NTC calibration and multiple temperature sensors: Difference between revisions

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== GY-91 ==
== GY-91 ==
== Semiconductor Physics ==
Fermi-Dirac distribution
<math>
f(\epsilon) = \frac1{e^{\beta(\epsilon-\mu)}+1}
</math>

Revision as of 18:47, 20 September 2023

Introduction

Calibration of NTC sensors and different

NTC

Note that the temperature of the sensor rises when the current supplies through the resistor. The NTC is nonlinear; see below Calibration.

Negative Temperature Coefficient, NTCLE100E3101JB0 or similar (MF52B NTC Thermistor). The NTC is connected in series with a "shunt" resistor , see Measurement of resistors: voltage divider. Usually is used. The total resistance of the circuit is , which gives

or

depending on the circuit. So check the circuit.




Calibrating: Steinhart-Hart Equation

A nonlinear Steinhart-Hart equation is widely used

The parameters , and can be obtained, if the resistance of three (3) temperatures is known.

Calibrating using known datapoints

Though the NTC sensor is nonlinear, locally it will be linear. Thus by using some known datapoints the temperature can be estimated.

Some known datapoints:

  • boiling water 100 deg
  • room temperature
  • freezing point of water

= LM35DZ

GY-91

Semiconductor Physics

Fermi-Dirac distribution