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Creation de la bibliothèque de mesure de temperature

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This commit is contained in:
anschrammh 2019-12-18 00:44:01 +01:00
parent 964c921738
commit 84b3bd56c8
7 changed files with 269 additions and 0 deletions
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19
lib/MeasureUnit/AdcSetting.cpp Normal file
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#include "AdcSetting.h"
AdcSetting::AdcSetting(double vref,
uint8_t adcResolution,
uint8_t measureIteration,
uint16_t delayBetweenIteration) : _vref(vref), _adcResolution(adcResolution), _measureIteration(measureIteration), _delayBetweenIteration(delayBetweenIteration), _quantum(vref/(pow(2.0,(double) adcResolution)-1))
{
}
uint8_t AdcSetting::getMeasureIteration()
{
return _measureIteration;
}
double AdcSetting::getQuantum()
{
return _quantum;
}

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lib/MeasureUnit/AdcSetting.h Normal file
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#ifndef ADCSETTING_H
#define ADCSETTING_H
#include <Arduino.h>
#include <math.h>
class AdcSetting
{
public:
AdcSetting(double vref, uint8_t adcResolution, uint8_t measureIteration = 5, uint16_t delayBetweenIteration = 5);
~AdcSetting(){}
uint8_t getMeasureIteration();
uint16_t getDelayBetweenIteration(){ return _delayBetweenIteration;}
double getQuantum();
double getVref(){return _vref;}
protected:
private:
double _vref;
uint8_t _adcResolution;
double _quantum;
uint8_t _measureIteration;
uint16_t _delayBetweenIteration;
};
#endif //ADCSETTING_H

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lib/MeasureUnit/MeasureUnit.cpp Normal file
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#include "MeasureUnit.h"
MeasureUnit::MeasureUnit(uint8_t *analogInput,
uint16_t thermistorCount,
uint64_t precResistor,
ThermistorSetting thermistorSetting,
AdcSetting adcSetting) : _analogInput(analogInput), _thermistorCount(thermistorCount), _precResistor(precResistor), _thermistorSetting(thermistorSetting), _adcSetting(adcSetting), _globalOffset(0), _error(OK)
{
//Allocation dynamique des différent tableaux
_temperatures = (double*) calloc(_thermistorCount, sizeof(double));
_rOffsetMap = (double*) calloc(_thermistorCount, sizeof(double));
_resistanceMap = (double*) calloc(_thermistorCount, sizeof(double));
if(_temperatures == NULL || _rOffsetMap == NULL || _resistanceMap == NULL)
{
_error = MALLOC_ERR;
_temperatures != NULL ? free(_temperatures):(void)_temperatures;
_rOffsetMap != NULL ? free(_rOffsetMap):(void)_rOffsetMap;
_resistanceMap != NULL ? free(_resistanceMap):(void)_resistanceMap;
_temperatures = NULL;
_rOffsetMap = NULL;
_resistanceMap = NULL;
}
}
MeasureUnit::~MeasureUnit()
{
if(_error != MALLOC_ERR)
{
free(_temperatures);
free(_rOffsetMap);
free(_resistanceMap);
}
}
/**
* Methode permettant d'effectuer les mesures de température et de les récupérer
*/
double *MeasureUnit::getTemperatures()
{
double courant(0), deltaTension(0);
//1) Nous calculons le courant présent dans la branche grace à la résistance de précision
#ifdef DEBUG
Serial.println("-------------");
#endif
for(int i(0); i < _adcSetting.getMeasureIteration(); i++)
{
delay(_adcSetting.getDelayBetweenIteration());
int sample = analogRead(_analogInput[0]);
deltaTension += sample;
#ifdef DEBUG
Serial.print("Adc value : ");Serial.println(sample);
#endif
}
#ifdef DEBUG
Serial.println("-------------");
#endif
deltaTension /= _adcSetting.getMeasureIteration();
#ifdef DEBUG
Serial.print("Adc value average : ");Serial.println(deltaTension);
#endif
deltaTension *= _adcSetting.getQuantum();
#ifdef DEBUG
char buffer[10] = "";
sprintf(buffer,"%.8f", deltaTension);
Serial.print("R prec voltage : ");Serial.println(buffer);
#endif
courant = deltaTension / (double) _precResistor;
#ifdef DEBUG
sprintf(buffer,"%.8f", courant);
Serial.print("R prec current : ");Serial.println(buffer);
#endif
//2) Nous calculons le delta de tensions pour chaque thermistances
for(int i(1); i < _thermistorCount; i++)
{
for(int j(0); j < _adcSetting.getMeasureIteration(); j++)
{
delay(_adcSetting.getDelayBetweenIteration());
int sample = analogRead(_analogInput[i]);
_resistanceMap[i-1] += sample;
}
_resistanceMap[i-1] /= _adcSetting.getMeasureIteration();
if(i == 1)
_resistanceMap[i-1] -= deltaTension;
else
_resistanceMap[i-1] -= _resistanceMap[i-2];
}
//Pour la dernière valeur:
_resistanceMap[7] = _adcSetting.getVref() - _resistanceMap[6];
for(int i(0); i < _thermistorCount; i++)
{
//3) Nous en déduisons la résistance
_resistanceMap[i] /= courant;
//4) Nous en déduisons la temperature
_temperatures[i] = (((25.0+273.15) * (double)_thermistorSetting.getBeta()) / ((double)_thermistorSetting.getBeta() + (25.0+273.15)*log(_resistanceMap[i]/(double) _thermistorSetting.getRat25()))) - 273.15;
}
return _temperatures;
}
void MeasureUnit::setGlobalTempOffset(double offset)
{
_globalOffset = offset;
}
double MeasureUnit::getGlobalTempOffset()
{
return _globalOffset;
}

