CAPACITIVE ELECTRODE BASED MOISTURE MEASUREMENT CONVERTER ERRORS AND HOW TO ELIMINATE THEM

Jabborov  Hamdam  Shaymardonovich; Rashidov   Timurbek Erkin ugli

The article discusses the errors associated with the moisture measuring transducer
that is based on the cylindrical electrode, along with their sources and calculation formulas for error
elimination. The initial capacitance of the capacitive electrode humidity converter is dependent on its
geometric parameters, such as the radii of the electrodes and their length. Accurate calculation of
these geometric parameters enables the reduction of regular measurement errors in the input and
switching circuit of the moisture converter to a minimum value, resulting in a significant increase in
the informativeness and accuracy of the output signal. Consequently, some sources of measurement
errors are eliminated or minimized during the design of the capacitive electrode moisture converter.
To further reduce errors in the measurement chain and minimize the influence of internal and external
destabilizing factors, there is a need to develop effective correction elements and schemes.
Additionally, the article presents a method for calculating the total measurement error of the
transducer by measuring the moisture content of scattered products with a capacitive electrode.

Журнал номиTechnical science and innovation
Нашр номи2023,№4son(19)
Кўришлар сони 59

Internet ҳавола

DOI

UzSCI тизимида яратилган сана 24-01-2024

Ўқишлар сони 59

Нашр санаси 19-01-2024

Мақола тилиIngliz

Саҳифалар сони70-75

Калит сўзлар

error

sources of error

entropic error

error calculation method

capacitive transducer

cylindrical electrode transducer

English

The article discusses the errors associated with the moisture measuring transducer
that is based on the cylindrical electrode, along with their sources and calculation formulas for error
elimination. The initial capacitance of the capacitive electrode humidity converter is dependent on its
geometric parameters, such as the radii of the electrodes and their length. Accurate calculation of
these geometric parameters enables the reduction of regular measurement errors in the input and
switching circuit of the moisture converter to a minimum value, resulting in a significant increase in
the informativeness and accuracy of the output signal. Consequently, some sources of measurement
errors are eliminated or minimized during the design of the capacitive electrode moisture converter.
To further reduce errors in the measurement chain and minimize the influence of internal and external
destabilizing factors, there is a need to develop effective correction elements and schemes.
Additionally, the article presents a method for calculating the total measurement error of the
transducer by measuring the moisture content of scattered products with a capacitive electrode.

Калит сўзлар

error

sources of error

entropic error

error calculation method

capacitive transducer

cylindrical electrode transducer

№ Муаллифнинг исми Лавозими Ташкилот номи

1 Jabborov H.S. PhD Tashkent State Technical University

2 Rashidov T.E. Student Tashkent State Technical University

№ Ҳавола номи

1 1. Arbuzov V. P. The use of time division of the channels in capacitive and inductive sensor measuring circuits. // Meas. Tech. 2007 (50), pp.752–757.

2 2. Garchev A.B., Churakov P.P. Converter of parameters of non-contact capacitive sensors for conductivity measurements // News of the Samara Scientific Center of the Russian Academy of Sciences, 2016. Т.18. № 4(47). –С. 1363-1366.

3 3. Djejora A.A. Electric capacitive converters and methods for their calculation. // Minsk «Bilaruskaya nauka». 2008.– 351 s

4 4. Ismatullayev P.R., Qodirov Sh.A, Jabborov X.Sh. O‘lchash vositalarining xatoliklari va ularning statistik xarakteristikalarini o‘rganish // “O‘z Standart” agentligi “Standart” jurnali 2011 yil № 2 17-22 б.

5 5. Ismatullayev P.R., Nosirov T.Z., Jabborov X.Sh. Calculation of the capacity of the cone converter for the moisture meter of grain and grain products. // Magazine " Devices " International Scientific and Technical Society of Instrument Makers and Metrologists. - Russia. 2019. №4. С. 11-16.

6 6. Qodirov Sh.A, Jabborov X.Sh.. Kichik kvadratlar usulida oʼlchash natijalarini qayta ishlash. // “ToshDTU xabarlari”. – Toshkent. 2018. №4. 22-28 б.

