morseCallsign[] = "-.- -.- ----. .--- . ..-.";
int morseCallsignLength = 25;
long morseElementLength = 70; //ms
//FOR WSPR MODE
double correctionFactor = 0; //adjusts the offset of the Si5351, in parts per million
double prevCorrectionFactor = correctionFactor; //allows us to track whether the CF has changed, to save on EEPROM writes
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int WSPR_TRANSMISSION_DATA[] = { //KK9JEF EN61 30
3,3,2,0,0,0,0,0,3,0,0,2,1,1,1,0,0,2,1,2,2,1,0,3,1,3,1,2,2,0,
0,0,2,2,1,0,2,3,0,1,2,0,2,2,2,2,3,2,3,1,2,0,1,3,2,3,2,0,2,1,
1,0,1,0,0,2,2,1,1,0,1,0,3,0,1,2,1,0,2,3,0,0,1,0,1,1,2,2,2,3,
1,0,1,2,3,2,2,0,1,2,2,0,2,0,1,2,2,3,0,2,1,1,1,0,1,3,2,2,3,1,
0,1,0,2,2,1,1,1,2,0,0,0,0,3,0,1,0,2,3,1,2,2,2,2,0,2,2,3,1,0,
1,2,1,3,2,0,2,3,3,2,0,2};
/*
int WSPR_TRANSMISSION_DATA[] = { //KK9JEF EN61 27
3,3,2,0,0,2,0,2,3,0,0,2,1,3,1,2,0,2,1,0,2,3,0,1,1,1,1,0,2,2,
0,0,2,2,1,2,2,3,0,1,2,2,2,2,2,0,3,0,3,1,2,0,1,3,2,1,2,0,2,3,
1,0,1,2,0,2,2,1,1,0,1,0,3,2,1,0,1,2,2,3,0,0,1,0,1,1,2,2,2,3,
1,2,1,2,3,0,2,0,1,0,2,0,2,0,1,2,2,3,0,0,1,1,1,0,1,1,2,0,3,3,
0,3,0,0,2,1,1,3,2,0,0,2,0,1,0,3,0,2,3,1,2,2,2,0,0,2,2,3,1,0,
1,0,1,1,2,0,2,1,3,0,0,2};
*/
//-----Enumerations of frequency steps and their labels for each mode----//
enum modes{mode_testing = 0, mode_basic, mode_polyakov, mode_bfo, mode_WSPR, mode_CQ, mode_calibrate};
const int NUM_MODES = 7;
int currMode = mode_basic;
char* modeNames[NUM_MODES] = {"TEST", "VFO", "POLYA", "BFO", "WSPR", "CQ", "CAL"};
long steps[][10] = { //don't forget to update the NUM_STEP_OPTIONS array below
{10000000, 5000000, 1000000, 500000, 100000, 10000, 1000, 10, 1}, //testing
{10000, 1000, 100, 10}, //basic
{1000, 100, 10, 1}, //polyakov
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{1000, 100, 10, 1}, //bfo
{5}, //WSPR
{500}, //CQ
{1} //calibrate
};
const int NUM_STEP_OPTIONS[NUM_MODES] = {
10, //testing
4, //basic
4, //polyakov
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4, //bfo
1, //wspr
1, //cq
1 //calibrate
};
char* stepNames[][10] = {
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{" 10MHz", " 5MHz", " 1MHz", "500Khz", "100KHz", " 10KHz", " 1KHz", " 100Hz", " 10Hz", " 1 Hz"}, //basic
{" 10KHz", " 1KHz", " 100Hz", " 10 Hz"}, //basic
{" 1KHz", " 100 Hz", " 10 Hz", " 1 Hz"}, //polyakov
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{" 1KHz", " 100 Hz", " 10 Hz", " 1 Hz"}, //BFO
{" 5 Hz"}, //WSPR
{" 500Hz"}, //CQ
{" 1 ppm"} //Calibrate
};
int stepIndex = 0; // holds the index of the currently selected step value
//-----AMATEUR BAND DEFININTIONS----------------//
//See function "getCurrentBand" below as well
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const int NUM_BANDS = 10;
char* bandNames[NUM_BANDS] = {"160m", "80m", "60m", "40m", "30m", "20m", "17m", "15m", "12m", "10m"};
char* OUT_OF_BAND_LABEL = "OOB";
long bandEdges[NUM_BANDS][2] = {
{1800000, 2000000}, //160m
{3500000, 4000000}, //80m
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{5288600, 5288800},
{7000000, 7300000}, //40m
{10100000, 10150000}, //30m
{14000000, 14350000}, //20m
{18068000, 18168000}, //17m
{21000000, 21450000}, //15m
{24890000, 24990000}, //12m
{28000000, 29700000} //10m
};
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long WSPRbandEdges[NUM_BANDS][2] = {
{1838000, 1838200}, //160m
{3594000, 3594200}, //80m
{5288600, 5288800}, //60m
{7040000, 7040200}, //40m
{10140100, 10140300}, //30m
{14097000, 14097200}, //20m
{18106000, 18106200}, //17m
{21096000, 21096200}, //15m
{24926000, 24926200}, //12m
{28126000, 28126200}, //10m
};
/*
* Holds the last-seen frequency within each band. The list below is also the default location at bootup.
