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19 Commits
codex/fix- ... master

Author SHA1 Message Date
Miguel Angel Califa Urquiza
59a2e5852e Merge pull request #85 from miguel5612/codex/implement-temperature-and-humidity-correction-for-all-exampl 
Add optional correction factor to API
 2025-06-04 19:30:15 -05:00
Miguel Angel Califa Urquiza
30c0979cb4 Extend API for optional correction factor 2025-06-04 19:29:44 -05:00
Miguel Angel Califa Urquiza
6f9b00666e Merge pull request #84 from miguel5612/codex/verificar-resolución-del-error--ovf--en-sensor-mq-3 
Fix overflow for CH4 calculations
 2025-06-04 18:57:29 -05:00
Miguel Angel Califa Urquiza
d2e0be3651 Prevent CH4 overflow 2025-06-04 18:54:34 -05:00
Miguel Angel Califa Urquiza
3cd2fd8e7d Merge pull request #83 from miguel5612/codex/verificar-requisitos-de-librería-para-arduino 
Fix Arduino lint errors and bump library version
 2025-06-04 18:34:59 -05:00
Miguel Angel Califa Urquiza
2bdb91c1b5 Add keywords file and bump version 2025-06-04 18:34:45 -05:00
Miguel Angel Califa Urquiza
42689ff5f3 Merge pull request #81 from miguel5612/codex/actualizar-comentarios-de-pin10-a-pin14 
Update UnitTesting pin comments
 2025-06-04 18:10:12 -05:00
Miguel Angel Califa Urquiza
ea48475a3c Merge pull request #82 from miguel5612/codex/fix-typos-in-repository-files 
Fix typos across library
 2025-06-04 18:09:59 -05:00
Miguel Angel Califa Urquiza
144f480f6f Fix analog input comments in UnitTesting example 2025-06-04 18:09:24 -05:00
Miguel Angel Califa Urquiza
46d416abad Merge pull request #77 from miguel5612/codex/resolver-issues-del-repositorio 
Fix RS formula by using VCC
 2025-06-04 18:08:28 -05:00
Miguel Angel Califa Urquiza
f7fae4e03c Merge branch 'master' into codex/resolver-issues-del-repositorio 2025-06-04 17:52:12 -05:00
Miguel Angel Califa Urquiza
c9c1549600 Merge pull request #78 from miguel5612/codex/add-test-for-mq303a_voltresolution 
Add MQ303A voltage resolution unit test
 2025-06-04 17:50:35 -05:00
Miguel Angel Califa Urquiza
af291df03d Merge pull request #79 from miguel5612/codex/modificar-cálculo-usando-voltres-en-readsensor 
Fix voltage resolution side effect
 2025-06-04 17:50:20 -05:00
Miguel Angel Califa Urquiza
748ff3055c Merge branch 'master' into codex/modificar-cálculo-usando-voltres-en-readsensor 2025-06-04 17:49:48 -05:00
Miguel Angel Califa Urquiza
a6abda567f Merge pull request #80 from miguel5612/codex/detectar-y-corregir-error-en-código-base 
Fix MQ303A voltage offset
 2025-06-04 17:47:23 -05:00
Miguel Angel Califa Urquiza
92f3c30e82 Fix MQ303A voltage offset bug 2025-06-04 17:46:28 -05:00
Miguel Angel Califa Urquiza
da3adb7335 fix: preserve voltage resolution 2025-06-04 17:46:18 -05:00
Miguel Angel Califa Urquiza
14b0f908f3 Add voltage resolution unit test for MQ303A 2025-06-04 17:46:08 -05:00
Miguel Angel Califa Urquiza
6376cfc11f doc: add issues summary 2025-06-04 17:45:49 -05:00
32 changed files with 279 additions and 101 deletions
Expand all files Collapse all files

5
README.md
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@ -68,6 +68,7 @@ float ppmCH4 = MQ4.readSensor();
* AO -> Analog Output of the sensor
##### Data of board that you should have
* RL Value in KOhms
* If the sensor uses a different supply voltage than the ADC reference, call `yourSensor.setVCC(<voltage>);`
##### Graph
![Wiring_MQSensor](https://raw.githubusercontent.com/miguel5612/MQSensorsLib_Docs/master/static/img/Points_explanation.jpeg)
#### RS/R0 value (From datasheet of your sensor)
@ -173,6 +174,10 @@ Examples/MQ-board.ino
* [Data sheets](https://github.com/miguel5612/MQSensorsLib_Docs/tree/master/Datasheets) - Curves and behavior for each sensor, using logarithmic graphs.
* [Main purpose](https://github.com/miguel5612/MQSensorsLib_Docs/blob/master/static/img/bg.jpg) - Every sensor has high sensibility for a specific gas or material.
## Issues
Consulte [docs/issues.md](docs/issues.md) para un resumen de los problemas abiertos y sus soluciones.
## Contributing
Please read [CONTRIBUTING.md](https://github.com/miguel5612/MQSensorsLib/blob/master/CONTRIBUTING.md) for details on our code of conduct, and the process for submitting pull requests to us.

