Title :
High Precision Multicolorimetric Pyrometer With a Novel Photoelectric MOSFET
Author :
Sheng Chang ; Qijun Huang ; Hao Wang ; Mincai He ; Feng Dai
Author_Institution :
Dept. of Electron. Sci. & Technol., Wuhan Univ., Wuhan, China
Abstract :
Colorimetric thermometry is a useful method for high temperature measurement. In this paper, a high precision multicolorimetric pyrometer is introduced. A multicolorimetric calculation without the gray body assumption is deduced. A novel photoelectric MOSFET with direct ac signal output is employed as the sensor, which works near the visible waveband and brings smaller uncertainty under the Wien approximation than the infrared radiation detectors. A dual-processor embedded signal process circuit is constructed, which ensures the pyrometer´s portability as well as supports the accuracy of colorimetric calculation. Through the tests, the precision of the pyrometer is better than 30/00 in the temperature range 1323-1923 K.
Keywords :
MOSFET; approximation theory; colorimetry; high-temperature techniques; measurement uncertainty; photodetectors; pyrometers; signal processing equipment; temperature measurement; temperature sensors; Wien approximation; colorimetric thermometry; direct ac signal; dual processor embedded signal process circuit; high temperature measurement uncertainty; multicolorimetric calculation accuracy; multicolorimetric pyrometer; photoelectric MOSFET; pyrometer portability; temperature 1323 K to 1923 K; temperature sensor; visible waveband; Digital signal processing; Logic gates; MOSFET; Steel; Temperature distribution; Temperature measurement; Temperature sensors; Colorimetric thermometry; embedded system; metallurgy; photoelectric MOSFET; pyrometer;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
DOI :
10.1109/TIM.2013.2281558
