Improvement of the Reliability of Information Received from Sensor Devices with Metrological Self-Check

Yulia Backsheeva; Kseniia Sapozhnikova; Roald Taymanov

doi:10.4028/www.scientific.net/KEM.613.307

Paper Titles

Accumulative Drifting Model of Inertial Navigation Platform under Elliptic Vibration
p.269

Artificial Intelligent Systems for Quality Assurance in Small Series Production
p.279

Efficient Commissioning Processes for the Automotive Final Assembly
p.288

Graphical Hardware Description as a High-Level Design Entry Method for FPGA-Based Data Acquisition Systems
p.296

Improvement of the Reliability of Information Received from Sensor Devices with Metrological Self-Check
p.307

Uncertainty Evaluation for Surgical Processes
p.317

Characterization and Correction of Geometric Errors Induced by Thermal Drift in CT Measurements
p.327

X-Ray Computed Tomography Applied as a Comprehensive Technique for Material Analysis and Dimensional Measurement of Metallic Parts
p.335

Theory and Practice of Uncertainty Evaluation of Coordinate Measurements
p.344

HomeKey Engineering MaterialsKey Engineering Materials Vol. 613Improvement of the Reliability of Information...

Improvement of the Reliability of Information Received from Sensor Devices with Metrological Self-Check

Abstract:

Sensor devices with metrological self-check represent one of the most advanced directions in the present-day development of measurement technique. Generally, in the process of sensor device operation, results of the metrological self-check enable changes of metrological characteristics to be revealed, automatic correction of an error to be performed, grounds for multiple increase of a calibration interval to be obtained. In the present paper an additional procedure of metrological assurance is substantiated which provides the increase in the reliability of metrological self-check results.

You might also be interested in these eBooks

Measurement Technology and Intelligent Instruments XI

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 613)

Pages:

307-313

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.613.307

Citation:

Cite this paper

Online since:

May 2014

Authors:

Yulia Backsheeva, Kseniia Sapozhnikova*, Roald Taymanov

Keywords:

Calibration Interval, Measurement, Metrological Self-Check, Sensor Device

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] R. Taymanov, K. Sapozhnikova, Problems of terminology in the field of measuring instruments with elements of artificial intelligence, Sensors & Transducers journal 102 3 (2009) 51-61.

Google Scholar

[2] R. Taymanov, K. Sapozhnikova, Chapter 1. What makes sensor devices and microsystems intelligent" or "smart", in: S. Nihtianov, A.L. Estepa (Еds. ), Smart Sensors and MEMS for Industrial Applications, Woodhead Publishing Limited, 2013 (in press).

DOI: 10.1016/b978-0-08-102055-5.00001-2

Google Scholar

[3] GOST R 8. 673 - 2009, State System for Ensuring the Uniformity of Measurements. Intelligent Sensors and Intelligent Measuring Systems. Basic Terms and Definitions, Standartinform, Moscow, (2010).

Google Scholar

[4] GOST R 8. 734 - 2011, State System for Ensuring the Uniformity of Measurements. Intelligent Sensors and Intelligent Measuring Systems. Methods of Metrological Self-checking, Standartinform, Moscow, (2012).

Google Scholar

[5] V. Gurevich, K. Sapozhnikova and R. Taymanov, Metrological self-check of a transit-time ultrasonic flowmeter, in: Proceedings of the 10th International Symposium on Measurement Technology and Intelligent Instruments (ISMTII-2011), Daejeon, Korea, 29 June- 2 July, 2011, D5-4, 6 p., (2011).

Google Scholar

[6] R. Taymanov, K. Sapozhnikova, I. Druzhinin, Sensor devices with metrological self-check, Sensors & Transducers journal 10 2 (special issue) (2011) 30-44.

Google Scholar

[7] Yu. Baksheeva, K. Sapozhnikova, R. Taymanov, Platinum resistance thermometer with metrological self-check, in: Proceedings of the SENSOR+TEST Conferences, 07-09 June 2011, Nurnberg, Germany, 2011, pp.708-713.

DOI: 10.5162/sensor11/sp2.6

Google Scholar

[8] G.V. Samsonov, A.I. Kitz, O.A. Kuzenia, V.I. Lakh et al., Sensors for Measuring Temperature in Industry, Naukova Dumka, Kyev, (1972).

Google Scholar

[9] R.J. Berry, Oxidation, stability and insulation characteristics of Rosemount standard platinum resistance thermometers, in: Temperature, Its Measurement and Control in Science and Industry, AIP, New York, 5 1982, pp.753-761.

Google Scholar

[10] X. Li, M. Zhao, and D. Chen, A Study on the stability of standard platinum resistance thermometer in the temperature range from 0 °C through 720 °C, information on http: /www. hartscientific. com.

Google Scholar