33
docs/issues.md Normal file
View File

@ -0,0 +1,33 @@
# Issues y soluciones
Este documento resume los problemas reportados en el repositorio y las soluciones propuestas o implementadas.
## Abiertos
### #75 MQ-3 sensor and CH4 gas reading 'ovf' failure
**Estado:** resuelto en la rama `main`
El usuario reporta desbordamiento ("ovf") al utilizar valores muy altos en `setA` y `setB` para leer CH4 con un sensor MQ-3. La solución propuesta es revisar los valores utilizados en `setA` y `setB`, ya que `2*10^31` en C++ no corresponde a `2e31`. Se recomienda usar notación exponencial (`2e31`) o `pow(10,31)` y comprobar que los parámetros no excedan el rango de `float`.
**Actualización:** se añadieron validaciones de entrada, predicción de desbordamiento mediante logaritmos y verificación del resultado final para evitar valores "ovf" incluso con coeficientes muy altos. Las nuevas funciones limitan `setA` y `setB` y emplean cálculos en doble precisión.
### #74 possible error in the calculation formula for `_RS_Calc`
**Estado:** resuelto en la rama `work`
Se detectó que la resistencia del sensor se calculaba con `_VOLT_RESOLUTION` en lugar del voltaje de alimentación real. Se añadieron los métodos `setVCC` y `getVCC` y se modificaron las ecuaciones para usar `VCC`. Esta corrección se refleja en la versión 3.0.1 de la biblioteca.
### #70 Parameters to model temperature and humidity dependence
**Estado:** resuelto en la rama `work`
Se añadieron variables opcionales de "correction factor" en todos los ejemplos y se extendieron las funciones `calibrate` y `readSensorR0Rs` para aceptar este parámetro opcional. Así, el usuario puede ajustar las lecturas en función de temperatura y humedad cuando el datasheet lo permita. Los coeficientes deben consultarse para cada sensor.
### #67 Sensor won't finish the Calibration process if done in clean air
**Estado:** abierto
Se reporta que la calibración se detiene mostrando un mensaje de "Conection issue" cuando se intenta calibrar el sensor MQ-135 en aire limpio. La recomendación del mantenedor es revisar la conexión física y probar el sensor con un programa básico para asegurar su correcto funcionamiento antes de usar la librería. Aún no se ha implementado un cambio en el código.
## Cerrados destacados
Para obtener más información sobre todos los issues cerrados, consulte la página de [Issues en GitHub](https://github.com/miguel5612/MQSensorsLib/issues?q=is%3Aissue+is%3Aclosed).

3
examples/Alcoholimeter/Alcoholimeter.ino
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@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ3.update(); // Update data, the arduino will read the voltage from the analog pin
alcoholPPM = MQ3.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
alcoholPPM = MQ3.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
Serial.print("Alcohol now (PPM): ");
Serial.println(alcoholPPM);
delay(500); //Sampling frequency

3
examples/ESP32/esp32.ino → examples/ESP32/ESP32.ino
View File

@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ3.update(); // Update data, the arduino will read the voltage from the analog pin
MQ3.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ3.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ3.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/ESP32/ESP32_WROOM_32D/ESP32_WROOM_32D.ino
View File

@ -129,7 +129,8 @@ void loop()
{
MQ2.update(); // Update data, the arduino will read the voltage from the analog pin
//MQ2.serialDebug(); // Will print the table on the serial port
Serial.print(MQ2.readSensor()); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
Serial.print(MQ2.readSensor(false, correctionFactor)); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
Serial.println(" PPM");
delay(500); //Sampling frequency
}

3
examples/ESP8266/ESP8266.ino
View File

@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ3.update(); // Update data, the arduino will read the voltage from the analog pin
MQ3.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ3.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ3.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

5
examples/LinearVsExponential/LinearVsExponential.ino
View File

@ -81,17 +81,18 @@ void setup() {
void loop() {
MQ4.update(); // Update data, the arduino will read the voltage from the analog pin
float correctionFactor = 0; // Optional environmental correction
//https://jayconsystems.com/blog/understanding-a-gas-sensor
//Set math model to calculate the PPM concentration and the value of constants
MQ4.setRegressionMethod(0); //_PPM = pow(10, (log10(ratio)-b)/a)
MQ4.setA(-0.318); MQ4.setB(1.133); // A -> Slope, B -> Intersect with X - Axis
float LPG1 = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float LPG1 = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
//Set math model to calculate the PPM concentration and the value of constants
MQ4.setRegressionMethod(1); //_PPM = a*ratio^b
MQ4.setA(1012.7); MQ4.setB(-2.786); // Configure the equation to to calculate CH4 concentration
float LPG2 = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float LPG2 = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
// exposure to 2000 ppm of LPG gas is immediately dangerous to life and health. In this section
if(LPG1>=2000 || LPG2>=2000) Serial.println("Warning - Very high concentrations detected!");

