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Fixed mq-3 example

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miguel5612 2020-03-26 10:23:51 -05:00
parent a03ceab3dc
commit aa11343a97
3 changed files with 34 additions and 14 deletions
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25
examples/MQ-3/MQ-3.ino
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@ -35,7 +35,7 @@ void setup() {
Output: Output:
Remarks: This function create the sensor object. Remarks: This function create the sensor object.
************************************************************************************/ ************************************************************************************/
MQ3.inicializar(); MQ3.init();
//pinMode(calibration_button, INPUT); //pinMode(calibration_button, INPUT);
} }
@ -62,12 +62,23 @@ void loop() {
//Lecture will be saved in lecture variable //Lecture will be saved in lecture variable
//float lecture = MQ3.readSensor("", true); // Return Alcohol concentration //float lecture = MQ3.readSensor("", true); // Return Alcohol concentration
// Options, uncomment where you need // Options, uncomment where you need
CH4 = MQ3.readSensor("CH4"); // Return CH4 concentration MQ3.setA(2*10^31); MQ3.setB(19.01); // Configurate the ecuation values
LPG = MQ3.readSensor("LPG"); // Return LPG concentration CH4 = MQ3.readSensor("Exponential"); // Return CH4 concentration
CO = MQ3.readSensor("CO"); // Return CO concentration
Alcohol = MQ3.readSensor("Alcohol"); // Return Alcohol concentration MQ3.setA(44771); MQ3.setB(-3.245); // Configurate the ecuation values
Hexane = MQ3.readSensor("Hexane"); // Return Hexane concentration LPG = MQ3.readSensor("Exponential"); // Return LPG concentration
Benzine = MQ3.readSensor("Benzene"); // Return Benzene concentration
MQ3.setA(521853); MQ3.setB(-3.821); // Configurate the ecuation values
CO = MQ3.readSensor("Exponential"); // Return CO concentration
MQ3.setA(0.3934); MQ3.setB(-1.504); // Configurate the ecuation values
Alcohol = MQ3.readSensor("Exponential"); // Return Alcohol concentration
MQ3.setA(7585.3); MQ3.setB(-2.849); // Configurate the ecuation values
Hexane = MQ3.readSensor("Exponential"); // Return Hexane concentration
MQ3.setA(4.8387); MQ3.setB(-2.68); // Configurate the ecuation values
Benzine = MQ3.readSensor("Exponential"); // Return Benzene concentration
Serial.println("***************************"); Serial.println("***************************");
Serial.println("Lectures for MQ-3"); Serial.println("Lectures for MQ-3");