* This array is updated when the BAND button is used to change between bands.
* If the used has scrolled outside of a defined band and then presses the BAND button, they will
* still be advanced to the next band, but the band-return location will not be updated
*/
long lastBandFreq[NUM_BANDS] = {
1800000, //160m
3500000, //80m
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5288600, //60m
7000000, //40m
10100000, //30m
14000000, //20m
18068000, //17m
21000000, //15m
24890000, //12m
28000000 //10m
};
/*Information on bandplan permissions and recommended communication modes is contained in the
* methods getPermission and getBandplanModes below
*/
//---------------------------------------------
long lastButtonPress[] = {0,0,0,0,0,0,0}; //holds the last timestamp, from millis(), that a pin changed state. Directly references the arduino output pin numbers, length may need to be increased
boolean buttonActive[] = {false, false, false, false, false, false, false};
long encoderPosition = 0;
boolean displayNeedsUpdate;
const long MIN_FREQ = 8500;
const long MAX_FREQ = 150000000;
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//Onboard LED Steup
const int PIN_LED = 13;
//---------LCD SETUP-------//
int PIN_RS = 7;
int PIN_EN = 8;
int PIN_DB4 = 9;
int PIN_DB5 = 10;
int PIN_DB6 = 11;
int PIN_DB7 = 12;
LiquidCrystal lcd(PIN_RS, PIN_EN, PIN_DB4, PIN_DB5, PIN_DB6, PIN_DB7);
//--------Si5351 Declaration---------------//
Si5351 si5351;
//SDA is on pin A4 for Arduino Uno
//SCL is on pin A5 for Arduino Uno
//--------Tuning Knob Interrupt Pins-------//
//Encoder knob(2, 3), pushbutton on 1
Encoder encoder(2, 3);
const int PIN_BUTTON_ENCODER = 1;
//Button Pins//
const int PIN_BUTTON_MODE = 4;
const int PIN_BUTTON_BAND = 0;
const int BUTTON_DEBOUNCE_TIME = 10; //milliseconds
//SWR Sensor Pins
const int PIN_SWR_FORWARD = A1;
const int PIN_SWR_REVERSE = A0;
void setup(){
// inialize LCD, display welcome message
lcd.begin(20, 4);
delay(250);
lcd.setCursor(4, 1);
lcd.print("VFO STARTING");
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pinMode(PIN_LED, OUTPUT);
digitalWrite(PIN_LED, LOW);
pinMode(PIN_BUTTON_ENCODER, INPUT);
digitalWrite(PIN_BUTTON_ENCODER, HIGH);
pinMode(PIN_BUTTON_MODE, INPUT);
digitalWrite(PIN_BUTTON_MODE, HIGH);
pinMode(PIN_BUTTON_BAND, INPUT);
digitalWrite(PIN_BUTTON_BAND, HIGH);
pinMode(PIN_SWR_FORWARD, INPUT);
pinMode(PIN_SWR_REVERSE, INPUT);
lcd.clear();
lcd.setCursor(0,1);
lcd.print("READING CALIBRATION");
double tempDouble;
EEPROM.get(0, correctionFactor);
//if (tempDouble < 0.00001 && tempDouble > -0.00001){correctionFactor = tempDouble;}
//else {correctionFactor = 0.00f;}
lcd.setCursor(0, 2);
lcd.print("*");
lcd.print(tempDouble);
lcd.setCursor(0, 3);
lcd.print("=");
lcd.print(correctionFactor);
delay(1000);
si5351.init(SI5351_CRYSTAL_LOAD_8PF, 0);
si5351.set_freq((currFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
enableOutput();
si5351.drive_strength(SI5351_CLK0, SI5351_DRIVE_8MA);