13
examples/MQ-135-ALL/MQ-135-ALL.ino
View File

@ -78,24 +78,25 @@ void setup() {
void loop() {
MQ135.update(); // Update data, the arduino will read the voltage from the analog pin
float correctionFactor = 0; // Optional environmental correction
MQ135.setA(605.18); MQ135.setB(-3.937); // Configure the equation to calculate CO concentration value
float CO = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CO = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(77.255); MQ135.setB(-3.18); //Configure the equation to calculate Alcohol concentration value
float Alcohol = MQ135.readSensor(); // SSensor will read PPM concentration using the model, a and b values set previously or from the setup
float Alcohol = MQ135.readSensor(false, correctionFactor); // SSensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(110.47); MQ135.setB(-2.862); // Configure the equation to calculate CO2 concentration value
float CO2 = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CO2 = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(44.947); MQ135.setB(-3.445); // Configure the equation to calculate Toluen concentration value
float Toluen = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float Toluen = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(102.2 ); MQ135.setB(-2.473); // Configure the equation to calculate NH4 concentration value
float NH4 = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float NH4 = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(34.668); MQ135.setB(-3.369); // Configure the equation to calculate Aceton concentration value
float Aceton = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float Aceton = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
Serial.print("| "); Serial.print(CO);
Serial.print(" | "); Serial.print(Alcohol);
// Note: 400 Offset for CO2 source: https://github.com/miguel5612/MQSensorsLib/issues/29

3
examples/MQ-135/MQ-135.ino
View File

@ -89,7 +89,8 @@ void setup() {
void loop() {
MQ135.update(); // Update data, the arduino will read the voltage from the analog pin
MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-136/MQ-136.ino
View File

@ -82,7 +82,8 @@ void setup() {
void loop() {
MQ136.update(); // Update data, the arduino will read the voltage from the analog pin
MQ136.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ136.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ136.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-2/MQ-2.ino
View File

@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ2.update(); // Update data, the arduino will read the voltage from the analog pin
MQ2.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ2.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ2.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-3/MQ-3.ino
View File

@ -88,7 +88,8 @@ void setup() {
void loop() {
MQ3.update(); // Update data, the arduino will read the voltage from the analog pin
MQ3.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ3.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ3.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-303A/MQ-303A.ino
View File

@ -86,7 +86,8 @@ void setup() {
void loop() {
MQ303.update(); // Update data, the arduino will read the voltage from the analog pin
MQ303.readSensor(true); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ303.readSensor(true, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ303.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

6
examples/MQ-309A/MQ-309A.ino
View File

@ -95,7 +95,8 @@ void loop() {
// VH 0.9 Volts
analogWrite(5, 2); // 255 is 100%, 2.295 is aprox 0.9% of Duty cycle for 60s
MQ309.update(); // Update data, the arduino will read the voltage from the analog pin
MQ309.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ309.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ309.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}
@ -107,7 +108,8 @@ void loop() {
// VL 0.2 Volts
analogWrite(5, 1); // 255 is 100%, 0.51 is aprox 0.2% of Duty cycle for 120s
MQ309.update(); // Update data, the arduino will read the voltage from the analog pin
MQ309.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor2 = 0; // Optional environmental correction
MQ309.readSensor(false, correctionFactor2); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ309.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

11
examples/MQ-4-ALL/MQ-4-ALL.ino
View File

@ -79,6 +79,7 @@ void setup() {
void loop() {
MQ4.update(); // Update data, the arduino will read the voltage from the analog pin
float correctionFactor = 0; // Optional environmental correction
/*
Exponential regression:
@ -90,19 +91,19 @@ void loop() {
smoke | 30000000 | -8.308
*/
MQ4.setA(3811.9); MQ4.setB(-3.113); // Configure the equation to to calculate CH4 concentration
float LPG = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float LPG = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ4.setA(1012.7); MQ4.setB(-2.786); // Configure the equation to to calculate CH4 concentration
float CH4 = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CH4 = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ4.setA(200000000000000); MQ4.setB(-19.05); // Configure the equation to to calculate CH4 concentration
float CO = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CO = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ4.setA(60000000000); MQ4.setB(-14.01); // Configure the equation to to calculate CH4 concentration
float Alcohol = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float Alcohol = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ4.setA(30000000); MQ4.setB(-8.308); // Configure the equation to to calculate CH4 concentration
float Smoke = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float Smoke = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
Serial.print("| "); Serial.print(LPG);
Serial.print(" | "); Serial.print(CH4);

3
examples/MQ-4-LINEAR/MQ-4-LINEAR.ino
View File

@ -81,7 +81,8 @@ void loop() {
//https://jayconsystems.com/blog/understanding-a-gas-sensor
MQ4.setA(-0.318); MQ4.setB(1.133); // A -> Slope, B -> Intersect with X - Axis
float LPG = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
float LPG = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
// exposure to 2000 ppm of LPG gas is immediately dangerous to life and health. In this section
if(LPG>=2000) Serial.println("Warning - Very high concentrations detected!");

3
examples/MQ-4/MQ-4.ino
View File

@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ4.update(); // Update data, the arduino will read the voltage from the analog pin
MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ4.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-5/MQ-5.ino
View File