7 7. Raxmanov А.T. Аnaliz pogreshnosti zondovыx mnogofunktsionalь¬nыx preobrazovateley parametrov dispersnыx sred. // Uzbekskiy fizicheskiy jurnal. - 2009. - №2. - С.153-156.

8 8. Stolbovskiy A.B. Raschet pogreshnostey rezulьtatov izmereniy v tablichnыx protsessorax. - Yekaterinburg: Ural. un-ta, 2017. - 86 s.

9 9. B. Javidi. Three-dimensional image fusion by use of multiwavelength digital holography. «Optics letters», 2005. 144–146

10 10. A. Stadelmaier, J. H. Massig. Compensation of lens aberrations in digital holography. «Optics Letters», 2000. 1630–1632.

11 11. T. Colomb. Automatic procedure for aberration compensation in digital holographic microscopy and applications to specimen shape compensation. «Applied Optics»,2006. 851–863.

12 12. L. H. Ma. Numerical reconstruction of digital holograms for three-dimensional shape measurement. «Journal of Optics A», 2004. 396–400.

13 13. J. Müller Characterization of spatial particle distributions in a spray-forming process using digital holography. «Measurement Science and Technology», 2004. 706–710.

14 14. G. Situ, J. Zhang. Multiple-image encryption by wavelength multiplexing

15 15. «Optics Letters», 2005. 1306-1308.

Кутилмоқда

№	Муаллифнинг исми	Лавозими	Ташкилот номи
1	Jabborov H.S.	PhD	Tashkent State Technical University
2	Rashidov T.E.	Student	Tashkent State Technical University

№	Ҳавола номи
1	1. Arbuzov V. P. The use of time division of the channels in capacitive and inductive sensor measuring circuits. // Meas. Tech. 2007 (50), pp.752–757.
2	2. Garchev A.B., Churakov P.P. Converter of parameters of non-contact capacitive sensors for conductivity measurements // News of the Samara Scientific Center of the Russian Academy of Sciences, 2016. Т.18. № 4(47). –С. 1363-1366.
3	3. Djejora A.A. Electric capacitive converters and methods for their calculation. // Minsk «Bilaruskaya nauka». 2008.– 351 s
4	4. Ismatullayev P.R., Qodirov Sh.A, Jabborov X.Sh. O‘lchash vositalarining xatoliklari va ularning statistik xarakteristikalarini o‘rganish // “O‘z Standart” agentligi “Standart” jurnali 2011 yil № 2 17-22 б.
5	5. Ismatullayev P.R., Nosirov T.Z., Jabborov X.Sh. Calculation of the capacity of the cone converter for the moisture meter of grain and grain products. // Magazine " Devices " International Scientific and Technical Society of Instrument Makers and Metrologists. - Russia. 2019. №4. С. 11-16.
6	6. Qodirov Sh.A, Jabborov X.Sh.. Kichik kvadratlar usulida oʼlchash natijalarini qayta ishlash. // “ToshDTU xabarlari”. – Toshkent. 2018. №4. 22-28 б.
7	7. Raxmanov А.T. Аnaliz pogreshnosti zondovыx mnogofunktsionalь¬nыx preobrazovateley parametrov dispersnыx sred. // Uzbekskiy fizicheskiy jurnal. - 2009. - №2. - С.153-156.
8	8. Stolbovskiy A.B. Raschet pogreshnostey rezulьtatov izmereniy v tablichnыx protsessorax. - Yekaterinburg: Ural. un-ta, 2017. - 86 s.
9	9. B. Javidi. Three-dimensional image fusion by use of multiwavelength digital holography. «Optics letters», 2005. 144–146
10	10. A. Stadelmaier, J. H. Massig. Compensation of lens aberrations in digital holography. «Optics Letters», 2000. 1630–1632.
11	11. T. Colomb. Automatic procedure for aberration compensation in digital holographic microscopy and applications to specimen shape compensation. «Applied Optics»,2006. 851–863.
12	12. L. H. Ma. Numerical reconstruction of digital holograms for three-dimensional shape measurement. «Journal of Optics A», 2004. 396–400.
13	13. J. Müller Characterization of spatial particle distributions in a spray-forming process using digital holography. «Measurement Science and Technology», 2004. 706–710.
14	14. G. Situ, J. Zhang. Multiple-image encryption by wavelength multiplexing
15	15. «Optics Letters», 2005. 1306-1308.