si5351.output_enable(SI5351_CLK1, 0);
si5351.output_enable(SI5351_CLK2, 0);
delay(300);
lcd.clear();
lcd.setCursor(2, 7);
lcd.print("WELCOME!");
delay(500);
displayInfo();
}
void loop(){
if (displayNeedsUpdate) {displayInfo();}
delay(80);
//detect whether encoder has changed position
long reading = encoder.read();
long encoderChange = reading - encoderPosition;
encoderPosition = reading;
displayNeedsUpdate = false;
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//step up or down or change step size, for encoder turns
if (currMode != mode_calibrate){
if ((encoderChange > 0)){currFreq += steps[currMode][stepIndex]; currFreq = min(currFreq, MAX_FREQ); setFrequency_5351(currFreq); displayNeedsUpdate = true;}
if ((encoderChange < 0)){currFreq -= steps[currMode][stepIndex]; currFreq = max(currFreq, MIN_FREQ); setFrequency_5351(currFreq); displayNeedsUpdate = true;}
}
else{
if (encoderChange > 0){correctionFactor += 0.0000001; setFrequency_5351(currFreq); displayNeedsUpdate = true;}
if (encoderChange < 0){correctionFactor -= 0.0000001; setFrequency_5351(currFreq); displayNeedsUpdate = true;}
}
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//pressing the encoder button increments through the possible step sizes for each mode;
//in WSPR or CQ modes, the encoder button triggers the transmission of WSPR or a CQ, respectively.
if (checkButtonPress(PIN_BUTTON_ENCODER)){
if (currMode == mode_testing || currMode == mode_basic || currMode == mode_polyakov || currMode == mode_bfo) {
stepIndex = (stepIndex + 1) % (NUM_STEP_OPTIONS[currMode]);
displayNeedsUpdate = true;
}
else if (currMode == mode_WSPR){
transmitWSPR();
}
else if (currMode == mode_CQ){
transmitMorseWord(CQ);
transmitSpace();
transmitMorseWord(CQ);
transmitSpace();
transmitMorseWord(DE);
transmitSpace();
transmitMorseWord(morseCallsign);
transmitSpace();
transmitMorseWord(morseCallsign);
}
else if (currMode == mode_calibrate){
correctionFactor = 0.00;
}
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}
//pressing the mode button cycles through the available modes
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if (checkButtonPress(PIN_BUTTON_MODE)){
//if the correctionFacotr has changed and we're leaving calibration mode, write the new correction factor to the EEPROM
//Note that we do this check before actually advancing to the next mode
if (currMode == mode_calibrate && correctionFactor != prevCorrectionFactor){
writeCF();
//DEBUG
lcd.clear();
lcd.setCursor(0, 0);
lcd.print("CALIBRATION STORED");
delay(1000);
displayNeedsUpdate = true;
double tempDouble;
EEPROM.get(0, tempDouble);
if (tempDouble < 0.00001 && tempDouble > -0.00001){correctionFactor = tempDouble;}
else correctionFactor = 0.00f;
lcd.setCursor(0, 2);
lcd.print("*");
lcd.print(tempDouble);
lcd.setCursor(0, 3);
lcd.print("=");
lcd.print(correctionFactor);
delay(10000);
}
//actually change the mode, and reset the step index
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currMode = (currMode+1) % NUM_MODES;