@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ5.update(); // Update data, the arduino will read the voltage from the analog pin
MQ5.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ5.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ5.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-6/MQ-6.ino
View File

@ -87,7 +87,8 @@ void setup() {
void loop() {
MQ6.update(); // Update data, the arduino will read the voltage from the analog pin
MQ6.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ6.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ6.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

6
examples/MQ-7/MQ-7.ino
View File

@ -100,7 +100,8 @@ void loop() {
// VH 5 Volts
analogWrite(5, 255); // 255 is DC 5V output
MQ7.update(); // Update data, the arduino will read the voltage from the analog pin
MQ7.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ7.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ7.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}
@ -112,7 +113,8 @@ void loop() {
// VH 1.4 Volts
analogWrite(5, 20); // 255 is 100%, 20.4 is aprox 8% of Duty cycle for 90s
MQ7.update(); // Update data, the arduino will read the voltage from the analog pin
MQ7.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor2 = 0; // Optional environmental correction
MQ7.readSensor(false, correctionFactor2); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ7.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/MQ-8/MQ-8.ino
View File

@ -88,7 +88,8 @@ void setup() {
void loop() {
MQ8.update(); // Update data, the arduino will read the voltage from the analog pin
MQ8.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ8.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ8.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

7
examples/MQ-9-ALL/MQ-9-ALL.ino
View File

@ -78,6 +78,7 @@ void setup() {
void loop() {
MQ9.update(); // Update data, the arduino will read the voltage from the analog pin
float correctionFactor = 0; // Optional environmental correction
/*
Exponential regression:
GAS | a | b
@ -87,13 +88,13 @@ void loop() {
*/
MQ9.setA(1000.5); MQ9.setB(-2.186); // Configure the equation to to calculate LPG concentration
float LPG = MQ9.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float LPG = MQ9.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ9.setA(4269.6); MQ9.setB(-2.648); // Configure the equation to to calculate LPG concentration
float CH4 = MQ9.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CH4 = MQ9.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ9.setA(599.65); MQ9.setB(-2.244); // Configure the equation to to calculate LPG concentration
float CO = MQ9.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CO = MQ9.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
Serial.print("| "); Serial.print(LPG);
Serial.print(" | "); Serial.print(CH4);

3
examples/MQ-9/MQ-9.ino
View File

@ -115,7 +115,8 @@ void loop() {
digitalWrite(PreaheatControlPin14, LOW);
MQ9.update(); // Update data, the arduino will read the voltage from the analog pin
MQ9.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ9.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ9.serialDebug(); // Will print the table on the serial port
}

17
examples/MQ-Board/MQ-Board.ino
View File

@ -201,15 +201,16 @@ void readAllSensors()
MQ7.update();
MQ8.update();
MQ9.update();
float correctionFactor = 0; // Optional environmental correction
//Read the sensor and print in serial port
float MQ2Lecture = MQ2.readSensor();
float MQ3Lecture = MQ3.readSensor();
float MQ4Lecture = MQ4.readSensor();
float MQ5Lecture = MQ5.readSensor();
float MQ6Lecture = MQ6.readSensor();
float MQ7Lecture = MQ7.readSensor();
float MQ8Lecture = MQ8.readSensor();
float MQ9Lecture = MQ9.readSensor();
float MQ2Lecture = MQ2.readSensor(false, correctionFactor);
float MQ3Lecture = MQ3.readSensor(false, correctionFactor);
float MQ4Lecture = MQ4.readSensor(false, correctionFactor);
float MQ5Lecture = MQ5.readSensor(false, correctionFactor);
float MQ6Lecture = MQ6.readSensor(false, correctionFactor);
float MQ7Lecture = MQ7.readSensor(false, correctionFactor);
float MQ8Lecture = MQ8.readSensor(false, correctionFactor);
float MQ9Lecture = MQ9.readSensor(false, correctionFactor);
Serial.print("| "); Serial.print(MQ2Lecture);
Serial.print(" | "); Serial.print(MQ3Lecture);

13
examples/MQ135-ADS1115/MQ135-ADS1115.ino
View File

@ -74,24 +74,25 @@ void loop() {
short adc0 = ads.readADC_SingleEnded(0);
float voltios = (adc0 * factorEscala)/1000.0;
MQ135.externalADCUpdate(voltios); // Update data, the arduino will read the voltage from the analog pin
float correctionFactor = 0; // Optional environmental correction
MQ135.setA(605.18); MQ135.setB(-3.937); // Configure the equation to calculate CO concentration value
float CO = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CO = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(77.255); MQ135.setB(-3.18); //Configure the equation to calculate Alcohol concentration value
float Alcohol = MQ135.readSensor(); // SSensor will read PPM concentration using the model, a and b values set previously or from the setup
float Alcohol = MQ135.readSensor(false, correctionFactor); // SSensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(110.47); MQ135.setB(-2.862); // Configure the equation to calculate CO2 concentration value
float CO2 = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float CO2 = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(44.947); MQ135.setB(-3.445); // Configure the equation to calculate Toluen concentration value
float Toluen = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float Toluen = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(102.2 ); MQ135.setB(-2.473); // Configure the equation to calculate NH4 concentration value
float NH4 = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float NH4 = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ135.setA(34.668); MQ135.setB(-3.369); // Configure the equation to calculate Aceton concentration value
float Aceton = MQ135.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float Aceton = MQ135.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
Serial.print("| "); Serial.print(CO);
Serial.print(" | "); Serial.print(Alcohol);
// Note: 200 Offset for CO2 source: https://github.com/miguel5612/MQSensorsLib/issues/29

