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Improved multi-channel interferometric fiber-optic sensor demodulation based on the Goertzel algorithm

Jianxiang Zhang, Wenzhu Huang, Wentao Zhang, Fang Li

2022Optics Express20 citationsDOIOpen Access PDF

Abstract

In a multi-channel interferometric fiber-optic sensor system using space-division multiplexing (SDM) and phase-generated-carrier (PGC) demodulation, the phase delay and phase modulation depth fluctuation of each channel will affect the amplitude consistency and harmonic distortion of the demodulation results. In this paper, an improved demodulation scheme based on the Goertzel algorithm is proposed to calculate the multi-channel phase delay and phase modulation depth and to compensate for their fluctuations simultaneously. First, the carrier's 1 st to 6 th harmonic amplitudes in the interference fringe are extracted using the Goertzel algorithm. Then, the phase delay is calculated using the real and imaginary components of the 1 st harmonic amplitude. The phase modulation depth is calculated with a combinatorial operation of the 1 st to 6 th harmonic amplitudes. In addition, a reference channel is introduced to implement phase delay and modulation depth feedback control. The experimental results demonstrate that the improved scheme can effectively suppress the harmonic distortion and improve the amplitude consistency of multi-channel interferometric fiber-optic sensors with low resource consumption.

Topics & Concepts

DemodulationInterference (communication)Distortion (music)Phase modulationInterferometryOpticsModulation (music)Phase (matter)HarmonicAmplitude modulationTotal harmonic distortionComputer scienceGroup delay and phase delayPhysicsAmplitude distortionPhase distortionElectronic engineeringAmplitudeChannel (broadcasting)Frequency modulationMultiplexingSynchronization (alternating current)Continuous phase modulationConsistency (knowledge bases)Phase noiseHarmonic analysisAdjacent-channel interferenceAdvanced Fiber Optic SensorsOptical measurement and interference techniquesOptical Coherence Tomography Applications