The Calibration Process and Metrological Analysis of a Transducer Used to Measure Two Physical Quantities

1. Cappa P., Marinozzi F., Sciuto S.A. (2001), A Novel method for the simultaneous measurement of temperature and strain using a three-wire connection, Measurement Science and Technology, 12(4), 502-506.10.1088/0957-0233/12/4/315Search in Google Scholar

2. Idzkowski A., Walendziuk W., Warsza Z.L. (2015), Unconventional double-current crcuit for deflection and temperature simultaneous measurement, Elektronika ir Elektrotechnika, 21(1), 23–27.10.5755/j01.eee.21.1.6834Search in Google Scholar

3. INTERSIL (2005), Sensor circuits and digitally controlled potentiometers, application note AN135.Search in Google Scholar

4. JCGM - Joint Committee of Guides in Metrology (2008), Evaluation of measurement data – guide to the expression of uncertainty in measurement.Search in Google Scholar

5. Kalita K., Das N., Boruah P.K., Sarma U. (2016), Design and uncertainty evaluation of a strain measurement system, MAPAN – Journal of Metrology Society of India, 31(1), 17-24.10.1007/s12647-015-0155-zSearch in Google Scholar

6. MAXIM Integrated Products Inc. (2002), Sensor temperature compensation using the four DAC signal conditioning architecture, application note 1839.Search in Google Scholar

7. Mozek M., Vrtacnik, D., Resnik D., Aljancic U., Penic S., Amon S. (2008), Digital self-learning calibration system for smart sensors, Sensors & Actuators: A. Physical 141(1), 101-108.Search in Google Scholar

8. Musiol K., Met A., Skubis T. (2010), Automatic bridge for comparison of inductance standards, Measurement, 43(10), 1661-1667.10.1016/j.measurement.2010.09.019Search in Google Scholar

9. Nudzikova, P., Slanina, Z. (2016), User identification by biometric methods, Intelligent Systems for Computer Modelling - Advances in Intelligent Systems and Computing, 423, 181-190.10.1007/978-3-319-27644-1_17Search in Google Scholar

10. Parker A.R. (1993), Simultaneous measurement of temperature and strain using four connecting wires, NASA Technical Memorandum 104271.Search in Google Scholar

11. Pedersen C., Jespersen S.T., Krog J.P., Christensen C., Thomsen E.V. (2005), Combined differential and static pressure sensor based on a double-bridged structure, IEEE Sensors Journal 5 (3), 446-454.10.1109/JSEN.2005.845199Search in Google Scholar

12. Proto A., Penhaker M., Bibbo D., Vala D., Conforto S., Schmid M. (2016), Measurements of generated energy/electrical quantities from locomotion activities using piezoelectric wearable sensors for body motion energy harvesting, Sensors, 16(4), 524.10.3390/s16040524485103827077867Search in Google Scholar

13. Surya S., Nag S., Fernandes A.J., Gandhi S., Agarwal D., Chatterjee G., Ramgopal Rao V. (2011), Highly sensitive ΔR/R measurement system for nano-electro-mechanical cantilever based biosensors, International Symposium on Electronic System Design (ISED), 34-38.10.1109/ISED.2011.36Search in Google Scholar

14. Swartz C., Derrington C., Gragg J. (2004), Temperature compensation methods for the Motorola X-ducer pressure sensor element, Motorola Semiconductor application notes AN840.Search in Google Scholar

15. TENMEX (2016), strain gauges producer webpage, http://www.tenmex.pl.Search in Google Scholar

16. VISHAY Precision Group (2007), Measurement of thermal expansion coefficient using strain gages, technical note TN-513-1, http://www.vishaypg.com/docs/11063/tn5131tn.pdf.Search in Google Scholar