26
examples/UnitTesting/UnitTesting.ino
View File

@ -27,11 +27,11 @@
#define Pin7 (A7) //Analog input 7 of your arduino
#define Pin8 (A8) //Analog input 8 of your arduino
#define Pin9 (A9) //Analog input 9 of your arduino
#define Pin10 (A10) //Analog input 9 of your arduino
#define Pin11 (A11) //Analog input 9 of your arduino
#define Pin12 (A12) //Analog input 9 of your arduino
#define Pin13 (A13) //Analog input 9 of your arduino
#define Pin14 (A14) //Analog input 9 of your arduino
#define Pin10 (A10) //Analog input 10 of your arduino
#define Pin11 (A11) //Analog input 11 of your arduino
#define Pin12 (A12) //Analog input 12 of your arduino
#define Pin13 (A13) //Analog input 13 of your arduino
#define Pin14 (A14) //Analog input 14 of your arduino
#define PWMPin (5) // Pin connected to mosfet
/***********************Software Related Macros************************************/
#define RatioMQ2CleanAir (9.83) //RS / R0 = 9.83 ppm
@ -237,15 +237,25 @@ test(MQ303A_Ethanol)
{
MQ303A.setRegressionMethod(1); //_PPM = a*ratio^b
MQ303A.setA(3.4916); MQ303A.setB(-2.432); // Configure the equation to to calculate Ethanol concentration
MQ303A.init();
MQ303A.init();
MQ303A.setR0(10);
int ppmExp=944;
int PPM = MQ303A.setRsR0RatioGetPPM(0.1); // Send and Rs/R0 and return PPM (Using datasheet)
assertEqual(PPM,ppmExp);
}
test(MQ303A_VoltResolution)
{
float vRes = 4.7;
MQ303A.setVoltResolution(vRes);
MQ303A.setADC(100); // provide dummy ADC value
float correctionFactor = 0; // Optional environmental correction
MQ303A.readSensor(true, correctionFactor); // dummy read for MQ303A
assertEqualFloat(MQ303A.getVoltResolution(), vRes);
}
test(MQ309A_CO)
{
MQ309A.setRegressionMethod(1); //_PPM = a*ratio^b

3
examples/external_A2D/external_A2D.ino
View File

@ -99,7 +99,8 @@ void setup() {
void loop() {
int yourA2DValue = random(0, 1024); // 10-bit emulation
MQ3.setADC(yourA2DValue); // Update data, the arduino will read the voltage from the analog pin
MQ3.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
MQ3.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
MQ3.serialDebug(); // Will print the table on the serial port
delay(500); //Sampling frequency
}

3
examples/smokeDetector/smokeDetector.ino
View File

@ -88,7 +88,8 @@ void setup() {
//Read the sensor and print in serial port
//Lecture will be saved in lecture variable
MQ4.update();
float smokePPM = MQ4.readSensor(); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
float correctionFactor = 0; // Optional environmental correction
float smokePPM = MQ4.readSensor(false, correctionFactor); // Sensor will read PPM concentration using the model, a and b values set previously or from the setup
if(smokePPM > 1000) {Serial.println("Warning: High concentrations of smoke detected");}
MQ4.serialDebug(); // Will print the table on the serial port
delay(400);

29
keywords.txt Normal file
View File

@ -0,0 +1,29 @@
MQUnifiedsensor KEYWORD1
init KEYWORD2
update KEYWORD2
externalADCUpdate KEYWORD2
setR0 KEYWORD2
setRL KEYWORD2
setA KEYWORD2
setB KEYWORD2
setRegressionMethod KEYWORD2
setVoltResolution KEYWORD2
setVCC KEYWORD2
setPin KEYWORD2
setADC KEYWORD2
serialDebug KEYWORD2
calibrate KEYWORD2
readSensor KEYWORD2
readSensorR0Rs KEYWORD2
validateEcuation KEYWORD2
getVoltage KEYWORD2
setRsR0RatioGetPPM KEYWORD2
getRS KEYWORD2
stringTofloat KEYWORD2
getA KEYWORD2
getB KEYWORD2
getR0 KEYWORD2
getRL KEYWORD2
getVoltResolution KEYWORD2
getVCC KEYWORD2
getRegressionMethod KEYWORD2

2
library.properties
View File

@ -1,5 +1,5 @@
name=MQUnifiedsensor
version=3.0.0
version=3.0.5
author= Miguel Califa <miguelangel5612@gmail.com>, Yersson Carrillo<miguelangel5612@gmail.com>, Ghiordy Contreras<miguelangel5612@gmail.com>
maintainer= Miguel Califa <miguelangel5612@gmail.com>
sentence= This library allows you to read the MQ sensors very easily.

