Thermistor: Difference between revisions

Latest revision as of 13:04, 9 April 2024

A common temperature sensor is a Thermistor, which is a device with a temperature-dependent resistance $R(T)$ and a negative temperature coefficient (NTC), i.e., the Resistance decreases with temperature, or ${\partial R(T) \over \partial T}<0$ . Therefore, thermistors are sometime referenced as NTC sensors.

Their resistances can be described by a Steinhardt-Hart equation, which relates resistance R and absolute temperature T:

${\frac {1}{T}}=a+b\ln R+c(\ln R)^{3}$

Usually, the coefficients $a,b,c$ are not specified in a data sheet of a device. More commonly, three things are quoted/specified:

Reference temperature, typically 25 Celsius; sometimes this is not even mentioned explicitly
Resistance R₀ at the reference temperature (typically 25 Celsius). Often, R₀=10kΩ.
Characteristic of the exponential, the constant B=1/b in the above expression. Typically around 4000 Kelvin.

These parameters can be used with a simplified Steinhart-Hart equation, which assumes c=0 in the expression above. Then, the equation becomes

${\frac {1}{T}}=A+B\ln R$

or

$R=R_{0}e^{B({1 \over T}-{1 \over T_{0}})}$ .

The absoute temperature then can be obtained by inverting the equation above:

$T=\left({1 \over T_{0}}+{1 \over B}\ln {R \over R_{0}}\right)^{-1}$

@@ Line 1: / Line 1: @@
-A common temperature sensor is a Thermistor, which is a device with negative temperature coefficient (NTC), i.e., the Resistance decreases with temperature, or <math>{\partial R \over \partial T} < 0 </math>. Therefore, thermistors are sometime referenced as NTC sensors.
+A common temperature sensor is a Thermistor, which is a device with a temperature-dependent resistance <math>R(T)</math> and a negative temperature coefficient (NTC), i.e., the Resistance decreases with temperature, or <math>{\partial R(T) \over \partial T} < 0 </math>. Therefore, thermistors are sometime referenced as NTC sensors.
-Their resistances can be well described by a Steinhardt-Hart equation, which relates resistance R and absolute temperature T:
+Their resistances can be described by a Steinhardt-Hart equation, which relates resistance R and absolute temperature T:
-<math> {\frac {1}{T}}=A+B\ln R+C(\ln R)^{3}</math>
+<math> {\frac {1}{T}}=a + b \ln R + c (\ln R)^{3} </math>
-Usually, the coefficients A,B,C are not specified in a data sheet of a device, but three things are quoted:
+Usually, the coefficients <math>a,b,c</math> are not specified in a data sheet of a device. More commonly, three things are quoted/specified:
-* Reference temperature, typically 25 Celsius; sometimes this is not even specified
+* Reference temperature, typically 25 Celsius; sometimes this is not even mentioned explicitly
-* Resistance R_0 at the reference temperature (typically 25 Celsius). Often, R_0=10k&Omega;
+* Resistance R<sub>0</sub> at the reference temperature (typically 25 Celsius). Often, R<sub>0</sub>=10k&Omega;.
-* Characteristic of the exponential, the constant B in the above expression. Typically around 4000 Kelvin.
+* Characteristic of the exponential, the constant B=1/b in the above expression. Typically around 4000 Kelvin.
-These parameters can be used with a simplified Steinhart-Hart equation, which assumes C=0 in the expression above. Then, the equation becomes
+These parameters can be used with a simplified Steinhart-Hart equation, which assumes c=0 in the expression above. Then, the equation becomes
 <math> {\frac {1}{T}}=A+B\ln R</math>
@@ Line 17: / Line 17: @@
 <math>R=R_0 e^{B({1\over T}-{1\over T_0})}</math>.
+The absoute temperature then can be obtained by inverting the equation above:
+<math>T = \left( {1\over T_0} + {1\over B} \ln {R\over R_0} \right) ^{-1}</math>

Thermistor: Difference between revisions

Latest revision as of 13:04, 9 April 2024

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