void printDateAndTime(LiquidCrystal & lcd, Date & date, Time & time) { lcd.clear(); lcd.setCursor(0,0); date.print(lcd); lcd.setCursor(0,1); time.print(lcd); }
// Allows user to change and select the temperature point // index: index of the current temperature point int CurveInput::getTempPoint( int index ) { initLCD(&col, &row); lcd.print("Enter Temp "); lcd.print(index); lcd.print(" (C)"); lcd.setCursor(0, 1); byte buttonID = NONE; int lowerLimit, upperLimit; temps[index] = getTempLimits(index, &lowerLimit, &upperLimit); int thisTemp = temps[index]; // scoping lcd.print(thisTemp); col = 0; row = 1; lcd.setCursor(col, row); delay(SELECT_DURATION); while ( buttonID != SELECT ) // any button other than SELECT { buttonID = btn.waitForButton(); thisTemp = btn.actionIncDec(buttonID, TIME_TEMP_DURATION, col, row, thisTemp, 3, lowerLimit, upperLimit); // user adjusts temperature } return thisTemp; }
void loop() { lcd.clear(); lcd.print("http://powerpacks." ); lcd.setCursor( 0,1 ); lcd.print("ArcolaEnergy.com"); lcd.setCursor( 0,3 ); lcd.print(RTC.get(DS1307_HR,true)); //read the hour and also update all the values by pushing in true lcd.print(":"); lcd.print(RTC.get(DS1307_MIN,false));//read minutes without update (false) lcd.print(":"); lcd.print(RTC.get(DS1307_SEC,false));//read seconds lcd.print(" "); // some space for a more happy life lcd.print(RTC.get(DS1307_DATE,false));//read date lcd.print("/"); lcd.print(RTC.get(DS1307_MTH,false));//read month lcd.print("/"); lcd.print(RTC.get(DS1307_YR,false)); //read year digitalWrite( STATUS_OK, HIGH); digitalWrite( STATUS_BAD, LOW ); delay( 100 ); digitalWrite( STATUS_OK, LOW); digitalWrite( STATUS_BAD, HIGH ); delay( 100 ); }
void loop() { statoPulsante = digitalRead(6); if(statoPulsante != precedenteStatoPulsante) if (statoPulsante == LOW) { risposta = random(8); lcd.clear(); lcd.setCursor(0,0); lcd.print("La Palla dice:"); lcd.setCursor(0,1); switch(risposta) { case 0: lcd.print("Si"); break; case 1: lcd.print("Molto probabilmente"); break; case 2: lcd.print("Certamemte"); break; case 3: lcd.print("Sembra di si"); break; case 4: lcd.print("Insicuro"); break; case 5: lcd.print("Domanda ancora"); break; case 6: lcd.print("Molto dubbio"); break; case 7: lcd.print("NO"); break; }; }; precedenteStatoPulsante = statoPulsante; }
void loop() { noLight=digitalRead(digitalSignal);// lightness=analogRead(analogSignal); // и о его количестве // set the cursor to column 0, line 1 lcd.setCursor(0, 0); //вывод сообщения Serial.print("There is "); lcd.clear(); if (noLight) { Serial.println("1"); lcd.print("1"); } else { Serial.println("0"); lcd.print("0"); } Serial.print("value: "); Serial.println(lightness); lcd.setCursor(0, 1); //clearLCD(); lcd.print(lightness); delay(1000); //задержка 1 сек }
// Allows user to change and select the time point // index: index of the current time point int CurveInput::getTimePoint( int index ) { initLCD(&col, &row); lcd.print("Enter Time "); lcd.print(index); lcd.print(" (s)"); lcd.setCursor(0, 1); byte buttonID = NONE; int thisTime = times[index]; // scoping current time lcd.print(thisTime); col = 0; row = 1; lcd.setCursor(col, row); delay(SELECT_DURATION); int lowerLimit, upperLimit; getTimeLimits(index, &lowerLimit, &upperLimit); while ( buttonID != SELECT ) // any button other than SELECT { buttonID = btn.waitForButton(); thisTime = btn.actionIncDec(buttonID, TIME_TEMP_DURATION, col, row, thisTime, 3, lowerLimit, upperLimit); // user adjusts time } return thisTime; }