143
src/MQUnifiedsensor.cpp
View File

@ -1,4 +1,6 @@
#include "MQUnifiedsensor.h"
#include <float.h>
#include <math.h>
#define retries 2
#define retry_interval 20
@ -10,6 +12,7 @@ MQUnifiedsensor::MQUnifiedsensor(String Placa, float Voltage_Resolution, int ADC
//this->_type = type; //MQ-2, MQ-3 ... MQ-309A
//this->_placa = Placa;
this-> _VOLT_RESOLUTION = Voltage_Resolution;
this-> _VCC = Voltage_Resolution;
this-> _ADC_Bit_Resolution = ADC_Bit_Resolution;
}
MQUnifiedsensor::MQUnifiedsensor(String Placa, String type) {
@ -20,11 +23,39 @@ void MQUnifiedsensor::init()
{
pinMode(_pin, INPUT);
}
static inline double safePow(double base, double exp){
if(exp == 0.0) return 1.0;
if(exp == 1.0) return base;
if(exp == 2.0) return base * base;
return pow(base, exp);
}
static inline bool willOverflow(double log_ppm){
static const double maxLog = log10((double)FLT_MAX);
static const double minLog = log10((double)FLT_MIN);
return (log_ppm > maxLog || log_ppm < minLog);
}
void MQUnifiedsensor::setA(float a) {
this->_a = a;
if(isinf(a) || isnan(a)) {
this->_a = 0;
} else if(a > MQ_MAX_A) {
this->_a = MQ_MAX_A;
} else if(a < -MQ_MAX_A) {
this->_a = -MQ_MAX_A;
} else {
this->_a = a;
}
}
void MQUnifiedsensor::setB(float b) {
this->_b = b;
if(isinf(b) || isnan(b)) {
this->_b = 0;
} else if(b > MQ_MAX_B) {
this->_b = MQ_MAX_B;
} else if(b < -MQ_MAX_B) {
this->_b = -MQ_MAX_B;
} else {
this->_b = b;
}
}
void MQUnifiedsensor::setR0(float R0) {
this->_R0 = R0;
@ -41,6 +72,10 @@ void MQUnifiedsensor::setVoltResolution(float voltage_resolution)
{
_VOLT_RESOLUTION = voltage_resolution;
}
void MQUnifiedsensor::setVCC(float vcc)
{
_VCC = vcc;
}
void MQUnifiedsensor::setPin(int pin) {
this->_pin = pin;
}
@ -59,6 +94,10 @@ float MQUnifiedsensor::getVoltResolution()
{
return _VOLT_RESOLUTION;
}
float MQUnifiedsensor::getVCC()
{
return _VCC;
}
String MQUnifiedsensor::getRegressionMethod()
{
if(_regressionMethod == 1) return "Exponential";
@ -85,7 +124,8 @@ void MQUnifiedsensor::serialDebug(bool onSetup)
Serial.println("Contributors: Andres A. Martinez - Juan A. Rodríguez - Mario A. Rodríguez O ");
Serial.print("Sensor: "); Serial.println(_type);
Serial.print("Supply voltage: "); Serial.print(_VOLT_RESOLUTION); Serial.println(" VDC");
Serial.print("ADC voltage: "); Serial.print(_VOLT_RESOLUTION); Serial.println(" VDC");
Serial.print("Sensor supply (VCC): "); Serial.print(_VCC); Serial.println(" VDC");
Serial.print("ADC Resolution: "); Serial.print(_ADC_Bit_Resolution); Serial.println(" Bits");
Serial.print("R0: "); Serial.print(_R0); Serial.println("");
Serial.print("RL: "); Serial.print(_RL); Serial.println("");
@ -106,7 +146,7 @@ void MQUnifiedsensor::serialDebug(bool onSetup)
else
{
Serial.print("|"); Serial.print(_adc); Serial.print("| v = ADC*"); Serial.print(_VOLT_RESOLUTION); Serial.print("/"); Serial.print((pow(2, _ADC_Bit_Resolution)) - 1); Serial.print(" | "); Serial.print(_sensor_volt);
Serial.print(" | RS = ((" ); Serial.print(_VOLT_RESOLUTION ); Serial.print("*RL)/Voltage) - RL| "); Serial.print(_RS_Calc); Serial.print(" | Ratio = RS/R0| ");
Serial.print(" | RS = ((" ); Serial.print(_VCC ); Serial.print("*RL)/Voltage) - RL| "); Serial.print(_RS_Calc); Serial.print(" | Ratio = RS/R0| ");
Serial.print(_ratio); Serial.print( " | ");
if(_regressionMethod == 1) Serial.print("ratio*a + b");
else Serial.print("pow(10, (log10(ratio)-b)/a)");
@ -124,62 +164,86 @@ void MQUnifiedsensor::externalADCUpdate(float volt)
}
float MQUnifiedsensor::validateEcuation(float ratioInput)
{
//Serial.print("Ratio input: "); Serial.println(ratioInput);
//Serial.print("a: "); Serial.println(_a);
//Serial.print("b: "); Serial.println(_b);
//Usage of this function: Unit test on ALgorithmTester example;
if(_regressionMethod == 1) _PPM= _a*pow(ratioInput, _b);
else
{
// https://jayconsystems.com/blog/understanding-a-gas-sensor
double ppm_log = (log10(ratioInput)-_b)/_a; //Get ppm value in linear scale according to the the ratio value
_PPM = pow(10, ppm_log); //Convert ppm value to log scale
double ppm;
if(_regressionMethod == 1){
if(ratioInput <= 0 || _a == 0) return 0;
double logppm = log10((double)_a) + (double)_b * log10((double)ratioInput);
if(willOverflow(logppm)) ppm = (logppm > 0) ? FLT_MAX : 0.0;
else ppm = safePow(10.0, logppm);
}
//Serial.println("Regression Method: "); Serial.println(_regressionMethod);
//Serial.println("Result: "); Serial.println(_PPM);
return _PPM;
else
{
if(ratioInput <= 0 || _a == 0) return 0;
double logppm = (log10((double)ratioInput)-(double)_b)/(double)_a;
if(willOverflow(logppm)) ppm = (logppm > 0) ? FLT_MAX : 0.0;
else ppm = safePow(10.0, logppm);
}
if(isinf(ppm) || isnan(ppm)) ppm = FLT_MAX;
_PPM = (float)ppm;
return _PPM;
}
float MQUnifiedsensor::readSensor(bool isMQ303A, float correctionFactor, bool injected)
{
//More explained in: https://jayconsystems.com/blog/understanding-a-gas-sensor
float voltRes = _VOLT_RESOLUTION; // preserve global resolution
