Discrimination between strain and temperature effects of a single fiber Bragg grating sensor using sidelobe power

A fiber Bragg grating (FBG) is one of the most common and widely used fiber optic sensors. One main issue when using a FBG-based sensor is that it is simultaneously sensitive to both the strain and the temperature, and compensation for the temperature and strain effects is necessary to measure these parameters. The available compensation techniques mean that the interrogation of FBG sensor systems is complex and make sensor networks bulky by increasing the number of sensors. Several of these compensation techniques are not feasible in in situ applications. In this paper, we propose a method for discriminating between the strain and the temperature by measuring the change in the single Bragg wavelength. Our proposed technique is based on measuring the sidelobe power, which appears adjacent to the main Bragg peak due to the strength of the interference between the forward and backward propagating waves of the Bragg grating sensor. We demonstrate by experiments that the proposed methodology can discriminate between the strain and temperature effects, making the interrogation system less complex with a very reasonable hardware cost.A fiber Bragg grating (FBG) is one of the most common and widely used fiber optic sensors. One main issue when using a FBG-based sensor is that it is simultaneously sensitive to both the strain and the temperature, and compensation for the temperature and strain effects is necessary to measure these parameters. The available compensation techniques mean that the interrogation of FBG sensor systems is complex and make sensor networks bulky by increasing the number of sensors. Several of these compensation techniques are not feasible in in situ applications. In this paper, we propose a method for discriminating between the strain and the temperature by measuring the change in the single Bragg wavelength. Our proposed technique is based on measuring the sidelobe power, which appears adjacent to the main Bragg peak due to the strength of the interference between the forward and backward propagating waves of the Bragg grating sensor. We demonstrate by experiments that the proposed methodology can discriminate ...