void loop(){ if(analogRead(0)<800)err=0; while(err!=1 && digitalRead(pinErr)!=HIGH){ digitalWrite(pinR1, LOW); lcd.clear(); lcd.setCursor(0,0); lcd.print("R1 ON"); delay(5000); digitalWrite(pinR2, LOW); lcd.clear(); lcd.setCursor(0,0); lcd.print("R2 ON"); delay(5000); //if(analogRead(pinTemp)<=0 && analogRead(pinTemp)>=100) digitalWrite(pinR3, LOW); //else err=1; if(digitalRead(pinErr)==HIGH) { err=1; lcd.clear(); lcd.print("Err R3"); digitalWrite(pinR1, HIGH); digitalWrite(pinR2, HIGH); digitalWrite(pinR3, HIGH); } } lcd.setCursor(0,0); lcd.print("Error!"); digitalWrite(pinR1, HIGH); digitalWrite(pinR2, HIGH); digitalWrite(pinR3, HIGH); }
// Allows user to change and select the time point // index: index of the current time point int CurveInput::getTimePoint( int index ) { initLCD(&col, &row); lcd.print("Duration "); lcd.print(index); lcd.print(" (s)"); lcd.setCursor(0, 1); byte buttonID = NONE; int lowerLimit = 1; int upperLimit = 150; //times[index] = getTimeLimits(index, &lowerLimit, &upperLimit); int duration; if ( index == 1 ) duration = 125; else if ( index == 2 ) duration = 90; else if ( index == 3 ) duration = 90; else duration = 30; lcd.print(duration); col = 0; row = 1; lcd.setCursor(col, row); delay(SELECT_DURATION); while ( buttonID != SELECT ) // any button other than SELECT { buttonID = btn.waitForButton(); duration = btn.actionIncDec(buttonID, TIME_TEMP_DURATION, col, row, duration, 3, lowerLimit, upperLimit); // user adjusts time } return times[index-1] + duration; }
void LcdHandler::refrashScreen(int menuPosittion, double *setParameters, Menu *menu) { lcd.clear(); lcd.setCursor(0, 0); lcd.print(menu->getItem(menuPosittion)); lcd.setCursor(0, 1); lcd.print((int)setParameters[menuPosittion]); }
// Prints curve choices on the LCD screen void CurveInput::printCurveChoices() { initLCD(&col, &row); lcd.print("A: Default Curve"); lcd.setCursor(0, 1); lcd.print("B: User Curve"); lcd.setCursor(0, 0); }
void loop() { // reads the value of the analog sensor int sensorVal = analogRead(sensorPin); Serial.print("Sensor Value: "); Serial.print(sensorVal); // converts the measure from the ADC (analog to digital converter) to volts float voltage = (sensorVal/1024.0)*5.0; Serial.print(", Volts: "); Serial.print(voltage); // turn volts into temperature in Celsius (C) float temperature = (voltage - 0.5)*100; Serial.print(", degrees C: "); Serial.println(temperature); if(temperature < baselineTemp) { digitalWrite(2, LOW); digitalWrite(3, LOW); digitalWrite(4, LOW); } else if(temperature >= baselineTemp+2 && temperature < baselineTemp+4) { digitalWrite(2, HIGH); digitalWrite(3, LOW); digitalWrite(4, LOW); } else if(temperature >= baselineTemp+4 && temperature < baselineTemp+6) { digitalWrite(2, HIGH); digitalWrite(3, HIGH); digitalWrite(4, LOW); } else if(temperature >= baselineTemp+6) { digitalWrite(2, HIGH); digitalWrite(3, HIGH); digitalWrite(4, HIGH); } delay(750); // enumeration of th positions in the LCD start at 0 lcd.setCursor(0, 0); // set the cursor of the LCD in the first position of the first row lcd.print(temperature); // print the value of the variable temperature in Celsius (C) lcd.print(" C"); lcd.setCursor(0, 1); // set the cursor of the LCD in the first position of the second row lcd.print(1.8*temperature + 32); // print the value of the variable temperature in Farenheit (F) lcd.print(" F"); }
void loop() { lcd.setCursor(3,1); lcd.write(1); // desenha o coração delay(500); lcd.setCursor(3,1); lcd.print(" Hello World! "); // Após 0.5s apaga o coração, assim ele delay(500); // ficará piscando }
void loop() { lcd.setCursor(0, 1); lcd.print(rotors[2]); lcd.setCursor(8, 1); lcd.print(rotors[1]); lcd.setCursor(15, 1); lcd.print(rotors[0]); delay(100); }
