Abstract
Fiber Bragg gratings (FBGs) are widely applied in optical sensing systems due to their advantages including being simple to use, high sensitivity, and having great potential for integration into optical communication systems. A common method used for FBG sensing systems is wavelength interrogation. The performance of interrogation based sensing systems is significantly determined by the accuracy of the wavelength peak detection processing. Direct maximum value readout (DMVR) is the simplest peak detection method. However, the detection accuracy of DMVR is sensitive to noise and the sampling resolution. Many modified peak detection methods, such as filtering and curve fitting schemes, have been studied in recent decades. Though these methods are less sensitive to noise and have better sensing accuracy at lower sampling resolutions, they also confer increased processing complexity. As massive sensors may be deployed for applications such as the Internet of things (IoT) and artificial intelligence (AI), lower levels of processing complexity are required. In this paper, an efficient scheme applying a three-point peak detection estimator is proposed and studied, which shows a performance that is close to the curve fitting methods along with reduced complexity. A proof-of-concept experiment for temperature sensing is performed. 34% accuracy improvement compared to the DMVR is demonstrated.
Highlights
Artificial intelligence (AI) is considered as a key element for the on-going industrial revolution and has rapidly developed in recent years
Fiber Bragg gratings (FBGs) have been extensively applied in optical sensing systems
It is estimated that the proposed scheme can obtain a similar accuracy level with the sampling rate about an order less than the Direct maximum value readout (DMVR) method
Summary
Artificial intelligence (AI) is considered as a key element for the on-going industrial revolution and has rapidly developed in recent years. Various different architectures have been proposed to improve the resolution and speed of the interrogation systems by estimating the wavelength shifts through different measurable parameters, such as power [4,5], frequency [6,7], and time [8,9,10] These parameters can be quickly and accurately measured with mature electronic devices; improving the sensing performance. A cost-effective and computationally-efficient peak detection scheme is proposed, employing both filtering and dynamic local peak estimation techniques This scheme is less sensitive to noise and offers finer peak detection resolution, with fewer crucial requirements for high-performance electronic devices. Further analyses and detailed illustrations of the works are provided
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