#include #include // Forward TC function float NISTdegCtoMilliVoltsKtype(float tempDegC); // returns EMF in millivolts // Inverse TC function float NISTmilliVoltsToDegCKtype(float tcEMFmV); // returns temp in degC assuming 0 degC cold jcn float adc_to_voltage(float v_ref, int n_adc); float kelvin_to_c(float k); float resistance_to_temperature(float r); float voltage_to_resistance(float v); float voltage_to_erc(float v); int main() { float v_ref = 5, e_rc, e_comp; float thermistor_temp, thermocouple_temp; int thermistor_val, thermocouple_val; // User input for pins A0 and A1 printf("Enter values for thermistor pin, thermocouple pin: "); scanf("%d %d", &thermistor_val, &thermocouple_val); // Calculate thermistor temperature in degrees C ( Part b, i,ii,iii & v) thermistor_temp = kelvin_to_c(resistance_to_temperature(voltage_to_resistance(adc_to_voltage(v_ref, thermistor_val)))); // Calculate thermocouple temperature in degrees C ( Part c, i - iv) e_rc = 1000*voltage_to_erc(adc_to_voltage(v_ref, thermocouple_val)); // convert to millivolts e_comp = NISTdegCtoMilliVoltsKtype(thermistor_temp); thermocouple_temp = NISTmilliVoltsToDegCKtype(e_rc + e_comp); // Output results printf("Thermistor temperature (deg C): %f \n", thermistor_temp); printf("Thermocouple temperature with CJC (deg C): %f \n", thermocouple_temp); return 0; } /* Write a function here to convert ADC value to voltages. (Part a, equation 1) Call it from the main() function above */ float adc_to_voltage(float v_ref, int n_adc) { return (float)n_adc*v_ref/1024.0; } /* Write a function to convert degrees K to degrees C (Part b, (iv)) Call it from the main() function above */ float kelvin_to_c(float k) { return k-273.15; } float resistance_to_temperature(float r) { // Define Thermistor constants float t_0 = 298.15; float r_0 = 10000; float b = 3975; return 1 / ( (1/t_0) + (1/b)*log(r/r_0)); } float voltage_to_resistance(float v) { return 1000*((10.0*3.3/v)-10.0); } float voltage_to_erc(float v) { return (v-0.35)/54.4; } /* returns EMF in millivolts */ float NISTdegCtoMilliVoltsKtype(float tempDegC) { int i; float milliVolts = 0; if(tempDegC >= -170 && tempDegC < 0) { const float coeffs[11] = { 0.000000000000E+00, 0.394501280250E-01, 0.236223735980E-04, -0.328589067840E-06, -0.499048287770E-08, -0.675090591730E-10, -0.574103274280E-12, -0.310888728940E-14, -0.104516093650E-16, -0.198892668780E-19, -0.163226974860E-22 }; for (i=0; i<=10; i++) { milliVolts += coeffs[i] * pow(tempDegC,i); } } else if(tempDegC >= 0 && tempDegC <= 1372) { const float coeffs[10] = { -0.176004136860E-01, 0.389212049750E-01, 0.185587700320E-04, -0.994575928740E-07, 0.318409457190E-09, -0.560728448890E-12, 0.560750590590E-15, -0.320207200030E-18, 0.971511471520E-22, -0.121047212750E-25 }; const float a0 = 0.118597600000E+00; const float a1 = -0.118343200000E-03; const float a2 = 0.126968600000E+03; for (i=0; i<=9; i++) { milliVolts += coeffs[i] * pow(tempDegC,i); } milliVolts += a0*exp(a1*(tempDegC - a2)*(tempDegC - a2)); } else { milliVolts = 99E99; } return milliVolts; } // returns temperature in deg C. float NISTmilliVoltsToDegCKtype(float tcEMFmV) { int i, j; float tempDegC = 0; const float coeffs[11][3] = { {0.0000000E+00, 0.000000E+00, -1.318058E+02}, {2.5173462E+01, 2.508355E+01, 4.830222E+01}, {-1.1662878E+00, 7.860106E-02, -1.646031E+00}, {-1.0833638E+00, -2.503131E-01, 5.464731E-02}, {-8.9773540E-01, 8.315270E-02, -9.650715E-04}, {-3.7342377E-01, -1.228034E-02, 8.802193E-06}, {-8.6632643E-02, 9.804036E-04, -3.110810E-08}, {-1.0450598E-02, -4.413030E-05, 0.000000E+00}, {-5.1920577E-04, 1.057734E-06, 0.000000E+00}, {0.0000000E+00, -1.052755E-08, 0.000000E+00} }; if(tcEMFmV >=-5.891 && tcEMFmV <=0 ) { j=0; } else if (tcEMFmV > 0 && tcEMFmV <=20.644 ) { j=1; } else if (tcEMFmV > 20.644 && tcEMFmV <=54.886 ) { j=2; } else { return 99E9; } for (i=0; i<=9; i++) { tempDegC += coeffs[i][j] * pow(tcEMFmV,i); } return tempDegC; }