stepIndex = 0;
//if entering calibration mode, make a note of the current correction factor so we can tell later if it changes
if (currMode == mode_calibrate){
prevCorrectionFactor = correctionFactor;
}
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if (currMode == mode_WSPR){ //If entering WSPR mode, set the current freqency to the bottom of the WSPR band slice
currFreq = findWSPRBand();
}
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if (currMode == mode_WSPR || currMode == mode_CQ){
disableOutput(); //In WSPR or CQ mode, the transmitter should be off until manually triggered
}
else{
enableOutput(); //In all other modes, the output of the VFO is on by default
}
setFrequency_5351(currFreq);
displayNeedsUpdate = true;
}
/*The band button: if currFreq is inside an amateur band, save that frequency as the one to return to when
* the user returns to this band, and jump to the return frequency for the next higher band. Otherwise,
* just jump to the next higher band
*/
if (checkButtonPress(PIN_BUTTON_BAND)){
int currBand = getCurrentBand();
if (currBand >= 0){
lastBandFreq[currBand] = currFreq;
currFreq = lastBandFreq[(getCurrentBand() + 1) % NUM_BANDS];
setFrequency_5351(currFreq);
}
else if (currBand == -2 || currBand == -3){
currFreq = lastBandFreq[0];
setFrequency_5351(currFreq);
}
else if (currBand == -1){
for (int i = 0; i < NUM_BANDS; i++){
if (currFreq < lastBandFreq[i]){currFreq = lastBandFreq[i]; setFrequency_5351(currFreq); break;}
}
}
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if (currMode == mode_WSPR){ //WSPR mode behaves differntly from other modes
currFreq = WSPRbandEdges[getCurrentBand()][0];
setFrequency_5351(currFreq);
}
displayNeedsUpdate = true;
}
}
void displayInfo(){
lcd.clear();
// frequency information be centeredw within 11 spaces on the second line:
if (currFreq >= 100000000) lcd.setCursor(3, 0);
else if (currFreq > 10000000) lcd.setCursor(4, 0);
else lcd.setCursor(5, 0);
int mhz = int(currFreq/ 1000000);
int khz = int((currFreq - (mhz*1000000)) / 1000);
int hz = int(currFreq % 1000);
int khzPad = 0;
if (khz < 100) khzPad++;
if (khz < 10) khzPad++;
int hzPad = 0;
if (hz < 100) hzPad++;
if (hz < 10) hzPad++;
lcd.print(mhz);
lcd.print(".");
for (int i = 0; i < khzPad; i++) lcd.print("0");
lcd.print(khz);
lcd.print(".");
for (int i = 0; i < hzPad; i++) lcd.print("0");
lcd.print(hz);
//The current amateur band is printed in the top-right corner
int currBand = getCurrentBand();
if (currBand >= 0){
char* currBandName = bandNames[currBand];
lcd.setCursor(20-strlen(currBandName), 0);
lcd.print(currBandName);
}
else{
lcd.setCursor(20-strlen(OUT_OF_BAND_LABEL), 0);
lcd.print(OUT_OF_BAND_LABEL);
}
//The license needed to operate on this frequency (ARRL, USA ONLY) is printed just below the band label
lcd.setCursor (19, 1);
lcd.print(getPermission());
//Step Information should take the middle 11 spaces on the 3nd line
//The first 5 symbols are "STEP:", leaving 6 chars for step info.