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lib/MeasureUnit/MeasureUnit.h Normal file
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#ifndef MEASUREUNIT_H
#define MEASUREUNIT_H
#include "AdcSetting.h"
#include "ThermistorSetting.h"
#define DEBUG
class MeasureUnit
{
public:
enum ERROR {OK = 0, MALLOC_ERR = 1};
MeasureUnit(uint8_t *analogInput, uint16_t thermistorCount, uint64_t precResistor, ThermistorSetting thermistorSetting, AdcSetting adcSetting);
~MeasureUnit();
void setGlobalTempOffset(double offset);
double getGlobalTempOffset();
double *getTemperatures();
ERROR getError(){return _error;}
protected:
private:
double _globalOffset; //Correspond à l'offset global nécessaire afin d'avoir une température qui corresponde à la réalité
double *_temperatures; //Tableau contenant toutes les températures
double *_rOffsetMap; //Tableau qui contient les offsets individuels pour chaque thermistance
double *_resistanceMap; //Tableau qui contient les resistances associées aux thermistances (pour debug seulement)
uint8_t *_analogInput; //Pointeur qui garde l'adresse du tableau contenant le nom des entrées analogiques
uint16_t _thermistorCount;
uint64_t _precResistor;
ERROR _error;
AdcSetting _adcSetting;
ThermistorSetting _thermistorSetting;
};
#endif //MEASUREUNIT_H

30
lib/MeasureUnit/MeasureUnit.ino Normal file
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/**
* Cet exemple correspond à l'application de test de la bibliothèque MeasureUnit qui
* permet de calculer la température mesurée par une matrice de thermistance
*
* Anatole SCHRAMM-HENRY
* 17/12/2019
*/
#include "MeasureUnit.h"
uint8_t analogInput[] = {PA0,PA1,PA2,PA3,PA4,PA5,PA6,PA7};
ThermistorSetting thermistorSetting(4050, 47000);
AdcSetting adcSetting(3.3, 12, 30, 20);
MeasureUnit measureUnit(analogInput, 8, 1000, thermistorSetting, adcSetting);
void setup() {
// put your setup code here, to run once:
Serial.begin(115200);
Serial.println("Start setup");
Serial.println("End setup");
}
void loop() {
// put your main code here, to run repeatedly:
measureUnit.getTemperatures();
delay(5000);
}

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lib/MeasureUnit/ThermistorSetting.cpp Normal file
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#include "ThermistorSetting.h"
ThermistorSetting::ThermistorSetting(uint16_t beta, uint64_t rAt25) : _beta(beta), _rAt25(rAt25)
{
}
ThermistorSetting::~ThermistorSetting()
{
}
uint16_t ThermistorSetting::getBeta()
{
return _beta;
}
uint64_t ThermistorSetting::getRat25()
{
return _rAt25;
}

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lib/MeasureUnit/ThermistorSetting.h Normal file
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#ifndef THERMISTORSETTING_H
#define THERMISTORSETTING_H
#include <Arduino.h> //Necessaire afin d'avoir les types : uintxx_t
class ThermistorSetting
{
public:
ThermistorSetting(uint16_t beta, uint64_t rAt25);
~ThermistorSetting();
uint16_t getBeta();
uint64_t getRat25();
protected:
private:
uint16_t _beta;
uint64_t _rAt25;
};
#endif //THERMISTORSETTING_H