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doc: add issues summary

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Miguel Angel Califa Urquiza 2025-06-04 17:45:49 -05:00
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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.

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docs/issues.md Normal file
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@ -0,0 +1,31 @@
# 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:** abierto
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`.
### #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:** abierto
Los usuarios solicitan factores de corrección para temperatura y humedad aplicables a otros sensores (MQ-4 y MQ-8) además del MQ-135. Aún no se han añadido estos parámetros. Se anima a la comunidad a contribuir con implementaciones y ejemplos.
### #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).

2
library.properties
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@ -1,5 +1,5 @@
name=MQUnifiedsensor
version=3.0.0
version=3.0.1
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.

22
src/MQUnifiedsensor.cpp
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@ -10,6 +10,7 @@ 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) {
@ -41,6 +42,10 @@ 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 +64,10 @@ float MQUnifiedsensor::getVoltResolution()
{
return _VOLT_RESOLUTION;
}
float MQUnifiedsensor::getVCC()
{
return _VCC;
}
String MQUnifiedsensor::getRegressionMethod()
{
if(_regressionMethod == 1) return "Exponential";
@ -85,7 +94,8 @@ 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 +116,7 @@ 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)");
@ -145,7 +155,7 @@ float MQUnifiedsensor::readSensor(bool isMQ303A, float correctionFactor, bool in
if(isMQ303A) {
_VOLT_RESOLUTION = _VOLT_RESOLUTION - 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;
@ -164,7 +174,7 @@ float MQUnifiedsensor::readSensor(bool isMQ303A, float correctionFactor, bool in
float MQUnifiedsensor::readSensorR0Rs()
{
//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
if(_ratio <= 0) _ratio = 0; //No negative values accepted or upper datasheet recomendation.
@ -194,7 +204,7 @@ 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
if(R0 < 0) R0 = 0; //No negative values accepted.
@ -231,7 +241,7 @@ 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;
}

3
src/MQUnifiedsensor.h
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@ -22,6 +22,7 @@ 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
@ -38,6 +39,7 @@ 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 +53,7 @@ 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