lcd.setCursor(4, 2);
lcd.print("STEP:");
lcd.print(stepNames[currMode][stepIndex]);
//Callsign is printed at the beginning of the 4th line
lcd.setCursor(0, 3);
lcd.print("KK9JEF");
//The mode is printed on the 4th line with no label
//lcd.setCursor(6, 3);
lcd.setCursor(20-strlen(modeNames[currMode]), 3);
lcd.print(modeNames[currMode]);
//If we're in calibration mode, print current calibration factor on line 2:
if (currMode == mode_calibrate){
lcd.setCursor(0, 1);
lcd.print("CORRECTION");
int correctionPPM = int(correctionFactor * pow(10, 6));
int correctionPad = 0;
if (correctionPPM < 100) correctionPad++;
if (correctionPPM < 10) correctionPad++;
if (correctionPPM > 0) correctionPad++;
lcd.setCursor(9, 1);
for (int i = 0; i < correctionPad; i++) lcd.print(" ");
lcd.print(correctionPPM);
}
}
boolean checkButtonPress(int pin){
long time = millis();
if (buttonActive[pin] && digitalRead(pin) == HIGH){
buttonActive[pin] = false;
lastButtonPress[pin] = time;
}
else if (digitalRead(pin) == LOW && !buttonActive[pin] && time > lastButtonPress[pin] + BUTTON_DEBOUNCE_TIME){
buttonActive[pin] = true;
lastButtonPress[pin] = time;
return true;
}
return false;
}
void setFrequency_5351(long newFreq){
switch (currMode){
case mode_testing:
si5351.set_freq((newFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
break;
case mode_basic:
si5351.set_freq((newFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
break;
case mode_polyakov:
si5351.set_freq(((newFreq * (1 + correctionFactor))/ 2) * 100ULL, 0ULL, SI5351_CLK0);
break;
case mode_bfo:
si5351.set_freq((newFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
break;
case mode_WSPR:
si5351.set_freq((newFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
break;
case mode_CQ:
si5351.set_freq((newFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
break;
case mode_calibrate:
si5351.set_freq((newFreq * (1 + correctionFactor)) * 100ULL, 0ULL, SI5351_CLK0);
break;
}
}
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void enableOutput(){
si5351.output_enable(SI5351_CLK0, 1);
digitalWrite(PIN_LED, HIGH);
}
void disableOutput(){
si5351.output_enable(SI5351_CLK0, 0);
digitalWrite(PIN_LED, LOW);
}
//Returns the index of the current amateur radio band based on currFreq. Does not include the 60m band
//Returns -1 if out of band, but within the HF amateur turning range
//returns -2 if out of band and lower than the lowest defined band
//returns -3 if out of band and higher than the highest defined band
int getCurrentBand(){
if (currFreq < bandEdges[0][0]) return -2; //we are lower than the lower edge of the lowest defined band
if (currFreq > bandEdges[NUM_BANDS-1][1]) return -3; //We are higher than the upper edge of the highest defined band
for (int i = 0; i < NUM_BANDS; i++){
if (currFreq >= bandEdges[i][0] && currFreq <= bandEdges[i][1]){return i;} //We are within a band
}
return -1;
}
char getPermission(){
if (getCurrentBand() < 0) return ' ';
//160m
if (currFreq >= 1800000 && currFreq <= 2000000) return 'G';
//80m
if (currFreq >= 3525000 && currFreq <= 3600000) return 'T';
if ((currFreq >= 3525000 && currFreq <= 3600000) || (currFreq >= 3800000 && currFreq <= 4000000)) return 'G';
if ((currFreq >= 3525000 && currFreq <= 3600000) || (currFreq >= 3700000 && currFreq <= 4000000)) return 'A';
if (currFreq >= 3500000 && currFreq <= 4000000) return 'E';
//40m
if (currFreq >= 7025000 && currFreq <= 7125000) return 'T';
if ((currFreq >= 7025000 && currFreq <= 7125000) || (currFreq >= 7175000 && currFreq <= 7300000)) return 'G';
if (currFreq >= 7025000 && currFreq <= 7300000) return 'A';
if (currFreq >= 7000000 && currFreq <= 7300000) return 'E';
//30m
if (currFreq >= 10100000 && currFreq <= 10150000) return 'G';
//20m
if ((currFreq >= 14025000 && currFreq <= 14150000) || (currFreq >= 14225000 && currFreq <= 14350000)) return 'G';
