diff --git a/klippy/extras/adc_temperature.py b/klippy/extras/adc_temperature.py
index 40c270ef4..d456a653d 100644
--- a/klippy/extras/adc_temperature.py
+++ b/klippy/extras/adc_temperature.py
@@ -262,7 +262,7 @@ AD8497 = [
]
def calc_pt100(base=100.):
- # Calc PT100/PT1000 temperature/resistance pairs using formula
+ # Calc PT100/PT1000 resistances using Callendar-Van Dusen formula
A, B = (3.9083e-3, -5.775e-7)
return [(float(t), base * (1. + A*t + B*t*t)) for t in range(0, 500, 10)]
diff --git a/klippy/extras/spi_temperature.py b/klippy/extras/spi_temperature.py
index c7ae77a8f..defc0037d 100644
--- a/klippy/extras/spi_temperature.py
+++ b/klippy/extras/spi_temperature.py
@@ -267,15 +267,18 @@ MAX31865_FAULT_REFINHIGH = 0x10
MAX31865_FAULT_RTDINLOW = 0x08
MAX31865_FAULT_OVUV = 0x04
-VAL_A = 0.00390830
-VAL_B = -0.0000005775
-VAL_C = -0.00000000000418301
-VAL_ADC_MAX = 32768.0 # 2^15
+MAX31865_ADC_MAX = 1<<15
+
+# Callendar-Van Dusen constants for platinum resistance thermometers (RTD)
+CVD_A = 3.9083e-3
+CVD_B = -5.775e-7
class MAX31865(SensorBase):
def __init__(self, config):
- self.rtd_nominal_r = config.getint('rtd_nominal_r', 100)
- self.reference_r = config.getfloat('rtd_reference_r', 430., above=0.)
+ rtd_nominal_r = config.getfloat('rtd_nominal_r', 100., above=0.)
+ rtd_reference_r = config.getfloat('rtd_reference_r', 430., above=0.)
+ adc_to_resist = rtd_reference_r / float(MAX31865_ADC_MAX)
+ self.adc_to_resist_div_nominal = adc_to_resist / rtd_nominal_r
SensorBase.__init__(self, config, "MAX31865",
self.build_spi_init(config))
def calc_temp(self, adc, fault):
@@ -295,20 +298,20 @@ class MAX31865(SensorBase):
if fault & 0x03:
self.fault("Max31865 Unspecified error")
adc = adc >> 1 # remove fault bit
- R_rtd = (self.reference_r * adc) / VAL_ADC_MAX
- temp = ((( ( -1 * self.rtd_nominal_r ) * VAL_A )
- + math.sqrt( ( self.rtd_nominal_r**2 * VAL_A * VAL_A )
- - ( 4 * self.rtd_nominal_r * VAL_B
- * ( self.rtd_nominal_r - R_rtd ) )))
- / (2 * self.rtd_nominal_r * VAL_B))
+ R_div_nominal = adc * self.adc_to_resist_div_nominal
+ # Resistance (relative to rtd_nominal_r) is calculated using:
+ # R_div_nominal = 1. + CVD_A * temp + CVD_B * temp**2
+ # Solve for temp using quadratic equation:
+ # temp = (-b +- sqrt(b**2 - 4ac)) / 2a
+ discriminant = math.sqrt(CVD_A**2 - 4. * CVD_B * (1. - R_div_nominal))
+ temp = (-CVD_A + discriminant) / (2. * CVD_B)
return temp
def calc_adc(self, temp):
- R_rtd = temp * ( 2 * self.rtd_nominal_r * VAL_B )
- R_rtd = math.pow( ( R_rtd + ( self.rtd_nominal_r * VAL_A ) ), 2)
- R_rtd = -1 * ( R_rtd - (self.rtd_nominal_r**2 * VAL_A * VAL_A ) )
- R_rtd = R_rtd / ( 4 * self.rtd_nominal_r * VAL_B )
- R_rtd = ( -1 * R_rtd ) + self.rtd_nominal_r
- adc = int( ( ( R_rtd * VAL_ADC_MAX ) / self.reference_r) + 0.5 )
+ # Calculate relative resistance via Callendar-Van Dusen formula:
+ # resistance = rtd_nominal_r * (1 + CVD_A * temp + CVD_B * temp**2)
+ R_div_nominal = 1. + CVD_A * temp + CVD_B * temp * temp
+ adc = int(R_div_nominal / self.adc_to_resist_div_nominal + 0.5)
+ adc = max(0, min(MAX31865_ADC_MAX, adc))
adc = adc << 1 # Add fault bit
return adc
def build_spi_init(self, config):