void Clock::printDateTime(void) { lcd.clear(); lcd.setCursor(0, 0); printDate(); // Start at beginning of second line lcd.setCursor(0, 1); printTime(); }
void lcd_printMoisture(Moisture *moisture) { lcd.setCursor(4, 0); char pch[4]; sprintf(pch, "%02d", moisture->proc); lcd.print(pch); lcd.setCursor(13, 0); sprintf(pch, "%02d", moisture->maxProc); lcd.print(pch); }
void StatsScreen::drawScreen( LiquidCrystal &_lcd ) { _lcd.clear(); _lcd.setCursor(0, 0); _lcd.print("Taken: "); _lcd.print(taken); _lcd.setCursor(0, 1); _lcd.print("Next: "); }
/* Writing non-variable characters. */ void FirstWrite() { lcd.clear(); for (byte i = 0; i < ROWCOUNT; i++) { lcd.setCursor(0, i); lcd.print(prefix[i]); lcd.setCursor(LCDWIDTH - postfix[i].length(), i); lcd.print(postfix[i]); } }
void setup() { lcd.begin(16, 2); // initialise the LCD. pinMode(ledPin, OUTPUT); // sets the digital pin as output pinMode(buttonPin, INPUT); // not really necessary, pins default to INPUT anyway digitalWrite(buttonPin, HIGH); // turn on pullup resistors. Wire button so that press shorts pin to ground. digitalWrite(stopButtonPin, HIGH); // turn on pullup resistors. Wire button so that press shorts pin to ground. lcd.setCursor(0,0); lcd.print("System Ready..."); lcd.setCursor(0,1); }
void LcdHandler::printHomeScreen() { lcd.clear(); lcd.setCursor(0, 0); lcd.print("Temp: "); lcd.print((int)*temp); lcd.print(" C"); lcd.setCursor(0, 1); lcd.print("Hum: "); lcd.print((int)*hum); lcd.print(" %"); }
void trigger() { lcd.clear(); // clears the screen and buffer lcd.setCursor(3,0); lcd.print("Time is up"); lcd.setCursor(1, 1); // set timer position on lcd for end. lcd.print("END OF SHOWER"); turnDownServo(); delay(1000); lcd.display(); }
void PIDControl::displayTemp(double currTemp, double setTempPoint) { lcd.clear(); lcd.setCursor(0,0); lcd.print("Cur Temp: "); lcd.print(currTemp); lcd.print(" C"); lcd.setCursor(0,1); lcd.print("Set Temp: "); lcd.print(setTempPoint); lcd.print(" C"); delay(2000); }
void Menux::showMenuOption(LiquidCrystal &lcd) { // Se envía al display el título del grupo de MenuOptions lcd.clear(); if (presentMenuCode == 1) { titleMenuOption = "Menu General"; } lcd.setCursor(0, 0); lcd.print(titleMenuOption); // Se envía al display la MenuOption actual lcd.setCursor(0, 1); lcd.print(menuOptionList[presentOption].getOptionText()); return; }
/* Writing numbers with padding. @param in number to be written. @param decimals decimal places. @param row to write the number. */ void PaddedWrite(double in, byte decimals, byte row) { // decimal mark byte dm = 0; if(decimals > 0) dm = 1; // clear row for (byte i = 0; i < (sides[row][1] - sides[row][0]); i++) { lcd.setCursor(sides[row][0] + i, row); lcd.write(' '); } lcd.setCursor(Padding(in, row) - dm - decimals, row); lcd.print((round(in * pow(10, decimals)) / pow(10, decimals)), decimals); }
void loop(){ if(gameFinished == false){ float time_to = random(1,2); //.. Aantal milliseconde om mee te beginnen int i; float current_multiplier = 0.98; float cashedOutMultiplier; int randomNumber = random(0,1000); if(randomNumber < 201){ randomNumber = 0; } for(i = 0; i <= randomNumber; i++){ switch (lcd_key){ case btnSELECT:{ cashedOut = true; cashedOutMultiplier = current_multiplier; break; }} lcd.clear(); lcd.print("BustaDuino"); // print a simple message on the LCD lcd.setCursor(0, 1); if(randomNumber > 0){ current_multiplier = current_multiplier + 0.01; }else{ current_multiplier = 0; } lcd.print(String(current_multiplier) + "x"); Serial.print(String(current_multiplier) + "x"); lcd_key = read_LCD_buttons(); // read the buttons if(i <= randomNumber && cashedOut == true){ lcd.clear(); lcd.print("You Win!"); lcd.setCursor(0, 1); lcd.print(String(cashedOutMultiplier) + "x"); Serial.print(String(cashedOutMultiplier) + "x"); gameFinished = true; break; }else if(i >= randomNumber && cashedOut == false){ lcd.clear(); lcd.print("BUSTED!"); lcd.setCursor(0, 1); lcd.print(String(current_multiplier) + "x"); Serial.print(String(current_multiplier) + "x"); gameFinished = true; } delay((time_to/i) * 3000); } } }
