Measurement Uncertainty Sources Analysis and Verification of Time-Grating with Variable Coupling Coefficient

Hong Tao Yang; Bin Fan; Jiao Zhou; Ye Tai Fei; Dong Lin Peng

doi:10.4028/www.scientific.net/AMM.742.65

Paper Titles

Refractive-Index Sensor Based on Metal-Insulator-Metal Waveguides
p.46

The Study on After-Treatment System and Algorithm of Piezoelectric Micromachined Modal Gyroscope
p.50

A PCR Chip with Reusable Electrodes and its Temperature Analysis
p.54

Evaluation of Measurement Uncertainty for Ball Pressure Test Based on Reading Microscope
p.61

Measurement Uncertainty Sources Analysis and Verification of Time-Grating with Variable Coupling Coefficient
p.65

Quality Evaluation Apparatus and Method for Laser Shock Processing the Weld Used in FDSO
p.71

Research on Mass Determination of International Comparison CCM.M-K4 of 1 kg Mass Weights
p.75

Study on Time of Flight Measurement for Ultrasonic Tomography
p.80

The MCCB Electrical Clearance and Creepage Distance Measurement Uncertainty Evaluation
p.86

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 742Measurement Uncertainty Sources Analysis and...

Measurement Uncertainty Sources Analysis and Verification of Time-Grating with Variable Coupling Coefficient

Abstract:

In order to improve the precision of Time-grating with Variable Coupling Coefficient, the electrical traveling wave equation was derived in detail base on the further study of working principle of Time-grating sensor. Combined with the processing and assembling methods of sensor, the uncertainty sources of sensor standing wave, synthesis traveling wave signal and the produce reasons of higher harmonic were analyzed by using uncertainty theory. The produce reasons of higher harmonic were verified with spectral analysis of the original sensor error data, and then the primary and secondary uncertainty sources affected the sensor measurement uncertainty sources were got, which were time and spatial orthogonal error, amplitude error of two roads signal and stator and rotor air gap uneven. The conclusion made in this paper can be used to conduct the structure optimal design, sensor error correction and uncertainty evaluation.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volume 742)

Pages:

65-70

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.742.65

Citation:

Cite this paper

Online since:

March 2015

Authors:

Hong Tao Yang*, Bin Fan, Jiao Zhou, Ye Tai Fei, Dong Lin Peng

Keywords:

Higher Harmonic, Spectral Analysis, Time-Grating with Variable Coupling Coefficient, Traveling Wave Equation, Uncertainty Sources

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Yang Wei. Design of time-grating sensor based on variable coupling coefficient transformer[J]. Chinese Journal of Scientific Instrument 2006, 27(11): 1403-1405.

Google Scholar

[2] Wu Liang. Research on Time-grating based on Variable Coupling Coefficient[M]. Chongqing University of technology.

Google Scholar

[3] PENG Dong-lin. High-precision Time-grating Displacement Sensor Based on Harmonic Wave Correcting Method[J]. Chinese Journal of Scientific Instrument2006, 27(1): 31-33.

Google Scholar

[4] PENG Dong-lin. New Method of Postprocessing in Time-grating with Variable Coupling Coefficient[J]. Instrument Technique and sensor 2012. 11: 31-33.

Google Scholar

[5] FEI Y T. Error Theory and Data Processing[M]. Beijing: China Machine Press，(2005).

Google Scholar

[6] WU Liang. Design of Time Grating Sensor Based on Standing Wave Modulation[J]. Instrument Technique and sensor2011. 4: 4-6.

Google Scholar

[7] PENG Dong-lin. Study on the Theory of Time-grating Coordinate Transformation and the Time Grating Displacement Sensor[J]. Chinese Journal of Scientific Instrument.

Google Scholar