Following comment in #31 we added example

examples/MQ-135-CorrectionFactorDHT11/MQ-135-CorrectionFactorDHT11.ino

@@ -0,0 +1,183 @@
+/*
+  MQUnifiedsensor Library - reading an MQ135
+
+  Demonstrates the use a MQ135 sensor.
+  Library originally added 01 may 2019
+  by Miguel A Califa, Yersson Carrillo, Ghiordy Contreras, Mario Rodriguez
+ 
+  Added example
+  modified 23 May 2019
+  by Miguel Califa 
+
+  Updated library usage
+  modified 26 March 2020
+  by Miguel Califa 
+
+  Wiring:
+  https://github.com/miguel5612/MQSensorsLib_Docs/blob/master/static/img/MQ_Arduino.PNG
+  Please take care, arduino A0 pin represent the analog input configured on #define pin
+
+ This example code is in the public domain.
+
+*/
+
+//Include the library
+#include <MQUnifiedsensor.h>
+#include <Adafruit_Sensor.h>
+#include <DHT.h>
+#include <DHT_U.h>
+
+//Definitions
+#define placa "Arduino UNO"
+#define Voltage_Resolution 5
+#define pin A0 //Analog input 0 of your arduino
+#define type "MQ-135" //MQ135
+#define ADC_Bit_Resolution 10 // For arduino UNO/MEGA/NANO
+#define RatioMQ135CleanAir 3.6//RS / R0 = 3.6 ppm  
+//#define calibration_button 13 //Pin to calibrate your sensor
+
+#define MQ135_DEFAULTPPM 399 //default ppm of CO2 for calibration
+#define MQ135_DEFAULTRO 68550 //default Ro for MQ135_DEFAULTPPM ppm of CO2
+#define MQ135_SCALINGFACTOR 116.6020682 //CO2 gas value
+#define MQ135_EXPONENT -2.769034857 //CO2 gas value
+#define MQ135_MAXRSRO 2.428 //for CO2
+#define MQ135_MINRSRO 0.358 //for CO2
+
+
+/// Parameters for calculating ppm of CO2 from sensor resistance
+#define PARA 116.6020682
+#define PARB 2.769034857
+
+/// Parameters to model temperature and humidity dependence
+#define CORA 0.00035
+#define CORB 0.02718
+#define CORC 1.39538
+#define CORD 0.0018
+
+#define DHTPIN 2     // Digital pin connected to the DHT sensor 
+// Feather HUZZAH ESP8266 note: use pins 3, 4, 5, 12, 13 or 14 --
+// Pin 15 can work but DHT must be disconnected during program upload.
+
+// Uncomment the type of sensor in use:
+//#define DHTTYPE    DHT11     // DHT 11
+#define DHTTYPE    DHT22     // DHT 22 (AM2302)
+//#define DHTTYPE    DHT21     // DHT 21 (AM2301)
+
+// See guide for details on sensor wiring and usage:
+//   https://learn.adafruit.com/dht/overview
+
+DHT_Unified dht(DHTPIN, DHTTYPE);
+
+uint32_t delayMS;
+
+//Declare Sensor
+MQUnifiedsensor MQ135(placa, Voltage_Resolution, ADC_Bit_Resolution, pin, type);
+
+void setup() {
+  //Init the serial port communication - to debug the library
+  Serial.begin(9600); //Init serial port
+  dht.begin();
+  sensor_t sensor;
+  
+  //Set math model to calculate the PPM concentration and the value of constants
+  MQ135.setRegressionMethod(1); //_PPM =  a*ratio^b
+  MQ135.setA(102.2); MQ135.setB(-2.473); // Configurate the ecuation values to get NH4 concentration
+
+  /*
+    Exponential regression:
+  GAS      | a      | b
+  CO       | 605.18 | -3.937  
+  Alcohol  | 77.255 | -3.18 
+  CO2      | 110.47 | -2.862
+  Tolueno  | 44.947 | -3.445
+  NH4      | 102.2  | -2.473
+  Acetona  | 34.668 | -3.369
+  */
+  
+  /*****************************  MQ Init ********************************************/ 
+  //Remarks: Configure the pin of arduino as input.