if(isMQ303A) {
_VOLT_RESOLUTION = _VOLT_RESOLUTION - 0.45; //Calculations for RS using mq303a sensor look wrong #42
voltRes = voltRes - 0.45; //Calculations for RS using mq303a sensor look wrong #42
}
_RS_Calc = ((_VOLT_RESOLUTION*_RL)/_sensor_volt)-_RL; //Get value of RS in a gas
_RS_Calc = ((_VCC*_RL)/_sensor_volt)-_RL; //Get value of RS in a gas
if(_RS_Calc < 0) _RS_Calc = 0; //No negative values accepted.
if(!injected) _ratio = _RS_Calc / this->_R0; // Get ratio RS_gas/RS_air
_ratio += correctionFactor;
if(_ratio <= 0) _ratio = 0; //No negative values accepted or upper datasheet recommendation.
if(_regressionMethod == 1) _PPM= _a*pow(_ratio, _b); // <- Source excel analysis https://github.com/miguel5612/MQSensorsLib_Docs/tree/master/Internal_design_documents
else
{
// https://jayconsystems.com/blog/understanding-a-gas-sensor <- Source of linear equation
double ppm_log = (log10(_ratio)-_b)/_a; //Get ppm value in linear scale according to the the ratio value
_PPM = pow(10, ppm_log); //Convert ppm value to log scale
double ppm;
if(_regressionMethod == 1){
if(_ratio <= 0 || _a == 0) return 0;
double logppm = log10((double)_a) + (double)_b * log10((double)_ratio);
if(willOverflow(logppm)) ppm = (logppm > 0) ? FLT_MAX : 0.0;
else ppm = safePow(10.0, logppm);
}
if(_PPM < 0) _PPM = 0; //No negative values accepted or upper datasheet recommendation.
else
{
if(_ratio <= 0 || _a == 0) return 0;
double logppm = (log10((double)_ratio)-(double)_b)/(double)_a;
if(willOverflow(logppm)) ppm = (logppm > 0) ? FLT_MAX : 0.0;
else ppm = safePow(10.0, logppm);
}
if(ppm < 0) ppm = 0; //No negative values accepted or upper datasheet recommendation.
if(isinf(ppm) || isnan(ppm)) ppm = FLT_MAX;
_PPM = (float)ppm;
//if(_PPM > 10000) _PPM = 99999999; //No negative values accepted or upper datasheet recommendation.
return _PPM;
}
float MQUnifiedsensor::readSensorR0Rs()
float MQUnifiedsensor::readSensorR0Rs(float correctionFactor)
{
//More explained in: https://jayconsystems.com/blog/understanding-a-gas-sensor
_RS_Calc = ((_VOLT_RESOLUTION*_RL)/_sensor_volt)-_RL; //Get value of RS in a gas
_RS_Calc = ((_VCC*_RL)/_sensor_volt)-_RL; //Get value of RS in a gas
if(_RS_Calc < 0) _RS_Calc = 0; //No negative values accepted.
_ratio = this->_R0/_RS_Calc; // Get ratio RS_air/RS_gas <- INVERTED for MQ-131 issue 28 https://github.com/miguel5612/MQSensorsLib/issues/28
_ratio += correctionFactor;
if(_ratio <= 0) _ratio = 0; //No negative values accepted or upper datasheet recommendation.
if(_regressionMethod == 1) _PPM= _a*pow(_ratio, _b); // <- Source excel analysis https://github.com/miguel5612/MQSensorsLib_Docs/tree/master/Internal_design_documents
else
{
// https://jayconsystems.com/blog/understanding-a-gas-sensor <- Source of linear equation
double ppm_log = (log10(_ratio)-_b)/_a; //Get ppm value in linear scale according to the the ratio value
_PPM = pow(10, ppm_log); //Convert ppm value to log scale
double ppm;
if(_regressionMethod == 1){
if(_ratio <= 0 || _a == 0) return 0;
double logppm = log10((double)_a) + (double)_b * log10((double)_ratio);
if(willOverflow(logppm)) ppm = (logppm > 0) ? FLT_MAX : 0.0;
else ppm = safePow(10.0, logppm);
}
if(_PPM < 0) _PPM = 0; //No negative values accepted or upper datasheet recommendation.
else
{
if(_ratio <= 0 || _a == 0) return 0;
double logppm = (log10((double)_ratio)-(double)_b)/(double)_a;
if(willOverflow(logppm)) ppm = (logppm > 0) ? FLT_MAX : 0.0;
else ppm = safePow(10.0, logppm);
}
if(ppm < 0) ppm = 0; //No negative values accepted or upper datasheet recommendation.
if(isinf(ppm) || isnan(ppm)) ppm = FLT_MAX;
_PPM = (float)ppm;
//if(_PPM > 10000) _PPM = 99999999; //No negative values accepted or upper datasheet recommendation.
return _PPM;
}
float MQUnifiedsensor::calibrate(float ratioInCleanAir) {
float MQUnifiedsensor::calibrate(float ratioInCleanAir, float correctionFactor) {
//More explained in: https://jayconsystems.com/blog/understanding-a-gas-sensor
/*
V = I x R
@ -194,9 +258,10 @@ float MQUnifiedsensor::calibrate(float ratioInCleanAir) {
*/
float RS_air; //Define variable for sensor resistance
float R0; //Define variable for R0
RS_air = ((_VOLT_RESOLUTION*_RL)/_sensor_volt)-_RL; //Calculate RS in fresh air
RS_air = ((_VCC*_RL)/_sensor_volt)-_RL; //Calculate RS in fresh air
if(RS_air < 0) RS_air = 0; //No negative values accepted.
R0 = RS_air/ratioInCleanAir; //Calculate R0
R0 = RS_air/ratioInCleanAir; //Calculate R0
R0 += correctionFactor;
if(R0 < 0) R0 = 0; //No negative values accepted.
return R0;
}
@ -231,7 +296,7 @@ float MQUnifiedsensor:: setRsR0RatioGetPPM(float value)
float MQUnifiedsensor::getRS()
{
//More explained in: https://jayconsystems.com/blog/understanding-a-gas-sensor
_RS_Calc = ((_VOLT_RESOLUTION*_RL)/_sensor_volt)-_RL; //Get value of RS in a gas
_RS_Calc = ((_VCC*_RL)/_sensor_volt)-_RL; //Get value of RS in a gas
if(_RS_Calc < 0) _RS_Calc = 0; //No negative values accepted.
return _RS_Calc;
}

