Abstract
Random fiber gratings (RFGs) have shown great potential applications in fiber sensing and random fiber lasers. However, a quantitative relationship between the degree of randomness of the RFG and its spectral response has never been analyzed. In this paper, two RFGs with different degrees of randomness are first characterized experimentally by optical frequency domain reflectometry (OFDR). Experimental results show that the high degree of randomness leads to low backscattering strength of the grating and strong strength fluctuations in the spatial domain. The local spectral response of the grating exhibits multiple peaks and a large peak wavelength variation range when its degree of randomness is high. The linewidth of its fine spectrum structures shows scaling behavior with the grating length. In order to find a quantitative relationship between the degree of randomness and spectrum property of RFG, entropy was introduced to describe the degree of randomness induced by period variation of the sub-grating. Simulation results showed that the average reflectivity of the RFG in dB scale decreased linearly with increased sub-grating entropy, when the measured wavelength range was smaller than the peak wavelength variation range of the sub-grating. The peak reflectivity of the RFG was determined by (where is the coupling coefficient, is the grating length, is period variation range of the sub-grating) rather than when is larger than 8 nm in the spatial domain. The experimental results agree well with the simulation results, which helps to optimize the RFG manufacturing processes for future applications in random fiber lasers and sensors.
Highlights
Over the past few years, random fiber gratings (RFGs) have drawn a great deal of interest in the field of random fiber lasers and optical fiber sensing [1,2,3,4,5]
We find a linear relationship between the sub-grating’s entropy and the average reflectivity of the RFG in dB scale
The experimental results agreed well with the simulation results, which provide the quantitative relationship between the degree of randomness and the spectral property of the RFG that is important for the application of RFGs
Summary
Over the past few years, random fiber gratings (RFGs) have drawn a great deal of interest in the field of random fiber lasers and optical fiber sensing [1,2,3,4,5]. Compared to the distributed feedback from Rayleigh scattering, the enhanced random reflections from an RFG could tolerate environmental perturbations and reduce resonating modes in Brillouin random fiber lasers, leading to reduced lasing thresholds and low intensity and frequency noises [13,14]. Based on the random fiber laser, a highly sensitive ultrasound sensor was realized where an RFG provided distributed random feedback as well as acting as the ultrasound sensing head [15,16]. Two RFGs with different degrees of randomness resulting from different sub-gratings period variation ranges were characterized by the OFDR technique. This characterization provided a qualitative description of the relationship between the degree of randomness and the performance of the RFG. The experimental results agreed well with the simulation results, which provide the quantitative relationship between the degree of randomness and the spectral property of the RFG that is important for the application of RFGs
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