/* Stop timer function. * Stops timer with the last lap time and display total time for the last lap. */ void StopTimer() { elapsedTime = millis() - startTime; blinking = false; lcd.setCursor (15,0); lcd.print(" "); lcd.setCursor(0,1); lcd.print(" "); if ( TotalTime == 0) { printTime (elapsedTime, 0, 1, "Total:"); } else printTime (TotalTime, 0, 1, "Total:"); LapNumber=0; TotalTime = 0; }
void setup() { SIM900.begin(9600); Serial.begin(9600); lcd.begin(16, 2); pinMode(8, INPUT); pinMode(9, INPUT); pinMode(10, OUTPUT); lcd.setCursor(3,0); lcd.print("CAR THEFT"); lcd.setCursor(1,1); lcd.print("DETECTION SYS"); delay(2000); lcd.clear(); }
void debug(char *l, int i1, int i2) { int x = (pos % 2) * 10; int y = pos / 2; y = y % 4; lcd.setCursor(x,y); lcd.print(" "); lcd.setCursor(x,y); lcd.print(l); lcd.setCursor(x+2, y); lcd.print(i1); lcd.setCursor(x+6, y); lcd.print(i2); pos++; eraseNext(pos); }
void loop() { //Smoothing of weight and level sensor values raw = ((raw+offset)*.8+.2*analogRead(11)-offset); weight = raw *171/27; if(weight <0) weight = 0; motion = .2*motion + .8*readDistance(motionTrig,motionEcho)/58; right = .9*right + .1*(readDistance(rightTrig,rightEcho)/58); //Sends weight over serial as 2 bytes Serial1.write((int)weight / 256); Serial1.write((int)weight % 256); delay(500); left = .9*left + .1*readDistance(leftTrig,leftEcho)/58; rfill = (raverage-right-2)/(raverage-2) * 100.0; lfill = (laverage-left-2)/(laverage-2) * 100.0; if(rfill <0) rfill = 0; if(lfill <0) lfill = 0; fill=(lfill+rfill)/2; if (motion<20 && pos == 0) { open(); } else if (motion >20 && pos > 0){ close(); } //Sets position and text on LCD display lcd.clear(); lcd.setCursor(0,0); lcd.print("W: "); lcd.print((int)weight); lcd.setCursor(8,0); lcd.print("M: "); lcd.print(motion); lcd.setCursor(0,1); lcd.print("L: "); lcd.print((int)lfill); lcd.print("%"); lcd.setCursor(8,1); lcd.print("R: "); lcd.print((int)rfill); lcd.print("%"); Serial.println(userselected); }
void loop() { static bool show_warning = false; int result = dht11.read(); switch (result) { case Dht11::OK: Serial.println("Read ok"); break; case Dht11::ERROR_TIMEOUT: Serial.println("Timeout"); return; case Dht11::ERROR_CHECKSUM: Serial.println("Checksum error"); return; default: Serial.println("WTF?"); return; } lcd.setCursor(0, 0); lcd.print("T: "); // lcd.print(dht11.getTemperature()); // lcd.print(" | "); // We trust more the thermistor than the humidity sensor... // The last one was giving **really** unrealistic results. float temperature = Tmp36AvgTemperature(); lcd.print(temperature, 2); lcd.print(" C"); lcd.setCursor(0, 1); lcd.print("Hum: "); lcd.print(dht11.getHumidity()); lcd.print('%'); if (temperature > TEMPERATURE_MAX || temperature < TEMPERATURE_MIN) show_warning = !show_warning; else show_warning = false; lcd.setCursor(LCD_COLS - 3, 0); if (show_warning) lcd.print("(!)"); else lcd.print(" "); delay(500); }
void setup(){ // Voltage sensors for (int i; i < countVoltagePins; i++) { pinMode(voltagePins[i], INPUT); } // Heartbeat LED pinMode(LEDpin, OUTPUT); // Serial port is used for debug Serial.begin(9600); // LCD lcd.begin(LCDcols, LCDlines); // Welcome lcd.setCursor(0, 0); lcd.print("Paleo 2011 2012"); // Relays initRelays(); // Init watchdog wdt_enable(WDTO_8S); }