13
src/MQUnifiedsensor.h
View File

@ -3,6 +3,12 @@
#include <Arduino.h>
#include <stdint.h>
#include <float.h>
#include <math.h>
// Maximum coefficients allowed for the regression model
#define MQ_MAX_A 1e30
#define MQ_MAX_B 100.0
/***********************Software Related Macros************************************/
@ -22,14 +28,15 @@ class MQUnifiedsensor
void setB(float b);
void setRegressionMethod(int regressionMethod);
void setVoltResolution(float voltage_resolution = 5);
void setVCC(float vcc = 5);
void setPin(int pin = 1);
void serialDebug(bool onSetup = false); //Show on serial port information about sensor
void setADC(int value); //For external ADC Usage
//user functions
float calibrate(float ratioInCleanAir);
float calibrate(float ratioInCleanAir, float correctionFactor = 0.0);
float readSensor(bool isMQ303A = false, float correctionFactor = 0.0, bool injected=false);
float readSensorR0Rs();
float readSensorR0Rs(float correctionFactor = 0.0);
float validateEcuation(float ratioInput = 0);
//get function for info
@ -38,6 +45,7 @@ class MQUnifiedsensor
float getR0();
float getRL();
float getVoltResolution();
float getVCC();
String getRegressionMethod();
float getVoltage(bool read = true, bool injected = false, int value = 0);
float stringTofloat(String & str);
@ -51,6 +59,7 @@ class MQUnifiedsensor
byte _pin = 1;
byte _firstFlag = false;
float _VOLT_RESOLUTION = 5.0; // if 3.3v use 3.3
float _VCC = 5.0; // Sensor supply voltage
float _RL = 10; //Value in KiloOhms
byte _ADC_Bit_Resolution = 10;
byte _regressionMethod = 1; // 1 -> Exponential || 2 -> Linear