SNAS264D April 2006 – February 2024 LM94
PRODUCTION DATA
The voltage seen by the LM94 also includes the IFRS voltage drop of the series resistance. The non-ideality factor, η, is the only other parameter not accounted for and depends on the diode that is used for measurement. Since ΔVBE is proportional to both η and T, the variations in η cannot be distinguished from variations in temperature. Since the non-ideality factor is not controlled by the temperature sensor, it will directly add to the inaccuracy of the sensor. For the Pentium D processor on 65nm process, Intel specifies a +4.06%/−0.89% variation in η from part to part when the processor diode is measured by a circuit that assumes diode equation, Equation 14, as true. As an example, assume a temperature sensor has an accuracy specification of ±2.5°C at a temperature of 75 °C (348 Kelvin) and the processor diode has a non-ideality variation of +4.06%/−0.89%. The resulting system accuracy of the processor temperature being sensed will be:
and
TruTherm technology uses the transistor equation, Equation 15, resulting in a non-ideality spread that truly reflects the process variation which is very small. The transistor equation non-ideality spread is ±0.4% for the Pentium D processor on 65nm process. The resulting accuracy when using TruTherm technology improves to:
The next error term to be discussed is that due to the series resistance of the thermal diode and printed circuit board traces. The thermal diode series resistance is specified on most processor data sheets. For the Pentium D processor on 65 nm process, this is specified at 4.52Ω typical. The LM94 accommodates the typical series resistance of the Pentium D processor on 90 nm process. The error that is not accounted for is the spread of the Pentium's series resistance, that is 2.79Ω to 6.24Ω or ±1.73Ω. The equation to calculate the temperature error due to series resistance (TER) for the LM94 is simply:
Solving Equation 19 for RPCB equal to ±1.73Ω results in the additional error due to the spread in the series resistance of ±1.07°C. The spread in error cannot be canceled out, as it would require measuring each individual thermal diode device. This is quite difficult and impractical in a large volume production environment.
Equation 19 can also be used to calculate the additional error caused by series resistance on the printed circuit board. Since the variation of the PCB series resistance is minimal, the bulk of the error term is always positive and can simply be cancelled out by subtracting it from the output readings of the LM94.