Computer simulation of logarithmic transformation function to expand the range of high-precision measurements

The object of research is the process of temperature measurement with a platinum thermistor. We have conducted studies on the cubic transformation function of the thermistor when using redundancy that yielded the equation of redundant measurements of the desired temperature. Owing to this, it became possible to directly apply the resulting equation without additional measures to linearize the function of the thermistor transformation. In addition, the obtained value of the desired temperature does not depend on the values of the parameters of the cubic transformation function and their deviations from the nominal values. Experimental studies have proven that the value of the normalized temperature T0 has a greater influence on the result of redundant measurements and the value of the normalized temperature DT on the entire range of measured temperatures Tx is almost unaffected. The best accuracy results (value of relative error δ=0.02 %) were obtained at T0 values lower than –60 °C. When the error of reproduction of normalized temperatures increased from ±0.02 °C to ±0.1 °C, the best accuracy results (value of relative error δ=0.06 %) were obtained at values of normalized temperature T0 below –130 °C. Analysis of results of the absolute error DT revealed that with an error of reproduction of normalized temperatures of ±0.02 °C and at T0=–180 °C, its value does not exceed 0.02 °C, that is, it is within the error of reproduction of normalized temperatures. This allows us to state that it is recommended to use sources of standardized temperatures of high accuracy during measurement control. Thus, there are reasons to assert the prospect for redundant measurements when directly measuring temperature with a thermistor with a cubic transformation function with high accuracy

Section: Discussion Of Results Of Computer Modeling With a Cubic Tran...mentioning

confidence: 62%

Section: Literature Review and Problem Statementmentioning

confidence: 99%

Determining features in the application of redundancy for the thermistor cubic transformation function using computer simulation

Shcherban’,

Korohod,

Kolysko

et al. 2024

“…Processing of measurement results in accordance with the proposed equations provides automatic exclusion of the additive and multiplicative components of the error, i.e. error correction, which does not contradict the data presented in [19][20][21][22][23][24][25]. In addition, due to the application of the proposed redundant measurement equations ( 11) and ( 14), it is possible to directly use a nonlinear TF without special measures for its linearization, which are typical for studies published in [12][13][14].…”

Section: Discussion Of the Results Of Computer Modeling Of The Quadra...mentioning

confidence: 79%

“…However, the issue of the influence of the values of normalized quantities and their relationship with the desired quantity on the final measurement result for a nonlinear transformation function remains unresolved. Therefore, further research on redundant measurement methods presented in [25] established a relationship between the normalized and desired quantities, which significantly expands the range of high-precision measurements. The results obtained demonstrated the high efficiency of redundant measurement methods in improving measurement accuracy by adjusting the values of normalized quantities for the logarithmic transformation function.…”

Section: Due To This It Can Be Argued On the Use Of Non-precision Nor...mentioning

confidence: 99%

Computer modeling in the study of the effect of normalized quantities on the measurement accuracy of the quadratic transformation function

Shcherban

Korogod

Kolysko

et al. 2022

The research of the systems of equations of quantities describing, respectively, 5 and 6 measurement cycles revealed the peculiarities of redundancy formation. It is proved that the normalized temperature T1 has the greatest effect on the measurement result for both systems. In addition, it was found that in both systems, an increase in the reproduction accuracy of the normalized temperature T1 (with a constant reproduction error of T2) does not lead to a significant improvement in the results. Due to this, it can be argued on the use of non-precision normalized sources to reproduce the temperature T1. However, an order of magnitude increase in the reproduction accuracy of both normalized quantities T1 and T2 also increases the measurement accuracy by an order of magnitude. Computer modeling confirmed that for the redundant measurement equation (11) at the ratio Т1=Ті(0.0005•Ті+1) in the range (10÷200) °С, measurement with a relative error (0.01÷0.00003) % is provided. When applying the redundant measurement equation (13), the accuracy increases to 0.0059 % only at the end of the range. Based on the results obtained, it was found that the accuracy of redundant measurements is influenced by the type of equation itself, not their number. Processing of the results based on the redundant measurement equation, by the way, ensures the independence of the measurement result from the influence of absolute values of the transformation function parameters, as well as their deviations from nominal values under the influence of external destabilizing factors. Thus, there is reason to believe that it is possible to increase the accuracy of measurement in a wide range by observing the ratio between normalized and controlled quantities

“…It is shown that this allows increasing the accuracy of measurements by eliminating the systematic component of the error due to changes in the parameters of the transformation function, as well as reducing the random component of the error. Redundant measurements with a nonlinear transformation function were further developed in [19]. It is shown that due to the regularity between the normalized and sought quantities, the range of high-precision measurements is significantly expanded.…”

Section: To This When Applying the Second Approach It Becomes Possibl...mentioning

confidence: 99%

Computer analysis of multiple measurements with the sensor's quadratic transformation function

SHCHERBAN

Korogod

Chuprynka

et al. 2023

The object of research is multiple measurements. The research aims to improve the accuracy of multiple measurements with a non-linear and unstable sensor transformation function. It is proved that the redundant measurement equation ensures the independence of the measurement result from the parameters of the transformation function and their deviations from the nominal values. It was found that the result of redundant measurements is affected by the reproduction errors of normalized temperatures T1 and T2. It is shown that the best accuracy results are obtained with a reproduction error of normalized temperature T2 within ±1.0 % and temperature T1 within ±0.1 %. This makes it possible to reduce the accuracy requirements for the source of reproduction of normalized temperature Т2. The possibility of processing the results of multiple measurements by two approaches is presented. Computer modeling using the first approach found that with a reproduction error of normalized temperature T2 within ±0.5 %, the relative measurement error is 0.003 %. When modeling the second approach, the relative error is 0.05 %. It was also found that with an increase in the reproduction error of normalized temperature T2 to ±1.0 %, the value of the relative error is 0.04 %. Due to this, when applying the second approach, it becomes possible to choose a non-high-precision source of reproduction of normalized temperature T2. In addition, the sensitivity of the second approach to the digit range of measuring devices was found, which leads to the dependence of the measurement result on their accuracy. There are reasons to assert the possibility of increasing the accuracy of multiple measurements by processing the results of intermediate measurements according to redundant measurement equations using two approaches