A Displacement Measuring Interferometer Based on a Frequency-Locked Laser Diode with High Modulation Frequency

Vu, Thanh Tung; Hoang, Hong Hai; Vu, Toan Thang; Bui, Lam Thu

doi:10.3390/app10082693

Cited by 4 publications

(1 citation statement)

References 25 publications

(29 reference statements)

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“…Traditional SMI techniques have primarily focused on detecting amplitude modulation (AM) signals, limiting their sensitivity and dynamic range. Advancements have explored the use of frequency modulation (FM) signals, which offer higher signalto-noise ratios but present challenges in detection [26][27][28][29][30]. The key advantages of this emerging trend in laser interferometry include an extremely high sensitivity to scattered light, the ability to estimate displacement direction and obtain information from small object surface areas, simple interferometer design, and low implementation cost [31,32].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Vibration Measurement through Frequency Modulated Laser Diode Self-Mixing Interferometry

Liao,

Chen,

Hsiao

2024

Preprint

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Self-mixing interference (SMI) has emerged as a powerful non-contact vibration sensing technique, leveraging the inherent coupling between laser emission and external optical feedback. However, conventional SMI systems often face limitations in signal resolution and measurement accuracy, particularly when probing low-amplitude vibrations or low-reflectivity targets. This study proposes a novel frequency modulation (FM) approach, FM-SMI, to enhance the capabilities of SMI setups. By intentionally modulating the laser frequency of 20 kHz, the FM-SMI technique induces a segmentation of the interference signal, effectively increasing the temporal resolution and facilitating the detection of finer vibration details. Comprehensive experiments involving oscillating speakers and rotating silicon wafers validate the superior performance of the FM-SMI system. Notably, the frequency-modulated signals exhibit stability and robustness, even under low-amplitude vibration conditions or when targeting low-reflectivity surfaces. The enhanced signal quality, coupled with numerical processing techniques, enables precise extraction of vibration characteristics, including amplitude variations and surface topographies. The proposed FM-SMI approach demonstrates its potential as a versatile tool for high-precision, non-contact vibration measurements across diverse applications, such as, non-destructive testing and the characterization of vibration induced by the rotational systems.

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