/* ____ __________________________________ ____ / __ \/ ____/_ __/ ____/ ____/_ __/ __ \/ __ \ / / / / __/ / / / __/ / / / / / / / / /_/ / / /_/ / /___ / / / /___/ /___ / / / /_/ / _, _/ /___________/ __________/\____/ _____\__________| / __ )/ / / / _/ / / __ \/ _/ | / / ____/ / __ / / / // // / / / / // // |/ / / __ / /_/ / /_/ // // /___/ /_/ // // /| / /_/ / /_____/\____/___/_____/_____/___/_/ |_/\____/ Ladue Horton Watkins High School Science Olympiad Licensed under the Parity Public License */ #include using ld = long double; const int LED_R = 8, LED_G = 10, LED_B = 12, THERM = 0; // Device component pins const ld R_k = 10000, V_in = 5, analog_max = 1023; // Device constants // Analog to digital conversion ld a2d(int a) { return V_in * a / analog_max; } int d2a(ld d) { return d * analog_max / V_in; } // Voltage to resistance conversion ld v2r(ld V_out) { return R_k * (V_in / V_out - 1); } ld vol[100]; int con[100]; const int order = 2; int coeff[order + 1]; void setup() { Serial.begin(9600); Serial.println("Starting calibration") Serial.println("Place sensor in water and enter the concentration into the console") Serial.println("When you are finished, type c to continue") int n = 0; while (1) { String s = Serial.readString(); if (s == "c") break; vol[n] = a2d(analogRead(THERM)); con[n] = toInt(s); Serial.println(n); Serial.println(vol[n]); Serial.println(con[n]); ++n; } fitCurve(order, n, vol, con, coeff); } void loop() { v = a2d(analogRead(THERM)); c = 0; for (int i = order; i >= 0; --i) c = v*c + coeff[i]; Serial.println(c); }