15
src/MQUnifiedsensor.cpp
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@ -6,7 +6,13 @@ MQUnifiedsensor::MQUnifiedsensor(String Placa, int Voltage_Resolution, int pin,
this->_placa = Placa; this->_placa = Placa;
this-> _VOLT_RESOLUTION = Voltage_Resolution; this-> _VOLT_RESOLUTION = Voltage_Resolution;
} }
MQUnifiedsensor::serialDebug(boolean onSetup) MQUnifiedsensor::setA(double a) {
this->_a = a;
}
MQUnifiedsensor::setB(double b) {
this->_b = b;
}
MQUnifiedsensor::serialDebug(boolean onSetup, String regressionMethod)
{ {
if(onSetup) if(onSetup)
{ {
@ -40,6 +46,7 @@ MQUnifiedsensor::serialDebug(boolean onSetup)
else else
{ {
String eq = ""; String eq = "";
if(regression == "Linear") eq = "ratio*a + b"
if(regression == "Exponential") eq = "a*ratio^b" if(regression == "Exponential") eq = "a*ratio^b"
Serial.println("|" + _adc + "|" + "v = ADC*" + _VOLT_RESOLUTION + "/1024" + "|" + _sensor_volt + "|" + "RS = ((" + _VOLT_RESOLUTION + "*RL)/Voltage) - RL" + "|" + _RS_Calc + "|" + "Ratio = RS/R0" + "|" + _ratio + "|" + eq + "|" + _PPM); Serial.println("|" + _adc + "|" + "v = ADC*" + _VOLT_RESOLUTION + "/1024" + "|" + _sensor_volt + "|" + "RS = ((" + _VOLT_RESOLUTION + "*RL)/Voltage) - RL" + "|" + _RS_Calc + "|" + "Ratio = RS/R0" + "|" + _ratio + "|" + eq + "|" + _PPM);
} }
@ -57,15 +64,15 @@ void MQUnifiedsensor::init()
{ {
pinMode(_pin, INPUT); pinMode(_pin, INPUT);
} }
float MQUnifiedsensor::readSensor(String nameLectureRequeired) float MQUnifiedsensor::readSensor(String regressionMethod)
{ {
setSensorCharacteristics(nameLectureRequeired, print); //In this function update _a and _b
//More explained in: https://jayconsystems.com/blog/understanding-a-gas-sensor //More explained in: https://jayconsystems.com/blog/understanding-a-gas-sensor
_RS_Calc = ((_VOLT_RESOLUTION*_RLValue)/_sensor_volt)-_RLValue; //Get value of RS in a gas _RS_Calc = ((_VOLT_RESOLUTION*_RLValue)/_sensor_volt)-_RLValue; //Get value of RS in a gas
if(_RS_Calc < 0) _RS_Calc = 0; //No negative values accepted. if(_RS_Calc < 0) _RS_Calc = 0; //No negative values accepted.
_ratio = _RS_Calc / this->_R0; // Get ratio RS_gas/RS_air _ratio = _RS_Calc / this->_R0; // Get ratio RS_gas/RS_air
if(_ratio <= 0 || _ratio>100) _ratio = 0.01; //No negative values accepted or upper datasheet recomendation. if(_ratio <= 0 || _ratio>100) _ratio = 0.01; //No negative values accepted or upper datasheet recomendation.
_PPM= _a*pow(_ratio, _b); if(regressionMethod == "Exponential") _PPM= _a*pow(_ratio, _b);
if(regressionMethod == "Linear") _PPM= _a*_ratio + _b);
if(_PPM < 0) _PPM = 0; //No negative values accepted or upper datasheet recomendation. if(_PPM < 0) _PPM = 0; //No negative values accepted or upper datasheet recomendation.
if(_PPM > 10000) _PPM = 9999; //No negative values accepted or upper datasheet recomendation. if(_PPM > 10000) _PPM = 9999; //No negative values accepted or upper datasheet recomendation.
return _PPM; return _PPM;

8
src/MQUnifiedsensor.h
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@ -20,12 +20,14 @@ class MQUnifiedsensor
void update(); void update();
void setR0(double R0 = 10); void setR0(double R0 = 10);
void setRL(double RL = 10); void setRL(double RL = 10);
void setA(double a);
void setB(double b);
void setVoltResolution(double voltage_resolution = 5); void setVoltResolution(double voltage_resolution = 5);
void serialDebug(boolean onSetup = false); //Show on serial port information about sensor void serialDebug(boolean onSetup = false); //Show on serial port information about sensor
//user functions //user functions
float calibrate(boolean print = false); float calibrate(boolean print = false, String regressionMethod = "Exponential");
float readSensor(<String regressionMethod = "Exponential", float _a, float _b); float readSensor(String regressionMethod = "Exponential", float _a, float _b);
//get function for info //get function for info
double getR0(); double getR0();
@ -43,7 +45,7 @@ class MQUnifiedsensor
byte _VOLT_RESOLUTION = 5.0; // if 3.3v use 3.3 byte _VOLT_RESOLUTION = 5.0; // if 3.3v use 3.3
byte _ratioInCleanAir, _sensor_volt; byte _ratioInCleanAir, _sensor_volt;
byte _RLValue = 10; //Value in KiloOhms byte _RLValue = 10; //Value in KiloOhms
double _adc; double _adc, _a, _b;
float _R0, RS_air, _ratio, _PPM, _RS_Calc; float _R0, RS_air, _ratio, _PPM, _RS_Calc;
}; };