Abstract

In this paper, a series of calibration-free temperature measurement methods based on light-induced thermoelastic spectroscopy (LITES) are proposed for the first time. These techniques utilize the steady-state and transient response characteristics of the quartz tuning fork (QTF), namely, the calibration-free LITES (CF-LITES) and calibration-free heterodyne LITES (CF-H-LITES) methods. Four methods, first harmonic (1 f ) difference signal to normalize the second harmonic (2 f ) fundamental signal (method I, 2 f fund /1 f diff ), 1 f overtone signal to normalize the 2 f fundamental signal (method II, 2 f fund /1 f over ), 1 f heterodyne difference signal to normalize the 2 f heterodyne fundamental signal (method III, 2 f - H fund /1 f-H diff ), and 1 f heterodyne overtone signal to normalize the 2 f heterodyne fundamental signal (method IV, 2 f-H fund /1 f-H over ), for simultaneously detecting 1 f and 2 f within the frequency response range of the QTF are proposed to achieve calibration-free measurement. A self-designed T-shaped QTF with low fundamental and overtone frequencies was used to increase the energy accumulation time, thereby enhancing the sensor signal level. A 3-stage tube furnace was adopted to verify the performance of these 4 methods. Experimental results showed that the errors for the 4 methods were less than 4%, with a standard deviation below 11 °C. Furthermore, the calibration-free method, which employs normalization of the 2 f signal with the 1 f signal, effectively mitigates the impact of laser beam jitter and power fluctuations on detection performance. A superior performance can be obtained by adopting the CF-H-LITES technique based on method IV. It not only has excellent detection performance but also reduces the measurement period to 4 s, which is about 5 times faster. This development shows substantial promise for expanding the application of the CF-LITES and CF-H-LITES techniques in harsh environments.