if ((currFreq >= 14025000 && currFreq <= 14150000) || (currFreq >= 14175000 && currFreq <= 14350000)) return 'A';
if (currFreq >= 14000000 && currFreq <= 14350000) return 'E';
//17m
if (currFreq >= 18068000 && currFreq <= 18168000) return 'G';
//15m
if (currFreq >= 21025000 && currFreq <= 21200000) return 'T';
if ((currFreq >= 21025000 && currFreq <= 21200000) || (currFreq >= 21275000 && currFreq <= 21450000)) return 'G';
if ((currFreq >= 21025000 && currFreq <= 21200000) || (currFreq >= 21225000 && currFreq <= 21450000)) return 'A';
if (currFreq >= 21000000 && currFreq <= 21450000) return 'E';
//12m
if (currFreq >= 24890000 && currFreq <= 24990000) return 'G';
//10m
if (currFreq >= 28000000 && currFreq <= 28500000) return 'T';
if (currFreq >= 28000000 && currFreq <= 29700000) return 'G';
return 'X';
}
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void transmitWSPR(){
long startTime = millis();
enableOutput();
for (int dataFrame = 0; dataFrame < 162; dataFrame++){
si5351.set_freq((currFreq + correctionFactor) * 100ULL + (146*WSPR_TRANSMISSION_DATA[dataFrame]*1ULL), SI5351_PLL_FIXED, SI5351_CLK0);
displayWSPR(dataFrame);
while (millis() < startTime + 683*(dataFrame+1)){
if (checkButtonPress(PIN_BUTTON_ENCODER) || dataFrame > 162){
goto escape;
}
}
}
escape:
disableOutput();
displayNeedsUpdate = true;
}
void displayWSPR(int frame){
lcd.clear();
lcd.setCursor(0,0);
long printFreq = currFreq * 100ULL + (146*WSPR_TRANSMISSION_DATA[frame]*1ULL);
lcd.print(printFreq);
//current frame and data are printed on the 3rd line
lcd.setCursor(0, 2);
lcd.print("FRAME:");
lcd.setCursor(6, 2);
lcd.print(frame);
lcd.setCursor(10, 2);
lcd.print("DATA:");
lcd.setCursor(15, 2);
lcd.print(WSPR_TRANSMISSION_DATA[frame]);
//The current amateur band is printed in the top-right corner
int currBand = getCurrentBand();
if (currBand >= 0){
char* currBandName = bandNames[currBand];
lcd.setCursor(20-strlen(currBandName), 0);
lcd.print(currBandName);
}
else{
lcd.setCursor(20-strlen(OUT_OF_BAND_LABEL), 0);
lcd.print(OUT_OF_BAND_LABEL);
}
//Callsign is printed at the beginning of the 4th line
lcd.setCursor(0, 3);
lcd.print("KK9JEF");
//The mode is printed on the 4th line with no label
//lcd.setCursor(6, 3);
lcd.setCursor(16, 3);
lcd.print("WSPR");
}
//When switching into WSPR mode, the VFO jumps to the WSPR portion of the appropriate band; if not inside a band when switching to WSPR mode,
//This fucntion determines where to jump to.
//Currently always resets to the bottom of the lowest band
long findWSPRBand(){
/*switch (getCurrentBand()){
case -2: //Below the lowest defined band
currFreq = WSPRbandEdges[0][0]; //set frequency to the bottom edge of lowest band
break;
case -3: //Above the highest defined band
currFreq = WSPRbandEdges[NUM_BANDS-1][0]; //Set frequency to bottom edge of highest band
break;
case -1: //in between bands
break;
default:
currFreq = currFreq = (currFreq % 5); //round to the nearest multiple of 5 hz, for readability in WSPR mode
break;
}
*/
return WSPRbandEdges[0][0];
}
void transmitMorseWord(char singleWord[]){
for (int i = 0; i < strlen(singleWord); i++){
if (singleWord[i] == '-') transmitDash();
else if (singleWord[i] == '.') transmitDot();
else transmitIntracharacter();
}
}
void transmitDash(){
enableOutput();
delay(morseElementLength * 3);
disableOutput();
delay(morseElementLength);
}
void transmitDot(){
enableOutput();
delay(morseElementLength);
disableOutput();
delay(morseElementLength);
}
void transmitIntracharacter(){
disableOutput();
delay(morseElementLength*2); //each element naturally has a one-dot space built in
}
void transmitSpace(){
disableOutput();
delay(morseElementLength*6); //each element naturally has a one-dot space built in that follows it.
}
void writeCF(){
EEPROM.put(0, correctionFactor);
}