#!/usr/bin/python # # Creates a C code lookup table for doing ADC to temperature conversion # on a microcontroller # based on: http://hydraraptor.blogspot.com/2007/10/measuring-temperature-easy-way.html """Thermistor Value Lookup Table Generator Generates lookup to temperature values for use in a microcontroller in C format based on: http://hydraraptor.blogspot.com/2007/10/measuring-temperature-easy-way.html The main use is for Arduino programs that read data from the circuit board described here: http://make.rrrf.org/ts-1.0 Usage: python createTemperatureLookup.py [options] Options: -h, --help show this help --rp=... pull-up resistor --t0=ttt:rrr low temperature temperature:resistance point (around 25C) --t1=ttt:rrr middle temperature temperature:resistance point (around 150C) --t2=ttt:rrr high temperature temperature:resistance point (around 250C) --num-temps=... the number of temperature points to calculate (default: 20) """ from math import * import sys import getopt class Thermistor: "Class to do the thermistor maths" def __init__(self, rp, t1, r1, t2, r2, t3, r3): t1 = t1 + 273.15 # low temperature (25C) r1 = r1 # resistance at low temperature t2 = t2 + 273.15 # middle temperature (150C) r2 = r2 # resistance at middle temperature t3 = t3 + 273.15 # high temperature (250C) r3 = r3 # resistance at high temperature self.rp = rp # pull-up resistance self.vadc = 5.0 # ADC reference self.vcc = 5.0 # supply voltage to potential divider a1 = log(r1) a2 = log(r2) a3 = log(r3) z = a1 - a2 y = a1 - a3 x = 1/t1 - 1/t2 w = 1/t1 - 1/t3 v = pow(a1,3) - pow(a2,3) u = pow(a1,3) - pow(a3,3) c3 = (x-z*w/y)/(v-z*u/y) c2 = (x-c3*v)/z c1 = 1/t1-c3*pow(a1,3)-c2*a1 self.c1 = c1 self.c2 = c2 self.c3 = c3 def res(self,adc): "Convert ADC reading into a resolution" res = self.temp(adc)-self.temp(adc+1) return res def v(self,adc): "Convert ADC reading into a Voltage" v = adc * self.vadc / (1024 ) # convert the 10 bit ADC value to a voltage return v def r(self,adc): "Convert ADC reading into a resistance in Ohms" v = adc * self.vadc / (1024 ) # convert the 10 bit ADC value to a voltage r = self.rp * v / (self.vcc - v) # resistance of thermistor return r def temp(self,adc): "Convert ADC reading into a temperature in Celcius" v = adc * self.vadc / (1024 ) # convert the 10 bit ADC value to a voltage r = self.rp * v / (self.vcc - v) # resistance of thermistor lnr = log(r) Tinv = self.c1 + (self.c2*lnr) + (self.c3*pow(lnr,3)) return (1/Tinv) - 273.15 # temperature def adc(self,temp): "Convert temperature into a ADC reading" y = (self.c1 - (1/(temp+273.15))) / (2*self.c3) x = sqrt(pow(self.c2 / (3*self.c3),3) + pow(y,2)) r = exp(pow(x-y,1.0/3) - pow(x+y,1.0/3)) # resistance of thermistor return (r / (self.rp + r)) * (1024) def main(argv): rp = 4700; t1 = 25; r1 = 100000; t2 = 150; r2 = 1641.9; t3 = 250; r3 = 226.15; num_temps = int(36); try: opts, args = getopt.getopt(argv, "h", ["help", "rp=", "t1=", "t2=", "t3=", "num-temps="]) except getopt.GetoptError: usage() sys.exit(2) for opt, arg in opts: if opt in ("-h", "--help"): usage() sys.exit() elif opt == "--rp": rp = int(arg) elif opt == "--t1": arg = arg.split(':') t1 = float( arg[0]) r1 = float( arg[1]) elif opt == "--t2": arg = arg.split(':') t2 = float( arg[0]) r2 = float( arg[1]) elif opt == "--t3": arg = arg.split(':') t3 = float( arg[0]) r3 = float( arg[1]) elif opt == "--num-temps": num_temps = int(arg) max_adc = (1024 ) - 1 min_temp = 0 max_temp = 350 increment = int(max_adc/(num_temps-1)); t = Thermistor(rp, t1, r1, t2, r2, t3, r3) tmp = (min_temp - max_temp) / (num_temps-1) print tmp temps = range(max_temp, min_temp + tmp, tmp); print "// Thermistor lookup table for Marlin" print "// ./createTemperatureLookup.py --rp=%s --t1=%s:%s --t2=%s:%s --t3=%s:%s --num-temps=%s" % (rp, t1, r1, t2, r2, t3, r3, num_temps) print "// Steinhart-Hart Coefficients: %.15g, %.15g, %.15g " % (t.c1, t.c2, t.c3) print "//#define NUMTEMPS %s" % (len(temps)) print "const short temptable[NUMTEMPS][2] PROGMEM = {" counter = 0 for temp in temps: counter = counter +1 if counter == len(temps): print " {(short)(%.2f*OVERSAMPLENR), %s} // v=%s r=%s res=%s C/count" % ((t.adc(temp)), temp, t.v(t.adc(temp)), t.r(t.adc(temp)),t.res(t.adc(temp))) else: print " {(short)(%.2f*OVERSAMPLENR), %s}, // v=%s r=%s res=%s C/count" % ((t.adc(temp)), temp, t.v(t.adc(temp)), t.r(t.adc(temp)),t.res(t.adc(temp))) print "};" def usage(): print __doc__ if __name__ == "__main__": main(sys.argv[1:])