LSTM-assisted optical fiber interferometric sensing: breaking the limitation of free spectral range.
Junling Hu, Sa Zhang, Meiyu Cai, Mingjian Ma, Shuguang Li, Hailiang Chen, Sigang Yang
Abstract
Open AccessOptical fiber interferometric sensors are of great importance in chemistry, biology, and medicine disciplines owing to high-sensitivity and high-quality factor. However, due to the limitation of free spectral range, the inherent trade-off between wide measurement range and high sensitivity poses a persistent challenge in interference sensor development, which has fundamentally hindered their widespread adoption in precision measurement applications. In this work, a long short-term memory neural network is utilized in a Mach-Zehnder interference-based refractive index sensor to break the free spectral range limitation. Unique gating mechanism in long short-term memory neural network enables it to efficiently process long-term dependent sequence information, such as interference spectrum, avoiding the need for complex spectral signal analysis. A one-to-one mapping relationship is established between the interference spectrum and refractive index with root mean square error of 3.029 × 10-4 and a coefficient of determination of 0.99971. The measurement range is extended from a single free spectral range of 1.3333-1.3561 to approximately three free spectral ranges of 1.3333-1.3921 without sacrificing sensitivity. Moreover, a wider measurement range can be achieved with sufficient training data. This work successfully resolves the inherent contradiction between high sensitivity and wide dynamic measurement range in optical interference-based sensors, opening up a path for the next generation of intelligent sensing systems.