+  /************************************************************************************/ 
+  MQ135.init(); 
+  /* 
+    //If the RL value is different from 10K please assign your RL value with the following method:
+    MQ135.setRL(10);
+  */
+  /*****************************  MQ CAlibration ********************************************/ 
+  // Explanation: 
+  // In this routine the sensor will measure the resistance of the sensor supposing before was pre-heated
+  // and now is on clean air (Calibration conditions), and it will setup R0 value.
+  // We recomend execute this routine only on setup or on the laboratory and save on the eeprom of your arduino
+  // This routine not need to execute to every restart, you can load your R0 if you know the value
+  // Acknowledgements: https://jayconsystems.com/blog/understanding-a-gas-sensor
+  Serial.print("Calibrating please wait.");
+  float calcR0 = 0;
+  for(int i = 1; i<=10; i ++)
+  {
+    MQ135.update(); // Update data, the arduino will be read the voltage on the analog pin
+    calcR0 += MQ135.calibrate(RatioMQ135CleanAir);
+    Serial.print(".");
+  }
+  MQ135.setR0(calcR0/10);
+  Serial.println("  done!.");
+  
+  if(isinf(calcR0)) {Serial.println("Warning: Conection issue founded, R0 is infite (Open circuit detected) please check your wiring and supply"); while(1);}
+  if(calcR0 == 0){Serial.println("Warning: Conection issue founded, R0 is zero (Analog pin with short circuit to ground) please check your wiring and supply"); while(1);}
+  /*****************************  MQ CAlibration ********************************************/ 
+  MQ135.serialDebug(true);
+  // Set delay between sensor readings based on sensor details.
+  delayMS = sensor.min_delay / 1000;
+}
+
+void loop() {
+  
+  delay(delayMS); //Sampling frequency
+
+  // if you want to apply corelation factor, you will add in this program the temperature and humidity sensor
+  sensors_event_t event;
+  dht.temperature().getEvent(&event);
+  float cFactor = 0;
+  if (!isnan(event.temperature) && !isnan(event.relative_humidity)) cFactor = getCorrectionFactor(event.temperature, event.relative_humidity);
+  Serial.print("Correction Factor: "); Serial.println(cFactor);
+  MQ135.update(); // Update data, the arduino will be read the voltage on the analog pin
+  MQ135.readSensor(false, cFactor); // Sensor will read PPM concentration using the model and a and b values setted before or in the setup
+  MQ135.serialDebug(); // Will print the table on the serial port
+  
+}
+
+/**************************************************************************/
+/*!
+@brief  Get the correction factor to correct for temperature and humidity
+@param[in] t  The ambient air temperature
+@param[in] h  The relative humidity
+@return The calculated correction factor
+*/
+/**************************************************************************/
+float getCorrectionFactor(float t, float h) {
+  return CORA * t * t - CORB * t + CORC - (h-33.)*CORD;
+}
+
+/**************************************************************************/
+/*!
+@brief  Get the resistance of the sensor, ie. the measurement value corrected
+        for temp/hum
+@param[in] t  The ambient air temperature
+@param[in] h  The relative humidity
+@return The corrected sensor resistance kOhm
+*/
+/**************************************************************************/
+float getCorrectedResistance(long resvalue, float t, float h) {
+  return resvalue/getCorrectionFactor(t, h);
+}
+
+/**************************************************************************/
+/*!
+@brief  Get the ppm of CO2 sensed (assuming only CO2 in the air), corrected
+        for temp/hum
+@param[in] t  The ambient air temperature
+@param[in] h  The relative humidity
+@return The ppm of CO2 in the air
+*/
+/**************************************************************************/
+float getCorrectedPPM(long resvalue,float t, float h, long ro) {
+  return PARA * pow((getCorrectedResistance(resvalue, t, h)/ro), -PARB);
+}